Takes of Marine Mammals Incidental to Specified Activities; Taking Marine Mammals Incidental to a Marine Geophysical Survey in the Northeast Pacific Ocean, 29090-29133 [2021-11375]
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Federal Register / Vol. 86, No. 102 / Friday, May 28, 2021 / Notices
DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric
Administration
[RTID 0648–XA144]
Takes of Marine Mammals Incidental to
Specified Activities; Taking Marine
Mammals Incidental to a Marine
Geophysical Survey in the Northeast
Pacific Ocean
National Marine Fisheries
Service (NMFS), National Oceanic and
Atmospheric Administration (NOAA),
Commerce.
ACTION: Notice; issuance of an incidental
harassment authorization.
AGENCY:
In accordance with the
regulations implementing the Marine
Mammal Protection Act (MMPA) as
amended, notification is hereby given
that NMFS has issued an incidental
harassment authorization (IHA) to
Lamont-Doherty Earth Observatory of
Columbia University (L–DEO) to
incidentally harass, by Level A and
Level B harassment, marine mammals
during a marine geophysical survey in
the northeast Pacific Ocean.
DATES: This Authorization is effective
from May 19, 2021 through May 18,
2022.
SUMMARY:
FOR FURTHER INFORMATION CONTACT:
Amy Fowler, Office of Protected
Resources, NMFS, (301) 427–8401.
Electronic copies of the application and
supporting documents, as well as a list
of the references cited in this document,
may be obtained online at: https://
www.fisheries.noaa.gov/permit/
incidental-take-authorizations-undermarine-mammal-protection-act. In case
of problems accessing these documents,
please call the contact listed above.
SUPPLEMENTARY INFORMATION:
Background
The MMPA prohibits the ‘‘take’’ of
marine mammals, with certain
exceptions. Sections 101(a)(5)(A) and
(D) of the MMPA (16 U.S.C. 1361 et
seq.) direct the Secretary of Commerce
(as delegated to NMFS) to allow, upon
request, the incidental, but not
intentional, taking of small numbers of
marine mammals by U.S. citizens who
engage in a specified activity (other than
commercial fishing) within a specified
geographical region if certain findings
are made and either regulations are
issued or, if the taking is limited to
harassment, a notice of a proposed
incidental take authorization may be
provided to the public for review.
Authorization for incidental takings
shall be granted if NMFS finds that the
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taking will have a negligible impact on
the species or stock(s) and will not have
an unmitigable adverse impact on the
availability of the species or stock(s) for
taking for subsistence uses (where
relevant). Further, NMFS must prescribe
the permissible methods of taking and
other ‘‘means of effecting the least
practicable adverse impact’’ on the
affected species or stocks and their
habitat, paying particular attention to
rookeries, mating grounds, and areas of
similar significance, and on the
availability of the species or stocks for
taking for certain subsistence uses
(referred to in shorthand as
‘‘mitigation’’); and requirements
pertaining to the mitigation, monitoring
and reporting of the takings are set forth.
Summary of Request
On November 8, 2019, NMFS received
a request from L–DEO for an IHA to take
marine mammals incidental to a marine
geophysical survey of the Cascadia
Subduction Zone off the coasts of
Washington, Oregon, and British
Columbia, Canada. The application was
deemed adequate and complete on
March 6, 2020. L–DEO’s request is for
take of small numbers of 31 species of
marine mammals by Level A and Level
B harassment. NMFS published a notice
of proposed IHA for public review and
comment on April 7, 2020 (85 FR
19580). On May 29, 2020, L–DEO
informed NMFS that the project had
been delayed by one year and would
begin in June 2021.
Description of Proposed Activity
Overview
Researchers from L–DEO, Woods Hole
Oceanographic Institution (WHOI), and
the University of Texas at Austin
Institute of Geophysics (UTIG), with
funding from the National Science
Foundation (NSF), and in collaboration
with researchers from Dalhousie
University and Simon Fraser University
(SFU) plan to conduct a high-energy
seismic survey from the Research Vessel
(R/V) Marcus G Langseth (Langseth) in
the northeast Pacific Ocean beginning in
June 2021. The seismic survey will be
conducted at the Cascadia Subduction
Zone off the coasts of Oregon,
Washington, and British Columbia,
Canada. The proposed two-dimensional
(2–D) seismic survey will occur within
the Exclusive Economic Zones (EEZs) of
Canada and the United States, including
U.S. state waters and Canadian
territorial waters. The survey will use a
36-airgun towed array with a total
discharge volume of ∼6,600 cubic inches
(in3) as an acoustic source, acquiring
return signals using both a towed
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streamer as well ocean bottom
seismometers (OBSs) and ocean bottom
nodes (OBNs).
The planned study will use 2–D
seismic surveying and OBSs and OBNs
to investigate the Cascadia Subduction
Zone and provide data necessary to
illuminate the depth, geometry, and
physical properties of the seismogenic
portion and updip extent of the
megathrust zone between the
subducting Juan de Fuca plate and the
overlying accretionary wedge/North
American plate. These data will provide
essential constraints for earthquake and
tsunami hazard assessment in this
heavily populated region of the Pacific
Northwest. The primary objectives of
the survey planned by researchers from
L–DEO, WHOI, and UTIG is to
characterize: (1) The deformation and
topography of the incoming plate; (2)
the depth, topography, and reflectivity
of the megathrust; (3) sediment
properties and amount of sediment
subduction; and (4) the structure and
evolution of the accretionary wedge,
including geometry and reflectivity of
fault networks, and how these
properties vary along strike, spanning
the full length of the margin and down
dip across what may be the full width
of the Cascadia Subduction Zone.
Dates and Duration
The survey is expected to last for 40
days, with 37 days of seismic
operations, 2 days of equipment
deployment, and 1 day of transit. R/V
Langseth will likely leave out of and
return to port in Newport, Oregon,
during June–July 2021.
Specific Geographic Region
The survey will occur within ∼42–51°
N, ∼124–130° W. Planned survey
tracklines are shown in Figure 1. Some
deviation in actual track lines, including
the order of survey operations, could be
necessary for reasons such as science
drivers, poor data quality, inclement
weather, or mechanical issues with the
research vessel and/or equipment. The
survey will occur within the EEZs of the
United States and Canada, as well as in
U.S. state waters and Canadian
territorial waters, ranging in depth 60–
4400 meters (m). A maximum of 6,540
kilometers (km) of transect lines will be
surveyed. Most of the survey (69
percent) will occur in deep water
(>1,000 m), 28 percent will occur in
intermediate water (100–1,000 m deep),
and 3 percent will take place in shallow
water <100 m deep. Approximately 3.6
percent of the transect lines (234 km)
will be undertaken in Canadian
territorial waters (from 0–12 nautical
miles (22.2 km) from shore), with most
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effort in intermediate water depths.
NMFS cannot authorize the incidental
take of marine mammals in the
territorial seas of foreign nations, as the
MMPA does not apply in those waters.
However, NMFS has still calculated the
level of incidental take in the entire
activity area (including Canadian
territorial waters) as part of the analysis
supporting our determination under the
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MMPA that the activity will have a
negligible impact on the affected
species.
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Figure 1. Location of the Planned Seismic Survey in the Northeast Pacific Ocean
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Detailed Description of Specific Activity
The procedures to be used for the
planned survey will be similar to those
used during previous seismic surveys by
L–DEO and will use conventional
seismic methodology. The surveys will
involve one source vessel, R/V
Langseth. R/V Langseth will deploy an
array of 36 airguns as an energy source
with a total volume of ∼6,600 in3. The
array consists of 20 Bolt 1500LL airguns
with volumes of 180 to 360 in3 and 16
Bolt 1900LLX airguns with volumes of
40 to 120 in3. The airgun array
configuration is illustrated in Figure 2–
11 of NSF and USGS’s Programmatic
Environmental Impact Statement (PEIS;
NSF–USGS, 2011). The vessel speed
during seismic operations will be
approximately 4.2 knots (∼7.8 km/hour)
during the survey and the airgun array
will be towed at a depth of 12 m. The
receiving system will consist of one 15km long hydrophone streamer, OBSs,
and OBNs. R/V Oceanus, which is
owned by NSF and operated by Oregon
State University, will be used to deploy
the OBSs and OBNs. As the airguns are
towed along the survey lines, the
hydrophone streamer will transfer the
data to the on-board processing system,
and the OBSs and OBNs will receive
and store the returning acoustic signals
internally for later analysis.
Long 15-km-offset multichannel
seismic (MCS) data will be acquired
along numerous 2–D profiles oriented
perpendicular to the margin and located
to provide coverage in areas inferred to
be rupture patches during past
earthquakes and their boundary zones.
The survey will also include several
strike lines including one continuous
line along the continental shelf centered
roughly over gravity-inferred fore-arc
basins to investigate possible
segmentation near the down-dip limit of
the seismogenic zone. The margin
normal lines will extend ∼50 km
seaward of the deformation front to
image the region of subduction bend
faulting in the incoming oceanic plate,
and landward of the deformation front
to as close to the shoreline as can be
safely maneuvered. L–DEO plans to
survey the southern transects off Oregon
first, followed by the profiles off
Washington and Vancouver Island,
British Columbia.
The OBSs will consist of short-period
multi-component OBSs from the Ocean
Bottom Seismometer Instrument Center
(OBSIC) and a large-N array of OBNs
from a commercial provider to record
shots along ∼11 MCS marginperpendicular profiles. OBSs will be
deployed at 10-km spacing along ∼10
profiles from Vancouver Island to
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Oregon, and OBNs will be deployed at
a 500-m spacing along a portion of three
profiles off Oregon. Two OBS
deployments will occur with a total of
115 instrumented locations. 60 OBSs
will be deployed to instrument seven
profiles off Oregon, followed by a
second deployment of 55 OBSs to
instrument four profiles off Washington
and Vancouver Island. The first
deployment off Oregon will occur prior
to the start of the planned survey, after
which R/V Langseth will acquire data in
the southern portion of the study area.
R/V Oceanus will start recovering the
OBSs from deployment 1, and then redeploy 55 OBSs off Washington and
Vancouver Island, so that R/V Langseth
can acquire data in the northern portion
of the survey area. The OBSs have a
height and diameter of ∼1 m, and an ∼80
kilogram (kg) anchor. To retrieve OBSs,
an acoustic release transponder (pinger)
is used to interrogate the instrument at
a frequency of 8–11 kilohertz (kHz), and
a response is received at a frequency of
11.5–13 kHz. The burn-wire release
assembly is then activated, and the
instrument is released to float to the
surface from the anchor, which is not
retrieved.
A total of 350 OBNs will be deployed:
179 nodes along one transect off
northern Oregon, 107 nodes along a
second transect off central Oregon, and
64 nodes along a third transect off
southern Oregon. The nodes are not
connected to each other; each node is
independent from each other, and there
are no cables attached to them. Each
node has internal batteries; all data is
recorded and stored internally. The
nodes weigh 21 kg in air (9.5 kg in
water). As the OBNs are small (330
millimeters (mm) × 289 mm × 115 mm),
compact, not buoyant, and lack an
anchor-release mechanism, they cannot
be deployed by free-fall as with the
OBSs. The nodes will be deployed and
retrieved using a remotely operated
vehicle (ROV); the ROV will be
deployed from R/V Oceanus. OBNs will
be deployed approximately 17 days
prior to the start of the R/V Langseth
cruise. The ROV will be fitted with a
skid with capacity for 32 units, lowered
to the seafloor, and towed at a speed of
0.6 knots at 5–10 m above the seafloor
between deployment sites. After the 32
units are deployed, the ROV will be
retrieved, the skid will be reloaded with
another 32 units, and sent back to the
seafloor for deployment, and so on. The
ROV will recover the nodes 3 days after
the completion of the R/V Langseth
cruise. The nodes will be recovered one
by one by a suction mechanism. Take of
marine mammals is not expected to
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occur incidental to L–DEO’s use of
OBSs and OBNs.
In addition to the operations of the
airgun array, a multibeam echosounder
(MBES), a sub-bottom profiler (SBP),
and an Acoustic Doppler Current
Profiler (ADCP) will be operated from R/
V Langseth continuously during the
seismic surveys, but not during transit
to and from the survey area. All planned
geophysical data acquisition activities
will be conducted by L–DEO with onboard assistance by the scientists who
have planned the studies. The vessel
will be self-contained, and the crew will
live aboard the vessel. Take of marine
mammals is not expected to occur
incidental to use of the MBES, SBP, or
ADCP because they will be operated
only during seismic acquisition, and it
is assumed that, during simultaneous
operations of the airgun array and the
other sources, any marine mammals
close enough to be affected by the
MBES, SBP, and ADCP would already
be affected by the airguns. However,
whether or not the airguns are operating
simultaneously with the other sources,
given their characteristics (e.g., narrow
downward-directed beam), marine
mammals would experience no more
than one or two brief ping exposures, if
any exposure were to occur. Mitigation,
monitoring, and reporting measures are
described in detail later in this
document (please see Mitigation and
Monitoring and Reporting).
Comments and Responses
A notice of NMFS’s proposal to issue
an IHA to L–DEO was published in the
Federal Register on April 7, 2020 (85 FR
19580). During the public comment
period, NMFS received comment letters
from the Marine Mammal Commission
(Commission), Ecojustice (on behalf of
the David Suzuki Foundation, Georgia
Strait Alliance, Raincoast Conservation
Foundation, and World Wildlife Fund
Canada), Deep Green Wilderness, and a
group of environmental nongovernmental organizations (ENGOs)
including the Center for Biological
Diversity (CBD), Natural Resources
Defense Council, Orca Relief Citizens
Alliance, Friends of the San Juans,
Whale and Dolphin Conservation,
Friends of the Earth, Oceana, and Orca
Conservancy. NMFS has posted the
comments online at: https://
www.fisheries.noaa.gov/national/
marine-mammal-protection/incidentaltake-authorizations-research-and-otheractivities. Please see the letters for full
details and rationale. A summary of the
comments and our responses are
provided here.
Comment 1: Ecojustice requested
NMFS deny L–DEO’s request for an IHA
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because the survey will affect Southern
Resident killer whale critical habitat
(e.g., Swiftsure and La Perouse Banks)
designated in Canada under the
Canadian Species at Risk Act (SARA).
The commenter asserts that noise
production in these areas will both
harm or harass individuals and
constitute destruction of a portion of
Canadian critical habitat.
Response: This comment is beyond
the scope of NMFS’ proposed action,
which is to authorize take of marine
mammals incidental to the proposed
survey. NMFS does not allow or deny
the survey itself, and NMFS’ action of
authorizing incidental take does not
cause effects to critical habitat (in
Canada or the U.S.). However, as part of
their consultation with Canada’s
Department of Fisheries and Oceans
(DFO) under Canada’s SARA, L–DEO
has removed all survey tracklines with
associated ensonified areas that overlap
with Canadian designated killer whale
critical habitat at Swiftsure and La
Perouse Bank (see Figure 1); therefore,
the Canadian critical habitat will not be
subject to destruction.
Comment 2: Ecojustice asserts that the
critically endangered status of Southern
Resident killer whales means there is no
acceptable level of take for the species.
Similarly, the ENGOs recommended
NMFS not issue any take authorization
until it has effectively reduced the take
of Southern Resident killer whales to
zero, citing concern that behavioral
disturbance can interfere with
reproduction and survival due to lost
foraging time.
Response: NMFS disagrees that there
is no acceptable level of take for
Southern Resident killer whales, and
the commenters have not demonstrated
that any level of taking of Southern
Resident killer whales would result in
greater than a negligible impact on the
stock. However, we do agree that
additional effort to reduce impacts to
Southern Resident killer whales is
warranted to minimize to the extent
practicable the amount of taking as well
as the impact of taking that is
authorized. In addition to removing
tracklines within Canadian designated
Southern Resident killer whale critical
habitat at Swiftsure and La Perouse
Banks (discussed above), L–DEO has
removed and modified tracklines
between Tillamook Head, Oregon and
Barkley Sound, British Columbia, the
area in which Southern Resident killer
whales have the highest estimated
densities (U.S. Navy 2019) and high-use
foraging areas (NMFS 2019). The effect
of these modifications to the survey
plan is that, between these landmarks,
the estimated Level B harassment
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ensonified area will not extend into
water shallower than the 100-m depth
contour. As a result, the total estimated
take of Southern Resident killer whales
has been reduced from 43 takes by Level
B harassment in the proposed IHA (with
an additional two takes within Canadian
territorial waters, outside NMFS’
jurisdiction) to 10 takes by Level B
harassment (plus one take by Level B
harassment within Canadian territorial
waters), which is less than the
population of any pod in the Southern
Resident stock. This estimated take
represents either 10 individual Southern
Resident killer whales taken by Level B
harassment once over the course of the
survey, or a smaller number of
individuals taken multiple times (e.g., a
single matriline of five animals taken by
Level B harassment on two separate
days). By avoiding surveying in the
areas with highest expected Southern
Resident killer whale presence and
foraging rates, the likelihood of survey
activities resulting in interference in
feeding and migration that could result
in lost feeding opportunities or
necessitate additional energy
expenditure to find other good foraging
opportunities or migration routes is
greatly reduced. Procedural mitigations
that avoid the likelihood of injury, such
as shutdown measures, also further
reduce the likelihood of more severe
behavioral responses.
Comment 3: The ENGOs assert that
NMFS inadequately considered the
impacts of the proposed action on prey
availability for Southern Resident killer
whales, citing studies showing
responses of fish to sound from seismic
surveys. The ENGOs also state that
NMFS must also consider the fitness of
salmon being indirectly affected by the
survey’s impacts on herring, a key prey
species for Pacific salmon.
Response: NMFS disagrees with the
suggestion that we ignored effects to
prey species. In fact, we considered
relevant literature (including that cited
by the ENGOs) in finding that the most
likely impact of survey activity to prey
species such as fish and invertebrates
would be temporary avoidance of an
area, with a rapid return to pre-survey
distribution and behavior, and minimal
impacts to recruitment or survival
anticipated. While there is a lack of
specific scientific information to allow
an assessment of the duration, intensity,
or distribution of effects to prey in
specific locations at specific times and
in response to specific surveys, NMFS’
review of the available information does
not indicate that such effects could be
significant enough to impact marine
mammal prey to the extent that marine
mammal fitness would be affected. We
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agree that seismic surveys could affect
certain marine mammal prey species,
and addressed these potential effects, as
well as the potential for those effects to
impact marine mammal populations, in
our notice of proposed IHA (85 FR
19580; April 7, 2020). As stated in the
notice of proposed IHA, our review of
the available information and the
specific nature of the activities
considered herein suggest that L–DEO’s
proposed survey activities are not likely
to have more than short-term adverse
effects on any prey habitat or
populations of prey species. Further,
any impacts to prey species are not
expected to result in significant or longterm consequences for individual
marine mammals, or to contribute to
adverse impacts on their populations.
For additional information on the
effects of L–DEO’s proposed survey on
salmon species present in the survey
area, we refer the reader to the
Biological Opinion issued by the NMFS
Office of Protected Resources,
Interagency Cooperation Division
(available at https://www.fisheries.
noaa.gov/national/marine-mammalprotection/incidental-takeauthorizations-research-and-otheractivities). In summary, fish react to
sounds which are especially strong and/
or intermittent low-frequency sounds,
and behavioral responses such as flight
or avoidance are the most likely effects.
However, the reaction of fish to airguns
depends on the physiological state of
the fish, past exposures, motivation
(e.g., feeding, spawning, migration), and
other environmental factors. While we
agree that some studies have
demonstrated that airgun sounds might
affect the distribution and behavior of
some fishes, potentially impacting
foraging opportunities or increasing
energetic costs (e.g., Fewtrell and
McCauley, 2012; Pearson et al., 1992;
Skalski et al., 1992; Santulli et al., 1999;
Paxton et al., 2017), our review shows
that the weight of evidence indicates
either no or only a slight reaction to
noise (e.g., Miller and Cripps, 2013;
Dalen and Knutsen, 1987; Pena et al.,
2013; Chapman and Hawkins, 1969;
Wardle et al., 2001; Sara et al., 2007;
Jorgenson and Gyselman, 2009; Blaxter
et al., 1981; Cott et al., 2012; Boeger et
al., 2006), and that, most commonly,
while there may be impacts to fish as a
result of noise from nearby airguns, any
effects will be temporary. For example,
investigators reported significant, shortterm declines in commercial fishing
catch rate of gadid fishes during and for
up to five days after seismic survey
operations, but the catch rate
subsequently returned to normal (Engas
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et al., 1996; Engas and Lokkeborg,
2002). Other studies have reported
similar findings (e.g., Hassel et al.,
2004). Skalski et al. (1992) also found a
reduction in catch rates—for rockfish
(Sebastes spp.) in response to controlled
airgun exposure—but suggested that the
mechanism underlying the decline was
not dispersal but rather decreased
responsiveness to baited hooks
associated with an alarm behavioral
response. A companion study showed
that alarm and startle responses were
not sustained following the removal of
the sound source (Pearson et al., 1992).
Therefore, Skalski et al. (1992)
suggested that the effects on fish
abundance may be transitory, primarily
occurring during the sound exposure
itself. In some cases, effects on catch
rates are variable within a study, which
may be more broadly representative of
temporary displacement of fish in
response to airgun noise (i.e., catch rates
may increase in some locations and
decrease in others) than any long-term
damage to the fish themselves (Streever
et al., 2016).
Sound pressure levels (SPLs) of
sufficient strength have been known to
cause injury to fish and fish mortality
and, in some studies, fish auditory
systems have been damaged by airgun
noise (McCauley et al., 2003; Popper et
al., 2005; Song et al., 2008). However, in
most fish species, hair cells in the ear
continuously regenerate and loss of
auditory function likely is restored
when damaged cells are replaced with
new cells. Halvorsen et al. (2012)
showed that a temporary threshold shift
(TTS) of 4–6 decibel (dB) was
recoverable within 24 hours for one
species. Impacts would be most severe
when the individual fish is close to the
source and when the duration of
exposure is long—both of which are
conditions unlikely to occur for surveys
that are necessarily transient in any
given location and likely result in brief,
infrequent noise exposure to prey
species in any given area. For these
surveys, the sound source is constantly
moving, and most fish would likely
avoid the sound source prior to
receiving sound of sufficient intensity to
cause physiological or anatomical
damage. In addition, ramp-up may
allow certain fish species the
opportunity to move further away from
the sound source.
NMFS considered the research
referenced by the ENGOs and disagrees
with the assertion that ‘‘[NMFS]
irrationally discounts those impacts,’’ as
well as with the commenters’
interpretation of the literature. A recent
comprehensive review (Carroll et al.,
2017) found that results are mixed as to
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the effects of airgun noise on the prey
of marine mammals. While some studies
suggest a change in prey distribution
and/or a reduction in prey abundance
following the use of seismic airguns,
others suggest no effects or even
positive effects in prey abundance.
Regarding Paxton et al. (2017), which
describes findings related to the effects
of a 2014 seismic survey on a reef off of
North Carolina, while the study did
show a 78 percent decrease in observed
nighttime abundance for certain species,
it is important to note that the evening
hours during which the decline in fish
habitat use was recorded (via video
recording) occurred on the same day
that the seismic survey passed, and no
subsequent data is presented to support
an inference that the response was longlasting. Additionally, given that the
finding is based on video images, the
lack of recorded fish presence does not
support a conclusion that the fish
actually moved away from the site or
suffered any serious impairment
because fish may remain present yet not
be recorded on video. In summary, this
particular study corroborates prior
studies demonstrating a startle response
or short-term displacement.
The Carroll et al. (2017) review article
concluded that, while laboratory results
provide scientific evidence for highintensity and low-frequency soundinduced physical trauma and other
negative effects on some fish and
invertebrates, the sound exposure
scenarios in some cases are not realistic
to those encountered by marine
organisms during routine seismic
operations. The review finds that there
has been no evidence of reduced catch
or abundance following seismic
activities for invertebrates, and that
there is conflicting evidence for fish
with catch observed to increase,
decrease, or remain the same. Further,
where there is evidence for decreased
catch rates in response to airgun noise,
these findings provide no information
about the underlying biological cause of
catch rate reduction (Carroll et al.,
2017).
In summary, the scientific literature
demonstrates that impacts of seismic
surveys on marine mammal prey species
will likely be limited to behavioral
responses, the majority of prey species
will be capable of moving out of the area
during surveys, a rapid return to normal
recruitment, distribution, and behavior
for prey species is anticipated, and,
overall, impacts to prey species, if any,
will be minor and temporary. Prey
species exposed to sound might move
away from the sound source, experience
TTS, experience masking of biologically
relevant sounds, or show no obvious
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direct effects. Mortality from
decompression injuries is possible in
close proximity to a sound, but only
limited data on mortality in response to
airgun noise exposure are available
(Hawkins et al., 2014). The most likely
impacts for most prey species in a given
survey area would be temporary
avoidance of the area. Surveys using
towed airgun arrays move through an
area relatively quickly, limiting
exposure to multiple impulsive sounds.
In all cases, sound levels would return
to ambient once a survey moves out of
the area or ends and the noise source is
shut down and, when exposure to
sound ends, behavioral and/or
physiological responses are expected to
end relatively quickly (McCauley et al.,
2000b). The duration of fish avoidance
of a given area after survey effort stops
is unknown, but a rapid return to
normal recruitment, distribution, and
behavior is anticipated. While the
potential for disruption of spawning
aggregations or schools of important
prey species can be meaningful on a
local scale, the mobile and temporary
nature of most surveys and the
likelihood of temporary avoidance
behavior suggest that impacts would be
minor.
NMFS believes that no evidence is
presented to contradict our conclusions
regarding likely impacts to marine
mammals due to effects on prey species,
i.e., that impacts of the specified activity
are not likely to have more than shortterm adverse effects on any prey habitat
or populations of prey species, and that
any effects that do occur are not
expected to result in significant or longterm consequences for individual
marine mammals, or to contribute to
adverse impacts on their populations.
Finally, we note that the National
Science Foundation (NSF) is funding a
study run by Oregon State University to
assess the effects of L–DEO’s survey
activities on rockfish, Dungeness crab,
and longnose skate. While the species
chosen for this study do not represent
important prey species for Southern
Resident killer whales, which were the
primary concern of the ENGOs, the
study will provide important
information on the effects of seismic
surveys on nearshore species.
Comment 4: The ENGOs commented
that in making the negligible impact
determination, NMFS underestimated
the potential harm to the relevant stocks
and distinct population segments (DPSs)
of humpback whales, adding that the
stock definitions for humpback whales
are outdated and should match the DPSs
as defined under the Endangered
Species Act. The ENGOs assert that the
takes proposed by NMFS are more than
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negligible for the California/Oregon/
Washington stock because the annual
rate of serious injury and mortality (40.2
humpback whales per year) exceeds the
potential biological removal (PBR; 33.4
humpbacks per year). Additionally, for
both humpback and blue whales, the
ENGOs assert that take by Level A
harassment in the form of permanent
hearing impairment amounts to serious
injury, therefore the negligible impact
determination overly relies on the
assumption that there will be no serious
injury or mortality from the seismic
survey.
Response: First, NMFS agrees that the
alignment of MMPA stocks and
Endangered Species Act (ESA) DPSs of
humpback whales is important, and is
actively working on rectifying the
differences between stocks and DPSs.
However, this issue is outside the scope
of the action considered here. NMFS
disagrees with the ENGOs’ assertion that
the authorized take of humpback or blue
whales (or any species of marine
mammal) by Level A harassment
constitutes serious injury or has any
relation to the PBR of the stock. PBR is
defined in the MMPA (16 U.S.C.
1362(20)) as ‘‘the maximum number of
animals, not including natural
mortalities, that may be removed from a
marine mammal stock while allowing
that stock to reach or maintain its
optimum sustainable population’’ and is
a measure to be considered when
evaluating the effects of mortality or
serious injury on a marine mammal
species or stock. There is no evidence
that permanent threshold shift (PTS)
can lead to mortality such that it should
be considered ‘‘serious injury’’ or
‘‘removing’’ an individual from a stock.
Therefore, it is not appropriate to use
the PBR metric to directly evaluate the
effects of Level A harassment (e.g., PTS)
on a stock in the manner suggested by
the ENGOs. Given the short duration of
exposure, only low levels of hearing
impairment are likely to occur, and
would not affect the fitness of
individual marine mammals or
populations.
As noted above, the PBR metric
concerns levels of allowable removals
from a population. Therefore, the PBR
metric is not directly related to an
assessment of negligible impact for this
specified activity, which does not
involve any expected potential for
serious injury or mortality. PBR is not
an appropriate metric with which to
evaluate Level B harassment. However,
we appropriately do consider levels of
ongoing anthropogenic mortality from
other sources, such as vessel strike, in
relation to calculated PBR values as an
important contextual factor in our
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negligible impact analysis, but a direct
comparison of takes by harassment to
the PBR value is not germane. While it
is conceptually possible to link
disturbance to potential fitness impacts
to individuals over time (e.g.,
population consequences of
disturbance), we have no evidence that
is the case here and the take authorized
here is not expected to affect the
reproduction or survivorship of any
individual marine mammals.
Comment 5: The ENGOs assert that
the negligible impact determination also
relies on an expectation that marine
mammals would be likely to move away
from the sound source, which
contradicts other statements from the
notice of proposed IHA that avoidance
is not assumed to occur because ‘‘the
extent to which marine mammals would
move away from the sound source is
difficult to quantify and is therefore not
accounted for in the take estimates.’’
The commenters go on to state that
animals avoiding the sound source still
provokes an adverse behavioral reaction
which displaces the animal from
preferred habitat and potentially toward
predators or shore with a risk of
stranding.
Response: NMFS does not rely on
avoidance behaviors to make its
negligible impact determination. NMFS
agrees that avoidance of preferred
habitat may temporarily limit optimal
feeding or other biologically important
behaviors. NMFS does not adjust take
estimates based on the assumption that
marine mammals would avoid the area,
as the avoidance itself may constitute
behavioral harassment. However,
avoiding the sound source prevents the
animal from exposure to the highest
source levels, reducing the likelihood of
temporary (Level B harassment) or
permanent hearing impairment (Level A
harassment), and reducing the intensity
and/or duration of the harassment
event. The avoidance is expected to be
temporary, and animals are likely to
return to the area after the survey vessel
has passed through. In consideration of
the likelihood of animals to
independently avoid the sound source,
and the mitigation requirements to shut
down the airgun array if animals do
approach within a certain distance,
NMFS finds that the level of take
expected to result from the survey is
unlikely to have any impact on fitness
or reproduction of individual animals,
let alone populations.
Comment 6: Citing studies suggesting
that blue whales are especially sensitive
to high intensity anthropogenic noise,
such as mid-frequency sonar (e.g.,
Goldbogen et al., 2013), the ENGOs
suggest that NMFS’ consideration of the
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impact of the proposed activities on
blue whales may underestimate the
adverse impacts on the stock.
Response: As discussed in the notice
of proposed IHA, Goldbogen et al.
(2013) found blue whales feeding on
highly concentrated prey in shallow
depths were less likely to respond and
cease foraging than whales feeding on
deep, dispersed prey when exposed to
simulated sonar sources, suggesting that
the benefits of feeding for blue whales
foraging on high-density prey may
outweigh perceived harm from the
acoustic stimulus, such as the seismic
survey. Southall et al. (2019b) observed
that after exposure to simulated and
operational mid-frequency active sonar,
more than 50 percent of blue whales in
deep-diving states responded to the
sonar, while no behavioral response was
observed in shallow-feeding blue
whales. Southall et al. (2019b) noted
that the behavioral responses they
observed were generally brief, of low to
moderate severity, and highly
dependent on exposure context
(behavioral state, source-to-whale
horizontal range, and prey availability).
The proposed survey area does not
represent a major feeding area for blue
whales and any disruption of feeding is
likely to be short-term and of low to
sometimes moderate severity, with no
anticipated effect on reproduction or
survival for individual whales or the
population as a whole.
Comment 7: Deep Green Wilderness
and the ENGOs noted that North Pacific
right whales have been documented
within the survey area, and
recommended NMFS consider the
potential effects of the survey on the
species. Deep Green Wilderness referred
to sightings of a North Pacific right
whale at Swiftsure Bank in 2013, and
the ENGOs noted an account of a
sighting of a North Pacific right whale
off northern Vancouver Island in May
2020.
Response: We thank the organizations
for providing information on recent
observations of North Pacific right
whales in the survey area. NMFS shares
the commenters’ concern regarding the
status of this endangered species.
Although sightings have been reported
in the survey area, the rate of sightings
is less than one per year and NMFS has
determined the likelihood of the
proposed 37-day survey encountering a
North Pacific right whale is
discountable. However, in the very
unlikely event a North Pacific right
whale is detected during the survey, at
any distance, L–DEO must immediately
shut down the airgun array to prevent
exposure to potentially injurious sound
levels and to minimize the intensity and
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duration of any sound exposure, and
must immediately report the
observation to NMFS and Canada’s DFO
to further inform research on the
distribution of the species.
Comment 8: The ENGOs challenge
NMFS’ preliminary finding that the
proposed take numbers are of no more
than small numbers of marine
mammals. The ENGOs reference a court
decision that they assert supports a
lower ‘‘small numbers’’ threshold, and
highlight certain species for which the
commenters deem the take to be too
high.
Response: The reference to a
supposed take limit of 12 percent for
small numbers comes from a 2003
district court opinion (Natural
Resources Defense Council v. Evans,
279 F. Supp. 2d 1129 (N.D. Cal. 2003)).
However, given the particular
administrative record and
circumstances in that case, including
the fact that our small numbers finding
for the challenged incidental take rule
was based on an invalid regulatory
definition of small numbers, we view
the district court’s opinion regarding 12
percent as dicta. Moreover, since that
time the Ninth Circuit Court of Appeals
has upheld a small numbers finding that
was not based on a quantitative
calculation. Center for Biological
Diversity v. Salazar, 695 F.3d 893 (9th
Cir. 2012). To maintain an interpretation
of small numbers as a proportion of a
species or stock that does not conflate
with negligible impact, we use the
following framework. A plain reading of
‘‘small’’ implies as corollary that there
also could be ‘‘medium’’ or ‘‘large’’
numbers of animals from the species or
stock taken. We therefore use a simple
approach that establishes equal bins
corresponding to small, medium, and
large proportions of the population
abundance.
NMFS’s practice for making small
numbers determinations is to compare
the number of individuals estimated
and authorized to be taken (often using
estimates of total instances of take,
without regard to whether individuals
are exposed more than once) against the
best available abundance estimate for
that species or stock. We note, however,
that although NMFS’s implementing
regulations require applications for
incidental take to include an estimate of
the marine mammals to be taken, there
is nothing in paragraphs (A) or (D) of
section 101(a)(5) that requires NMFS to
quantify or estimate numbers of marine
mammals to be taken for purposes of
evaluating whether the number is small.
(See CBD v. Salazar.) While it can be
challenging to predict the numbers of
individual marine mammals that will be
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taken by an activity (again, many
models calculate instances of take and
are unable to account for repeated
exposures of individuals), in some cases
we are able to generate a reasonable
estimate utilizing a combination of
quantitative tools and qualitative
information. When it is possible to
predict with relative confidence the
number of individual marine mammals
of each species or stock that are likely
to be taken, the small numbers
determination should be based directly
upon whether or not these estimates
exceed one third of the stock
abundance. In other words, consistent
with past practice, when the estimated
number of individual animals taken
(which may or may not be assumed as
equal to the total number of takes,
depending on the available information)
is up to, but not greater than, one third
of the species or stock abundance,
NMFS will determine that the numbers
of marine mammals taken of a species
or stock are small.
Finally, regarding the species
highlighted by the ENGOs with
proposed take above 20 percent of the
stock (Pacific white-sided dolphin,
Risso’s dolphin, pygmy and dwarf
sperm whale, Dall’s porpoise, harbor
porpoise, northern fur seal and harbor
seal), the revised take estimates for all
of the aforementioned stocks aside from
the California/Oregon/Washington stock
of Dall’s porpoise and Northern Oregon/
Washington Coast stock of harbor
porpoise represent under one-third of
the stock. The analysis of these two
stocks is discussed further in the Small
Numbers section of this notice.
Comment 9: The ENGOs further object
to NMFS’ small numbers determination
for the Southern Resident killer whale,
for which NMFS proposed to authorize
take of more than 57 percent of the
stock. Regarding the Southern Resident
killer whale take estimate, the ENGOs
disagree with NMFS’ assumption that
the number of individual Southern
Resident killer whales taken by Level B
harassment will be fewer than the total
estimated instances of take due to the
historical pattern of Southern Resident
killer whales occupying the inland
waters of the Salish Sea during the
summer months. Additionally, because
they travel in pods, the commenters
assert that there is risk of exposure of an
entire pod to airgun blasting, and state
that they are unclear whether such
aggregation has been considered.
Response: The ENGO’s objection to
NMFS’ small numbers threshold was
addressed in the previous response, but
we also note here that using the revised
survey tracklines, the authorized take of
Southern Resident killer whales
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represents only 13.7 percent of the
stock, which falls under NMFS’
threshold for small numbers, even if all
takes represent different individuals
taken by Level B harassment. The
authorized take is less than the size of
any pod of Southern Residents (J, K, or
L pods), and is more likely to represent
a single matriline (typically two to nine
killer whales; Weiss et al., 2020)
exposed to the survey on one or two
days of the survey. NMFS agrees that
the seasonal distribution of Southern
Resident killer whales in recent years
has deviated from the historical pattern
of residency within the Salish Sea (e.g.,
Shields et al., 2018), but note that our
discussion of the distribution of
Southern Resident killer whales was in
the context of the U.S. Navy density
models used to estimate take, which
were created with the assumption that
the entire population was either within
the Salish Sea or outside the Salish Sea
on the outer coast at any given time
(U.S. Navy 2019). Southern Resident
killer whales may be encountered
during the survey along the coast, but
the revised tracklines are expected to
reduce the likelihood of whole pods
being exposed to sound from the
seismic survey by avoiding surveying in
areas of expected high Southern
Resident killer whale occurrence.
Additionally, L–DEO is required to shut
down the airgun array if killer whales
(of any ecotype) are observed at any
distance. Killer whales are highly
visible animals, especially when
traveling as large pods as the ENGOs
suggest, and we expect PSOs will be
able to detect killer whales at sufficient
distances to implement shutdown
procedures to avoid exposing large pods
of killer whales to sounds from the
survey.
Comment 10: The ENGOs commented
that NMFS must include estimated takes
off Canada in making the small numbers
determination, adding that since the
take prohibition applies outside U.S.
waters, the Service must make a small
numbers determination that analyzes all
of the estimated take. The commenters
state that, accordingly, NMFS must
demonstrate compliance with these
standards and may not issue the
authorization without fully analyzing
and authorizing all take contemplated
under this action. The commenters also
state that it is unclear in the small
numbers determination whether the
takes in Canadian waters have been
taken into consideration. The ENGOs
also expressed concern that the small
numbers determination was based on 1
year of activities and did not consider
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the potential renewal of the
authorization.
Response: NMFS has not authorized
any take of marine mammals within the
territorial waters of Canada. An estimate
of take that may occur within Canadian
territorial waters is presented in Table
11, and the take has been considered in
our negligible impact determination as
part of the larger implications of the
survey on the marine mammal
populations and habitat in the survey
area. However, our small numbers
analysis applies only to the take we
have authorized. NMFS has made the
necessary small numbers and negligible
impact determinations for this
authorization.
The ENGOs appear to misunderstand
the context in which a potential renewal
IHA could be issued for this activity, as
well as the requirements for issuing a
renewal IHA. Although renewal IHAs in
general may be issued in appropriate
circumstances for up to another year of
identical or nearly identical activities as
were covered by the initial IHA, this
context is not relevant to the proposed
seismic survey. L–DEO would not
conduct the survey as planned and then
duplicate the survey activities in a
subsequent year. Regardless, NMFS
would not grant a renewal IHA in those
circumstances. However, if the planned
survey were unexpectedly delayed for
another year, NMFS could consider a
request for issuance of a renewal IHA.
In order to do so, NMFS would need to
review all relevant information,
including the status of the affected
species or stocks and any other
pertinent information, such as
information relevant to the small
numbers determination. In short,
potential consideration of a renewal in
this context would necessarily be
associated with the same activity
associated with this IHA, in the event
that it is not conducted during the
period of effectiveness for this IHA, and
would entail a review of all relevant
information to ensure that the findings
NMFS has made in support of issuance
of this initial IHA remain valid.
Comment 11: The ENGOs
recommended NMFS analyze the effects
of L–DEO’s use of a multi-beam
echosounder (MBES) associated with
the survey, noting that the proposed
equipment (the Kongsberg Simrad E122)
is similar to another Kongsberg system
that was closely associated with a 2008
mass stranding of melon-headed whales
in Madagascar. The ENGOs
recommended NMFS apply its take
threshold for continuous noise sources
(120 dB) rather than its threshold for
intermittent sources (160 dB) to the
proposed system and revise its take
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estimates accordingly. Further, NMFS
should not assume, for purposes of
making its negligible impact
determinations, that the severity of
impacts from an airgun array operating
concurrently with such an echosounder
system would be equivalent to that of an
airgun array operating alone.
Response: Although it is correct that
an investigation of the stranding event
referenced by the ENGOs indicated that
use of a high-frequency mapping system
(12-kilohertz (kHz) MBES) was the most
plausible and likely initial behavioral
trigger of the event (with the caveat that
there was no unequivocal and easily
identifiable single cause), the panel also
noted several site- and situation-specific
secondary factors that may have
contributed to the avoidance responses
that led to the eventual entrapment and
mortality of the whales (Southall et al.,
2013). Specifically, regarding survey
patterns prior to the event and in
relation to bathymetry, the vessel
transited in a north-south direction on
the shelf break parallel to the shore,
ensonifying deep-water habitat prior to
operating intermittently in a
concentrated area offshore from the
stranding site. This may have trapped
the animals between the sound source
and the shore, thus driving them
towards the lagoon system. Shorewarddirected surface currents and elevated
chlorophyll levels in the area preceding
the event may also have played a role.
The risk of similar events recurring is
expected to be very low, given the
extensive use of active acoustic systems
used for scientific and navigational
purposes worldwide on a daily basis
and the lack of direct evidence of such
responses previously reported. The only
report of a stranding that may be
associated with this type of sound
source is the one reported in
Madagascar.
NMFS disagrees with the
recommendation that the 120 dB
threshold should be applied to estimate
takes incidental to use of the MBES.
Sound sources can be divided into
broad categories based on various
criteria or for various purposes. As
discussed by Richardson et al. (1995),
source characteristics include strength
of signal amplitude, distribution of
sound frequency and, importantly in
context of these thresholds, variability
over time. With regard to temporal
properties, sounds are generally
considered to be either continuous or
transient (i.e., intermittent). Continuous
sounds, which are produced by the
industrial noise sources for which the
120-dB behavioral harassment threshold
was selected, are simply those whose
sound pressure level remains above
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ambient sound during the observation
period (ANSI, 2005). Intermittent
sounds are defined as sounds with
interrupted levels of low or no sound
(NIOSH, 1998). Simply put, a
continuous noise source produces a
signal that continues over time, while
an intermittent source produces signals
of relatively short duration having an
obvious start and end with predictable
patterns of bursts of sound and silent
periods (i.e., duty cycle) (Richardson
and Malme, 1993). It is this fundamental
temporal distinction that is most
important for categorizing sound types
in terms of their potential to cause a
behavioral response. For example,
Gomez et al. (2016) found a significant
relationship between source type and
marine mammal behavioral response
when sources were split into continuous
(e.g., shipping, icebreaking, drilling)
versus intermittent (e.g., sonar, seismic,
explosives) types. In addition, there
have been various studies noting
differences in responses to intermittent
and continuous sound sources for other
species (e.g., Neo et al., 2014; Radford
et al., 2016; Nichols et al., 2015).
Sound sources may also be
categorized based on their potential to
cause physical damage to auditory
structures and/or result in threshold
shifts. In contrast to the temporal
distinction discussed above, the most
important factor for understanding the
differing potential for these outcomes
across source types is simply whether
the sound is impulsive or not. Impulsive
sounds, such as those produced by
airguns, are defined as sounds which
are typically transient, brief (<1 second
(sec)), broadband, and consist of a high
peak pressure with rapid rise time and
rapid decay (ANSI, 1986; NIOSH, 1998).
These sounds are generally considered
to have greater potential to cause
auditory injury and/or result in
threshold shifts. Non-impulsive sounds
can be broadband, narrowband or tonal,
brief or prolonged, continuous or
intermittent, and typically do not have
the high peak pressure with rapid rise/
decay time that impulsive sounds do
(ANSI, 1995; NIOSH, 1998). Because the
selection of the 160-dB behavioral
threshold was focused largely on airgun
signals, it has historically been
commonly referred to as the ‘‘impulse
noise’’ threshold (including by NMFS).
However, this longstanding confusion in
terminology—i.e., the erroneous
impulsive/continuous dichotomy—
presents a narrow view of the sound
sources to which the thresholds apply,
and inappropriately implies a limitation
in scope of applicability for the 160-dB
behavioral threshold in particular.
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An impulsive sound is by definition
intermittent; however, not all
intermittent sounds are impulsive.
Many sound sources for which it is
generally appropriate to consider the
authorization of incidental take are in
fact either impulsive (and intermittent)
(e.g., impact pile driving) or continuous
(and non-impulsive) (e.g., vibratory pile
driving). However, scientific sonars
(such as MBESs) present a less common
case where the sound produced is
considered intermittent but nonimpulsive. We note also the
commenters’ assertion that the system
produces ‘‘virtually continuous noise
output’’ in support of their
recommendation to apply the
continuous noise threshold to
evaluation of this source. In context of
marine mammal hearing, this would
mean that the interval between signals
would not be discernible to the animal,
rendering them effectively continuous.
However, echosounder signals are
emitted in a similar fashion as
odontocete echolocation click trains.
Research indicates that marine
mammals, in general, have extremely
fine auditory temporal resolution and
can detect each signal separately (e.g.,
Au et al., 1988; Dolphin et al., 1995;
Supin and Popov, 1995; Mooney et al.,
2009), especially for species with
echolocation capabilities. Therefore, it
is highly unlikely that marine mammals
would perceive echosounder signals as
being continuous.
Given the existing paradigm—
dichotomous thresholds appropriate for
generic use in evaluating the potential
for behavioral harassment resulting from
exposure to continuous or intermittent
sound sources—the ENGOs do not
adequately explain why potential
harassment from an intermittent sound
source should be evaluated using a
threshold developed for use with
continuous sound sources. Therefore,
we have not reevaluated L–DEO’s use of
the MBES using the 120 dB continuous
noise threshold.
As discussed in the notice of
proposed IHA, due to the lower source
level of the MBES relative to the R/V
Langseth’s airgun array, sounds from the
MBES are expected to be effectively
subsumed by the sounds from the
airgun array when both sources are
operational. Thus, NMFS has
determined that any marine mammal
potentially exposed to sounds from the
MBES would already have been exposed
to sounds from the airgun array, which
are expected to propagate further in the
water, when both sources are
operational. NMFS has determined that,
given the movement and speed of the
vessel and the intermittent and narrow
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downward-directed nature of the
sounds emitted by the MBES (each ping
emitted by the MBES consists of eight
(in water >1,000 m deep) or four (<1,000
m) successive fan-shaped transmissions,
each ensonifying a sector that extends 1°
fore-aft), the MBES would result in no
more than one or two brief ping
exposures to any individual marine
mammal, if any exposure were to occur.
The ENGOs do not offer any evidence in
support of their contention that
potentially greater impacts than we have
considered should be assumed likely in
relation to use of this source.
Comment 12: The ENGOs comment
that NMFS has failed to implement
‘‘means of effecting the least practicable
impact’’ on marine mammals and assert
that NMFS relies on mitigation
measures that are known to be
ineffective (e.g., real-time detectionbased measures).
Response: Under section 101(a)(5)(D)
of the MMPA, NMFS must set forth the
permissible methods of taking by
harassment pursuant to such activity,
and other means of effecting the least
practicable impact on such species or
stock and its habitat, paying particular
attention to rookeries, mating grounds,
and areas of similar significance, and on
the availability of such species or stock
for taking for subsistence uses
(hereinafter referred to as least
practicable adverse impact). NMFS does
not have a regulatory definition for least
practicable adverse impact.
NMFS disagrees with the assertion
that we have failed to meet the least
practicable adverse impact standard in
this case. NMFS considered all
recommended mitigation in the context
of both the reduction of impacts on
marine mammal species and stocks and
their habitat and the practicability of
such mitigation in reaching the required
set of measures that we believe satisfy
the least practicable adverse impact
standard.
NMFS’ evaluation of potential
mitigation measures includes
consideration of two primary factors:
(1) The manner in which, and the
degree to which, implementation of the
potential measure(s) is expected to
reduce adverse impacts to marine
mammal species or stocks, their habitat,
and their availability for subsistence
uses (where relevant). This analysis
considers such things as the nature of
the potential adverse impact (such as
likelihood, scope, and range), the
likelihood that the measure will be
effective if implemented, and the
likelihood of successful
implementation.
(2) The practicability of the measures
for applicant implementation.
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Practicability of implementation may
consider such things as cost, impact on
activities, personnel safety, and
practicality of implementation.
While the language of the least
practicable adverse impact standard
calls for minimizing impacts to affected
species or stocks and their habitat,
NMFS recognizes that the reduction of
impacts to those species or stocks
accrues through the application of
mitigation measures that limit impacts
to individual animals. Accordingly,
NMFS’ analysis focuses on measures
that are designed to avoid or minimize
impacts on individual marine mammals
that are likely to increase the probability
or severity of population-level effects.
While direct evidence of impacts to
species or stocks from a specified
activity is rarely available, and
additional study is still needed to
understand how specific disturbance
events affect the fitness of individuals of
certain species, there have been
improvements in understanding the
process by which disturbance effects are
translated to the population. With
recent scientific advancements (both
marine mammal energetic research and
the development of energetic
frameworks), the relative likelihood or
degree of impacts on species or stocks
may often be inferred given a detailed
understanding of the activity, the
environment, and the affected species or
stocks. This same information is used in
the development of mitigation measures
and helps us understand how mitigation
measures contribute to lessening effects
(or the risk thereof) to species or stocks.
NMFS also acknowledges that there is
always the potential that new
information, or a new recommendation
that had not previously been
considered, becomes available and
necessitates re-evaluation of mitigation
measures to see if further reductions of
population impacts are possible and
practicable.
In the evaluation of specific measures,
the details of the specified activity will
necessarily inform each of the two
primary factors discussed above
(expected reduction of impacts and
practicability) and are carefully
considered to determine the types of
mitigation that are appropriate under
the least practicable adverse impact
standard. Analysis of how a potential
mitigation measure may reduce adverse
impacts on a marine mammal stock or
species and practicability of
implementation are not issues that can
be meaningfully evaluated through a
yes/no lens. The manner in which, and
the degree to which, implementation of
a measure is expected to reduce
impacts, as well as its practicability, can
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vary widely. For example, a time-area
restriction could be of very high value
for reducing the potential for, or severity
of, population-level impacts (e.g.,
avoiding disturbance of feeding females
in an area of established biological
importance) or it could be of lower
value (e.g., decreased disturbance in an
area of high productivity but of less
firmly established biological
importance). Regarding practicability, a
measure might involve restrictions in an
area or time that impede the operator’s
ability to acquire necessary data (higher
impact), or it could mean incremental
delays that increase operational costs
but still allow the activity to be
conducted (lower impact). A
responsible evaluation of ‘‘least
practicable adverse impact’’ will
consider the factors along these realistic
scales. Expected effects of the activity
and of the mitigation as well as status
of the stock all weigh into these
considerations. Accordingly, the greater
the likelihood that a measure will
contribute to reducing the probability or
severity of adverse impacts to the
species or stock or their habitat, the
greater the weight that measure is given
when considered in combination with
practicability to determine the
appropriateness of the mitigation
measure, and vice versa. Consideration
of these factors is discussed in greater
detail below.
1. Reduction of Adverse Impacts to
Marine Mammal Species or Stocks and
Their Habitat
The emphasis given to a measure’s
ability to reduce the impacts on a
species or stock considers the degree,
likelihood, and context of the
anticipated reduction of impacts to
individuals (and how many individuals)
as well as the status of the species or
stock.
The ultimate impact on any
individual from a disturbance event
(which informs the likelihood of
adverse species- or stock-level effects) is
dependent on the circumstances and
associated contextual factors, such as
duration of exposure to stressors.
Though any proposed mitigation needs
to be evaluated in the context of the
specific activity and the species or
stocks affected, measures with the
following types of effects have greater
value in reducing the likelihood or
severity of adverse species- or stocklevel impacts: Avoiding or minimizing
injury or mortality; limiting interruption
of known feeding, breeding, mother/
young, or resting behaviors; minimizing
the abandonment of important habitat
(temporally and spatially); minimizing
the number of individuals subjected to
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these types of disruptions; and limiting
degradation of habitat. Mitigating these
types of effects is intended to reduce the
likelihood that the activity will result in
energetic or other types of impacts that
are more likely to result in reduced
reproductive success or survivorship. It
is also important to consider the degree
of impacts that are expected in the
absence of mitigation in order to assess
the added value of any potential
measures. Finally, because the least
practicable adverse impact standard
gives NMFS discretion to weigh a
variety of factors when determining
appropriate mitigation measures and
because the focus of the standard is on
reducing impacts at the species or stock
level, the least practicable adverse
impact standard does not compel
mitigation for every kind of take, or
every individual taken, if that mitigation
is unlikely to meaningfully contribute to
the reduction of adverse impacts on the
species or stock and its habitat, even
when practicable for implementation by
the applicant.
The status of the species or stock is
also relevant in evaluating the
appropriateness of potential mitigation
measures in the context of least
practicable adverse impact. The
following are examples of factors that
may (either alone, or in combination)
result in greater emphasis on the
importance of a mitigation measure in
reducing impacts on a species or stock:
The stock is known to be decreasing or
status is unknown, but believed to be
declining; the known annual mortality
(from any source) is approaching or
exceeding the PBR level; the affected
species or stock is a small, resident
population; or the stock is involved in
a UME or has other known
vulnerabilities, such as recovering from
an oil spill.
Habitat mitigation, particularly as it
relates to rookeries, mating grounds, and
areas of similar significance, is also
relevant to achieving the standard and
can include measures such as reducing
impacts of the activity on known prey
utilized in the activity area or reducing
impacts on physical habitat. As with
species- or stock-related mitigation, the
emphasis given to a measure’s ability to
reduce impacts on a species or stock’s
habitat considers the degree, likelihood,
and context of the anticipated reduction
of impacts to habitat. Because habitat
value is informed by marine mammal
presence and use, in some cases there
may be overlap in measures for the
species or stock and for use of habitat.
NMFS considers available
information indicating the likelihood of
any measure to accomplish its objective.
If evidence shows that a measure has
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29099
not typically been effective nor
successful, then either that measure
should be modified or the potential
value of the measure to reduce effects
should be lowered.
2. Practicability
Factors considered may include those
costs, impact on activities, personnel
safety, and practicality of
implementation.
In carrying out the MMPA’s mandate
for this action, NMFS applies the
previously described context-specific
balance between the manner in which
and the degree to which measures are
expected to reduce impacts to the
affected species or stocks and their
habitat and practicability for operators.
The effects of concern (i.e., those with
the potential to adversely impact
species or stocks and their habitat),
addressed previously in the Potential
Effects of the Specified Activity on
Marine Mammals and Their Habitat
section of the notice of proposed IHA,
include auditory injury, severe
behavioral reactions, disruptions of
critical behaviors, and to a lesser degree,
masking and impacts on acoustic
habitat. Here, we focus on measures
with proven or reasonably presumed
ability to avoid or reduce the intensity
of acute exposures that have potential to
result in these anticipated effects with
an understanding of the drawbacks or
costs of these requirements, as well as
time-area restrictions that would avoid
or reduce both acute and chronic
impacts. To the extent of the
information available to NMFS, we
considered practicability concerns, as
well as potential undesired
consequences of the measures, e.g.,
extended periods using the acoustic
source due to the need to reshoot lines.
NMFS also recognizes that
instantaneous protocols, such as
shutdown requirements, are not capable
of avoiding all acute effects, and are not
suitable for avoiding many cumulative
or chronic effects and do not provide
targeted protection in areas of greatest
importance for marine mammals.
Therefore, in addition to a basic suite of
seismic mitigation protocols, we also
consider measures that may or may not
be appropriate for other activities (e.g.,
survey plan modifications specific to
the action discussed herein), but that are
warranted here given the potential for
impacts to a stock of particular concern
(i.e., Southern Resident killer whales)
(see Negligible Impact Analysis and
Determination), and the information we
have regarding habitat for certain
species.
We appreciate the ENGOs suggestions
for additional mitigation and monitoring
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requirements. However, we note that
many of the recommendations require a
scale of effort that is not commensurate
to the scale of either the underlying
activities or the anticipated impacts of
the activities on marine mammals
covered by this authorization. In other
words, many of the recommended
measures would necessitate complex
and expensive survey designs and
methods that are not reasonable in the
context of an activity that consists of
one mobile source moving across a large
area and that will last for only 37 days.
As described in the Mitigation Measures
Considered but Eliminated section of
this notice, out of concern for the status
of Southern Resident killer whales and
proposed critical habitat, NMFS
considered implementing a closure area
and prohibiting L–DEO from conducting
survey operations between the 200-m
isobath and the coastline. However, as
the main goal of L–DEO’s survey is to
examine the geologic features of the
Cascadia subduction zone along the
coastal shelf, NMFS determined that
this exclusion would not be practicable.
NMFS did ultimately incorporate
mitigation measures that are specific to
this action and beyond that which is
typically required for L–DEO’s surveys.
Specifically, we have required L–DEO to
revise their proposed tracklines to avoid
surveying in waters less than 100 m
deep in areas with highest estimated
Southern Resident killer whale
occurrence. We have determined this
measure, which will significantly
reduce impacts to Southern Resident
killer whales while allowing L–DEO to
complete its survey objectives, to be
practicable. Additionally, L–DEO must
use a second vessel traveling ahead of
the R/V Langseth with additional PSOs
to increase the likelihood of detecting
Southern Resident killer whales and,
therefore, allowing for greater efficacy in
implementing shutdown procedures to
minimize impacts to animals that may
be in the area. Regardless of whether
other monitoring plans suggested by the
ENGOs would also suffice, NMFS has
determined that the mitigation and
monitoring required as part of this
authorization meets the MMPA
requirement for least practicable adverse
impact.
Comment 13: The ENGOs suggested
NMFS should work with L–DEO and
explore ways to conduct the survey
without ensonifying designated and
proposed Southern Resident killer
whale critical habitat, or at minimum,
prohibit ramp-up in the proposed and
designated critical habitat unless the
location of all three pods of Southern
Resident killer whales is known to be
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within the Salish Sea or in an area not
impacted by survey activity on each day
of the survey.
Response: As discussed above, NMFS
considered prohibiting L–DEO from
operating within the proposed critical
habitat for Southern Resident killer
whales, but determined that the
exclusion was not practicable, as it
would prevent L–DEO from completing
their survey objectives. NMFS has
worked with L–DEO to revise the survey
tracklines to avoid ensonifying waters
less than 100 m deep above the Level B
harassment threshold, between
Tillamook Head, Oregon and Barkley
Sound, British Columbia. As stated
above, this area contains the highest
estimated density of Southern Resident
killer whales. NMFS has not required L–
DEO to confirm the location of Southern
Resident killer whales before beginning
survey activities each day as the
location of all three pods is often
unknown and waiting for confirmation
would not allow L–DEO to complete
their research objectives. L–DEO is
required to contact several entities
(including NMFS, Canada’s DFO, Orca
Network, and the Whale Museum) on
each day of the survey to obtain any
recent reports of Southern Resident
killer whales in the survey area.
Comment 14: The ENGOs suggested
NMFS should consider closures or
limits on survey activity in proposed
humpback whale critical habitat and
biologically important areas for blue
whales.
Response: The revised tracklines
mentioned above, while primarily
intended to avoid areas of highest
Southern Resident killer whale
occurrence, also reduce survey
tracklines in recently finalized
humpback whale critical habitat (86 FR
21082; April 21, 2021) and BIAs for
humpback whales and other marine
mammals (we note that no BIAs for blue
whales have been identified in the
survey area). Eliminating all tracklines
in humpback whale critical habitat
would prevent L–DEO from completing
their research objectives, as the
proposed critical habitat occupies most
of the continental shelf area off of the
west coast of the U.S., the key area for
L–DEO’s research. Additionally, the
ENGOs do not provide any substantive
reasoning for why prohibiting L–DEO
from operating within humpback whale
critical habitat or BIAs is warranted. As
discussed in the Negligible Impact
Analysis and Determination section of
this notice, L–DEO’s activity is not
expected to have a lasting physical
impact on humpback whale critical
habitat, prey within it, or overall
humpback whale fitness.
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Comment 15: In addition to vesselbased passive acoustic monitoring
(PAM), the ENGOs suggested NMFS
should require the use of existing
moored passive acoustic monitoring
systems and installation of temporary
hydrophones or sonabuoys in the survey
area to monitor marine mammal
presence.
Response: NMFS appreciates the
suggestions regarding increasing
acoustic monitoring. However, the
existing network of acoustic recorders
along the Washington coast is
comprised of archival recorders, which
are not monitored in real-time. While
the deployment of temporary
hydrophones and sonabuoys in the
survey area may aid in detection and
monitoring of marine mammals, NMFS
does not expect that any additional
protection would outweigh the cost and
practicability concerns associated with
additional personnel required to
monitor the systems and relay
detections to the research vessel. The
use of on-board PAM will adequately
alert L–DEO of vocalizing marine
mammals in the immediate vicinity of
the survey activity.
Comment 16: The ENGOs
recommended NMFS should require the
use of a support vessel traveling ahead
of the R/V Langseth in proposed critical
habitat for humpback whales and
biologically important areas (BIAs) for
other cetaceans.
Response: The support vessel
referenced by the ENGOs is required to
travel approximately 5 km ahead of the
R/V Langseth while surveying in waters
200 m or less between Tillamook Head,
Oregon and Barkley Sound, British
Columbia (see Mitigation section of this
notice). This area encompasses much of
the critical habitat for humpback whales
and biologically important areas for
other species (e.g., gray whale BIA for
migration). The area of the humpback
whale critical habitat expected to be
surveyed on a given day is only a small
portion of the overall critical habitat
along the coast. Any impacts to marine
mammals in this area are expected to be
minor and temporary, and any
additional protection that may be
provided by requiring L–DEO to use the
support vessel outside of the 200-m
isobath is not warranted in the context
of the expected effects and practicability
concerns.
Comment 17: The ENGOs suggested
NMFS should prohibit survey activity in
low-visibility conditions.
Response: NMFS disagrees that
survey activity should be prohibited in
low-visibility conditions. Any
requirement to cease operations during
low visibility conditions, including at
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night, would not only be impracticable,
it would also likely result in greater
impacts to marine mammals, as such a
measure would require operations to
continue for significantly more time, to
make up for lost operations during lowvisibility times. Ramp-up of the acoustic
source, when necessary, may occur at
times of poor visibility (including
nighttime), assuming that a preclearance period has been observed. If
the pre-clearance period occurs at
nighttime, the pre-clearance watch
would be conducted only by the
acoustic observer.
Comment 18: The ENGOs suggested
NMFS should consider whether aerial
observations would have less impact
(than the support vessel).
Response: Similar to the suggestion of
deploying additional PAM systems
above, NMFS has determined it is not
practicable to require L–DEO to use
aerial monitoring systems. NMFS does
not expect that any additional
protection would outweigh the cost and
practicability of additional personnel
required to monitor the systems and
relay detections to the research vessel.
Comment 19: The ENGOs suggested
the 1,500-meter exclusion zone, which
is required for beaked whales, should
apply for other marine mammal species
that they suggest are particularly
sensitive — such as harbor porpoises,
Steller sea lions, baleen whales (except
gray whales) and Southern Resident
killer whales. The commenters suggest
that the presence of Southern Residents
should trigger a shut-down whenever
they are detected, regardless of distance.
Response: NMFS disagrees that a
larger standard exclusion zone is
warranted for the species and groups
suggested by the ENGOs. The standard
exclusion zone for all marine mammals
included in the IHA is 500 m, with
larger exclusion zones or shutdown
requirements for certain species and/or
scenarios. NMFS’ intent in prescribing a
standard exclusion zone distance is to
(1) encompass zones for most species
within which auditory injury could
occur on the basis of instantaneous
exposure; (2) provide additional
protection from the potential for more
severe behavioral reactions (e.g., panic,
antipredator response) for marine
mammals at relatively close range to the
acoustic source; (3) provide consistency
and ease of implementation for
protected species observers (PSOs), who
need to monitor and implement the
exclusion zone; and (4) define a
distance within which detection
probabilities are reasonably high for
most species under typical conditions.
The use of 500 m as the zone is not
based directly on any quantitative
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understanding of the range at which
auditory injury would be entirely
precluded or any range specifically
related to disruption of behavioral
patterns. Rather, NMFS believes it is
based on a reasonable combination of
factors. In summary, a practicable
criterion such as this has the advantage
of familiarity and simplicity while still
providing in most cases a zone larger
than relevant auditory injury zones,
given realistic movement of source and
receiver. Increased shutdowns, without
a firm idea of the outcome the measure
seeks to avoid, simply displace survey
activity in time and increase the total
duration of acoustic influence as well as
total sound energy in the water, which
NMFS seeks to avoid. In keeping with
the four broad goals outlined above, and
in context of the information given here,
the standard 500-m exclusion zone is
appropriate. The ENGOs do not provide
any substantive reasoning for a larger
zone.
The proposed IHA included the
requirement to shut down the airgun
array if killer whales (of any ecotype)
are visually or acoustically detected at
any distance and NMFS has retained
this requirement in the final
authorization.
Comment 20: The ENGOs suggested
NMFS should require L–DEO to use the
lowest practicable source level for
airgun usage.
Response: L–DEO has selected the
equipment necessary to achieve their
research objectives. We have evaluated
the specified activity as defined by the
applicant, including changes agreedupon with NMFS in order to provide
additional protection for Southern
Resident killer whales, and made the
necessary findings to authorize taking of
marine mammals incidental to L–DEO’s
survey activities. We also note that an
expert panel was convened by the
Bureau of Ocean Energy Management to
determine whether it would be feasible
to develop standards to determine a
lowest practicable source level. The
panel determined that it would not be
reasonable or practicable to develop
such metrics (see Appendix L in BOEM,
2017).
Comment 21: The ENGOs suggested
NMFS should require in situ sound
source verification to determine
accurate exclusion zones. Similarly, the
Commission recommended NMFS
require L–DEO analyze the data
recorded on the OBSs and OBNs to
determine the extents of the Level B
harassment zones in shallow-,
intermediate-, and deep-water depths
and specify how the in-situ zones
compare to the Level B harassment
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29101
zones specified in the final
authorization.
Response: As stated above, the
exclusion zones are not necessarily
based on specific acoustic parameters,
thus sound source verification is not
necessary in the context of exclusion
zones. Regarding the Commission’s
recommendation to conduct analysis of
OBS data, L–DEO has not previously
undertaken the type of analysis
suggested by the Commission, and
indicated to NMFS that it does not have
the expertise or capability to do so at
this time. In addition, we note that the
Commission’s recommendation is
vague; detailed direction would be
needed from the Commission on how to
accomplish the recommended effort.
This would need to include agreement
on the analytical approach in order to
meet expectations and to ensure
acceptance of results. The Commission’s
recommendation does not acknowledge
the time it would take to perform the
analysis or the level of effort and cost
that would be involved, e.g., experts
needed to obtain and review data,
performing detailed comparative
analysis, preparation of a report. Based
on these concerns, NMFS believes that
the recommendation is not practicable.
Also, implementation of this
recommendation would not provide any
additional conservation value (e.g.,
improvement in mitigation
effectiveness) for the proposed survey.
The analysis would be retrospective and
could be used to help inform analysis of
future surveys in the same area. NSF is
considering funding a survey of the
Queen Charlotte Fault, north of the
planned survey area for this action, but
the survey would be completed before
the acoustic data from this survey
suggested by the Commission could be
analyzed. NMFS is not aware of any
other NSF-proposed seismic surveys on
the R/V Langseth for this region in the
foreseeable future that could incorporate
the in situ data, if analyzed.
Comment 22: The ENGOs suggested
NMFS should prohibit the use of the
Kongsberg Simrad 122 MBES in shallow
water because the system’s lower
frequencies were designed for use in
deeper water.
Response: The ENGOs provide no
justification for prohibiting the use of
the MBES in shallow water aside from
describing its characteristics. As
discussed in previous comment
responses, NMFS has determined the
MBES is not likely to result in take of
marine mammals and has no reason to
believe that the use of the Kongsberg
Simrad 122 in shallow water is cause for
concern. The ENGOs do not provide any
substantive argument to the contrary.
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Comment 23: The ENGOs suggested
NMFS should require L–DEO to
immediately cease survey activities if
any authorized take limits are exceeded
or if a take of an unauthorized species
occurs (e.g., take of a North Pacific right
whale).
Response: NMFS agrees with the
ENGOs that L–DEO must shut down the
airgun array if a marine mammal species
for which take was not authorized, or a
species for which authorization was
granted but the takes have been met,
approaches the Level A or Level B
harassment zones. This requirement was
included in the notice of proposed IHA
but was inadvertently omitted from the
draft IHA. The final authorization
includes this requirement.
Comment 24: The ENGOs suggested
NMFS should require L–DEO to
immediately cease survey activities if a
take of an unauthorized level or
intensity occurs, (e.g., serious injury or
mortality of any species or take of a
Southern Resident killer whale by Level
A harassment). The ENGOs further
suggest that if take is found to have been
exceeded, then there should be an
investigation and additional mitigation
to avoid any additional take before
activities can resume. Similarly, the
Commission recommended NMFS
include in all draft and final
authorizations an explicit requirement
to cease activities if a marine mammal
is injured or killed during the specified
activities, including by vessel strike,
until NMFS reviews the circumstances
involving any injury or death that is
likely attributable to the activities and
determines what additional measures
are necessary to minimize additional
injuries or death.
Response: NMFS does not expect that
the proposed activities have the
potential to result in injury or mortality
to marine mammals and therefore does
not agree that a blanket requirement for
project activities to cease would be
warranted. NMFS does not agree that a
requirement for a vessel that is
operating on the open water to suddenly
stop operating is practicable, and it is
unclear what mitigation benefit would
result from such a requirement in
relation to vessel strike. The
Commission does not suggest what
measures other than those prescribed in
this IHA would potentially prove more
effective in reducing the risk of strike.
Therefore, we have not included this
requirement in the authorization. NMFS
retains authority to modify the IHA and
cease all activities immediately based
on a vessel strike and will exercise that
authority if warranted.
With respect to the Commission’s
recommendation that NMFS include
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these requirements in all proposed and
final IHAs, NMFS determines the
requirements for mitigation measures in
each authorization based on numerous
case-specific factors, including the
practicability of the measures for
applicant implementation, which may
consider such things as cost, impact on
operations, and, in the case of a military
readiness activity, personnel safety,
practicality of implementation, and
impact on the effectiveness of the
military readiness activity. As NMFS
must make these determinations on a
case by case basis, we therefore do not
agree with this recommendation.
Comment 25: The ENGOs suggested
NMFS impose a ship speed limit of 10
knots or less at all times to reduce noise
and prevent ship strikes, with an
exception for rare emergency or safety
necessities. While the vessel conducting
the survey is likely to be traveling well
under 10 knots, NMFS should make this
a requirement of any crew-transfer
vessels used in the project.
Response: NMFS has analyzed the
potential for ship strike resulting from
L–DEO’s planned activity and has
determined that the mitigation measures
specific to ship strike avoidance are
sufficient to avoid the potential for ship
strike. These include: A requirement
that all vessel operators reduce vessel
speed to 10 knots (18.5 km/hour) or less
when any large whale, any mother/calf
pairs, pods, or large assemblages of nondelphinoid cetaceans are observed
within 100 m of an underway vessel; a
requirement that all survey vessels
maintain a separation distance of 100 m
or greater from all large whales, and 500
m or greater from any sighted North
Pacific right whale (if a whale is
observed but cannot be confirmed as a
species other than a right whale, the
vessel operator must assume that it is a
right whale and take appropriate
action); a requirement that if protected
species are sighted while a vessel is
underway, the vessel must take action
as necessary to avoid violating the
relevant separation distance (e.g.,
attempt to remain parallel to the
animal’s course, avoid excessive speed
or abrupt changes in direction until the
animal has left the area); and a
requirement that if marine mammals are
sighted within the relevant separation
distance, the vessel must reduce speed
and shift the engine to neutral, not
engaging the engines until animals are
clear of the area. Finally, we note that
all crew will be aboard the R/V Langseth
through the entire survey, and there will
not be any crew transfer vessels. We
have determined that the ship strike
avoidance measures are sufficient to
ensure the least practicable adverse
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impact on species or stocks and their
habitat and therefore we do not include
the 10 knot ship speed limit
recommended by the ENGOs.
Comment 26: The ENGOs
recommended NMFS require L–DEO to
minimize the use of lines and cables
and ensure that they are not flexible to
reduce entanglement risk.
Response: As discussed in the notice
of proposed IHA, no incidents of
entanglement of marine mammals with
seismic survey gear have been
documented in over 54,000 nautical
miles (nmi; 100,000 km) of previous
NSF-funded seismic surveys when
observers were aboard (e.g., Holst and
Smultea 2008; RPS 2019; RPS 2021).
Although entanglement with the
streamer is theoretically possible, it has
not been documented during tens of
thousands of miles of NSF-sponsored
seismic cruises or, to our knowledge,
during hundreds of thousands of miles
of industrial seismic cruises.
Entanglement in OBSs and OBNs is also
not expected to occur. There are a
relative few deployed devices, and no
interaction between marine mammals
and any such device has been recorded
during prior NSF surveys using the
devices. There are no meaningful
entanglement risks posed by the
proposed survey, and therefore although
we encourage L–DEO to use lines and
cables that minimize entanglement risk,
NMFS has not included the
recommended requirement as a
condition in the final authorization.
Comment 27: The ENGOs state that
marine mammal strandings are most
likely to result when a sound source is
moving directly toward the shore.
Therefore, the ENGOs suggested NMFS
should require reconfigured tracklines
to avoid these approaches when the
airguns are firing.
Response: There is no conclusive
evidence that exposure to airgun noise
results in behaviorally-mediated forms
of injury (i.e., mass stranding events).
Behaviorally-mediated injury has been
primarily associated with beaked
whales exposed to mid-frequency active
(MFA) naval sonar. As described in the
notice of proposed IHA, tactical sonar is
very different from the noise produced
by airguns. One should therefore not
expect the same reaction to airgun noise
as to these other sources. The ENGOs
reference a survey conducted by L–DEO
in 2002 that was contemporaneous with
and reasonably associated spatially with
the stranding of two Cuvier’s beaked
whales. However, the event was not
considered a ‘‘true atypical mass
stranding’’ (according to Frantzis (1998))
as used in the analysis of Castellote and
Llorens (2016). While we agree with the
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authors that this lack of evidence should
not be considered conclusive, it is clear
that there is very little evidence that
seismic surveys should be considered as
posing a significant risk of acute harm
to beaked whales or other midfrequency cetaceans. Although NMFS
does not expect that stranding is a
potential outcome of this survey
activity, we also note that certain
tracklines closest to shore (i.e., in waters
less than 100 m deep in areas with
highest estimated Southern Resident
killer whale occurrence) have been
eliminated, further reducing the risk of
this outcome. We have considered the
potential for the proposed surveys to
result in marine mammal stranding and
have concluded that, based on the best
available information, stranding is not
expected to occur. Therefore, we have
not adopted the ENGOs
recommendation to reconfigure the
survey tracklines.
Comment 28: Both the ENGOs and
Commission object to NMFS’ potential
consideration of a renewal IHA for this
action, and in general. The ENGOs
assert that IHA renewals are not
permissible under the MMPA and
instead recommend that applicants
request a multi-year permit and
accordingly reevaluate the effects of the
action based on multiple years of take.
The Commission recommended NMFS
refrain from issuing IHA renewals for
any authorization and instead use an
abbreviated Federal Register notice
process, which is similarly expeditious
and fulfills NMFS’ intent to maximize
efficiencies. If NMFS continues to
propose to issue IHA renewals, the
Commission recommends that NMFS (1)
stipulate that a renewal is a one-time
opportunity (a) in all Federal Register
notices requesting comments on the
possibility of a renewal, (b) on its web
page detailing the renewal process, and
(c) in all draft and final authorizations
that include a term and condition for a
renewal and (2) if NMFS declines to
adopt this recommendation, explain
fully its rationale for not doing so.
Response: NMFS’ IHA renewal
process meets all statutory
requirements. All IHAs issued, whether
an initial IHA or a renewal IHA, are
valid for a period of not more than one
year. In addition, the public has at least
30 days to comment on all proposed
IHAs, with a cumulative total of 45 days
for IHA renewals. As noted above, the
Request for Public Comments section of
the notice of proposed IHA made clear
that the agency was seeking comment
on both the initial proposed IHA and
the potential issuance of a renewal for
this project. Because any renewal (as
explained in the Request for Public
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Comments section of the notice of
proposed IHA) is limited to another year
of identical or nearly identical activities
in the same location (as described in the
Description of Proposed Activity
section) or the same activities that were
not completed within the 1 year period
of the initial IHA, reviewers have the
information needed to effectively
comment on both the immediate
proposed IHA and a possible 1 year
renewal, should the IHA holder choose
to request one in the coming months.
While there will be additional
documents submitted with a renewal
request, for a qualifying renewal these
will be limited to documentation that
NMFS will make available and use to
verify that the activities are identical to
those in the initial IHA, are nearly
identical such that the changes would
have either no effect on impacts to
marine mammals or decrease those
impacts, or are a subset of activities
already analyzed and authorized but not
completed under the initial IHA. NMFS
will also confirm, among other things,
that the activities will occur in the same
location; involve the same species and
stocks; provide for continuation of the
same mitigation, monitoring, and
reporting requirements; and that no new
information has been received that
would alter the prior analysis. The
renewal request will also contain a
preliminary monitoring report, but that
is to verify that effects from the
activities do not indicate impacts of a
scale or nature not previously analyzed.
The additional 15-day public comment
period provides the public an
opportunity to review these few
documents, provide any additional
pertinent information and comment on
whether they think the criteria for a
renewal have been met. Between the
initial 30-day comment period on these
same activities and the additional 15
days, the total comment period for a
renewal is 45 days.
In addition to the IHA renewal
process being consistent with all
requirements under section 101(a)(5)(D),
it is also consistent with Congress’
intent for issuance of IHAs to the extent
reflected in statements in the legislative
history of the MMPA. Through the
provision for renewals in the
regulations, description of the process
and express invitation to comment on
specific potential renewals in the
Request for Public Comments section of
each proposed IHA, the description of
the process on NMFS’ website, further
elaboration on the process through
responses to comments such as these,
posting of substantive documents on the
agency’s website, and provision of 30 or
45 days for public review and comment
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29103
on all proposed initial IHAs and
renewals respectively, NMFS has
ensured that the public ‘‘is invited and
encouraged to participate fully in the
agency decision-making process.’’
NMFS does not agree with the
Commission and therefore does not
adopt the Commission’s
recommendation that NMFS use an
abbreviated Federal Register notice
instead of IHA renewal. NMFS has
previously provided responses to this
specific recommendation in multiple
notices, including 84 FR 52464 (October
2, 2019). NMFS does agree with the
Commission’s recommendation that
NMFS specify that IHA renewals are a
one-time opportunity in all Federal
Register notices requesting comments
on the possibility of an IHA renewal, in
all associated proposed and final IHAs,
and on our website. NMFS has specified
this in the final IHA for L–DEO’s
activities and has been including this in
Federal Register notices and proposed
and final authorizations since last year.
Comment 29: The ENGOs
recommended NMFS and L–DEO
explore whether the proposed research
could be conducted using alternative
technologies or approaches that are less
harmful to marine mammals. More
broadly, and beyond the scope of this
action, the ENGOs recommended NMFS
engage with NSF to invest in research
that explores alternative technologies.
Response: NMFS agrees with the
ENGOs that development and use of
technologies that reduce the
environmental impact of geophysical
surveys is a laudable objective and may
be warranted in some cases. Alternative
technologies are in various stages of
development, and none of the systems
with the potential to replace airguns as
a seismic source are currently
commercially available for use on a
scale of activity such as that considered
herein. Although some alternative
technologies are available now, or will
be in the next several years, for select
uses, none are at a stage where they can
replace airgun arrays outright. However,
some may be used in select
environments when commercially
available. Such technologies may be
evaluated in the future as they become
commercially available and on a scale
commensurate to the need. In summary,
while we agree that alternative
technologies may be beneficial, the
ENGOs do not suggest any specific
technologies or approaches and the
suggestion that NMFS engage with NSF
to research these methods is outside the
authority provided to NMFS by the
MMPA. However, NMFS would
consider participating in related efforts
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by the ENGOs or other entities
interested in these technologies.
Comment 30: The ENGOs and the
Commission recommended NMFS
require L–DEO to use the method
proposed by the Commission to estimate
take and apply relevant corrections for
airgun activity in daylight vs nighttime
(including dawn and dusk) to better
estimate the numbers of marine
mammals taken by Level A and B
harassment. The Commission further
recommends that NMFS require L–DEO
to specify in the final monitoring report
(1) the number of days on which the
airgun array was active and (2) the
percentage of time and total time the
array was active during daylight vs
nighttime hours (including dawn and
dusk).
Response: NMFS appreciates the
Commission’s development of a
recommended approach to better
estimate the numbers of marine
mammals that may have been taken
during geophysical survey activities,
including marine mammals that were
not detected. The ‘‘Commission’s
method’’ (see the Commission’s letter
for additional discussion and citation to
a full description provided in an
addendum to a May 1, 2019
Commission comment letter) involves
correction of marine mammal sightings
data through use of proxies for marine
mammal detectability (f (0)) and
platform/observer bias on marine
mammal detection (g (0)), and
extrapolation of corrected marine
mammal sightings data based on the
assumed extent of the Level B
harassment zones.
However, NMFS does not concur with
the recommendation to require L–DEO
to implement this approach because we
do not have confidence in the reliability
of estimates of potential marine
mammal take that would result from use
of the approach. The Commission does
not address the multiple assumptions
that must be made in order to have
confidence in the estimates that would
be produced through application of the
method. For example, the assumption
that the application of proxy values for
g (0) and f (0) is appropriate is not
justified (including application of f (0)
values to species for which no value is
available and assuming that application
of f (0) to species in a wholly different
region is appropriate). Notably, g (0)
values are typically derived on a
platform-specific basis, and even for
specific observers—not generalized
across platforms, as the Commission’s
method would require.
Separately, the appropriate
application of distance sampling
methods requires that certain
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assumptions are valid, and the
Commission does not explain why these
assumptions should be assumed to be
valid during a seismic survey, as
compared with typical line-transect
surveys operating without an active
acoustic source. For example, a key
underlying concept of distance
sampling methodology is that the
probability of detecting an animal
decreases as its distance from the
observer increases. This cannot be
assumed true during an active seismic
survey. NMFS believes it unlikely that
the numerous assumptions inherent to
application of the Commission’s method
would be accepted in a research context
(where distance sampling approaches
are typically applied).
Furthermore, the area over which
observations are to be extrapolated
through the Commission’s method is a
modeled ensonified area. We do not
believe it appropriate to assume a
modeled ensonified area is always
accurate for purposes of estimating total
take. In purporting to estimate total
takes, the method ignores the fact that
marine mammals exposed to a level of
received sound assumed to cause take
for analytical purposes may not in fact
respond behaviorally in a way that
equates to take, especially at great
distance from the source.
NMFS believes it is important to focus
on collection and reporting of empirical
data that can directly inform an
assessment of the effects of a specified
activity on the affected species or stock.
While there may be value in an
assessment of potential unobserved
take, we need to proceed cautiously in
the development of derived values given
our low confidence in multiple inputs.
NMFS is currently more broadly
evaluating monitoring requirements,
including data collection, interpretation,
and reporting, as well as the specific
issue the Commission has raised, and is
committed to developing improved
approaches.
NMFS does concur with the
Commission’s recommendation that
NMFS require L–DEO to specify in the
final monitoring report (1) the number
of days on which the airgun array was
active and (2) the percentage of time and
total time the array was active during
daylight vs nighttime hours (including
dawn and dusk). This requirement has
been added to the final authorization.
Comment 31: The Commission asserts
that L–DEO and other NSF-affiliated
entities have not complied with all of
the requirements set forth in certain
final IHAs, and recommends that,
should the alleged shortcomings occur
again, NMFS refrain from issuing any
further authorizations to L–DEO and
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other NSF-affiliated entities until such
time that the monitoring reports include
all of the required information.
Response: NMFS appreciates the
Commission’s concern and will
consider any future requests for
incidental take authorization from NSFaffiliated entities according to the
requirements of the MMPA.
Comment 32: Noting its disagreement
with L–DEO’s approach to estimating
the size of various ensonified areas, the
Commission recommends that NMFS
require L–DEO to either (1) re-estimate
the proposed Level A and B harassment
zones and associated takes of marine
mammals using (a) both operational and
site-specific environmental parameters,
(b) what the Commission believes to be
a comprehensive source model and (c)
what the Commission believes to be an
appropriate sound propagation model
for the proposed IHA or (2) collect or
provide the relevant acoustic data to
substantiate that its modeling approach
is conservative for both deep- and
intermediate-water depths beyond the
Gulf of Mexico. In addition, the
Commission recommends that NMFS (1)
explain why sound channels with
downward refraction, as well as seafloor
reflections, are not likely to occur
during the geophysical survey, (2)
specify the degree to which both of
those parameters would affect the
estimation (or underestimation) of Level
B harassment zones in deep- and
intermediate- water depths, (3) explain
why L–DEO’s model and other
modeling approaches provide more
accurate, realistic, and appropriate
Level A and B harassment zones than
BELLHOP (a different propagation
model favored by the Commission),
particularly for deep- and intermediatewater depths, and (4) explain why, if L–
DEO’s model and other modeling
approaches are considered best
available science, other action
proponents that conduct seismic
surveys are not implementing similar
methods, particularly given their
simplicity.
Response: As noted by the
Commission, these comments reflect a
longstanding disagreement between
NMFS and the Commission regarding
L–DEO’s approach to modeling the
output of their airgun array and its
propagation through the water column.
NMFS has previously responded to
similar Commission comments on L–
DEO’s modeling approach. We refer the
reader to previous Federal Register
notices providing responses rather than
repeat them here (e.g., 84 FR 60059,
November 07, 2019; 84 FR 54849,
October 11, 2019; 84 FR 35073, July 22,
2019). Regardless of the addition of
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slightly different points or modifications
to the language with which the
Commission expresses these points, the
gist of the Commission’s disagreement
with L–DEO’s modeling approach
remains the same. NMFS believes that
its prior responses have adequately
explained the rationale for not following
the Commission’s recommendations
and, importantly, why L–DEO’s
modeling approach is adequate.
Comment 33: The ENGOs asserted
that NMFS must prepare an
Environmental Impact Statement and
cannot rely on the NSF’s Environmental
Assessment (EA) because they believe
that there are significant environmental
impacts. The CBD’s comments on the
NSF’s draft EA were incorporated by
reference in the ENGOs’ comment letter
on the proposed IHA. CBD’s comments
on NSF’s draft EA primarily concerned
Southern Resident killer whales, similar
to the concerns addressed above.
Response: The NSF’s draft EA, which
NMFS adopted, was revised in
consideration of CBD’s comments (and
those of other public commenters) and
adequately analyzes the effects of the
action. The commenters do not provide
any information to support their claim
of significant environmental impacts
under NEPA. NMFS has reviewed the
NSF’s final EA, determined it to be
sufficient, and adopted that EA and
signed a Finding of No Significant
Impact (FONSI).
Comment 34: The ENGOs expressed
doubt that the proposed activities were
permissible under the ESA because they
would jeopardize the continued
existence of Southern Resident killer
whales, North Pacific right whales,
humpback whales, and blue whales,
among other protected species and
adversely modify proposed critical
habitat. The proposed action clearly
affects listed species as well as proposed
and designated critical habitat, and
therefore both NMFS and the NSF must
undergo consultation under the ESA.
The ENGOs urged NMFS to fulfill our
commitment to complete consultation
before authorizing any take of marine
mammals, and requested a public
comment period on the products of the
consultation. The ENGOs strongly
believe that NMFS cannot authorize the
specified activities because they will
jeopardize the recovery and survival of
Southern Resident killer whales and
North Pacific right whales.
Response: NMFS has completed
consultation under the ESA on our
proposal to authorize take of listed
marine mammals incidental to L–DEO’s
survey activities. The NMFS Office of
Protected Resources, Interagency
Cooperation Division issued a Biological
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Opinion concluding that the proposed
action is not likely to jeopardize the
continued existence of ESA-listed blue
whales, fin whales, sei whales, sperm
whales, Central America DPS humpback
whales, Mexico DPS humpback whales,
Southern Resident killer whale DPS,
and Guadalupe fur seals and is not
likely to destroy or adversely modify
Steller sea lion or humpback whale
critical habitat. There is no designated
critical habitat in the action area for the
other listed species. The Interagency
Cooperation Division determined that a
public comment period on the
Biological Opinion was not warranted.
The final Biological Opinion is available
on our website at: https://www.fisheries.
noaa.gov/national/marine-mammalprotection/incidental-takeauthorizations-research-and-otheractivities.
Comment 35: The ENGOs asserted
that NMFS cannot approve the proposed
activity without first consulting with the
states of Washington and Oregon under
the Coastal Zone Management Act
(CZMA). The CZMA authorizes states
with federally approved coastal
management programs to review
applications for Federal licenses or
permits to conduct activities in, or
outside of, the coastal zone that affects
land uses, water uses, or natural
resources within the coastal zone to
ensure the activity is fully consistent
with the state’s management plan.
Response: The NSF submitted
consistency determinations to
Washington and Oregon. Both the
Washington State Department of
Ecology and Oregon Coastal
Management Program, the respective
CZMA authorities for Washington and
Oregon, concurred with the NSF’s
determinations. NMFS’ action of
authorizing take of marine mammal is
incidental to the NSF’s action of
conducting the survey, therefore NMFS
is not required to independently submit
consistency determinations under
CZMA.
Comment 36: The ENGOs and Deep
Green Wilderness expressed concern
that the proposed survey overlaps with
Olympic Coast National Marine
Sanctuary (OCNMS). The ENGOs
reference the National Marine
Sanctuaries Act (NMSA), which aims to
maintain the natural biological
communities in the national marine
sanctuaries, and to protect, and, where
appropriate, restore and enhance natural
habitats, populations, and ecological
processes. To achieve these purposes,
the NMSA requires that Federal agency
actions internal or external to a national
marine sanctuary, including private
activities authorized by licenses, leases,
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29105
or permits that are likely to destroy,
cause the loss of, or injure any sanctuary
resource are subject to consultation with
the Secretary. The ENGOs noted that the
action agency must follow the
recommendations of the Secretary to
avoid injury to any sanctuary resource
or otherwise act to prevent and mitigate
damage to such resources.
Response: NMFS satisfied our
responsibilities under section 304(d) of
the NMSA. NMFS and the NSF drafted
a joint Sanctuary Resource Statement
(SRS) to consult with the NOAA Office
of National Marine Sanctuaries (ONMS)
under the NMSA. ONMS provided two
recommended alternatives to minimize
injury and to protect sanctuary
resources: (1) Limit operations in
OCNMS to daylight hours only
regardless of depth; and 2) use of the
secondary support vessel aiding in
marine mammal observations
throughout the entire sanctuary. NMFS
has included these recommendations in
the final IHA.
Changes From the Proposed IHA to
Final IHA
There are numerous changes from the
proposed IHA, starting with the timing
of the survey. The survey was initially
proposed to occur in summer 2020 but
was delayed until summer 2021. Since
conclusion of the public comment
period in May 2020, NMFS has
reviewed newly available information,
including recent draft Stock Assessment
Reports, information on relevant
Unusual Mortality Events, and other
scientific literature, and incorporated
this information into our analysis of
impacts on marine mammals and their
habitat.
In addition to the timing changes, the
survey tracklines have been modified to
avoid surveying in the areas with the
highest expected occurrence of
Southern Resident killer whales.
Between Tillamook Head, Oregon and
Barkley Sound, British Columbia, L–
DEO’s planned tracklines have been
truncated or removed entirely such that
the ensonified area does not extend
within the 100-meter (m) depth contour
(see Estimated Take section for
description of the Level B harassment
zones and ensonified area). In addition
to removing tracklines in nearshore
shallow waters along the coast, L–DEO
also modified tracklines such that the
ensonified area will not extend within
Canadian designated Southern Resident
and Northern Resident killer whale
critical habitat. Additionally, under
consultation with Canada DFO, L–DEO
removed all tracklines in waters 100 m
or less in Canadian waters. Thus north
of Tillamook Head, Oregon, no surveys
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will occur in waters 100 m or less (see
Figure 1). Based on informal
recommendations from the Commission,
NMFS recalculated the densities of
Steller sea lions by applying the
appropriate pup and non-pup growth
rates of the population in Washington
and British Columbia. Takes of all
species and stocks have been
recalculated using the revised tracklines
and resulting ensonified areas.
Additionally, NMFS has revised the
mitigation requirements regarding use of
a second support vessel and daylightonly operations in waters 200 m or less.
The proposed IHA required the use of
the support vessel and limited
operations to daylight only along the
entire survey area in waters 200 m or
less. In consideration of operational
practicability, we have revised that
requirement to apply only between
Tillamook Head, Oregon and Barkley
Sound, British Columbia. Based on
consultation with the Olympic Coast
National Marine Sanctuary (OCNMS),
the final IHA requires L–DEO to use the
support vessel and operate only during
daylight hours within the OCNMS,
regardless of water depth. OCNMS has
also been added to the list of entities L–
DEO must contact each day to obtain
sightings reports of Southern Resident
killer whales in the survey area and, in
turn, report their own sightings of killer
whales to the Sanctuary. Finally, as
recommended by the Commission, we
have clarified the required elements that
must be included in L–DEO’s
monitoring report.
Description of Marine Mammals in the
Area of Specified Activities
Sections 3 and 4 of the application
summarize available information
regarding status and trends, distribution
and habitat preferences, and behavior
and life history, of the potentially
affected species. Additional information
regarding population trends and threats
may be found in NMFS’s Stock
Assessment Reports (SARs; https://
www.fisheries.noaa.gov/national/
marine-mammal-protection/marinemammal-stock-assessments) and more
general information about these species
(e.g., physical and behavioral
descriptions) may be found on NMFS’s
website (https://www.fisheries.
noaa.gov/find-species).
Table 1 lists all species with expected
potential for occurrence in the survey
area and summarizes information
related to the population or stock,
including regulatory status under the
MMPA and ESA and potential
biological removal (PBR), where known.
For taxonomy, we follow Committee on
Taxonomy (2020). PBR is defined by the
MMPA as the maximum number of
animals, not including natural
mortalities, that may be removed from a
marine mammal stock while allowing
that stock to reach or maintain its
optimum sustainable population (as
described in NMFS’s SARs). While no
mortality is anticipated or authorized
here, PBR and annual serious injury and
mortality from anthropogenic sources
are included here as gross indicators of
the status of the species and other
threats.
Marine mammal abundance estimates
presented in this document represent
the total number of individuals that
make up a given stock or the total
number estimated within a particular
study or survey area. NMFS’s stock
abundance estimates for most species
represent the total estimate of
individuals within the geographic area,
if known, that comprises that stock. For
some species, this geographic area may
extend beyond U.S. waters. All managed
stocks in this region are assessed in
NMFS’s U.S. Pacific and Alaska SARs.
All MMPA stock information presented
in Table 1 is the most recent available
at the time of publication and is
available in the 2019 SARs (Caretta et
al., 2020; Muto et al., 2020) and draft
2020 SARs (available online at: https://
www.fisheries.noaa.gov/national/
marine-mammal-protection/draftmarine-mammal-stock-assessmentreports). Where available, abundance
and status information is also presented
for marine mammals in Canadian waters
in British Columbia.
TABLE 1—MARINE MAMMALS THAT COULD OCCUR IN THE SURVEY AREA
Common name
Scientific name
ESA/
MMPA
status;
strategic
(Y/N) 1
Stock
I
Stock abundance
(CV, Nmin, most recent
abundance
survey) 2
PBR
Annual
M/SI 3
Order Cetartiodactyla—Cetacea—Superfamily Mysticeti (baleen whales)
Family Eschrichtiidae:
Gray whale .....................
Family Balaenopteridae
(rorquals):
Humpback whale ............
Eschrichtius robustus ..........
Eastern North Pacific ...........
-/-; N
26,960 (0.05, 25,849, 2016)
801
131
Megaptera novaeangliae .....
California/Oregon/Washington.
Central North Pacific ...........
California/Oregon/Washington.
Eastern North Pacific ...........
California/Oregon/Washington.
Northeast Pacific .................
Eastern North Pacific ...........
-/-; Y
2,900 (0.05, 2,784, 2014) ....
16.7
>42.1
-/-; Y
-/-; N
10,103 (0.30, 7,891, 2006) ..
636 (0.72, 369, 2014) ..........
83
3.5
26
>1.3
E/D; Y
E/D; Y
519 (0.4, 374, 2014) ............
9,029 (0.12, 8,127, 2014) ....
0.75
81
>0.2
>43.7
E/D; Y
E/D; Y
3,168 (0.26, 2,554, 2013) ....
1,496 (0.44, 1,050, 2014) ....
5.1
1.2
0.6
>19.4
Minke whale ...................
Balaenoptera acutorostrata
Sei whale ........................
Fin whale ........................
Balaenoptera borealis ..........
Balaenoptera physalus ........
Blue whale ......................
Balaenoptera musculus .......
Superfamily Odontoceti (toothed whales, dolphins, and porpoises)
Family Physeteridae:
Sperm whale ..................
Physeter macrocephalus .....
California/Oregon/Washington.
E/D; Y
1,997 (0.57, 1,270, 2014) ....
2.5
0.4
Family Kogiidae:
Pygmy sperm whale .......
Kogia breviceps ...................
-/-; N
4,111 (1.12, 1,924, 2014) ....
19
0
Dwarf sperm whale ........
Kogia sima ...........................
California/Oregon/Washington.
California/Oregon/Washington.
-/-; N
Unknown (Unknown, Unknown, 2014).
Undetermined
0
Family Ziphiidae (beaked
whales):
Cuvier’s beaked whale ...
Ziphius cavirostris ................
California/Oregon/Washington.
-/-; N
3,274 (0.67, 2,059, 2014) ....
21
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TABLE 1—MARINE MAMMALS THAT COULD OCCUR IN THE SURVEY AREA—Continued
Common name
Scientific name
Baird’s beaked whale .....
Berardius bairdii ...................
Mesoplodont beaked
whales.
Family Delphinidae:
Bottlenose dolphin ..........
Mesoplodon spp. .................
Striped dolphin ...............
Stenella coeruleoalba ..........
Common dolphin ............
Delphinus delphis ................
Pacific white-sided dolphin.
Lagenorhynchus obliquidens
Tursiops truncatus ...............
Northern right whale dolphin.
Risso’s dolphin ...............
Lissodelphis borealis ...........
False killer whale ...........
Killer whale .....................
Pseudorca crassidens .........
Orcinus orca ........................
Short-finned pilot whale
Globicephala
macrorhynchus.
Family Phocoenidae (porpoises):
Harbor porpoise .............
Dall’s porpoise .......................
ESA/
MMPA
status;
strategic
(Y/N) 1
Stock
Grampus griseus .................
Phocoena phocoena ............
Phocoenoides dalli ..............
Stock abundance
(CV, Nmin, most recent
abundance
survey) 2
PBR
Annual
M/SI 3
California/Oregon/Washington.
California/Oregon/Washington.
-/-; N
2,697 (0.6, 1,633, 2014) ......
16
0
-/-; N
3,044 (0.54, 1,967, 2014) ....
20
0.1
California/Oregon/Washington offshore.
California/Oregon/Washington.
California/Oregon/Washington.
California/Oregon/Washington.
British Columbia 4 ................
-/-; N
1,924 (0.54, 1,255, 2014) ....
11
>1.6
-/-; N
29,211 (0.2, 24,782, 2014) ..
238
>0.8
-/-; N
969,861 (0.17, 839,325,
2014).
26,814 (0.28, 21,195, 2014)
8,393
>40
-/-; N
7.5
Unknown
-/-; N
22,160 (unknown, 16,522,
2008).
26,556 (0.44, 18,608, 2014)
179
3.8
-/-; N
6,336 (0.32, 4,817, 2014) ....
46
>3.7
N/A
-/-; N
E/D; Y
-/-; N
-/-; N
-/-; N
N/A .......................................
300 (0.1, 276, 2012) ............
73 (N/A, 73, 2019) ...............
302 (N/A, 302, 2018) ...........
349 (N/A, 349, 2018) ...........
836 (0.79, 466, 2014) ..........
N/A
2.8
0.13
2.2
3.5
4.5
N/A
0
>0.4
0.2
0.4
1.2
Northern Oregon/Washington Coast.
Northern California/Southern
Oregon.
British Columbia 4 ................
-/-; N
21,487 (0.44, 15,123, 2011)
151
>3.0
-/-; N
35,769 (0.52, 23,749, 2011)
475
>0.6
N/A
Unknown
California/Oregon/Washington.
British Columbia 4 ................
-/-; N
8,091 (unknown, 4,885,
2008).
25,750 (0.45, 17,954, 2014)
California/Oregon/Washington.
California/Oregon/Washington.
N/A .......................................
Offshore ...............................
Southern Resident ...............
Northern Resident ...............
West Coast Transient ..........
California/Oregon/Washington.
N/A
191
N/A
172
Unknown
Unknown
0.3
5,303 (unknown, 4,638,
2008).
Unknown
Unknown
608,143 (0.2, 514,738,
2018).
14,050 (N/A, 7,524, 2013) ...
257,606 (N/A, 233,515,
2014).
43,201 (see SAR, 43,201,
2017).
4,037 (unknown, 1,100,
2008).
34,187 (N/A, 31,019, 2013)
11,067
387
451
14,011
1.8
>321
2,592
113
Order Carnivora—Superfamily Pinnipedia
Family Otariidae (eared seals
and sea lions):
Northern fur seal ............
Callorhinus ursinus ..............
Eastern Pacific .....................
-/D; Y
California sea lion ..........
Zalophus californianus .........
California ..............................
U.S. ......................................
-/D; N
-/-; N
Steller sea lion ...............
Eumetopias jubatus .............
Eastern U.S. ........................
-/-; N
British Columbia 4 ................
N/A
Arctocephalus philippii
townsendi.
Mexico to California .............
T/D; Y
Phoca vitulina ......................
Oregon/Washington Coastal
-/-; N
British Columbia 4 ................
N/A
California Breeding ..............
-/-; N
Guadalupe fur seal .........
Family Phocidae (earless
seals):
Harbor seal .....................
Northern elephant seal ...
Mirounga angustirostris .......
Unknown (Unknown, Unknown, 1999).
24,916 (Unknown, 19,666,
2008).
179,000 (N/A, 81,368, 2010)
Unknown
Unknown
1,062
>3.8
Undetermined
10.6
Unknown
4,882
Unknown
8.8
1—Endangered Species Act (ESA) status: Endangered (E), Threatened (T)/MMPA status: Depleted (D). A dash (-) indicates that the species is not listed under the
ESA or designated as depleted under the MMPA. Under the MMPA, a strategic stock is one for which the level of direct human-caused mortality exceeds PBR or
which is determined to be declining and likely to be listed under the ESA within the foreseeable future. Any species or stock listed under the ESA is automatically
designated under the MMPA as depleted and as a strategic stock.
2—NMFS marine mammal stock assessment reports online at: https://www.fisheries.noaa.gov/national/marine-mammal-protection/marine-mammal-stock-assessments. CV is coefficient of variation; Nmin is the minimum estimate of stock abundance. In some cases, CV is not applicable.
3—These values, found in NMFS’s SARs, represent annual levels of human-caused mortality plus serious injury from all sources combined (e.g., commercial fisheries, ship strike). Annual M/SI often cannot be determined precisely and is in some cases presented as a minimum value or range. A CV associated with estimated
mortality due to commercial fisheries is presented in some cases.
4—Best et al. (2015) total abundance estimates for animals in British Columbia based on surveys of the Strait of Georgia, Johnstone Strait, Queen Charlotte
Sound, Hecate Strait, and Dixon Entrance. These rows represent British Columbia abundance estimates, where available, but do not represent additional stocks.
5—The California/Oregon/Washington stock of Mesoplodont beaked whales includes six species of beaked whales. Of the six species represented in this stock,
only Blainville’s beaked whales, Hubbs’ beaked whales, and Stejneger’s beaked whales are expected to be encountered or taken.
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All species that could potentially
occur in the planned survey areas are
included in Table 1. However,
additional species have been recorded
in the specified geographic region but
are considered sufficiently rare that take
is not anticipated. The temporal and/or
spatial occurrence of North Pacific right
whales (Eubalaena japonica) is such
that take is not expected to occur, and
they are not discussed further beyond
the explanation provided here. Only 82
sightings of right whales in the entire
eastern North Pacific were reported
from 1962 to 1999, with the majority of
these occurring in the Bering Sea and
adjacent areas of the Aleutian Islands
(Brownell et al., 2001). Most sightings in
the past 20 years have occurred in the
southeastern Bering Sea, with a few in
the Gulf of Alaska (Wade et al., 2011).
Despite many miles of systematic aerial
and ship-based surveys for marine
mammals off the coasts of Washington,
Oregon and California over several
years, only seven documented sightings
of right whales were made from 1990 to
2000 (Waite et al., 2003), and NMFS
only aware of two documented sightings
in the area since then. Because of the
small population size and the fact that
North Pacific right whales spend the
summer feeding in high latitudes, the
likelihood that the planned survey
would encounter a North Pacific right
whale is discountable.
In addition, the Northern sea otter
(Enhydra lutris kenyoni) may be found
in coastal waters of the survey area.
However, sea otters are managed by the
U.S. Fish and Wildlife Service and are
not considered further in this document.
A detailed description of the species
likely to be affected by L–DEO’s
geophysical survey, including brief
introductions to the species and
relevant stocks as well as available
information regarding population trends
and threats, and information regarding
local occurrence, were provided in the
Federal Register notice of proposed IHA
(85 FR 19580; April 7, 2020). Since that
time, NMFS has published the draft
2020 SARs with updated abundance,
PBR, and/or mortality information for
the Eastern Pacific stock of northern fur
seals, West Coast Transient stock of
killer whales, Central North Pacific
stock of humpback whales, Northeast
Pacific and California/Oregon/
Washington stocks of fin whale, Eastern
North Pacific Southern Resident stock of
killer whales, and Eastern North Pacific
Stock and Pacific Coast Feeding Group
of gray whales. The relevant information
for these stocks has been updated in
Table 1, however the status of these
species and stocks has not changed;
therefore detailed descriptions are not
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provided here. Please refer to the
Federal Register notice of proposed IHA
for these descriptions. Please also refer
to NMFS’ website (https://
www.fisheries.noaa.gov/find-species) for
generalized species accounts.
Biologically Important Areas and
Critical Habitat
Biologically Important Areas (BIAs)
for feeding gray whales along the coasts
of Washington, Oregon, and California
have been identified, including northern
Puget Sound, Northwestern
Washington, and Grays Harbor in
Washington, Depoe Bay and Cape
Blanco and Orford Reef in Oregon, and
Point St. George in California; most of
these areas are of importance from late
spring through early fall (Calambokidis
et al., 2015). BIAs have also been
identified for migrating gray whales
along the entire coasts of Washington,
Oregon, and California; although most
whales travel within 10 km from shore,
the BIAs were extended out to 47 km
from the coastline (Calambokidis et al.,
2015). The planned survey will occur
during the late spring/summer feeding
season, when most individuals from the
eastern North Pacific stock occur farther
north. Nonetheless, individual gray
whales, particularly those from the
PCFG could be encountered in
nearshore waters of the project area.
Prior to 2016, humpback whales were
listed under the ESA as an endangered
species worldwide. Following a 2015
global status review (Bettridge et al.,
2015), NMFS delineated 14 distinct
population segments (DPS) with
different listing statuses (81 FR 62259;
September 8, 2016) pursuant to the ESA.
The DPSs that occur in U.S. waters do
not necessarily equate to the existing
stocks designated under the MMPA and
shown in Table 1. Because MMPA
stocks cannot be portioned, i.e., parts
managed as ESA-listed while other parts
managed as not ESA-listed, until such
time as the MMPA stock delineations
are reviewed in light of the DPS
designations, NMFS considers the
existing humpback whale stocks under
the MMPA to be endangered and
depleted for MMPA management
purposes (e.g., selection of a recovery
factor, stock status).
Within the survey area, three DPSs
may occur: The Hawaii DPS (not listed),
Mexico DPS (threatened), and Central
America DPS (endangered). On April
21, 2021, NMFS issued a final rule to
designate critical habitat in nearshore
waters of the North Pacific Ocean for the
endangered Central America DPS and
the threatened Mexico DPS of
humpback whale (86 FR 21082). Critical
habitat for the Central America DPS and
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Mexico DPS was established within the
California Current Ecosystem (CCE) off
the coasts California, Oregon, and
Washington, representing areas of key
foraging habitat. Off Washington and
northern Oregon, the critical habitat
extends from the 50-m isobath out to the
1200-m isobath; off southern Oregon
(south of 42°10′ N), it extends out to the
2000-m isobath. L–DEO’s easternmost
planned tracklines occur within
designated humpback whale critical
habitat along the coast.
Critical habitat for humpbacks has
been designated under Canadian law in
four locations in British Columbia (DFO
2013), including in the waters of the
survey area off southwestern Vancouver
Island. The other three locations are
located north of the survey area at Haida
Gwaii (Langara Island and Southeast
Moresby Island) and at Gil Island (DFO
2013). These areas show persistent
aggregations of humpback whales and
have features such as prey availability,
suitable acoustic environment, water
quality, and physical space that allow
for feeding, foraging, socializing, and
resting (DFO 2013). A small portion of
L–DEO’s planned tracklines overlap
with Canadian designated humpback
whale critical habitat off southwest
Vancouver Island.
BIAs for feeding humpbacks along the
coasts of Oregon and Washington,
which have been described from May to
November, are all within approximately
80 km from shore, and include the
waters off northern Washington, and
Stonewall and Heceta Bank, Oregon
(Calambokidis et al., 2015). Some
segments of L–DEO’s planned tracklines
overlap with these BIAs.
The U.S. Southern Resident killer
whale critical habitat designated under
the ESA currently includes inland
waters of Washington relative to a
contiguous shoreline delimited by the
line at a depth of 6.1 m relative to
extreme high water (71 FR 69054;
November 29, 2006). On September 19,
2019, NMFS published a proposed rule
to revise designated Southern Resident
killer whale critical habitat to include
40,472.7 km2 of marine waters between
the 6.1-m depth contour and the 200-m
depth contour from the U.S.
international border with Canada south
to Point Sur, California (84 FR 49214;
September 19, 2019). The planned
survey tracklines overlap with NMFS’
proposed expanded Southern Resident
critical habitat.
In Canada, Southern Resident killer
whales are listed as Endangered under
the Species at Risk Act (SARA), and
critical habitat has been designated in
the trans-boundary waters in southern
British Columbia, including the
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southern Strait of Georgia, Haro Strait,
and Strait of Juan de Fuca (SOR/2018–
278, December 13, 2018; SOR/2009–68,
February 19, 2009; DFO 2018). The
continental shelf waters off
southwestern Vancouver Island,
including Swiftsure and La Pe´rouse
Banks have also been designated as
critical habitat for Southern Resident
and Northern Resident killer whales
(SOR/2018–278, December 13, 2018). As
discussed above, L–DEO’s initial
proposed survey tracklines that
overlapped with Canadian designated
critical habitat for killer whales have
been eliminated.
Federally designated critical habitat
for Steller sea lions in Oregon and
California includes all rookeries (NMFS
1993). Although the Eastern DPS was
delisted from the ESA in 2013, the
designated critical habitat remains valid
(NOAA 2019e). The critical habitat in
Oregon is located along the coast at
Rogue Reef (Pyramid Rock) and Orford
Reef (Long Brown Rock and Seal Rock).
The critical habitat area includes
aquatic zones that extend 0.9 km
seaward and air zones extending 0.9 km
above these terrestrial and aquatic zones
(NMFS 1993). L–DEO’s planned
tracklines lie about 9 and 13 km away
from the two Oregon units of Steller sea
lion critical habitat.
Unusual Mortality Events
On May 30, 2019, NMFS declared an
unusual mortality event (UME) for gray
whales after elevated numbers of
strandings occurred along the U.S. west
coast. As of April 5, 2021, a total of 430
stranded gray whales have been
reported, including 209 in the United
States (93 in Alaska, 50 in Washington,
9 in Oregon, and 57 in California), 205
in Mexico, and 16 in Canada. Full or
partial necropsy examinations were
conducted on a subset of the whales.
Preliminary findings in several of the
whales have shown evidence of
emaciation. These findings are not
consistent across all of the whales
examined, so more research is needed.
The UME is ongoing, and NMFS
continues to investigate the cause(s).
Additional information about the UME
is available at https://www.fisheries.
noaa.gov/national/marine-life-distress/
2019-2020-gray-whale-unusualmortality-event-along-west-coast.
Increased strandings of Guadalupe fur
seals have occurred along the entire
coast of California. Guadalupe fur seal
strandings began in January 2015 and
were eight times higher than the
historical average. Strandings have
continued since 2015 and have
remained well above average through
2019. Strandings are seasonal and
generally peak in April through June of
each year. Strandings in Oregon and
Washington became elevated starting in
2019 and have continued to present.
Strandings in these two states in 2019
are five times higher than the historical
average. Guadalupe fur seals have
stranded alive and dead. Those
stranding are mostly weaned pups and
juveniles (1–2 years old). The majority
of stranded animals showed signs of
malnutrition with secondary bacterial
and parasitic infections. NMFS has
declared a UME for Guadalupe fur seals
along the entire U.S. West Coast; the
UME is ongoing and NMFS is
continuing to investigate the cause(s).
For additional information on the UME,
see https://www.fisheries.noaa.gov/
national/marine-life-distress/2015-2020guadalupe-fur-seal-unusual-mortalityevent-california.
Elevated strandings of California sea
lion pups occurred in Southern
California between January 2013 and
September 2016. As a result, NMFS
declared a UME. The UME was confined
to pup and yearling California sea lions,
many of which were emaciated,
dehydrated, and underweight for their
age. A change in the availability of sea
lion prey, especially sardines, a high
value food source for nursing mothers,
was a likely contributor to the large
number of strandings. Sardine spawning
grounds shifted further offshore in 2012
and 2013, and while other prey were
available (market squid and rockfish),
these may not have provided adequate
nutrition in the milk of sea lion mothers
supporting pups, or for newly-weaned
pups foraging on their own. Although
the pups showed signs of some viruses
and infections, findings indicate that
this event was not caused by disease,
but rather by the lack of high quality,
close-by food sources for nursing
29109
mothers. Current evidence does not
indicate that this UME was caused by a
single infectious agent, though a variety
of disease-causing bacteria and viruses
were found in samples from sea lion
pups. The investigative team examined
multiple potential explanations for the
high numbers of malnourished
California sea lion pups observed on the
island rookeries and stranded on the
mainland in 2013. For more
information, see https://www.fisheries.
noaa.gov/national/marine-life-distress/
2013-2017-california-sea-lion-unusualmortality-event-california.
Marine Mammal Hearing
Hearing is the most important sensory
modality for marine mammals
underwater, and exposure to
anthropogenic sound can have
deleterious effects. To appropriately
assess the potential effects of exposure
to sound, it is necessary to understand
the frequency ranges marine mammals
are able to hear. Current data indicate
that not all marine mammal species
have equal hearing capabilities (e.g.,
Richardson et al., 1995; Wartzok and
Ketten, 1999; Au and Hastings, 2008).
To reflect this, Southall et al. (2007)
recommended that marine mammals be
divided into functional hearing groups
based on directly measured or estimated
hearing ranges on the basis of available
behavioral response data, audiograms
derived using auditory evoked potential
techniques, anatomical modeling, and
other data. Note that no direct
measurements of hearing ability have
been successfully completed for
mysticetes (i.e., low-frequency
cetaceans). Subsequently, NMFS (2018)
described generalized hearing ranges for
these marine mammal hearing groups.
Generalized hearing ranges were chosen
based on the approximately 65 dB
threshold from the normalized
composite audiograms, with the
exception for lower limits for lowfrequency cetaceans where the lower
bound was deemed to be biologically
implausible and the lower bound from
Southall et al. (2007) retained. Marine
mammal hearing groups and their
associated hearing ranges are provided
in Table 2.
TABLE 2—MARINE MAMMAL HEARING GROUPS (NMFS, 2018)
Hearing group
Generalized hearing range *
Low-frequency (LF) cetaceans (baleen whales) ................................................................................................
Mid-frequency (MF) cetaceans (dolphins, toothed whales, beaked whales, bottlenose whales) .....................
High-frequency (HF) cetaceans (true porpoises, Kogia, river dolphins, cephalorhynchid, Lagenorhynchus
cruciger & L. australis).
Phocid pinnipeds (PW) (underwater) (true seals) .............................................................................................
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7 Hz to 35 kHz.
150 Hz to 160 kHz.
275 Hz to 160 kHz.
50 Hz to 86 kHz.
28MYN3
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TABLE 2—MARINE MAMMAL HEARING GROUPS (NMFS, 2018)—Continued
Hearing group
Generalized hearing range *
Otariid pinnipeds (OW) (underwater) (sea lions and fur seals) .........................................................................
60 Hz to 39 kHz.
* Represents the generalized hearing range for the entire group as a composite (i.e., all species within the group), where individual species’
hearing ranges are typically not as broad. Generalized hearing range chosen based on ∼65 dB threshold from normalized composite audiogram,
with the exception for lower limits for LF cetaceans (Southall et al. 2007) and PW pinniped (approximation).
The pinniped functional hearing
group was modified from Southall et al.
(2007) on the basis of data indicating
that phocid species have consistently
demonstrated an extended frequency
range of hearing compared to otariids,
especially in the higher frequency range
(Hemila¨ et al., 2006; Kastelein et al.,
2009; Reichmuth and Holt, 2013).
For more detail concerning these
groups and associated frequency ranges,
please see NMFS (2018) for a review of
available information. 31 marine
mammal species (25 cetacean and six
pinniped (four otariid and two phocid)
species) have the reasonable potential to
co-occur with the planned survey
activities. Please refer to Table 1. Of the
cetacean species that may be present,
six are classified as low-frequency
cetaceans (i.e., all mysticete species), 15
are classified as mid-frequency
cetaceans (i.e., all delphinid and ziphiid
species and the sperm whale), and four
are classified as high-frequency
cetaceans (i.e., porpoises and Kogia
spp.).
Potential Effects of Specified Activities
on Marine Mammals and Their Habitat
The effects of underwater noise from
L–DEO’s geophysical survey activities
have the potential to result in behavioral
harassment of marine mammals in the
vicinity of the survey area. The notice
of proposed IHA (85 FR 19580; April 7,
2020) included a discussion of the
effects of anthropogenic noise on marine
mammals and the potential effects of
underwater noise from L–DEO’s
geophysical survey activities on marine
mammals and their habitat. That
information and analysis is incorporated
by reference into this final IHA
determination and is not repeated here;
please refer to the notice of proposed
IHA (85 FR 19580; April 7, 2020). The
referenced information includes a
summary and discussion of the ways
that the specified activity may impact
marine mammals and their habitat.
Consistent with the analysis in our prior
Federal Register notices for similar L–
DEO surveys and after independently
evaluating the analysis in L–DEO’s
application, we determine that the
survey is likely to result in the takes
described in the Estimated Take section
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of this document and that other forms
of take are not expected to occur.
The Estimated Take section later in
this document includes a quantitative
analysis of the number of individuals
that are expected to be taken by this
activity. The Negligible Impact Analysis
and Determination section considers the
content of this section, the Estimated
Take section, and the Mitigation section,
to draw conclusions regarding the likely
impacts of these activities on the
reproductive success or survivorship of
individuals and how those impacts on
individuals are likely to impact marine
mammal species or stocks.
Description of Active Acoustic Sound
Sources
The notice of proposed IHA provided
a brief technical background on sound,
on the characteristics of certain sound
types, and on metrics used in the
proposal inasmuch as the information
was relevant to the specified activity
and to a discussion of the potential
effects of the specified activity on
marine mammals found later in this
document. Please see that document (85
FR 19580; April 7, 2020) for additional
information. For general information on
sound and its interaction with the
marine environment, please see, e.g., Au
and Hastings (2008); Richardson et al.
(1995); Urick (1983).
Estimated Take
This section provides an estimate of
the number of incidental takes
authorized through this IHA, which will
inform both NMFS’ consideration of
‘‘small numbers’’ and the negligible
impact determination.
Harassment is the only type of take
expected to result from these activities.
Except with respect to certain activities
not pertinent here, section 3(18) of the
MMPA defines ‘‘harassment’’ as any act
of pursuit, torment, or annoyance,
which (i) has the potential to injure a
marine mammal or marine mammal
stock in the wild (Level A harassment);
or (ii) has the potential to disturb a
marine mammal or marine mammal
stock in the wild by causing disruption
of behavioral patterns, including, but
not limited to, migration, breathing,
nursing, breeding, feeding, or sheltering
(Level B harassment).
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Authorized takes will primarily be by
Level B harassment, as use of seismic
airguns has the potential to result in
disruption of behavioral patterns for
individual marine mammals. There is
also some potential for auditory injury
(Level A harassment) for mysticetes and
high frequency cetaceans (i.e.,
porpoises, Kogia spp.). The mitigation
and monitoring measures are expected
to minimize the severity of such taking
to the extent practicable.
As described previously, no serious
injury or mortality is anticipated or
authorized for this activity. Below we
describe how the take is estimated.
Generally speaking, we estimate take
by considering: (1) Acoustic thresholds
above which NMFS believes the best
available science indicates marine
mammals will be behaviorally harassed
or incur some degree of permanent
hearing impairment; (2) the area or
volume of water that will be ensonified
above these levels in a day; (3) the
density or occurrence of marine
mammals within these ensonified areas;
and, (4) and the number of days of
activities. We note that while these
basic factors can contribute to a basic
calculation to provide an initial
prediction of takes, additional
information that can qualitatively
inform take estimates is also sometimes
available (e.g., previous monitoring
results or average group size). Below, we
describe the factors considered here in
more detail and present the take
estimate.
Acoustic Thresholds
NMFS uses acoustic thresholds that
identify the received level of
underwater sound above which exposed
marine mammals would be reasonably
expected to be behaviorally harassed
(equated to Level B harassment) or to
incur PTS of some degree (equated to
Level A harassment).
Level B Harassment for non-explosive
sources—Though significantly driven by
received level, the onset of behavioral
disturbance from anthropogenic noise
exposure is also informed to varying
degrees by other factors related to the
source (e.g., frequency, predictability,
duty cycle), the environment (e.g.,
bathymetry), and the receiving animals
(hearing, motivation, experience,
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demography, behavioral context) and
can be difficult to predict (Southall et
al., 2007, Ellison et al., 2012). NMFS
uses a generalized acoustic threshold
based on received level to estimate the
onset of behavioral harassment. NMFS
predicts that marine mammals are likely
to be behaviorally harassed in a manner
we consider Level B harassment when
exposed to underwater anthropogenic
noise above received levels of 120 dB re
1 microPascal (mPa) root mean square
(rms) for continuous (e.g., vibratory piledriving, drilling) and above 160 dB re 1
mPa (rms) for non-explosive impulsive
(e.g., seismic airguns) or intermittent
(e.g., scientific sonar) sources. L–DEO’s
planned activity includes the use of
impulsive seismic sources. Therefore,
the 160 dB re 1 mPa (rms) criteria is
applicable for analysis of Level B
harassment.
Level A harassment for non-explosive
sources—NMFS’ Technical Guidance
for Assessing the Effects of
Anthropogenic Sound on Marine
Mammal Hearing (Version 2.0)
(Technical Guidance, 2018) identifies
dual criteria to assess auditory injury
(Level A harassment) to five different
marine mammal groups (based on
hearing sensitivity) as a result of
exposure to noise from two different
types of sources (impulsive or nonimpulsive). L–DEO’s planned seismic
survey includes the use of impulsive
(seismic airguns) sources.
These thresholds are provided in the
table below. The references, analysis,
and methodology used in the
development of the thresholds are
described in NMFS 2018 Technical
Guidance, which may be accessed at
https://www.fisheries.noaa.gov/
national/marine-mammal-protection/
marine-mammal-acoustic-technicalguidance.
TABLE 3—THRESHOLDS IDENTIFYING THE ONSET OF PERMANENT THRESHOLD SHIFT
PTS onset acoustic thresholds *
(received level)
Hearing group
Impulsive
Low-Frequency (LF) Cetaceans ......................................
Mid-Frequency (MF) Cetaceans ......................................
High-Frequency (HF) Cetaceans .....................................
Phocid Pinnipeds (PW) (Underwater) .............................
Otariid Pinnipeds (OW) (Underwater) .............................
Cell
Cell
Cell
Cell
Cell
1:
3:
5:
7:
9:
Lpk,flat:
Lpk,flat:
Lpk,flat:
Lpk,flat:
Lpk,flat:
219
230
202
218
232
dB;
dB;
dB;
dB;
dB;
Non-impulsive
LE,LF,24h: 183 dB. ........................
LE,MF,24h: 185 dB ........................
LE,HF,24h: 155 dB ........................
LE,PW,24h: 185 dB .......................
LE,OW,24h: 203 dB .......................
Cell
Cell
Cell
Cell
Cell
2: LE,LF,24h: 199 dB.
4: LE,MF,24h: 198 dB.
6: LE,HF,24h: 173 dB.
8: LE,PW,24h: 201 dB.
10: LE,OW,24h: 219 dB.
* Dual metric acoustic thresholds for impulsive sounds: Use whichever results in the largest isopleth for calculating PTS onset. If a non-impulsive sound has the potential of exceeding the peak sound pressure level thresholds associated with impulsive sounds, these thresholds should
also be considered.
Note: Peak sound pressure (Lpk) has a reference value of 1 μPa, and cumulative sound exposure level (LE) has a reference value of 1μPa2s.
In this Table, thresholds are abbreviated to reflect American National Standards Institute standards (ANSI 2013). However, peak sound pressure
is defined by ANSI as incorporating frequency weighting, which is not the intent for this Technical Guidance. Hence, the subscript ‘‘flat’’ is being
included to indicate peak sound pressure should be flat weighted or unweighted within the generalized hearing range. The subscript associated
with cumulative sound exposure level thresholds indicates the designated marine mammal auditory weighting function (LF, MF, and HF
cetaceans, and PW and OW pinnipeds) and that the recommended accumulation period is 24 hours. The cumulative sound exposure level
thresholds could be exceeded in a multitude of ways (i.e., varying exposure levels and durations, duty cycle). When possible, it is valuable for
action proponents to indicate the conditions under which these acoustic thresholds will be exceeded.
Ensonified Area
Here, we describe operational and
environmental parameters of the activity
that will feed into identifying the area
ensonified above the acoustic
thresholds, which include source levels
and acoustic propagation modeling.
L–DEO’s modeling methodology is
described in greater detail in the IHA
application (LGL 2019). The planned 2D
survey will acquire data using the 36airgun array with a total discharge
volume of 6,600 cubic inches (in3) at a
maximum tow depth of 12 m. L–DEO
model results are used to determine the
160-dBrms radius for the 36-airgun
array in deep water (≤1,000 m) down to
a maximum water depth of 2,000 m.
Water depths in the project area may be
up to 4,400 m, but marine mammals are
generally not anticipated to dive below
2,000 m (Costa and Williams 1999).
Received sound levels were predicted
by L–DEO’s model (Diebold et al., 2010)
which uses ray tracing for the direct
wave traveling from the array to the
receiver and its associated source ghost
(reflection at the air-water interface in
the vicinity of the array), in a constant-
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velocity half-space (infinite
homogeneous ocean layer, unbounded
by a seafloor). In addition, propagation
measurements of pulses from the 36airgun array at a tow depth of 6 m have
been reported in deep water
(approximately 1600 m), intermediate
water depth on the slope (approximately
600–1100 m), and shallow water
(approximately 50 m) in the Gulf of
Mexico in 2007–2008 (Tolstoy et al.
2009; Diebold et al. 2010).
For deep and intermediate-water
cases, the field measurements cannot be
used readily to derive Level A and Level
B harassment isopleths, as at those sites
the calibration hydrophone was located
at a roughly constant depth of 350–500
m, which may not intersect all the
sound pressure level (SPL) isopleths at
their widest point from the sea surface
down to the maximum relevant water
depth for marine mammals of ∼2,000 m.
At short ranges, where the direct
arrivals dominate and the effects of
seafloor interactions are minimal, the
data recorded at the deep and slope sites
are suitable for comparison with
modeled levels at the depth of the
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calibration hydrophone. At longer
ranges, the comparison with the
model—constructed from the maximum
SPL through the entire water column at
varying distances from the airgun
array—is the most relevant.
In deep and intermediate-water
depths, comparisons at short ranges
between sound levels for direct arrivals
recorded by the calibration hydrophone
and model results for the same array
tow depth are in good agreement (Fig.
12 and 14 in Appendix H of NSF–USGS,
2011). Consequently, isopleths falling
within this domain can be predicted
reliably by the L–DEO model, although
they may be imperfectly sampled by
measurements recorded at a single
depth. At greater distances, the
calibration data show that seafloorreflected and sub-seafloor-refracted
arrivals dominate, whereas the direct
arrivals become weak and/or
incoherent. Aside from local topography
effects, the region around the critical
distance is where the observed levels
rise closest to the model curve.
However, the observed sound levels are
found to fall almost entirely below the
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model curve. Thus, analysis of the Gulf
of Mexico calibration measurements
demonstrates that although simple, the
L–DEO model is a robust tool for
conservatively estimating isopleths. For
deep water (>1,000 m), L–DEO used the
deep-water radii obtained from model
results down to a maximum water depth
of 2,000 m.
A recent retrospective analysis of
acoustic propagation from use of the
R/V Langseth sources during a 2012
survey off Washington (i.e., in the same
location) suggests that predicted
(modeled) radii (using the same
approach as that used here) were 2–3
times larger than the measured radii in
shallow water. (Crone et al., 2014).
Therefore, because the modeled
shallow-water radii were specifically
demonstrated to be overly conservative
for the region in which the current
survey is planned, L–DEO used the
received levels from multichannel
seismic data collected by the R/V
Langseth during the 2012 survey to
estimate Level B harassment radii in
shallow (<100 m) and intermediate
(100–1,000 m) depths (Crone et al.,
2014). Streamer data in shallow water
collected in 2012 have the advantage of
including the effects of local and
complex subsurface geology, seafloor
topography, and water column
properties, and thus allow
determination of radii more confidently
than using data from calibration
experiments in the Gulf of Mexico.
The survey will acquire data with a
four-string 6,600-in3 airgun array at a
tow depth of 12 m while the data
collected in 2012 were acquired with
the same airgun array at a tow depth of
9 m. To account for the differences in
tow depth between the 2012 survey and
the planned 2021 survey, L–DEO
calculated a scaling factor using the
deep water modeling (see Appendix D
in L–DEO’s IHA application). A scaling
factor of 1.15 was applied to the
measured radii from the airgun array
towed at 9 m.
The estimated distances to the Level
B harassment isopleth for the R/V
Langseth’s 36-airgun array are shown in
Table 4.
TABLE 4—PREDICTED RADIAL DISTANCES TO ISOPLETHS CORRESPONDING TO LEVEL B HARASSMENT THRESHOLD
Tow depth
(m)
Source and volume
36 airgun array, 6,600-in3 ............................................................................................................
a Distance
b Distance
>1000
100–1000
<100
Level B
harassment
zone (m)
using L–DEO
model
a 6,733
b 9,468
b 12,650
based on L–DEO model results.
based on data from Crone et al. (2014).
Predicted distances to Level A
harassment isopleths, which vary based
on marine mammal hearing groups,
were calculated based on modeling
performed by L–DEO using the
NUCLEUS source modeling software
program and the NMFS User
Spreadsheet, described below. The
acoustic thresholds for impulsive
sounds (e.g., airguns) contained in the
Technical Guidance were presented as
dual metric acoustic thresholds using
both cumulative sound exposure level
(SELcum) and peak sound pressure
metrics (NMFS 2018). As dual metrics,
NMFS considers onset of PTS (Level A
harassment) to have occurred when
either one of the two metrics is
exceeded (i.e., metric resulting in the
largest isopleth). The SELcum metric
considers both level and duration of
exposure, as well as auditory weighting
functions by marine mammal hearing
group. In recognition of the fact that the
requirement to calculate Level A
harassment ensonified areas could be
more technically challenging to predict
due to the duration component and the
use of weighting functions in the new
SELcum thresholds, NMFS developed an
optional User Spreadsheet that includes
tools to help predict a simple isopleth
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that can be used in conjunction with
marine mammal density or occurrence
to facilitate the estimation of take
numbers.
The values for SELcum and peak SPL
for the R/V Langseth airgun array were
derived from calculating the modified
far-field signature (Table 5). The farfield
signature is often used as a theoretical
representation of the source level. To
compute the farfield signature, the
source level is estimated at a large
distance below the array (e.g., 9 km),
and this level is back projected
mathematically to a notional distance of
1 m from the array’s geometrical center.
However, when the source is an array of
multiple airguns separated in space, the
source level from the theoretical farfield
signature is not necessarily the best
measurement of the source level that is
physically achieved at the source
(Tolstoy et al. 2009). Near the source (at
short ranges, distances <1 km), the
pulses of sound pressure from each
individual airgun in the source array do
not stack constructively, as they do for
the theoretical farfield signature. The
pulses from the different airguns spread
out in time such that the source levels
observed or modeled are the result of
the summation of pulses from a few
airguns, not the full array (Tolstoy et al.
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2009). At larger distances, away from
the source array center, sound pressure
of all the airguns in the array stack
coherently, but not within one time
sample, resulting in smaller source
levels (a few dB) than the source level
derived from the farfield signature.
Because the farfield signature does not
take into account the large array effect
near the source and is calculated as a
point source, the modified farfield
signature is a more appropriate measure
of the sound source level for distributed
sound sources, such as airgun arrays. L–
DEO used the acoustic modeling
methodology as used for Level B
harassment with a small grid step of 1
m in both the inline and depth
directions. The propagation modeling
takes into account all airgun
interactions at short distances from the
source, including interactions between
subarrays, which are modeled using the
NUCLEUS software to estimate the
notional signature and MATLAB
software to calculate the pressure signal
at each mesh point of a grid.
For a more complete explanation of
this modeling approach, please see
‘‘Appendix A: Determination of
Mitigation Zones’’ in the IHA
application.
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TABLE 5—MODELED SOURCE LEVELS BASED ON MODIFIED FARFIELD SIGNATURE FOR THE 6,600-IN 3 AIRGUN ARRAY
Low frequency
cetaceans
(Lpk,flat: 219
dB; LE,LF,24h:
183 dB)
Mid frequency
cetaceans
(Lpk,flat: 230
dB; LE,MF,24h:
185 dB
252.06
232.98
252.65
232.84
6,600 in3 airgun array (Peak SPLflat) ..................................
6,600 in3 airgun array (SELcum) ...........................................
In order to more realistically
incorporate the Technical Guidance’s
weighting functions over the seismic
array’s full acoustic band, unweighted
spectrum data for the R/V Langseth’s
airgun array (modeled in 1 Hz bands)
was used to make adjustments (dB) to
the unweighted spectrum levels, by
frequency, according to the weighting
functions for each relevant marine
mammal hearing group. These adjusted/
weighted spectrum levels were then
converted to pressures (mPa) in order to
integrate them over the entire
broadband spectrum, resulting in
broadband weighted source levels by
hearing group that could be directly
incorporated within the User
Spreadsheet (i.e., to override the
Spreadsheet’s more simple weighting
factor adjustment). Using the User
Spreadsheet’s ‘‘safe distance’’
methodology for mobile sources
(described by Sivle et al., 2014) with the
hearing group-specific weighted source
levels, and inputs assuming spherical
spreading propagation and source
velocities (4.2 knots) and shot intervals
(37.5 m) specific to the planned survey,
potential radial distances to auditory
injury zones were then calculated for
SELcum thresholds.
Inputs to the User Spreadsheets in the
form of estimated SLs are shown in
High
frequency
cetaceans
(Lpk,flat: 202
dB; LE,HF,24h:
155 dB)
Phocid
pinnipeds
(underwater)
(Lpk,flat: 218
dB; LE,HF,24h:
185 dB)
253.24
233.10
Otariid
pinnipeds
(underwater)
(Lpk,flat: 232
dB; LE,HF,24h:
203 dB)
252.25
232.84
252.52
232.08
Table 5. User Spreadsheets used by
L–DEO to estimate distances to Level A
harassment isopleths for the 36-airgun
array for the surveys are shown in Table
A–3 in Appendix A of the IHA
application. Outputs from the User
Spreadsheets in the form of estimated
distances to Level A harassment
isopleths for the survey are shown in
Table 6. As described above, NMFS
considers onset of PTS (Level A
harassment) to have occurred when
either one of the dual metrics (SELcum
and Peak SPLflat) is exceeded (i.e.,
metric resulting in the largest isopleth).
TABLE 6—MODELED RADIAL DISTANCES (M) TO ISOPLETHS CORRESPONDING TO LEVEL A HARASSMENT THRESHOLDS
Level A harassment zone (m)
Source
(volume)
Threshold
36-airgun array (6,600 in3) ................
SELcum ..................
Peak .....................
LF cetaceans
Note that because of some of the
assumptions included in the methods
used (e.g., stationary receiver with no
vertical or horizontal movement in
response to the acoustic source),
isopleths produced may be
overestimates to some degree, which
will ultimately result in some degree of
overestimation of Level A harassment.
However, these tools offer the best way
to predict appropriate isopleths when
more sophisticated modeling methods
are not available, and NMFS continues
to develop ways to quantitatively refine
these tools and will qualitatively
address the output where appropriate.
For mobile sources, such as this seismic
survey, the User Spreadsheet predicts
the closest distance at which a
stationary animal would not incur PTS
if the sound source traveled by the
animal in a straight line at a constant
speed.
Auditory injury is unlikely to occur
for mid-frequency cetaceans, otariid
pinnipeds, and phocid pinnipeds given
very small modeled zones of injury for
those species (up to 43.7 m), in context
of distributed source dynamics. The
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MF cetaceans
HF cetaceans
0
13.6
1.3
268.3
426.9
38.9
source level of the array is a theoretical
definition assuming a point source and
measurement in the far-field of the
source (MacGillivray, 2006). As
described by Caldwell and Dragoset
(2000), an array is not a point source,
but one that spans a small area. In the
far-field, individual elements in arrays
will effectively work as one source
because individual pressure peaks will
have coalesced into one relatively broad
pulse. The array can then be considered
a ‘‘point source.’’ For distances within
the near-field, i.e., approximately 2–3
times the array dimensions, pressure
peaks from individual elements do not
arrive simultaneously because the
observation point is not equidistant
from each element. The effect is
destructive interference of the outputs
of each element, so that peak pressures
in the near-field will be significantly
lower than the output of the largest
individual element. Here, the relevant
peak isopleth distances for these three
hearing groups would in all cases be
expected to be within the near-field of
the array where the definition of source
level breaks down. Therefore, actual
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Phocids
13.9
43.7
Otariids
0
10.6
locations within this distance of the
array center where the sound level
exceeds the relevant criteria would not
necessarily exist. In general, Caldwell
and Dragoset (2000) suggest that the
near-field for airgun arrays is considered
to extend out to approximately 250 m.
For full discussion of these concepts,
please see our notice of proposed IHA
(85 FR 19580; April 7, 2020).
In consideration of the received sound
levels in the near-field as described
above, we expect the potential for Level
A harassment of mid-frequency
cetaceans, otariid pinnipeds, and
phocid pinnipeds to be de minimis,
even before the likely moderating effects
of aversion and/or other compensatory
behaviors (e.g., Nachtigall et al., 2018)
are considered. We do not believe that
Level A harassment is a likely outcome
for any mid-frequency cetacean, otariid
pinniped, or phocid pinniped and have
not authorized any Level A harassment
for these species.
Marine Mammal Occurrence
In this section we provide the
information about the presence, density,
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and group dynamics of marine
mammals that will inform the take
calculations.
Extensive systematic aircraft- and
ship-based surveys have been
conducted for marine mammals in
offshore waters of Oregon and
Washington (e.g., Bonnell et al., 1992;
Green et al., 1992, 1993; Barlow 1997,
2003; Barlow and Taylor 2001;
Calambokidis and Barlow 2004; Barlow
and Forney 2007; Forney 2007; Barlow
2010). Ship surveys for cetaceans in
slope and offshore waters of Oregon and
Washington were conducted by NMFS’
Southwest Fisheries Science Center
(SWFSC) in 1991, 1993, 1996, 2001,
2005, 2008, and 2014 and synthesized
by Barlow (2016); these surveys were
conducted from the coastline up to ∼556
km from shore from June or August to
November or December. These data
were used by the SWFSC to develop
spatial models of cetacean densities for
the California Current Ecosystem (CCE).
Systematic, offshore, at-sea survey data
for pinnipeds are more limited (e.g.,
Bonnell et al., 1992; Adams et al., 2014).
In British Columbia, several systematic
surveys have been conducted in coastal
waters (e.g., Williams and Thomas 2007;
Ford et al., 2010a; Best et al., 2015;
Harvey et al., 2017). Surveys in coastal
as well as offshore waters were
conducted by DFO during 2002 to 2008;
however, little effort occurred off the
west coast of Vancouver Island during
late spring/summer (Ford et al., 2010).
Density estimates for the survey areas
outside the U.S. EEZ, i.e., in the
Canadian EEZ, were not readily
available, so density estimates for U.S.
waters were applied to the entire survey
area.
The U.S. Navy primarily used SWFSC
habitat-based cetacean density models
to develop a marine species density
database (MSDD) for the Northwest
Training and Testing (NWTT) Study
Area for NWTT Phase III activities (U.S.
Navy 2019a), which encompasses the
U.S. portion of the survey area. For
several cetacean species, the Navy
updated densities estimated by linetransect surveys or mark-recapture
studies (e.g., Barlow 2016). These
methods usually produce a single value
for density that is an averaged estimate
across very large geographical areas,
such as waters within the U.S. EEZ off
California, Oregon, and Washington
(referred to as a ‘‘uniform’’ density
estimate). This is the general approach
applied in estimating cetacean
abundance in the NMFS stock
assessment reports. The disadvantage of
these methods is that they do not
provide spatially- or temporally-explicit
density information. More recently, a
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newer method called spatial habitat
modeling has been used to estimate
cetacean densities that address some of
these shortcomings (e.g., Barlow et al.,
2009; Becker et al., 2010; 2012a; 2014;
Becker et al., 2016; Ferguson et al.,
2006; Forney et al., 2012; 2015; Redfern
et al., 2006). (Note that spatial habitat
models are also referred to as ‘‘species
distribution models’’ or ‘‘habitat-based
density models.’’) These models
estimate density as a continuous
function of habitat variables (e.g., sea
surface temperature, seafloor depth) and
thus, within the study area that was
modeled, densities can be predicted at
all locations where these habitat
variables can be measured or estimated.
Spatial habitat models therefore allow
estimates of cetacean densities on finer
scales (spatially and temporally) than
traditional line-transect or markrecapture analyses.
The methods used to estimate
pinniped at-sea densities are typically
different than those used for cetaceans,
because pinnipeds are not limited to the
water and spend a significant amount of
time on land (e.g., at rookeries).
Pinniped abundance is generally
estimated via shore counts of animals
on land at known haulout sites or by
counting number of pups weaned at
rookeries and applying a correction
factor to estimate the abundance of the
population (for example Harvey et al.,
1990; Jeffries et al., 2003; Lowry, 2002;
Sepulveda et al., 2009). Estimating inwater densities from land-based counts
is difficult given the variability in
foraging ranges, migration, and haulout
behavior between species and within
each species, and is driven by factors
such as age class, sex class, breeding
cycles, and seasonal variation. Data
such as age class, sex class, and seasonal
variation are often used in conjunction
with abundance estimates from known
haulout sites to assign an in-water
abundance estimate for a given area.
The total abundance divided by the area
of the region provides a representative
in-water density estimate for each
species in a different location. In
addition to using shore counts to
estimate pinniped density, traditional
line-transect derived estimates are also
used, particularly in open ocean areas.
The Navy’s MSDD is currently the
most comprehensive compendium for
density data available for the CCE.
However, data products are currently
not publically available for the database;
thus, in this analysis the Navy’s data
products were used only for species for
which density data were not available
from an alternative spatially-explicit
model (e.g., pinnipeds, Kogia spp.,
minke whales, sei whales, gray whales,
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short-finned pilot whales, and Northern
Resident, transient, and offshore killer
whales). For these species, a geographic
information system (GIS) was used to
determine the areas expected to be
ensonified in each density category (i.e.,
distance from shore). For pinnipeds, the
densities from the Navy’s MSDD were
corrected by projecting the most recent
population growth and updated
population estimates to 2020, when
available. Where available, the
appropriate seasonal density estimate
from the MSDD was used in the
estimation here (i.e., summer).
NMFS obtained data products from
the Navy for densities of Southern
Resident killer whales in the NWTT
Offshore Study Area. The modeled
density estimates were available on the
scale of 1 km by 1 km grid cells. The
densities from grid cells overlapping the
ensonified area in each depth category
were multiplied by the corresponding
area to estimate potential exposures
(Table 9).
For most other species, (i.e.,
humpback, blue, fin, sperm, Baird’s
beaked, and other small beaked whales;
bottlenose, striped, common, Pacific
white-sided, Risso’s and northern right
whale dolphins; and Dall’s porpoise),
habitat-based density models from
Becker et al. (2016) were used. Becker
et al. (2016) used seven years of SWFSC
cetacean line-transect survey data
collected between 1991 and 2009 to
develop predictive habitat-based models
of cetacean densities in the CCE. The
modeled density estimates were
available on the scale of 7 km by 10 km
grid cells. The densities from all grid
cells overlapping the ensonified areas
within each water depth category were
averaged to calculate a zone-specific
density for each species.
Becker et al. (2016) did not develop a
density model for the harbor porpoise,
so densities from Forney et al. (2014)
were used for that species. Forney et al.
(2014) presented estimates of harbor
porpoise abundance and density along
the Pacific coast of California, Oregon,
and Washington based on aerial linetransect surveys conducted between
2007 and 2012. Separate density
estimates were provided for harbor
porpoises in Oregon south of 45° N and
Oregon/Washington north of 45° N (i.e.,
within the boundaries of the Northern
California/Southern Oregon and
Northern Oregon/Washington Coast
stocks), so stock-specific take estimates
were generated (Forney et al., 2014).
Background information on the
density calculations for each species/
guild (if different from the general
methods from the Navy’s MSDD, Becker
et al. (2016), or Forney et al. (2014)
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described above) are reported here.
Density estimates for each species/guild
(aside from Southern Resident killer
whales, which are discussed separately)
are found in Table 7.
Gray Whale
DeAngelis et al. (2011) developed a
migration model that provides monthly,
spatially explicit predictions of gray
whale abundance along the U.S. West
Coast from December through June.
These monthly density estimates apply
to a ‘‘main migration corridor’’ that
extends from the coast to 10 km
offshore. A zone from the main
migration corridor out to 47 km offshore
is designated as an area of ‘‘potential
presence’’. To derive a density estimate
for this area the Navy assumed that 1
percent of the population could be
within the 47-km ‘‘potential presence’’
area during migration. Given the 2014
stock assessment population estimate of
20,990 animals (Carretta et al., 2017b),
approximately 210 gray whales may use
this corridor. Assuming the migration
wave lasts 30 days, then 7 whales on
average on any one day could occur in
the ‘‘potential presence’’ area. The area
from the main migration route offshore
to 47 km within the NWTT study area
= 45,722.06 km2, so density within this
zone = 0.00015 whales/km2. From July–
November, gray whale occurrence off
the coast is expected to consist
primarily of whales belonging to the
Pacific Coast Feeding Group (PCFG).
Calambokidis et al. (2012) provided an
updated analysis of the abundance of
the PCFG whales in the Pacific
Northwest and recognized that this
group forms a distinct feeding
aggregation. For the purposes of
establishing density, the Navy assumed
that from July 1 to November 30 all the
209 PCFG whales could be present off
the coast in the Northern California/
Oregon/Washington region (this
accounts for the potential that some
PCFG whales may be outside of the area
but that there also may be some nonPCFG whales in the region as noted by
Calambokidis et al.(2012)). Given that
the PCFG whales are found largely
nearshore, it was assumed that all the
whales could be within 10 km of the
coast. To capture the potential presence
of whales further offshore (e.g., Oleson
et al., 2009), it was assumed that a
percentage of the whales could be
present from 10 km out to 47 km off the
coast; the 47 km outer limit is consistent
with the DeAngelis et al. (2011)
migration model. Since 77 percent of
the PCFG sightings were within the
nearshore BIAs (Calambokidis et al.,
2015), it was assumed that 23 percent
(48 whales) could potentially be found
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further offshore. Two strata were thus
developed for the July–November gray
whale density layers: (1) From the coast
to 10 km offshore, and (2) from 10 km
to 47 km offshore. The density was
assumed to be 0 animals/km2 for areas
offshore of 47 km.
Small Beaked Whale Guild
NMFS has developed habitat-based
density models for a small beaked whale
guild in the CCE (Becker et al., 2012b;
Forney et al., 2012). The small beaked
whale guild includes Cuvier’s beaked
whale and beaked whales of the genus
Mesoplodon, including Blainville’s
beaked whale, Hubbs’ beaked whale,
and Stejneger’s beaked whale. NMFS
SWFSC developed a CCE habitat-based
density model for the small beaked
whale guild which provides spatially
explicit density estimates off the U.S.
West Coast for summer and fall based
on survey data collected between 1991
and 2009 (Becker et al., 2016).
False Killer Whale
False killer whales were not included
in the Navy’s MSDD, as they are very
rarely encountered in the northeast
Pacific. Density estimates for false killer
whales were also not presented in
Barlow (2016) or Becker et al. (2016), as
no sightings occurred during surveys
conducted between 1986 and 2008
(Ferguson and Barlow 2001, 2003;
Forney 2007; Barlow 2003, 2010). One
sighting was made off of southern
California during 2014 (Barlow 2016).
One pod of false killer whales occurred
in Puget Sound for several months
during the 1990s (Navy 2015). Based on
the available information, NMFS does
not believe false killer whales are
expected to be taken, but L–DEO has
requested take of this species so we are
acting on that request.
Killer Whale
A combination of movement data
(from both visual observations and
satellite-linked tags) and detections
from stationary acoustic recorders have
provided information on the offshore
distribution of the Southern Resident
stock (Hanson et al., 2018). These data
have been used to develop state space
movement models that provide
estimates of the probability of
occurrence (or relative density) of
Southern Residents in the offshore
study area in winter and spring (Hanson
et al., 2018). Since the total number of
animals that comprise each pod is
known, the relative density estimates
were used in association with the total
abundance estimates to derive absolute
density estimates (i.e., number of
animals/km2) within the offshore study
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29115
area. Given that the K and L pods were
together during all but one of the
satellite tag deployments, Hanson et al.
(2018) developed two separate state
space models, one for the combined K
and L pods and one for the J pod. The
absolute density estimates were thus
derived based on a total of 53 animals
for the K and L pods (K pod = 18
animals, L pod = 35 animals) and 22
animals for the J pod (Center for Whale
Research, 2019). Of the three pods, the
K and L pods appear to have a more
extensive and seasonally variable
offshore coastal distribution, with rare
sightings as far south as Monterey Bay,
California (Carretta et al., 2019; Ford et
al., 2000; Hanson et al., 2018). Two
seasonal density maps were thus
developed for the K and L pods, one
representing their distribution from
January to May (the duration of the tag
deployments), and another representing
their distribution from June to
December. Based on stationary acoustic
recording data, their excursions offshore
from June to December are more limited
and typically do not extend south of the
Columbia River (Emmons 2019). To
provide more conservative density
estimates, the Navy extended the June to
December distribution to just south of
the Columbia River and redistributed
the total K and L populations (53
animals) within the more limited range
boundaries. A conservative approach
was also adopted for the J pod since the
January to May density estimates were
assumed to represent annual occurrence
patterns, despite information that this
pod typically spends more time in the
inland waters during the summer and
fall (Carretta et al., 2019; Ford et al.,
2000; Hanson et al., 2018). Further, for
all seasons the Navy assumed that all
members of the three pods of Southern
Residents could occur either offshore or
in the inland waters, so the total number
of animals in the stock was used to
derive density estimates for both study
areas.
Due to the difficulties associated with
reliably distinguishing the different
stocks of killer whales from at sea
sightings, and anticipated equal
likelihood of occurrence among the
stocks, density estimates for the rest of
the stocks are presented as a whole (i.e.,
includes the Offshore, West Coast
Transient, and Northern Resident
stocks). Barlow (2016) presents density
values for killer whales in the CCE, with
separate densities for waters off Oregon/
Washington (i.e., north of the California
border) and Northern California for
summer/fall. Density data are not
available for the NWTT Offshore area
northwest of the CCE study area, so data
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from the SWFSC Oregon/Washington
area were used as representative
estimates. These values were used to
represent density year-round.
Short-Finned Pilot Whale
Along the U.S. West Coast, shortfinned pilot whales were once common
south of Point Conception, California
(Carretta et al., 2017b; Reilly & Shane,
1986), but now sightings off the U.S.
West Coast are infrequent and typically
occur during warm water years (Carretta
et al., 2017b). Stranding records for this
species from Oregon and Washington
waters are considered to be beyond the
normal range of this species rather than
an extension of its range (Norman et al.,
2004). Density values for short-finned
pilot whales are available for the
SWFSC Oregon/Washington and
Northern California strata for summer/
fall (Barlow, 2016). Density data are not
available for the NWTT Offshore area
northwest of the SWFSC strata, so data
from the SWFSC Oregon/Washington
stratum were used as representative
estimates. These values were used to
represent density year-round.
Guadalupe Fur Seal
Adult male Guadalupe fur seals are
expected to be ashore at breeding areas
over the summer, and are not expected
to be present during the planned
geophysical survey (Caretta et al.,
2017b; Norris 2017b). Additionally,
breeding females are unlikely to be
present within the Offshore Study Area
as they remain ashore to nurse their
pups through the fall and winter,
making only short foraging trips from
rookeries (Gallo-Reynoso et al., 2008;
Norris 2017b; Yochem et al., 1987). To
estimate the total abundance of
Guadalupe fur seals, the Navy adjusted
the population reported in the 2016
SAR (Caretta et al., 2017b) of 20,000
seals by applying the average annual
growth rate of 7.64 percent over the
seven years between 2010 and 2017.
The resulting 2017 projected abundance
was 33,485 fur seals. Using the reported
composition of the breeding population
of Guadalupe fur seals (Gallo-Reynoso
1994) and satellite telemetry data
(Norris 2017b), the Navy established
seasonal and demographic abundances
of Guadalupe fur seals expected to occur
within the Offshore Study Area.
The distribution of Guadalupe fur
seals in the Offshore Study Area was
stratified by distance from shore (or
water depth) to reflect their preferred
pelagic habitat (Norris, 2017a). Ten
percent of fur seals in the Study Area
are expected to use waters over the
continental shelf (approximated as
waters with depths between 10 and 200
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m). A depth of 10 m is used as the
shoreward extent of the shelf (rather
than extending to shore), because
Guadalupe fur seals in the Offshore
Study Area are not expected to haul out
and would not be likely to come close
to shore. All fur seals (i.e., 100 percent)
would use waters off the shelf (beyond
the 200-m isobath) out to 300 km from
shore, and 25 of percent of fur seals
would be expected to use waters
between 300 and 700 km from shore
(including the planned geophysical
survey area). The second stratum (200 m
to 300 km from shore) is the preferred
habitat where Guadalupe fur seals are
most likely to occur most of the time.
Individuals may spend a portion of their
time over the continental shelf or farther
than 300 km from shore, necessitating a
density estimate for those areas, but all
Guadalupe fur seals would be expected
to be in the central stratum most of the
time, which is the reason 100 percent is
used in the density estimate for the
central stratum (Norris, 2017a). Spatial
areas for the three strata were estimated
in a GIS and used to calculate the
densities.
The Navy’s density estimate for
Guadalupe fur seals projected the
abundance through 2017, while L–
DEO’s survey was initially planned to
occur in 2020. Therefore, we have
projected the abundance estimate in
2020 using the abundance estimate
(34,187 animals) and population growth
rate (5.9 percent) presented in the 2019
draft SARs (Caretta et al., 2019). This
calculation yielded an increased density
estimate of Guadalupe fur seals than
what was presented in the Navy’s
MSDD.
Northern Fur Seal
The Navy estimated the abundance of
northern fur seals from the Eastern
Pacific stock and the California breeding
stock that could occur in the NWTT
Offshore Study Area by determining the
percentage of time tagged animals spent
within the Study Area and applying that
percentage to the population to
calculate an abundance for adult
females, juveniles, and pups
independently on a monthly basis.
Adult males are not expected to occur
within the Offshore Study Area and the
planned survey area during the planned
geophysical survey as they spend the
summer ashore at breeding areas in the
Bering Sea and San Miguel Island
(Caretta et al., 2017b). Using the
monthly abundances of fur seals within
the Offshore Study Area, the Navy
created strata to estimate the density of
fur seals within three strata: 22 km to 70
km from shore, 70 km to 130 km from
shore, and 130 km to 463 km from shore
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Sfmt 4703
(the western Study Area boundary). L–
DEO’s planned survey is 423 km from
shore at the closest point. Based on
satellite tag data and historic sealing
records (Olesiuk 2012; Kajimura 1984),
the Navy assumed 25 percent of the
population present within the overall
Offshore Study Area may be within the
130 km to 463 km stratum.
The Navy’s density estimates for
northern fur seals did not include the
latest abundance data collected from
Bogoslof Island or the Pribilof Islands in
2015 and 2016. Incorporating the latest
pup counts yielded a slight decrease in
the population abundance estimate,
which resulted in a slight decrease in
the estimated densities of northern fur
seals in each depth stratum.
Steller Sea Lion
The Eastern stock of Steller sea lions
has established rookeries and breeding
sites along the coasts of California,
Oregon, British Columbia, and southeast
Alaska. A new rookery was recently
discovered along the coast of
Washington at the Carroll Island and
Sea Lion Rock complete, where more
than 100 pups were born in 2015 (Muto
et al., 2017; Wiles 2015). The 2017 SAR
did not factor in pups born at sites along
the Washington coast (Muto et al.,
2017). Considering that pups have been
observed at multiple breeding sites
since 2013, specifically at the Carroll
Island and Sea Lion Rock complex
(Wiles 2015), the 2017 SAR abundance
of 1,407 Steller sea lions (non-pups
only) for Washington underestimates
the total population. Wiles (2015)
estimates that up to 2,500 Steller sea
lions are present along the Washington
coast, which is the abundance estimate
used by the Navy to calculate densities.
Approximately 30,000 Steller sea lions
occur along the coast of British
Columbia, but these animals were not
included in the Navy’s calculations. The
Navy applied the annual growth rate for
each regional population (California,
Oregon, Washington, and southeast
Alaska), reported in Muto et al. (2017),
to each population to estimate the stock
abundance in 2017, and we further
projected the population estimate in
2020. The Commission noted that we
had used the non-pup population
growth rate to project the population of
both non-pups and pups. Additionally,
the Commission suggested we include
the British Columbia population in our
projections. We have revised the
population projections and resulting
density estimates accordingly.
Sea lions from northern California
and southern Oregon rookeries migrate
north in September following the
breeding season and winter in northern
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Oregon, Washington, and British
Columbia waters. They disperse widely
following the breeding season, which
extends from May through July, likely in
search of different types of prey, which
may be concentrated in areas where
oceanic fronts and eddies persist (Fritz
et al., 2016; Jemison et al., 2013; Lander
et al., 2010; Muto et al., 2017; NMFS
2013; Raum-Suryan et al., 2004; Sigler
et al., 2017). Adults depart rookeries in
August. Females with pups remain
within 500 km of their rookery during
the non-breeding season and juveniles
of both sexes and adult males disperse
more widely but remain primarily over
the continental shelf (Wiles 2015).
Based on 11 sightings along the
Washington coast, Steller sea lions were
observed at an average distance of 13
km from shore and 35 km from the shelf
break (defined as the 200-m isobath)
(Oleson et al., 2009). The mean water
depth in the area of occurrence was 42
m, and surveys were conducted out to
approximately 60 km from shore. Wiles
(2015) estimated that Steller sea lions
off the Washington coast primarily
occurred within 60 km of shore,
favoring habitats over the continental
shelf. However, a few individuals may
travel several hundred km offshore
(Merrick & Loughlin 1997; Wiles 2015).
Based on these occurrence and
distribution data, two strata were used
to estimate densities for Steller sea
lions. The spatial area extending from
shore to the 200-m isobath (i.e., over the
continental shelf) was defined as one
stratum, and the second stratum
extended from the 200-m isobath to 300
km from shore to account for reports of
Steller sea lions occurring several
hundred km offshore. Ninety-five
percent of the population of Steller sea
lions occurring in the NWTT Study
Area were distributed over the
continental shelf stratum and the
remaining five percent were assumed to
occur between the 200-m isobath and
300 km from shore.
The percentage of time Steller sea
lions spend hauled out varies by season,
life stage, and geographic location. To
calculated densities in the Study Area,
the projected population abundance was
adjusted to account for time spent
hauled out. In spring and winter, sea
lions were estimated to be in the water
64 percent of the time. In summer, when
sea lions are more likely to be in the
water, the percent of animals estimated
to be in the water was increased to 76
percent, and in fall, sea lions were
anticipated to be in the water 53 percent
of the time (U.S. Navy 2019). Densities
were calculated for each depth stratum
off Washington and off Oregon.
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California Sea Lion
Seasonal at-sea abundance of
California sea lions is estimated from
strip transect survey data collected
offshore along the California coastline
(Lowry & Forney 2005). The survey area
was divided into seven strata, labeled A
through G. Abundance estimates from
the two northernmost strata (A and B)
were used to estimate the abundance of
California sea lions occurring in the
NWTT Study Area. While the
northernmost stratum (A) only partially
overlaps with the Study Area, this
approach conservatively assumes that
all sea lions from the two strata would
continue north into the Study Area.
The majority of male sea lions would
be expected in the NWTT Study Area
from August to mid-June (Wright et al.,
2010). In summer, males are expected to
be at breeding sites off of Southern
California. In-water abundance
estimates of adult and sub-adult males
in strata A and B were extrapolated to
estimate seasonal densities in the Study
Area. Approximately 3,000 male
California sea lions are known to pass
through the NWTT Study Area in
August as they migrate northward to the
Washington coast and inland waters
(DeLong 2018a; Wright et al., 2010).
Nearly all male sea lions are expected to
be on or near breeding sites off
California in July (DeLong et al., 2017;
Wright et al., 2010). An estimate of
3,000 male sea lions is used for the
month of August. Projected 2017
seasonal abundance estimates were
derived by applying an annual growth
rate of 5.4 percent (Caretta et al., 2017b)
between 1999 and 2017 to the
abundance estimates from Lowry &
Forney (2005).
The strata used to calculated densities
in the NWTT Study Area were based on
distribution data from Wright et al.
(2010) and Lowry & Forney (2005)
indicating that approximately 90
percent of California sea lions occurred
within 40 km of shore and 100 percent
of sea lions were within 70 km of shore.
A third stratum was added that extends
from shore to 450 km offshore to
account for anomalous conditions, such
as changes in sea surface temperature
and upwelling associated with El Nin˜o,
during which California sea lions have
been encountered farther from shore,
presumably seeking prey (DeLong &
Jeffries 2017; Weise et al., 2010). The
Navy calculated densities for each
stratum (0 to 40 km, 40 to 70 km, and
0 to 450 km) for each season, spring,
summer, fall, and winter, but noted that
the density of California sea lions in all
strata for June and July was 0 animals/
km2. The Navy’s calculated densities for
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29117
August were conservatively used here,
as sightings of California sea lions have
been reported on the continental shelf
in June and July (Adams et al., 2014).
Northern Elephant Seal
The most recent surveys supporting
the abundance estimate for northern
elephant seals were conducted in 2010
(Caretta et al., 2017b). By applying the
average growth rate of 3.8 percent per
year for the California breeding stock
over the 7 years from 2010 to 2017, the
Navy calculated a projected 2017
abundance estimate of 232,399 elephant
seals (Caretta et al., 2017b; Lowry et al.,
2014). Male and female distributions at
sea differ both seasonally and spatially.
Pup counts reported by Lowry et al.,
(2014) and life tables compiled by
Condit et al., (2014) were used to
determine the proportion of males and
females in the population, which was
estimated to be 56 percent female and
44 percent male. Females are assumed
to be at sea 100 percent of the time
within their seasonal distribution area
in fall and summer (Robinson et al.,
2012). Males are at sea approximately 90
percent of the time in fall and spring,
remain ashore through the entire winter,
and spend one month ashore to molt in
the summer (i.e., are at sea 66 percent
of the summer). Monthly distribution
maps produced by Robinson et al.
(2012) showing the extent of foraging
areas used by satellite tagged female
elephant seals were used to estimate the
spatial areas to calculate densities.
Although the distributions were based
on tagged female seals, Le Boeuf et al.
(2000) and Simmons et al. (2007)
reported similar tracks by males over
broad spatial scales. The spatial areas
representing each monthly distribution
were calculating using GIS and then
averaged to produce seasonally variable
areas and resulting densities.
As with other pinniped species above,
NMFS used the population growth rate
reported by Caretta et al. (2017b) to
project the estimated abundance in
2020. The resulting population estimate
and estimated densities increased from
those presented in the Navy’s MSDD
(U.S. Navy 2019).
Harbor Seal
Only harbor seals from the
Washington and Oregon Coast stock
would be expected to occur in the
survey area. The most recent abundance
estimate for the Washington and Oregon
Coast stock is 24,732 harbor seals
(Caretta et al., 2017b). Survey data
supporting this abundance estimate are
from 1999, which exceeds the 8 year
limit beyond which NMFS will not
confirm abundance in a SAR (Caretta et
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al., 2017b). However, based on logistical
growth curves for the Washington and
Oregon Coast stock that leveled off in
the early 1990s (Caretta et al., 2017b)
and unpublished data from the
Washington Department of Fish and
Wildlife (DeLong & Jeffries 2017), an
annual growth rate of 0 percent (i.e., the
population has remained stable) was
applied such that the 2017 abundance
estimate used by the Navy, and 2020
estimate used here, was still 24,732
harbor seals. A haulout factor of 33
percent was used to account for hauled-
out seals (i.e., seals are estimated to be
in the water 33 percent of the time)
(Huber et al., 2001). A single stratum
extending from shore to 30 km offshore
was used to define the spatial area used
by the Navy for calculating densities off
Washington and Oregon (Bailey et al.,
2014; Oleson et al., 2009).
No significant new information is
available since we published the notice
of proposed IHA, and no changes have
been made, other than those described
in the Changes from the Proposed IHA
section, provided previously in this
document.
Marine Mammal Densities
Densities for most species are
presented by depth stratum (shallow,
intermediate, and deep water) in Table
7. For species where densities are
available based on other categories (gray
whale, harbor porpoise, northern fur
seal, Guadalupe fur seal, California sea
lion, Steller sea lion), category
definitions are provided in the footnotes
of Table 7.
TABLE 7—MARINE MAMMAL DENSITY VALUES IN THE SURVEY AREA
Estimated density (#/km2)
Species
Shallow <100
m/Category 1
LF Cetaceans:
Humpback whale .....................................
Blue whale ...............................................
Fin whale .................................................
Sei whale .................................................
Minke whale .............................................
Gray whale a ............................................
MF Cetaceans:
Sperm whale ............................................
Baird’s beaked whale ..............................
Small beaked whale ................................
Bottlenose dolphin ...................................
Striped dolphin .........................................
Short-beaked common dolphin ................
Pacific white-sided dolphin ......................
Northern right-whale dolphin ...................
Risso’s dolphin .........................................
False killer whale b ...................................
Killer whale (all stocks except Southern
Residents).
Short-finned pilot whale ...........................
HF Cetaceans:
Pygmy/dwarf sperm whale ......................
Dall’s porpoise .........................................
Harbor porpoise c .....................................
Otariids:
Northern fur seal d ....................................
Guadalupe fur seal e ................................
California sea lion f ...................................
Steller sea lion g .......................................
Phocids:
Northern elephant seal ............................
Harbor seal h ............................................
Intermediate
100–1,000
m/Category 2
Reference
Deep >1,000
m/Category 3
0.0052405
0.0020235
0.0002016
0.0004000
0.0013000
0.0155000
0.0040200
0.0010518
0.0009306
0.0004000
0.0013000
0.0010000
0.0004830
0.0003576
0.0013810
0.0004000
0.0013000
N.A.
Becker et al. (2016)
Becker et al. (2016)
Becker et al. (2016)
U.S. Navy (2019)
U.S. Navy (2019)
U.S. Navy (2019)
0.0000586
0.0001142
0.0007878
0.0000007
0.0000000
0.0005075
0.0515230
0.0101779
0.0306137
N.A.
0.0009200
0.0001560
0.0002998
0.0013562
0.0000011
0.0000025
0.0010287
0.0948355
0.0435350
0.0308426
N.A.
0.0009200
0.0013023
0.0014680
0.0039516
0.0000108
0.0001332
0.0016437
0.0700595
0.0621242
0.0158850
N.A.
0.0009200
Becker
Becker
Becker
Becker
Becker
Becker
Becker
Becker
Becker
U.S. Navy (2019)
0.0002500
0.0002500
0.0002500
U.S. Navy (2019)
0.0016300
0.1450767
0.6240000
0.0016300
0.1610605
0.4670000
0.0016300
0.1131827
N.A.
U.S. Navy (2019)
Becker et al. (2016)
Forney et al. (2014)
0.0113247
0.0234772
0.0288000
0.4804893
0.1346441
0.0262595
0.0037000
0.0035811
0.0103424
N.A.
0.0065000
N.A.
U.S.
U.S.
U.S.
U.S.
0.0345997
0.3424000
0.0345997
N.A.
0.0345997
N.A.
U.S. Navy (2019)
U.S. Navy (2019)
et
et
et
et
et
et
et
et
et
Navy
Navy
Navy
Navy
al.
al.
al.
al.
al.
al.
al.
al.
al.
(2016)
(2016)
(2016)
(2016)
(2016)
(2016)
(2016)
(2016)
(2016)
(2019)
(2019)
(2019)
(2019)
a Category
1 = 0–10 km offshore, Category 2 = 10–47 km offshore (U.S. Navy 2019).
density estimates available for false killer whales in the survey area, take is based on mean group size from Mobley et al. (2000).
1 = South of 45° N, Category 2 = North of 45° N (Forney et al., 2014).
d Category 1 = 22–70 km offshore, Category 2 = 70–130 km offshore, Category 3 = 130–463 km offshore (U.S. Navy 2019).
e Category 1 = 10–200 m depth, Category 2 = 200 m depth–300 km offshore; No stock-specific densities are available so these densities were
applied to northern fur seals as a species (U.S. Navy 2019).
f Category 1 = 0–40 km offshore, Category 2 = 40–70 km offshore, Category 3 = 0–450 km offshore (U.S. Navy 2019).
g Category 1 = shore–200 m depth, Category 2 = 200 m depth–300 m offshore (U.S. Navy 2019).
h Category 1 = 0–30 km offshore (U.S. Navy 2019).
b No
c Category
Take Calculation and Estimation
Here we describe how the information
provided above is brought together to
produce a quantitative take estimate. In
order to estimate the number of marine
mammals predicted to be exposed to
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sound levels that would result in Level
A or Level B harassment, radial
distances from the airgun array to
predicted isopleths corresponding to the
Level A harassment and Level B
harassment thresholds are calculated, as
described above. Those radial distances
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are then used to calculate the area(s)
around the airgun array predicted to be
ensonified to sound levels that exceed
the Level A and Level B harassment
thresholds. The distance for the 160-dB
threshold (based on L–DEO model
results) was used to draw a buffer
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around every transect line in GIS to
determine the total ensonified area in
each depth category (Table 8). The areas
presented in Table 8 do not include
areas ensonified within Canadian
territorial waters (from 0–12 nmi (22.2
km) from shore). As discussed above,
NMFS cannot authorize the incidental
take of marine mammals in the
territorial seas of foreign nations, as the
MMPA does not apply in those waters.
However, NMFS has still calculated the
level of incidental take in the entire
activity area (including Canadian
territorial waters) as part of the analysis
supporting our determination under the
MMPA that the activity will have a
negligible impact on the affected
species. The total estimated take in U.S.
and Canadian waters is presented in
Table 11.
In past applications, to account for
unanticipated delays in operations,
L–DEO has added 25 percent in the
form of operational days, which is
equivalent to adding 25 percent to the
proposed line km to be surveyed. In this
application, however, due to the strict
operational timelines and availability of
the R/V Langseth, no additional time or
distance has been added to the survey
calculations. 37 days is the absolute
maximum amount of time the R/V
Langseth is available to conduct seismic
operations.
The ensonified areas in Table 8 were
used to estimate take of marine mammal
species with densities available for the
three depth strata (shallow,
intermediate, and deep waters). For
other species where densities are
available based on other categories (i.e.,
gray whale, harbor porpoise, northern
fur seal, Guadalupe fur seal, California
sea lion, Steller sea lion; see Table 7),
GIS was used to determine the areas
expected to be ensonified in each
density category (see L–DEO’s EA for
the ensonified areas in each category).
The areas provided in Tables 8 and 9
here have been updated from those
provided in Tables 8 and 9 of the notice
of proposed IHA (85 FR 19580; April 7,
2020) based on the revised planned
survey tracklines.
TABLE 8—AREAS (KM2) ESTIMATED TO BE ENSONIFIED TO LEVEL A AND LEVEL B HARASSMENT THRESHOLDS
Survey zone
Level B Harassment:
Shallow <100 m .....................................................
Intermediate 100–1,000 m ....................................
Deep >1,000 m .....................................................
Overall ............................................................
Level A Harassment:
All depth zones ......................................................
a Based
b Based
Total
ensonified
area
(km2)
Relevant
isopleth
(m)
Criteria
a 12,650
160 dB ..........................................................................
160 dB ..........................................................................
160 dB ..........................................................................
.......................................................................................
b 6,733
........................
3,580.73
23,562.43
52,438.71
79,581.85
LF Cetacean .................................................................
MF Cetacean ................................................................
HF Cetacean ................................................................
Otariid ...........................................................................
Phocid ...........................................................................
426.9
13.6
268.3
10.6
43.7
5,334.55
171.42
3,363.99
133.61
550.53
b 9,468
on L–DEO model results
on data from Crone et al. (2014)
Density estimates for Southern
Resident killer whales from the U.S.
Navy’s MSDD were overlaid with GIS
layers of the Level B harassment zones
in each depth category to determine the
areas expected to be ensonified in each
density category (Table 9).
TABLE 9—SOUTHERN RESIDENT KILLER WHALE DENSITIES AND CORRESPONDING ENSONIFIED AREAS
Pod
K/L ...............................................................................................................................................................
J ...................................................................................................................................................................
The marine mammals predicted to
occur within these respective areas,
based on estimated densities or other
occurrence records, are assumed to be
incidentally taken. For species where
NMFS expects take by Level A
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harassment to potentially occur, the
calculated Level A harassment takes
have been subtracted from the total
within the Level B harassment zone.
Estimated exposures for the survey
outside of Canadian territorial waters
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Density (animals/km2)
Ensonified area
(km2)
0.000000
0.000001–0.002803
0.002804–0.005615
0.005616–0.009366
0.009367–0.015185
0.000000
0.000001–0.001991
0.001992–0.005010
0.005011–0.009602
0.009603–0.018822
5,888
15,470
342
0
0
6,427
5,556
0
0
20
are shown in Table 10. These numbers
have changed from those provided in
Table 10 of the notice of proposed IHA
(85 FR 19580; April 7, 2020) because of
the revised planned survey tracklines.
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TABLE 10—ESTIMATED TAKING BY LEVEL A AND LEVEL B HARASSMENT, AND PERCENTAGE OF POPULATION
Estimated take
Level 1B
Level 1A
Total
authorized
take
10,103
2,900
112
........................
29
........................
b 141
........................
1.40
4.86
1,647
9,029
40
94
11
1
51
95
3.10
1.05
3,168
27,197
25,000
........................
30
96
........................
2
7
........................
32
103
3.00
0.12
0.41
26,960
43
1
44
0.16
26,300
72
0
72
0.27
2,697
84
0
84
3.12
6,318
242
0
c 242
3.83
1,924
1
0
d 13
0.68
29,211
7
0
d 46
0.16
969,861
112
0
d 179
0.02
26,814
6,084
0
6,084
22.69
26,556
4,318
0
4,318
16.26
6,336
1,664
0
1,664
26.26
Unknown
73
302
349
300
836
n/a
10
73
........................
........................
20
n/a
0
0
........................
........................
0
e5
10
73
........................
........................
d 29
f n/a
13.70
24.17
20.92
24.33
3.47
4,111
125
5
130
3.16
27,750
9,762
488
10,250
g 36.94
21,487
7,958
283
8,241
g 38.35
35,769
........................
........................
........................
23.04
Eastern Pacific ...................
California ............................
Mexico to California ...........
U.S. ....................................
Eastern U.S. .......................
608,143
14,050
34,187
257,606
43,201
4,592
........................
2,048
889
7,504
0
........................
0
0
0
4,592
........................
2,048
889
7,504
0.76
32.68
5.99
0.35
17.37
California Breeding .............
Oregon/Washington Coast
179,000
h 24,732
2,754
3,887
0
0
2,754
3,887
1.54
15.72
Stock
abundance
MMPA stock a
Species
Percent of
MMPA stock
LF Cetaceans:
Humpback whale .........
Blue whale ...................
Fin whale .....................
Sei whale .....................
Minke whale .................
Gray whale ...................
MF Cetaceans:
Sperm whale ................
Baird’s beaked whale ..
Small beaked whale ....
Bottlenose dolphin .......
Striped dolphin .............
Short-beaked common
dolphin.
Pacific white-sided dolphin.
Northern right-whale
dolphin.
Risso’s dolphin .............
False killer whale .........
Killer whale ..................
Short-finned pilot whale
HF Cetaceans:
Pygmy/dwarf sperm
whale.
Dall’s porpoise .............
Harbor porpoise ...........
Otariid Seals:
Northern fur seal ..........
Guadalupe fur seal ......
California sea lion ........
Steller sea lion .............
Phocid Seals:
Northern elephant seal
Harbor seal ..................
Central North Pacific ..........
California/Oregon/Washington.
Eastern North Pacific .........
California/Oregon/Washington.
Northeast Pacific ................
Eastern North Pacific .........
California/Oregon/Washington.
Eastern North Pacific .........
California/Oregon/Washington.
California/Oregon/Washington.
California/Oregon/Washington.
California/Oregon/Washington (offshore).
California/Oregon/Washington.
California/Oregon/Washington.
California/Oregon/Washington.
California/Oregon/Washington.
California/Oregon/Washington.
n/a ......................................
Southern Resident .............
Northern Resident ..............
West Coast Transient .........
Offshore ..............................
California/Oregon/Washington.
California/Oregon/Washington.
California/Oregon/Washington.
Northern Oregon/Washington Coast.
Northern California/Southern Oregon.
a In most cases, where multiple stocks are being affected, for the purposes of calculating the percentage of the stock impacted, the take is
being analyzed as if all authorized takes occurred within each stock.
b Takes are allocated among the three DPSs in the area based on Wade et al. (2017) (Oregon: 32.7% Mexico DPS, 67.2% Central America
DPS; Washington/British Columbia: 27.9% Mexico DPS, 8.7% Central America DPS, 63.5% Hawaii DPS).
c Total for small beaked whale guild (Appendix B of L–DEO’s application describes potential take estimates of each species represented in the
guild, but we present the authorized take of small beaked whales as a whole).
d Authorized take increased to mean group size from Barlow (2016).
e Authorized take increased to mean group size from Mobley et al. (2000).
f False killer whales that may be taken during this survey are not likely to belong to any designated stock. Therefore we cannot determine the
percent of stock that may be taken, but we assume that five individuals would be considered small relative to the abundance of the population
they belong to.
g The percentage of these stocks expected to experience take is discussed further in the Small Numbers section later in the document.
h As noted in Table 1, there is no current estimate of abundance available for the Oregon/Washington Coast stock of harbor seal. The abundance estimate from 1999, included here, is the best available.
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Marine mammals would be expected
to move away from a loud sound source
that represents an aversive stimulus,
such as an airgun array, potentially
reducing the number of takes by Level
A harassment. However, the extent to
which marine mammals would move
away from the sound source is difficult
to quantify and is therefore not
accounted for in the take estimates.
Also, note that in consideration of the
near-field soundscape of the airgun
array, we have authorized a different
number of takes of mid-frequency
cetaceans and pinnipeds by Level A
harassment than the number estimated
by L–DEO (see Appendix B in L–DEO’s
IHA application).
Mitigation
In order to issue an IHA under
Section 101(a)(5)(D) of the MMPA,
NMFS must set forth the permissible
methods of taking pursuant to the
activity, and other means of effecting
the least practicable impact on the
species or stock and its habitat, paying
particular attention to rookeries, mating
grounds, and areas of similar
significance, and on the availability of
the species or stock for taking for certain
subsistence uses (latter not applicable
for this action). NMFS regulations
require applicants for incidental take
authorizations to include information
about the availability and feasibility
(economic and technological) of
equipment, methods, and manner of
conducting the activity or other means
of effecting the least practicable adverse
impact upon the affected species or
stocks and their habitat (50 CFR
216.104(a)(11)).
In evaluating how mitigation may or
may not be appropriate to ensure the
least practicable adverse impact on
species or stocks and their habitat, as
well as subsistence uses where
applicable, we carefully consider two
primary factors:
(1) The manner in which, and the
degree to which, the successful
implementation of the measure(s) is
expected to reduce impacts to marine
mammals, marine mammal species or
stocks, and their habitat. This considers
the nature of the potential adverse
impact being mitigated (likelihood,
scope, range). It further considers the
likelihood that the measure will be
effective if implemented (probability of
accomplishing the mitigating result if
implemented as planned), the
likelihood of effective implementation
(probability implemented as planned);
and
(2) The practicability of the measures
for applicant implementation, which
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may consider such things as cost and
impact on operations.
L–DEO has reviewed mitigation
measures employed during seismic
research surveys authorized by NMFS
under previous incidental harassment
authorizations, as well as recommended
best practices in Richardson et al.
(1995), Pierson et al. (1998), Weir and
Dolman (2007), Nowacek et al. (2013),
Wright (2014), and Wright and
Cosentino (2015), and incorporated a
suite of proposed mitigation measures
into their project description based on
the above sources.
To reduce the potential for
disturbance from acoustic stimuli
associated with the activities, L–DEO
will implement mitigation measures for
marine mammals. Mitigation measures
that will be adopted during the planned
surveys include (1) Vessel-based visual
mitigation monitoring; (2) Vessel-based
passive acoustic monitoring; (3)
Establishment of an exclusion zone; (4)
Shutdown procedures; (5) Ramp-up
procedures; and (6) Vessel strike
avoidance measures.
Vessel-Based Visual Mitigation
Monitoring
Visual monitoring requires the use of
trained observers (herein referred to as
visual PSOs) to scan the ocean surface
visually for the presence of marine
mammals. The area to be scanned
visually includes primarily the
exclusion zone, within which
observation of certain marine mammals
requires shutdown of the acoustic
source, but also the buffer zone. The
buffer zone means an area beyond the
exclusion zone to be monitored for the
presence of marine mammals that may
enter the exclusion zone. During preclearance monitoring (i.e., before rampup begins), the buffer zone also acts as
an extension of the exclusion zone in
that observations of marine mammals
within the buffer zone would also
prevent airgun operations from
beginning (i.e., ramp-up). The buffer
zone encompasses the area at and below
the sea surface from the edge of the 0–
500 m exclusion zone, out to a radius
of 1,000 m from the edges of the airgun
array (500–1,000 m). Visual monitoring
of the exclusion zone and adjacent
waters is intended to establish and,
when visual conditions allow, maintain
zones around the sound source that are
clear of marine mammals, thereby
reducing or eliminating the potential for
injury and minimizing the potential for
more severe behavioral reactions for
animals occurring closer to the vessel.
Visual monitoring of the buffer zone is
intended to (1) provide additional
protection to naı¨ve marine mammals
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29121
that may be in the area during preclearance, and (2) during airgun use, aid
in establishing and maintaining the
exclusion zone by alerting the visual
observer and crew of marine mammals
that are outside of, but may approach
and enter, the exclusion zone.
L–DEO must use dedicated, trained,
NMFS-approved Protected Species
Observers (PSOs). The PSOs must have
no tasks other than to conduct
observational effort, record
observational data, and communicate
with and instruct relevant vessel crew
with regard to the presence of marine
mammals and mitigation requirements.
PSO resumes must be provided to
NMFS for approval.
At least one of the visual and two of
the acoustic PSOs (discussed below)
aboard the vessel must have a minimum
of 90 days at-sea experience working in
those roles, respectively, during a deep
penetration (i.e., ‘‘high energy’’) seismic
survey, with no more than 18 months
elapsed since the conclusion of the atsea experience. One visual PSO with
such experience must be designated as
the lead for the entire protected species
observation team. The lead PSO must
serve as primary point of contact for the
vessel operator and ensure all PSO
requirements per the IHA are met. To
the maximum extent practicable, the
experienced PSOs should be scheduled
to be on duty with those PSOs with
appropriate training but who have not
yet gained relevant experience.
During survey operations (e.g., any
day on which use of the acoustic source
is planned to occur, and whenever the
acoustic source is in the water, whether
activated or not), a minimum of two
visual PSOs must be on duty and
conducting visual observations at all
times during daylight hours (i.e., from
30 minutes prior to sunrise through 30
minutes following sunset). Visual
monitoring of the exclusion and buffer
zones must begin no less than 30
minutes prior to ramp-up and must
continue until one hour after use of the
acoustic source ceases or until 30
minutes past sunset. Visual PSOs must
coordinate to ensure 360° visual
coverage around the vessel from the
most appropriate observation posts, and
must conduct visual observations using
binoculars and the naked eye while free
from distractions and in a consistent,
systematic, and diligent manner.
PSOs must establish and monitor the
exclusion and buffer zones. These zones
must be based upon the radial distance
from the edges of the acoustic source
(rather than being based on the center of
the array or around the vessel itself).
During use of the acoustic source (i.e.,
anytime airguns are active, including
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ramp-up), detections of marine
mammals within the buffer zone (but
outside the exclusion zone) must be
communicated to the operator to
prepare for the potential shutdown of
the acoustic source.
During use of the airgun (i.e., anytime
the acoustic source is active, including
ramp-up), detections of marine
mammals within the buffer zone (but
outside the exclusion zone) should be
communicated to the operator to
prepare for the potential shutdown of
the acoustic source. Visual PSOs must
immediately communicate all
observations to the on duty acoustic
PSO(s), including any determination by
the PSO regarding species
identification, distance, and bearing and
the degree of confidence in the
determination. Any observations of
marine mammals by crew members
must be relayed to the PSO team. During
good conditions (e.g., daylight hours;
Beaufort sea state (BSS) 3 or less), visual
PSOs must conduct observations when
the acoustic source is not operating for
comparison of sighting rates and
behavior with and without use of the
acoustic source and between acquisition
periods, to the maximum extent
practicable.
While the R/V Langseth is surveying
in water depths of 200 m or less along
the coast between Tillamook Head,
Oregon and Barkley Sound, British
Columbia (between latitudes
45.9460903° N and 48.780291° N), and
within the boundaries of Olympic Coast
National Marine Sanctuary, a second
vessel with additional PSOs must travel
approximately 5 km ahead of the R/V
Langseth. Two PSOs must be on watch
on the second vessel during all such
survey operations and must alert PSOs
on the R/V Langseth of any marine
mammal observations so that they may
be prepared to initiate shutdowns. This
requirement has been modified from
what was included in the proposed IHA,
which proposed using the second vessel
through the entire survey area in waters
under 200 m. This requirement was
primarily intended to increase the
likelihood of PSOs detecting Southern
Resident killer whales. However, L–
DEO has described practicability
concerns with the second vessel,
including high cost and limited
availability for the time period
specified. NMFS carefully considered
the area in which the second vessel
would effect the most reduction in
impacts to Southern Resident killer
whales and, accordingly, the area
requiring the second vessel has been
revised to reflect the areas of highest
occurrence (based on Navy, 2019),
between Tillamook Head and Barkley
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Sound and within the boundaries of
Olympic Coast National Marine
Sanctuary.
Visual PSOs on both vessels may be
on watch for a maximum of four
consecutive hours followed by a break
of at least one hour between watches
and may conduct a maximum of 12
hours of observation per 24-hour period.
Combined observational duties (visual
and acoustic but not at same time) may
not exceed 12 hours per 24-hour period
for any individual PSO.
Passive Acoustic Monitoring
Acoustic monitoring means the use of
trained personnel (sometimes referred to
as passive acoustic monitoring (PAM)
operators, herein referred to as acoustic
PSOs) to operate PAM equipment to
acoustically detect the presence of
marine mammals. Acoustic monitoring
involves acoustically detecting marine
mammals regardless of distance from
the source, as localization of animals
may not always be possible. Acoustic
monitoring is intended to further
support visual monitoring (during
daylight hours) in maintaining an
exclusion zone around the sound source
that is clear of marine mammals. In
cases where visual monitoring is not
effective (e.g., due to weather,
nighttime), acoustic monitoring may be
used to allow certain activities to occur,
as further detailed below.
Passive acoustic monitoring will take
place in addition to the visual
monitoring program. Visual monitoring
typically is not effective during periods
of poor visibility or at night, and even
with good visibility, is unable to detect
marine mammals when they are below
the surface or beyond visual range.
Acoustical monitoring can be used in
addition to visual observations to
improve detection, identification, and
localization of cetaceans. The acoustic
monitoring will serve to alert visual
PSOs (if on duty) when vocalizing
cetaceans are detected. It is only useful
when marine mammals call, but it can
be effective either by day or by night,
and does not depend on good visibility.
It will be monitored in real time so that
the visual observers can be advised
when cetaceans are detected.
The R/V Langseth must use a towed
PAM system, which must be monitored
by at a minimum one on duty acoustic
PSO beginning at least 30 minutes prior
to ramp-up and at all times during use
of the acoustic source. Acoustic PSOs
may be on watch for a maximum of 4
consecutive hours followed by a break
of at least 1 hour between watches and
may conduct a maximum of 12 hours of
observation per 24-hour period.
Combined observational duties (acoustic
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Sfmt 4703
and visual but not at same time) may
not exceed 12 hours per 24-hour period
for any individual PSO.
Survey activity may continue for 30
minutes when the PAM system
malfunctions or is damaged, while the
PAM operator diagnoses the issue. If the
diagnosis indicates that the PAM system
must be repaired to solve the problem,
operations may continue for an
additional five hours without acoustic
monitoring during daylight hours only
under the following conditions:
• Sea state is less than or equal to
BSS 4;
• No marine mammals (excluding
delphinids, other than killer whales)
detected solely by PAM in the
applicable exclusion zone in the
previous 2 hours;
• NMFS is notified via email as soon
as practicable with the time and
location in which operations began
occurring without an active PAM
system; and
• Operations with an active acoustic
source, but without an operating PAM
system, do not exceed a cumulative total
of five hours in any 24-hour period.
Establishment of Exclusion and Buffer
Zones
An exclusion zone (EZ) is a defined
area within which occurrence of a
marine mammal triggers mitigation
action intended to reduce the potential
for certain outcomes, e.g., auditory
injury, disruption of critical behaviors.
The PSOs must establish a minimum EZ
with a 500-m radius. The 500-m EZ
must be based on radial distance from
the edge of the airgun array (rather than
being based on the center of the array
or around the vessel itself). With certain
exceptions (described below), if a
marine mammal appears within or
enters this zone, the acoustic source
must be shut down.
The 500-m EZ is intended to be
precautionary in the sense that it would
be expected to contain sound exceeding
the injury criteria for all cetacean
hearing groups, (based on the dual
criteria of SELcum and peak SPL), while
also providing a consistent, reasonably
observable zone within which PSOs
would typically be able to conduct
effective observational effort.
Additionally, a 500-m EZ is expected to
minimize the likelihood that marine
mammals will be exposed to levels
likely to result in more severe
behavioral responses. Although
significantly greater distances may be
observed from an elevated platform
under good conditions, we believe that
500 m is likely regularly attainable for
PSOs using the naked eye during typical
conditions.
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An extended EZ of 1,500 m must be
enforced for all beaked whales, and
dwarf and pygmy sperm whales. No
buffer zone is required.
Pre-Clearance and Ramp-Up
Ramp-up (sometimes referred to as
‘‘soft start’’) means the gradual and
systematic increase of emitted sound
levels from an airgun array. Ramp-up
begins by first activating a single airgun
of the smallest volume, followed by
doubling the number of active elements
in stages until the full complement of an
array’s airguns are active. Each stage
should be approximately the same
duration, and the total duration should
not be less than approximately 20
minutes. The intent of pre-clearance
observation (30 minutes) is to ensure no
protected species are observed within
the buffer zone prior to the beginning of
ramp-up. During pre-clearance is the
only time observations of protected
species in the buffer zone would
prevent operations (i.e., the beginning of
ramp-up). The intent of ramp-up is to
warn protected species of pending
seismic operations and to allow
sufficient time for those animals to leave
the immediate vicinity. A ramp-up
procedure, involving a step-wise
increase in the number of airguns firing
and total array volume until all
operational airguns are activated and
the full volume is achieved, is required
at all times as part of the activation of
the acoustic source. All operators must
adhere to the following pre-clearance
and ramp-up requirements:
• The operator must notify a
designated PSO of the planned start of
ramp-up as agreed upon with the lead
PSO; the notification time should not be
less than 60 minutes prior to the
planned ramp-up in order to allow the
PSOs time to monitor the exclusion and
buffer zones for 30 minutes prior to the
initiation of ramp-up (pre-clearance);
• Ramp-ups must be scheduled so as
to minimize the time spent with the
source activated prior to reaching the
designated run-in;
• One of the PSOs conducting preclearance observations must be notified
again immediately prior to initiating
ramp-up procedures and the operator
must receive confirmation from the PSO
to proceed;
• Ramp-up may not be initiated if any
marine mammal is within the applicable
exclusion or buffer zone. If a marine
mammal is observed within the
applicable exclusion zone or the buffer
zone during the 30 minute pre-clearance
period, ramp-up may not begin until the
animal(s) has been observed exiting the
zones or until an additional time period
has elapsed with no further sightings
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(15 minutes for small odontocetes and
pinnipeds, and 30 minutes for all
mysticetes and all other odontocetes,
including sperm whales, pygmy sperm
whales, dwarf sperm whales, beaked
whales, pilot whales, false killer whales,
and Risso’s dolphins);
• Ramp-up must begin by activating a
single airgun of the smallest volume in
the array and must continue in stages by
doubling the number of active elements
at the commencement of each stage,
with each stage of approximately the
same duration. Duration must not be
less than 20 minutes. The operator must
provide information to the PSO
documenting that appropriate
procedures were followed;
• PSOs must monitor the exclusion
and buffer zones during ramp-up, and
ramp-up must cease and the source
must be shut down upon detection of a
marine mammal within the applicable
exclusion zone. Once ramp-up has
begun, detections of marine mammals
within the buffer zone do not require
shutdown, but such observation must be
communicated to the operator to
prepare for the potential shutdown;
• Ramp-up may occur at times of
poor visibility, including nighttime, if
appropriate acoustic monitoring has
occurred with no detections in the 30
minutes prior to beginning ramp-up.
Acoustic source activation may only
occur at times of poor visibility where
operational planning cannot reasonably
avoid such circumstances;
• If the acoustic source is shut down
for brief periods (i.e., less than 30
minutes) for reasons other than that
described for shutdown (e.g.,
mechanical difficulty), it may be
activated again without ramp-up if PSOs
have maintained constant visual and/or
acoustic observation and no visual or
acoustic detections of marine mammals
have occurred within the applicable
exclusion zone. For any longer
shutdown, pre-clearance observation
and ramp-up are required. For any
shutdown at night or in periods of poor
visibility (e.g., BSS 4 or greater), rampup is required, but if the shutdown
period was brief and constant
observation was maintained, preclearance watch of 30 minutes is not
required; and
• Testing of the acoustic source
involving all elements requires rampup. Testing limited to individual source
elements or strings does not require
ramp-up but does require pre-clearance
of 30 min.
Shutdown
The shutdown of an airgun array
requires the immediate de-activation of
all individual airgun elements of the
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array. Any PSO on duty has the
authority to delay the start of survey
operations or to call for shutdown of the
acoustic source if a marine mammal is
detected within the applicable EZ. The
operator must also establish and
maintain clear lines of communication
directly between PSOs on duty and
crew controlling the acoustic source to
ensure that shutdown commands are
conveyed swiftly while allowing PSOs
to maintain watch. When both visual
and acoustic PSOs are on duty, all
detections must be immediately
communicated to the remainder of the
on-duty PSO team for potential
verification of visual observations by the
acoustic PSO or of acoustic detections
by visual PSOs. When the airgun array
is active (i.e., anytime one or more
airguns is active, including during
ramp-up) and (1) a marine mammal
appears within or enters the applicable
exclusion zone and/or (2) a marine
mammal (other than delphinids, see
below) is detected acoustically and
localized within the applicable
exclusion zone, the acoustic source
must be shut down. When shutdown is
called for by a PSO, the acoustic source
must be immediately deactivated and
any dispute resolved only following
deactivation. Additionally, shutdown
must occur whenever PAM alone
(without visual sighting), confirms
presence of marine mammal(s) in the
EZ. If the acoustic PSO cannot confirm
presence within the EZ, visual PSOs
must be notified but shutdown is not
required. L–DEO must also implement
shutdown of the airgun array if killer
whale vocalizations are detected,
regardless of localization.
Following a shutdown, airgun activity
must not resume until the marine
mammal has cleared the 500-m EZ. The
animal would be considered to have
cleared the 500-m EZ if it is visually
observed to have departed the 500-m
EZ, or it has not been seen within the
500-m EZ for 15 min in the case of small
odontocetes and pinnipeds, or 30 min in
the case of mysticetes and large
odontocetes, including sperm whales,
pygmy sperm whales, dwarf sperm
whales, pilot whales, beaked whales,
killer whales, false killer whales, and
Risso’s dolphins.
The shutdown requirement can be
waived for small dolphins if an
individual is visually detected within
the exclusion zone. As defined here, the
small dolphin group is intended to
encompass those members of the Family
Delphinidae most likely to voluntarily
approach the source vessel for purposes
of interacting with the vessel and/or
airgun array (e.g., bow riding). This
exception to the shutdown requirement
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applies solely to specific genera of small
dolphins—Tursiops, Delphinus,
Stenella, Lagenorhynchus, and
Lissodelphis.
We include this small dolphin
exception because shutdown
requirements for small dolphins under
all circumstances represent
practicability concerns without likely
commensurate benefits for the animals
in question. Small dolphins are
generally the most commonly observed
marine mammals in the specific
geographic region and would typically
be the only marine mammals likely to
intentionally approach the vessel. As
described above, auditory injury is
extremely unlikely to occur for midfrequency cetaceans (e.g., delphinids),
as this group is relatively insensitive to
sound produced at the predominant
frequencies in an airgun pulse while
also having a relatively high threshold
for the onset of auditory injury (i.e.,
permanent threshold shift).
A large body of anecdotal evidence
indicates that small dolphins commonly
approach vessels and/or towed arrays
during active sound production for
purposes of bow riding, with no
apparent effect observed in those
delphinoids (e.g., Barkaszi et al., 2012).
The potential for increased shutdowns
resulting from such a measure would
require the R/V Langseth to revisit the
missed track line to reacquire data,
resulting in an overall increase in the
total sound energy input to the marine
environment and an increase in the total
duration over which the survey is active
in a given area. Although other midfrequency hearing specialists (e.g., large
delphinoids) are no more likely to incur
auditory injury than are small dolphins,
they are much less likely to approach
vessels. Therefore, retaining a shutdown
requirement for large delphinoids
would not have similar impacts in terms
of either practicability for the applicant
or corollary increase in sound energy
output and time on the water. We do
anticipate some benefit for a shutdown
requirement for large delphinoids in
that it simplifies somewhat the total
range of decision-making for PSOs and
may preclude any potential for
physiological effects other than to the
auditory system as well as some more
severe behavioral reactions for any such
animals in close proximity to the source
vessel.
Visual PSOs must use best
professional judgment in making the
decision to call for a shutdown if there
is uncertainty regarding identification
(i.e., whether the observed marine
mammal(s) belongs to one of the
delphinid genera for which shutdown is
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waived or one of the species with a
larger exclusion zone).
Upon implementation of shutdown,
the source may be reactivated after the
marine mammal(s) has been observed
exiting the applicable exclusion zone
(i.e., animal is not required to fully exit
the buffer zone where applicable) or
following 15 minutes for small
odontocetes and pinnipeds, and 30
minutes for mysticetes and all other
odontocetes, including sperm whales,
pygmy sperm whales, dwarf sperm
whales, beaked whales, pilot whales,
and Risso’s dolphins, with no further
observation of the marine mammal(s).
L–DEO must implement shutdown if
a marine mammal species for which
take was not authorized, or a species for
which authorization was granted but the
takes have been met, approaches the
Level A or Level B harassment zones. L–
DEO must also implement shutdown if
any of the following are observed at any
distance:
• Any large whale (defined as a
sperm whale or any mysticete species)
with a calf (defined as an animal less
than two-thirds the body size of an adult
observed to be in close association with
an adult;
• An aggregation of six or more large
whales;
• A North Pacific right whale; and/or
• A killer whale of any ecotype.
Vessel Strike Avoidance
These measures apply to all vessels
associated with the planned survey
activity; however, we note that these
requirements do not apply in any case
where compliance would create an
imminent and serious threat to a person
or vessel or to the extent that a vessel
is restricted in its ability to maneuver
and, because of the restriction, cannot
comply. These measures include the
following:
1. Vessel operators and crews must
maintain a vigilant watch for all marine
mammals and slow down, stop their
vessel, or alter course, as appropriate
and regardless of vessel size, to avoid
striking any marine mammal. A single
marine mammal at the surface may
indicate the presence of submerged
animals in the vicinity of the vessel;
therefore, precautionary measures
should be exercised when an animal is
observed. A visual observer aboard the
vessel must monitor a vessel strike
avoidance zone around the vessel
(specific distances detailed below), to
ensure the potential for strike is
minimized. Visual observers monitoring
the vessel strike avoidance zone can be
either third-party observers or crew
members, but crew members
responsible for these duties must be
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provided sufficient training to
distinguish marine mammals from other
phenomena and broadly to identify a
marine mammal to broad taxonomic
group (i.e., as a large whale or other
marine mammal);
2. Vessel speeds must be reduced to
10 knots or less when mother/calf pairs,
pods, or large assemblages of any
marine mammal are observed near a
vessel;
3. All vessels must maintain a
minimum separation distance of 100 m
from large whales (i.e., sperm whales
and all mysticetes);
4. All vessels must attempt to
maintain a minimum separation
distance of 50 m from all other marine
mammals, with an exception made for
those animals that approach the vessel;
and
5. When marine mammals are sighted
while a vessel is underway, the vessel
should take action as necessary to avoid
violating the relevant separation
distance (e.g., attempt to remain parallel
to the animal’s course, avoid excessive
speed or abrupt changes in direction
until the animal has left the area). If
marine mammals are sighted within the
relevant separation distance, the vessel
should reduce speed and shift the
engine to neutral, not engaging the
engines until animals are clear of the
area. This recommendation does not
apply to any vessel towing gear.
Operational Restrictions
While the R/V Langseth is surveying
in waters 200 m deep or less along the
coast between Tillamook Head, Oregon
and Barkley Sound, British Columbia
(between latitudes 45.9460903° N and
48.780291° N), and within the
boundaries of Olympic Coast National
Marine Sanctuary, survey operations
must occur in daylight hours only (i.e.,
from 30 minutes prior to sunrise
through 30 minutes following sunset) to
ensure the ability to use visual
observation as a detection-based
mitigation tool and to implement
shutdown procedures for species or
situations with additional shutdown
requirements outlined above (e.g., killer
whale of any ecotype, North Pacific
right whale, aggregation of six or more
large whales, large whale with a calf).
The proposed IHA included this
requirement to operate only during
daylight hours in waters 200 m deep or
less throughout the entire survey area.
We have revised that requirement to
apply only between Tillamook Head
and Barkley Sound and within the
boundaries of Olympic Coast National
Marine Sanctuary because those are the
areas with the highest expected
Southern Resident killer whale
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occurrence, and we determined that
requiring this operational restriction
throughout the entire survey area was
not practicable, in consideration of cost
and vessel availability concerns.
Communication
Each day of survey operations, L–DEO
must contact NMFS Northwest Fisheries
Science Center, NMFS West Coast
Region, The Whale Museum, Orca
Network, Canada’s DFO, Olympic Coast
National Marine Sanctuary, and/or other
sources to obtain near real-time
reporting for the whereabouts of
Southern Resident killer whales.
Mitigation Measures in Canadian
Waters
As stated above, NMFS cannot
authorize the incidental take of marine
mammals in the territorial seas of
foreign nations, as the MMPA does not
apply in those waters. Therefore, the
mitigation requirements described
above do not apply within Canadian
territorial waters. The MMPA is
applicable in the EEZs of foreign
nations, and therefore, the mitigation
measures above apply within the
Canadian EEZ. However, L–DEO also
consulted with Canada’s DFO under the
Canada Species at Risk Act and must
also comply with DFO’s mitigation
requirements within the Canadian EEZ
in order to avoid causing the death of
fish or marine mammals and/or the
harmful alteration, disruption, or
destruction of fish habitat, or causing
prohibited effects to aquatic species at
risk. Within the Canadian EEZ, L–DEO
must:
• Conduct seismic survey activities
outside of designated Killer Whale
Critical Habitat (KWCH) with a setback
that ensures that the estimated sound
pressure level has diminished to ≤160
dB rms re: 1 mPa at the boundary of
KWCH;
• Initiate an immediate and complete
shutdown of the airgun array if a killer
whale (all ecotypes), North Pacific right
whale, whale with calf (any species) or
aggregation of whales (any species) is
observed;
• Initiate an immediate and complete
shutdown of the airgun array if a sperm
whale or a beaked whale (any species)
is sighted within 1,500 m of the airgun
array;
• For other observations of marine
mammals, initiate an immediate and
complete shutdown of the airgun array
if these animals are observed within an
established EZ with a radius of 1,000 m;
• Refrain from conducting seismic
surveys in waters less than 100 m in
depth;
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• Conduct seismic surveys in waters
100 to 200 m deep during daylight
hours only, with a second vessel having
two marine mammal observers on
watch, positioned 5 km ahead of the
R/V Langseth;
• Combine enhanced visual
observations (e.g., reticle and big-eye
binoculars, night vision devices and
digital cameras) with non-visual
detection methods (e.g., infrared
technology (FLIR) and passive acoustic
monitoring) to increase the likelihood of
detecting marine mammals during ramp
up, Beaufort sea states >3, and nighttime
survey operations; and
• Monitor the established EZ with a
radius of 1,000 m for 60 minutes prior
to initial start-up of the airgun array or
resumption of operations following a
complete shutdown to allow for the
detection of deep diving animals.
While operating within the Canadian
EEZ but outside Canadian territorial
waters, if mitigation requirements in the
IHA differ from the requirements
established by DFO, L–DEO must
adhere to the most protective measure
(e.g., larger EZ, visual monitoring
procedures).
Mitigation Measures Considered But
Eliminated
As stated above, in determining
appropriate mitigation measures, NMFS
considers the practicability of the
measures for applicant implementation,
which may include such things as cost
or impact on operations. NMFS has
proposed expanding critical habitat for
Southern Resident killer whales to
include marine waters between the 6.1m depth contour and the 200-m depth
contour from the U.S. international
border with Canada south to Point Sur,
California (84 FR 49214; September 19,
2019). Though the proposed expansion
has not been finalized, due to the
habitat features of the area and the
higher likelihood of occurrence within
the area, NMFS considered
implementing a closure area and
prohibiting L–DEO from conducting
survey operations between the 200-m
isobath and the coastline. However, this
measure was eliminated from
consideration because the closure
would not be practicable for L–DEO, as
the primary purpose of their survey is
to investigate the geologic features that
occur within that area. Therefore, NMFS
has not prohibited L–DEO from
operating in waters within the 200-m
isobath for this survey.
We have carefully evaluated the suite
of mitigation measures described here
and considered a range of other
measures in the context of ensuring that
we prescribe the means of effecting the
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29125
least practicable adverse impact on the
affected marine mammal species and
stocks and their habitat. Based on our
evaluation of the proposed measures, as
well as other measures considered by
NMFS described above, NMFS has
determined that the mitigation measures
provide the means effecting the least
practicable impact on the affected
species or stocks and their habitat,
paying particular attention to rookeries,
mating grounds, and areas of similar
significance.
Monitoring and Reporting
In order to issue an IHA for an
activity, Section 101(a)(5)(D) of the
MMPA states that NMFS must set forth
requirements pertaining to the
monitoring and reporting of such taking.
The MMPA implementing regulations at
50 CFR 216.104 (a)(13) indicate that
requests for authorizations must include
the suggested means of accomplishing
the necessary monitoring and reporting
that will result in increased knowledge
of the species and of the level of taking
or impacts on populations of marine
mammals that are expected to be
present in the action area. Effective
reporting is critical both to compliance
as well as ensuring that the most value
is obtained from the required
monitoring.
Monitoring and reporting
requirements prescribed by NMFS
should contribute to improved
understanding of one or more of the
following:
• Occurrence of marine mammal
species or stocks in the area in which
take is anticipated (e.g., presence,
abundance, distribution, density);
• Nature, scope, or context of likely
marine mammal exposure to potential
stressors/impacts (individual or
cumulative, acute or chronic), through
better understanding of: (1) Action or
environment (e.g., source
characterization, propagation, ambient
noise); (2) affected species (e.g., life
history, dive patterns); (3) co-occurrence
of marine mammal species with the
action; or (4) biological or behavioral
context of exposure (e.g., age, calving or
feeding areas);
• Individual marine mammal
responses (behavioral or physiological)
to acoustic stressors (acute, chronic, or
cumulative), other stressors, or
cumulative impacts from multiple
stressors;
• How anticipated responses to
stressors impact either: (1) Long-term
fitness and survival of individual
marine mammals; or (2) populations,
species, or stocks;
• Effects on marine mammal habitat
(e.g., marine mammal prey species,
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acoustic habitat, or other important
physical components of marine
mammal habitat); and
• Mitigation and monitoring
effectiveness.
Vessel-Based Visual Monitoring
As described above, PSO observations
must take place during daytime airgun
operations. During seismic operations,
at least five visual PSOs must be based
aboard the R/V Langseth. Two visual
PSOs must be on duty at all time during
daytime hours, with an additional two
PSOs on duty aboard a second scout
vessel at all times during daylight hours
when operating in waters shallower
than 200 m. Monitoring must be
conducted in accordance with the
following requirements:
• The operator must provide PSOs
with bigeye binoculars (e.g., 25 x 150;
2.7 view angle; individual ocular focus;
height control) of appropriate quality
(i.e., Fujinon or equivalent) solely for
PSO use. These must be pedestalmounted on the deck at the most
appropriate vantage point that provides
for optimal sea surface observation, PSO
safety, and safe operation of the vessel;
and
• The operator must work with the
selected third-party observer provider to
ensure PSOs have all equipment
(including backup equipment) needed
to adequately perform necessary tasks,
including accurate determination of
distance and bearing to observed marine
mammals.
PSOs must have the following
requirements and qualifications:
• PSOs must be independent,
dedicated, trained visual and acoustic
PSOs and must be employed by a thirdparty observer provider;
• PSOs must have no tasks other than
to conduct observational effort (visual or
acoustic), collect data, and
communicate with and instruct relevant
vessel crew with regard to the presence
of protected species and mitigation
requirements (including brief alerts
regarding maritime hazards);
• PSOs must have successfully
completed an approved PSO training
course appropriate for their designated
task (visual or acoustic). Acoustic PSOs
are required to complete specialized
training for operating PAM systems and
are encouraged to have familiarity with
the vessel with which they will be
working;
• PSOs can act as acoustic or visual
observers (but not at the same time) as
long as they demonstrate that their
training and experience are sufficient to
perform the task at hand;
• NMFS must review and approve
PSO resumes accompanied by a relevant
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training course information packet that
includes the name and qualifications
(i.e., experience, training completed, or
educational background) of the
instructor(s), the course outline or
syllabus, and course reference material
as well as a document stating successful
completion of the course;
• NMFS shall have one week to
approve PSOs from the time that the
necessary information is submitted,
after which PSOs meeting the minimum
requirements shall automatically be
considered approved;
• PSOs must successfully complete
relevant training, including completion
of all required coursework and passing
(80 percent or greater) a written and/or
oral examination developed for the
training program;
• PSOs must have successfully
attained a bachelor’s degree from an
accredited college or university with a
major in one of the natural sciences, a
minimum of 30 semester hours or
equivalent in the biological sciences,
and at least one undergraduate course in
math or statistics; and
• The educational requirements may
be waived if the PSO has acquired the
relevant skills through alternate
experience. Requests for such a waiver
must be submitted to NMFS and must
include written justification. Requests
shall be granted or denied (with
justification) by NMFS within one week
of receipt of submitted information.
Alternate experience that may be
considered includes, but is not limited
to (1) secondary education and/or
experience comparable to PSO duties;
(2) previous work experience
conducting academic, commercial, or
government-sponsored protected
species surveys; or (3) previous work
experience as a PSO; the PSO should
demonstrate good standing and
consistently good performance of PSO
duties.
For data collection purposes, PSOs
must use standardized data collection
forms, whether hard copy or electronic.
PSOs must record detailed information
about any implementation of mitigation
requirements, including the distance of
animals to the acoustic source and
description of specific actions that
ensued, the behavior of the animal(s),
any observed changes in behavior before
and after implementation of mitigation,
and if shutdown was implemented, the
length of time before any subsequent
ramp-up of the acoustic source. If
required mitigation was not
implemented, PSOs should record a
description of the circumstances. At a
minimum, the following information
must be recorded:
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• Vessel names (source vessel and
other vessels associated with survey)
and call signs;
• PSO names and affiliations;
• Dates of departures and returns to
port with port name;
• Date and participants of PSO
briefings;
• Dates and times (Greenwich Mean
Time) of survey effort and times
corresponding with PSO effort;
• Vessel location (latitude/longitude)
when survey effort began and ended and
vessel location at beginning and end of
visual PSO duty shifts;
• Vessel heading and speed at
beginning and end of visual PSO duty
shifts and upon any line change;
• Environmental conditions while on
visual survey (at beginning and end of
PSO shift and whenever conditions
changed significantly), including BSS
and any other relevant weather
conditions including cloud cover, fog,
sun glare, and overall visibility to the
horizon;
• Factors that may have contributed
to impaired observations during each
PSO shift change or as needed as
environmental conditions changed (e.g.,
vessel traffic, equipment malfunctions);
and
• Survey activity information, such as
acoustic source power output while in
operation, number and volume of
airguns operating in the array, tow
depth of the array, and any other notes
of significance (i.e., pre-clearance, rampup, shutdown, testing, shooting, rampup completion, end of operations,
streamers, etc.).
The following information should be
recorded upon visual observation of any
protected species:
• Watch status (sighting made by PSO
on/off effort, opportunistic, crew,
alternate vessel/platform);
• PSO who sighted the animal;
• Time of sighting;
• Vessel location at time of sighting;
• Water depth;
• Direction of vessel’s travel (compass
direction);
• Direction of animal’s travel relative
to the vessel;
• Pace of the animal;
• Estimated distance to the animal
and its heading relative to vessel at
initial sighting;
• Identification of the animal (e.g.,
genus/species, lowest possible
taxonomic level, or unidentified) and
the composition of the group if there is
a mix of species;
• Estimated number of animals (high/
low/best);
• Estimated number of animals by
cohort (adults, yearlings, juveniles,
calves, group composition, etc.);
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• Description (as many distinguishing
features as possible of each individual
seen, including length, shape, color,
pattern, scars or markings, shape and
size of dorsal fin, shape of head, and
blow characteristics);
• Detailed behavior observations (e.g.,
number of blows/breaths, number of
surfaces, breaching, spyhopping, diving,
feeding, traveling; as explicit and
detailed as possible; note any observed
changes in behavior);
• Animal’s closest point of approach
(CPA) and/or closest distance from any
element of the acoustic source;
• Platform activity at time of sighting
(e.g., deploying, recovering, testing,
shooting, data acquisition, other); and
• Description of any actions
implemented in response to the sighting
(e.g., delays, shutdown, ramp-up) and
time and location of the action.
If a marine mammal is detected while
using the PAM system, the following
information should be recorded:
• An acoustic encounter
identification number, and whether the
detection was linked with a visual
sighting;
• Date and time when first and last
heard;
• Types and nature of sounds heard
(e.g., clicks, whistles, creaks, burst
pulses, continuous, sporadic, strength of
signal); and
• Any additional information
recorded such as water depth of the
hydrophone array, bearing of the animal
to the vessel (if determinable), species
or taxonomic group (if determinable),
spectrogram screenshot, and any other
notable information.
Reporting
A report must be submitted to NMFS
within 90 days after the end of the
cruise. The report must describe the
operations that were conducted and
sightings of marine mammals near the
operations. The report must provide full
documentation of methods, results, and
interpretation pertaining to all
monitoring. The 90-day report must
summarize the dates and locations of
seismic operations, and all marine
mammal sightings (dates, times,
locations, activities, associated seismic
survey activities). The report must also
include estimates of the number and
nature of exposures that occurred above
the harassment threshold based on PSO
observations and including an estimate
of those that were not detected, in
consideration of both the characteristics
and behaviors of the species of marine
mammals that affect detectability, as
well as the environmental factors that
affect detectability.
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The draft report must also include
geo-referenced time-stamped vessel
tracklines for all time periods during
which airguns were operating.
Tracklines should include points
recording any change in airgun status
(e.g., when the airguns began operating,
when they were turned off, or when
they changed from full array to single
gun or vice versa). GIS files must be
provided in ESRI shapefile format and
include the UTC date and time, latitude
in decimal degrees, and longitude in
decimal degrees. All coordinates must
be referenced to the WGS84 geographic
coordinate system. In addition to the
report, all raw observational data must
be made available to NMFS. The report
must summarize the information
submitted in interim monthly reports as
well as additional data collected as
described above and in the IHA. A final
report must be submitted within 30 days
following resolution of any comments
on the draft report.
Reporting Injured or Dead Marine
Mammals
Discovery of injured or dead marine
mammals—In the event that personnel
involved in survey activities covered by
the authorization discover an injured or
dead marine mammal, the L–DEO must
report the incident to the Office of
Protected Resources (OPR), NMFS and
to the NMFS West Coast Regional
Stranding Coordinator as soon as
feasible. The report must include the
following information:
• Time, date, and location (latitude/
longitude) of the first discovery (and
updated location information if known
and applicable);
• Species identification (if known) or
description of the animal(s) involved;
• Condition of the animal(s)
(including carcass condition if the
animal is dead);
• Observed behaviors of the
animal(s), if alive;
• If available, photographs or video
footage of the animal(s); and
• General circumstances under which
the animal was discovered.
Vessel strike—In the event of a ship
strike of a marine mammal by any vessel
involved in the activities covered by the
authorization, L–DEO must report the
incident to OPR, NMFS and to the
NMFS West Coast Regional Stranding
Coordinator as soon as feasible. The
report must include the following
information:
• Time, date, and location (latitude/
longitude) of the incident;
• Vessel’s speed during and leading
up to the incident;
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• Vessel’s course/heading and what
operations were being conducted (if
applicable);
• Status of all sound sources in use;
• Description of avoidance measures/
requirements that were in place at the
time of the strike and what additional
measures were taken, if any, to avoid
strike;
• Environmental conditions (e.g.,
wind speed and direction, Beaufort sea
state, cloud cover, visibility)
immediately preceding the strike;
• Species identification (if known) or
description of the animal(s) involved;
• Estimated size and length of the
animal that was struck
• Description of the behavior of the
animal immediately preceding and
following the strike;
• If available, description of the
presence and behavior of any other
marine mammals present immediately
preceding the strike;
• Estimated fate of the animal (e.g.,
dead, injured but alive, injured and
moving, blood or tissue observed in the
water, status unknown, disappeared);
and
• To the extent practicable,
photographs or video footage of the
animal(s).
Actions To Minimize Additional Harm
to Live-Stranded (or Milling) Marine
Mammals
In the event of a live stranding (or
near-shore atypical milling) event
within 50 km of the survey operations,
where the NMFS stranding network is
engaged in herding or other
interventions to return animals to the
water, the Director of OPR, NMFS (or
designee) will advise L–DEO of the need
to implement shutdown procedures for
all active acoustic sources operating
within 50 km of the stranding.
Shutdown procedures for live stranding
or milling marine mammals include the
following: If at any time, the marine
mammal the marine mammal(s) die or
are euthanized, or if herding/
intervention efforts are stopped, the
Director of OPR, NMFS (or designee)
will advise the IHA-holder that the
shutdown around the animals’ location
is no longer needed. Otherwise,
shutdown procedures must remain in
effect until the Director of OPR, NMFS
(or designee) determines and advises L–
DEO that all live animals involved have
left the area (either of their own volition
or following an intervention).
If further observations of the marine
mammals indicate the potential for restranding, additional coordination with
the IHA-holder will be required to
determine what measures are necessary
to minimize that likelihood (e.g.,
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extending the shutdown or moving
operations farther away) and to
implement those measures as
appropriate.
Additional Information Requests—If
NMFS determines that the
circumstances of any marine mammal
stranding found in the vicinity of the
activity suggest investigation of the
association with survey activities is
warranted, and an investigation into the
stranding is being pursued, NMFS will
submit a written request to L–DEO
indicating that the following initial
available information must be provided
as soon as possible, but no later than 7
business days after the request for
information:
• Status of all sound source use in the
48 hours preceding the estimated time
of stranding and within 50 km of the
discovery/notification of the stranding
by NMFS; and
• If available, description of the
behavior of any marine mammal(s)
observed preceding (i.e., within 48
hours and 50 km) and immediately after
the discovery of the stranding.
In the event that the investigation is
still inconclusive, the investigation of
the association of the survey activities is
still warranted, and the investigation is
still being pursued, NMFS may provide
additional information requests, in
writing, regarding the nature and
location of survey operations prior to
the time period above.
Reporting Species of Concern
To support NMFS’s goal of improving
our understanding of occurrence of
marine mammal species or stocks in the
area (e.g., presence, abundance,
distribution, density), L–DEO must
immediately report observations of
Southern Resident killer whales and
North Pacific right whales to OPR,
NMFS. L–DEO must also immediately
report all sightings of Southern Resident
killer whales and North Pacific right
whales within Olympic Coast National
Marine Sanctuary to the Sanctuary.
Negligible Impact Analysis and
Determination
NMFS has defined negligible impact
as an impact resulting from the
specified activity that cannot be
reasonably expected to, and is not
reasonably likely to, adversely affect the
species or stock through effects on
annual rates of recruitment or survival
(50 CFR 216.103). A negligible impact
finding is based on the lack of likely
adverse effects on annual rates of
recruitment or survival (i.e., populationlevel effects). An estimate of the number
of takes alone is not enough information
on which to base an impact
determination. In addition to
considering estimates of the number of
marine mammals that might be ‘‘taken’’
through harassment, NMFS considers
other factors, such as the likely nature
of any responses (e.g., intensity,
duration), the context of any responses
(e.g., critical reproductive time or
location, migration), as well as effects
on habitat, and the likely effectiveness
of the mitigation. We also assess the
number, intensity, and context of
estimated takes by evaluating this
information relative to population
status. Consistent with the 1989
preamble for NMFS’s implementing
regulations (54 FR 40338; September 29,
1989), the impacts from other past and
ongoing anthropogenic activities are
incorporated into this analysis via their
impacts on the environmental baseline
(e.g., as reflected in the regulatory status
of the species, population size and
growth rate where known, ongoing
sources of human-caused mortality, or
ambient noise levels).
To avoid repetition, our analysis
applies to all species listed in Tables 10
and 11, given that NMFS expects the
anticipated effects of the planned
geophysical survey to be similar in
nature. Where there are meaningful
differences between species or stocks, or
groups of species, in anticipated
individual responses to activities,
impact of expected take on the
population due to differences in
population status, or impacts on habitat,
NMFS has identified species-specific
factors to inform the analysis. As
described above, we have authorized
only the takes estimated to occur
outside of Canadian territorial waters
(Table 10); however, for the purposes of
our negligible impact analysis and
determination, we consider the total
number of takes that are anticipated to
occur as a result of the entire survey
(including the portion of the survey that
would occur within the Canadian
territorial waters (approximately six
percent of the survey) (Table 11).
TABLE 11—TOTAL ESTIMATED TAKE INCLUDING CANADIAN TERRITORIAL WATERS
Estimated take
(excluding Canadian territorial
waters)
Species
Estimated take
(within Canadian territorial
waters)
Total estimated take
Level B
Level B
LF Cetaceans:
Humpback whale ..............................
Blue whale ........................................
Fin whale ..........................................
Sei whale ..........................................
Minke whale ......................................
Gray whale ........................................
MF Cetaceans:
Sperm whale .....................................
Baird’s beaked whale .......................
Small beaked whale .........................
Bottlenose dolphin ............................
Striped dolphin ..................................
Short-beaked common dolphin .........
Pacific white-sided dolphin ...............
Northern right-whale dolphin ............
Risso’s dolphin ..................................
False killer whale ..............................
Killer whale (Southern Resident) ......
Killer whale (Northern Resident) ......
Killer whale (West Coast Transient)
Killer whale (Offshore) ......................
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Jkt 253001
PO 00000
Level A
Level B
Level A
Level A
112
40
94
30
96
43
29
11
1
2
7
1
21
7
2
2
6
23
1
1
0
0
0
1
133
47
96
31
101
66
30
11
1
2
7
2
72
84
242
1
7
112
6093
4320
1669
5
10
0
0
0
0
0
0
0
0
0
0
0
1
1
5
0
0
4
333
118
145
0
1
0
0
0
0
0
0
0
0
0
0
0
73
85
247
1
7
116
6426
4438
1814
5
11
0
0
0
0
0
0
0
0
0
0
0
73
0
4
0
77
0
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TABLE 11—TOTAL ESTIMATED TAKE INCLUDING CANADIAN TERRITORIAL WATERS—Continued
Estimated take
(excluding Canadian territorial
waters)
Species
Estimated take
(within Canadian territorial
waters)
Total estimated take
Level B
Level B
Short-finned pilot whale ....................
HF Cetaceans:
Pygmy/dwarf sperm whale ...............
Dall’s porpoise ..................................
Harbor porpoise ................................
Otariid Pinnipeds:
Northern fur seal ...............................
Guadalupe fur seal ...........................
California sea lion .............................
Steller sea lion ..................................
Phocid Pinnipeds:
Northern elephant seal .....................
Harbor seal .......................................
NMFS does not anticipate that serious
injury or mortality will occur as a result
of L–DEO’s planned survey, even in the
absence of mitigation, and none are
authorized. As discussed in the
Potential Effects section of the notice of
proposed IHA (85 FR 19580; April 7,
2020), non-auditory physical effects,
stranding, and vessel strike are not
expected to occur.
We have authorized a limited number
of instances of Level A harassment of
nine species (low- and high-frequency
cetacean hearing groups only) and Level
B harassment of 31 marine mammal
species. However, we believe that any
PTS incurred in marine mammals as a
result of the planned activity would be
in the form of only a small degree of
PTS, not total deafness, because of the
constant movement relative to each
other of both the R/V Langseth and of
the marine mammals in the project
areas, as well as the fact that the vessel
is not expected to remain in any one
area in which individual marine
mammals would be expected to
concentrate for an extended period of
time (i.e., since the duration of exposure
to loud sounds will be relatively short)
and, further, would be unlikely to affect
the fitness of any individuals. Also, as
described above, we expect that marine
mammals would be likely to move away
from a sound source that represents an
aversive stimulus, especially at levels
that would be expected to result in PTS,
given sufficient notice of the R/V
Langseth’s approach due to the vessel’s
relatively low speed when conducting
seismic surveys. We expect that the
majority of takes would be in the form
of short-term Level B behavioral
harassment in the form of temporary
avoidance of the area or decreased
foraging (if such activity were
occurring), reactions that are considered
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Level A
Level B
20
0
1
0
21
0
125
9762
7958
5
488
283
8
696
2403
0
23
87
134
10457
10361
6
511
369
4424
2048
889
7504
0
0
0
0
54
113
137
1920
0
0
0
0
4478
2161
1026
9424
0
0
0
0
2754
3887
0
0
164
1623
0
0
2918
5510
0
0
to be of low severity and with no lasting
biological consequences (e.g., Southall
et al., 2007, Ellison et al., 2012).
Potential impacts to marine mammal
habitat were discussed in detail in the
Potential Effects of the Specified
Activity on Marine Mammals and their
Habitat section of the notice of
proposed IHA (85 FR 19580; April 7,
2020). Marine mammal habitat may be
impacted by elevated sound levels, but
these impacts would be temporary. Prey
species are mobile and are broadly
distributed throughout the project areas;
therefore, marine mammals that may be
temporarily displaced during survey
activities are expected to be able to
resume foraging once they have moved
away from areas with disturbing levels
of underwater noise. Because of the
relatively short duration (37 days) and
temporary nature of the disturbance, the
availability of similar habitat and
resources in the surrounding area, the
impacts to marine mammals and the
food sources that they utilize are not
expected to cause significant or longterm consequences for individual
marine mammals or their populations.
The tracklines of this survey either
traverse or are proximal to BIAs for
humpback and gray whales (Ferguson et
al., 2015). The entire U.S. West Coast
within 47 km of the coast is a BIA for
migrating gray whale potential presence
from January to July and October to
December. The BIA for northbound gray
whale migration is broken into two
phases, Phase A (within 8 km of shore)
and Phase B (within 5 km of shore),
which are active from January to July
and March to July, respectively. The
BIA for southbound migration includes
waters within 10 km of shore and is
active from October to March. There are
four gray whale feeding BIAs within the
survey area: The Grays Harbor gray
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whale feeding BIA is used between
April and November; the Northwest
Washington gray whale feeding BIA is
used between May and November; and
the Depoe Bay and Cape Blanco and
Orford Reef gray whale feeding BIAs off
Oregon are each used between June and
November. There are also two
humpback whale feeding BIAs within
the survey area: The Stonewall and
Heceta Bank humpback whale feeding
BIA off central Oregon and the northern
Washington BIA off the Washington
Olympic Peninsula are each used
between May and November.
For the humpback whale feeding and
gray whale feeding and northbound
migration BIAs, L–DEO’s survey
beginning in June 2021 could overlap
with a period where BIAs represent an
important habitat. However, only a
portion of seismic survey days would
actually occur in or near these BIAs, and
all survey efforts would be completed
by mid-July, still in the early window of
primary use for these BIAs. Gray whales
are most commonly seen migrating
northward between March and May and
southward between November and
January. As planned, there is no
possibility that L–DEO’s survey impacts
the southern migration, and presence of
northern migrating individuals should
be below peak during survey operations
beginning in June 2021.
Although migrating gray whales may
slightly alter their course in response to
the survey, the exposure would not
substantially impact their migratory
behavior (Malme et al., 1984; Malme
and Miles 1985; Richardson et al.,
1995), and Yazvenko et al. (2007b)
reported no apparent changes in the
frequency of feeding activity in Western
gray whales exposed to airgun sounds in
their feeding grounds near Sakhalin
Island. Goldbogen et al. (2013) found
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blue whales feeding on highly
concentrated prey in shallow depths
(such as the conditions expected within
humpback feeding BIAs) were less
likely to respond and cease foraging
than whales feeding on deep, dispersed
prey when exposed to simulated sonar
sources, suggesting that the benefits of
feeding for humpbacks foraging on highdensity prey may outweigh perceived
harm from the acoustic stimulus, such
as the seismic survey (Southall et al.,
2016). Additionally, L–DEO must shut
down the airgun array upon observation
of an aggregation of six or more large
whales, which would reduce impacts to
cooperatively foraging animals. For all
habitats, no physical impacts to BIA
habitat are anticipated from seismic
activities. While SPLs of sufficient
strength have been known to cause
injury to fish and fish and invertebrate
mortality, in feeding habitats, the most
likely impact to prey species from
survey activities would be temporary
avoidance of the affected area and any
injury or mortality of prey species
would be localized around the survey
and not of a degree that would adversely
impact marine mammal foraging. The
duration of fish avoidance of a given
area after survey effort stops is
unknown, but a rapid return to normal
recruitment, distribution and behavior
is expected. Given the short operational
seismic time near or traversing BIAs, as
well as the ability of cetaceans and prey
species to move away from acoustic
sources, NMFS expects that there would
be, at worst, minimal impacts to animals
and habitat within the designated BIAs.
Critical habitat has been established
on the U.S. West Coast for the eastern
DPS of Steller sea lions (58 FR 45269;
August 27, 1993) and in inland waters
of Washington for Southern Resident
killer whales (71 FR 69054; November
29, 2006). Critical habitat for the Mexico
and Central America DPSs of humpback
whales has been established along the
U.S. West Coast (86 FR 21082; April 21,
2021), and NMFS has proposed
expanding Southern Resident killer
whale critical habitat to include coastal
waters of Washington, Oregon, and
California (84 FR 49214; September 19,
2019). Only a small portion of L–DEO’s
seismic survey will occur in or near
these established or proposed critical
habitats.
Critical habitat for Steller sea lions
has been established at two rookeries on
the Oregon coast, at Rogue Reef
(Pyramid Rock) and Orford Reef (Long
Brown Rock and Seal Rock). The critical
habitat area includes aquatic zones that
extend 0.9 km seaward and air zones
extending 0.9 km above these rookeries
(NMFS 1993). Steller sea lions occupy
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rookeries and pup from late-May
through early-July (NMFS 2008), which
coincides with L–DEO’s survey. The
Orford Reef and Rogue Reef critical
habitats are located 7 km and 9 km from
the nearest planned seismic transect
line, respectively. Impacts to Steller sea
lions within these areas, and throughout
the survey area, are expected to be
limited to short-term behavioral
disturbance, with no lasting biological
consequences.
Critical habitat for the threatened
Mexico DPS and endangered Central
America DPS humpback whales has
been established along the U.S. West
Coast (86 FR 21082; April 21, 2021). The
critical habitat encompasses the
humpback whale feeding BIAs
described above and generally includes
waters between the 50-m isobath and
the 1,200-m isobath, though some areas
extend further offshore. NMFS
determined that prey within humpback
whale feeding areas are essential to the
conservation of each of the three DPSs
of humpback whales for which critical
habitat was established (Mexico, Central
America, and Western North Pacific
DPSs). Critical habitat was therefore
designated in consideration of
importance that the whales not only
have reliable access to prey within their
feeding areas, but that prey are of a
sufficient density to support feeding and
the build-up of energy reserves.
Although humpback whales are
generalist predators and prey
availability can very seasonally and
spatially, substantial data indicate that
the humpback whales’ diet is
consistently dominated by euphausiid
species (of genus Euphausia,
Thysanoessa, Nyctiphanes, and
Nematoscelis) and small pelagic fishes,
such as northern anchovy (Engraulis
mordax), Pacific herring (Clupea
pallasii), Pacific sardine (Sardinops
sagax), and capelin (Mallotus villosus)
(Nemoto 1957, 1959; Klumov 1963; Rice
Krieger and Wing 1984; Baker 1985;
Kieckhefer 1992; Clapham et al., 1997;
Neilson et al., 2015). While there are
possible impacts of seismic activity on
plankton and fish species (e.g.,
McCauley et al., 2017; Hastings and
Popper 2005), the areas expected to be
affected by L–DEO’s activities are small
relative to the greater habitat areas
available. Additionally, humpback
whales feeding on high-density prey
may be less likely to cease foraging
when the benefit of energy intake
outweighs the perceived harm from
acoustic stimulus (Southall et al., 2016).
Therefore, this seismic activity is not
expected to have a lasting physical
impact on humpback whale critical
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habitat, prey within it, or overall
humpback whale fitness. Any impact
would be a temporary increase in sound
levels when the survey is occurring in
or near the critical habitat and resulting
temporary avoidance of prey or marine
mammals themselves due these elevated
sound levels. As stated above, L–DEO
must shut down the airgun array upon
observation of an aggregation of six or
more large whales, which would reduce
direct impacts to groups of humpback
whales that may be cooperatively
feeding in the area.
As discussed earlier, in response to
comments from the ENGOs, we
acknowledge ongoing concern over the
health and growth of the California/
Oregon/Washington stock of humpback
whales, due to vessel strikes and other
factors. As described above, though,
impacts from this seismic survey are not
expected to impact the fitness of any
individuals and thereby will not alone,
or incrementally in combination with
other baseline stressors, adversely affect
the stock through impacts on rates of
recruitment or survival.
Southern Resident Killer Whales
In acknowledgment of our concern
regarding the status of Southern
Resident killer whales, including low
abundance and a decreasing trend, we
address impacts to this stock separately
in this section.
L–DEO’s planned tracklines do not
overlap with existing Southern Resident
killer whale habitat, but NMFS has
proposed expanding Southern Resident
critical habitat to include waters
between the 6.1-m and 200-m depth
contours from the U.S. international
border with Canada south to Point Sur,
California (84 FR 49214; September 19,
2019). The proposed expanded critical
habitat areas were identified in
consideration of physical and biological
features essential to conservation of
Southern Resident killer whales
(essential features): (1) Water quality to
support growth and development; (2)
Prey species of sufficient quantity,
quality, and availability to support
individual growth, reproduction, and
development, as well as overall
population growth; and (3) Passage
conditions to allow for migration,
resting, and foraging. NMFS did not
identify in-water sound levels as a
separate essential feature of existing or
proposed expanded critical habitat
areas, though anthropogenic sound is
recognized as one of the primary threats
to Southern Resident killer whales
(NMFS 2019). Exposure to vessel noise
and presence of whale watching boats
can significantly affect the foraging
behavior of Southern Resident killer
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whales (Williams et al., 2006; Lusseau et
al., 2009; Giles and Cendak 2010;
Senigaglia et al., 2016). Nutritional
stress has also been identified as a
primary cause of Southern Resident
killer whale decline (Ayres et al., 2012;
Wasser et al., 2017), suggesting that
reduced foraging effort may have a
greater impact than behavioral
disturbance alone. However, these
studies have primarily focused on
effects of whale watch vessels operating
in close proximity to Southern Resident
killer whales, and commercial shipping
traffic in the Salish Sea (i.e., the inland
waters of Washington and British
Columbia). Commercial whale watch
and private recreational vessels
operating in the waters around the San
Juan Islands in summer months number
in the dozens (Erbe 2002), and at least
400 piloted vessels (commercial vessels
over 350 gross tons and pleasure craft
over 500 gross tons that are required to
be guided in and out of the Port of
Vancouver by British Columbia Coast
Pilots) transit through Haro Strait each
month (Joy et al., 2002). Concentration
of vessel traffic on the outer coast,
where the survey area occurs, is much
lower than in the inland waters
(Cominelli et al., 2018), suggesting that
effects from vessel noise may be lower
than in inland waters. Increased noise
levels from the survey in any specific
area would be short-term due to the
mobile nature of the survey, unlike the
near-constant vessel presence in inland
waters.
Approximately 30 percent of L–DEO’s
total tracklines occur within the 200-m
isobath along the coast of Oregon,
Washington, and British Columbia. L–
DEO is required to shut down seismic
airguns immediately upon visual
observation or acoustic detection of
killer whales of any ecotype at any
distance to minimize potential
exposures of Southern Resident killer
whales, and must operate within the
200-m isobath in daylight hours only, to
increase the ability to visually detect
killer whales and implement
shutdowns. Southern Resident killer
whales exposed to elevated sound levels
from the R/V Langseth and the airgun
array may reduce foraging time, but no
survey tracklines or ensonified area
overlap with the areas of highest
estimated densities of Southern
Resident killer whales (see Table 9 of
this notice and Figures 7–9 and 7–11 in
the U.S. Navy’s MSDD (U.S. Navy
2019)). While Southern Resident killer
whales may be encountered outside of
these areas of highest density, the
likelihood is significantly decreased and
the relatively small amount of time of
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altered behavior would not likely affect
their overall foraging ability. Short-term
impacts to foraging ability are not likely
to result in significant or lasting
consequences for individual Southern
Resident killer whales or the population
as a whole (Ayres et al., 2012). Due to
the mobile nature of the survey, animals
would not be exposed to elevated
sounds for an extended period, and the
proposed critical habitat contains a large
area of suitable habitat that would allow
Southern Resident killer whales to
forage away from the survey. Noren et
al. (2016) reported that although
resident killer whales increase energy
expenditure in response to vessel
presence, the increase is considered to
be negligible.
No permanent hearing impairment
(Level A harassment) is anticipated or
authorized. Authorized takes of
Southern Resident killer whales would
be limited to Level B harassment in the
form of behavioral disturbance. We
anticipate 11 instances of Level B
harassment of Southern Resident killer
whales (10 takes by Level B harassment
authorized in this IHA and one take by
Level B harassment within Canadian
territorial waters), which we expect
would likely occur to a smaller subset
of the population on only a few days.
Limited, short term behavioral
disturbance of the nature expected here
would not be expected to result in
fitness-level effects to individual
Southern Resident killer whales or the
population as a whole.
Negligible Impact Conclusions
The survey will be of short duration
(37 days of seismic operations), and the
acoustic ‘‘footprint’’ of the survey is
small relative to the ranges of the
marine mammals that will potentially
be affected. Sound levels will increase
in the marine environment in a
relatively small area surrounding the
vessel compared to the range of the
marine mammals within the survey
area. Short term exposures to survey
operations are not likely to significantly
disrupt marine mammal behavior, and
the potential for longer-term avoidance
of important areas is limited.
The prescribed mitigation measures
are expected to reduce the number and/
or severity of takes by allowing for
detection of marine mammals in the
vicinity of the vessel by visual and
acoustic observers, and by minimizing
the severity of any potential exposures
via shutdowns of the airgun array.
Based on previous monitoring reports
for substantially similar activities that
have been previously authorized by
NMFS, we expect that the required
mitigation will be effective in
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preventing, at least to some extent,
potential PTS in marine mammals that
may otherwise occur in the absence of
the mitigation (although all authorized
PTS has been accounted for in this
analysis). Further, for Southern Resident
Killer Whales (as described above),
additional mitigation (e.g., second
monitoring vessel, daylight only
surveys) is expected to increase the
ability of PSOs to detect killer whales
and shut down the airgun array to
reduce the instances and severity of
behavioral disturbance.
While operating within the Canadian
EEZ, L–DEO will implement certain
measures prescribed by Canada’s DFO
that are more protective than those
prescribed by NMFS under the MMPA.
These include a requirement to avoid
operating within or nearby designated
Southern Resident or Northern Resident
killer whale critical habitat such that the
ensonified area above the 160 dB rms
threshold does not extend inside critical
habitat, shutting down the airgun array
if a sperm whale or a beaked whale (any
species) is observed within 1,500 m, and
shutting down the airgun array if any
species of marine mammal is observed
within 1,000 m of the array.
Additionally, throughout the entire
survey area within the Canadian EEZ,
L–DEO will not conduct survey
operations in waters 100 m or less and
will conduct seismic surveys in waters
100 to 200 m deep during daylight
hours only, with a second vessel having
two marine mammal observers on
watch, positioned 5 km ahead of the R/
V Langseth. L–DEO must also combine
enhanced visual observations (e.g.,
reticle and big-eye binoculars, night
vision devices and digital cameras) with
non-visual detection methods (e.g.,
infrared technology (FLIR) and PAM) to
increase the likelihood of detecting
marine mammals during ramp up,
Beaufort sea states >3, and night time
survey operations. Finally, L–DEO must
monitor the established exclusion zone
with a radius of 1,000 m for 60 minutes
prior to initial start-up of the airgun
array or resumption of operations
following a complete shutdown to allow
for the detection of deep diving animals.
NMFS concludes that exposures to
marine mammal species and stocks due
to L–DEO’s planned survey will result
in only short-term (temporary and short
in duration) effects to individuals
exposed, over relatively small areas of
the affected animals’ ranges. Animals
may temporarily avoid the immediate
area, but are not expected to
permanently abandon the area. Major
shifts in habitat use, distribution, or
foraging success are not expected.
NMFS does not anticipate the
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authorized take to impact annual rates
of recruitment or survival.
In summary and as described above,
the following factors primarily support
our determination that the impacts
resulting from this activity are not
expected to adversely affect the species
or stock through effects on annual rates
of recruitment or survival:
• No serious injury or mortality is
anticipated or authorized;
• The planned activity is temporary
and of relatively short duration (37
days);
• The anticipated impacts of the
activity on marine mammals will
primarily be temporary behavioral
changes due to avoidance of the area
around the survey vessel;
• The number of instances of
potential PTS that may occur are
expected to be very small in number.
Instances of potential PTS that are
incurred in marine mammals are
expected to be of a low level, due to
constant movement of the vessel and of
the marine mammals in the area, and
the nature of the survey design (not
concentrated in areas of high marine
mammal concentration);
• The availability of alternate areas of
similar habitat value for marine
mammals to temporarily vacate the
survey area during the planned survey
to avoid exposure to sounds from the
activity;
• The potential adverse effects on fish
or invertebrate species that serve as prey
species for marine mammals from the
survey will be temporary and spatially
limited, and impacts to marine mammal
foraging will be minimal; and
• The mitigation requirements,
including visual and acoustic
monitoring, shutdowns, and enhanced
measures for areas of biological
importance (e.g., additional monitoring
vessel, daylight operations only) are
expected to minimize potential impacts
to marine mammals (both amount and
severity).
• Additionally as described above for
Southern Resident killer whales
specifically, anticipated impacts are
limited to few days of behavioral
disturbance for any one individual and
additional mitigation (e.g., additional
monitoring vessel, survey timing,
shutdowns) are expected to ensure that
both the numbers and severity of
impacts to this stock are minimized,
and, therefore the authorization of
Southern Resident killer whale take is
not expected to impact the fitness of any
individuals, much less rates of
recruitment or survival.
Based on the analysis contained
herein of the likely effects of the
specified activity on marine mammals
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and their habitat, and taking into
consideration the implementation of the
prescribed mitigation and monitoring
measures, NMFS finds that the total
marine mammal take from the planned
activity will have a negligible impact on
all affected marine mammal species or
stocks.
Small Numbers
As noted above, only small numbers
of incidental take may be authorized
under Sections 101(a)(5)(A) and (D) of
the MMPA for specified activities other
than military readiness activities. The
MMPA does not define small numbers
and so, in practice, where estimated
numbers are available, NMFS compares
the number of individuals taken to the
most appropriate estimation of
abundance of the relevant species or
stock in our determination of whether
an authorization is limited to small
numbers of marine mammals.
Additionally, other qualitative factors
may be considered in the analysis, such
as the temporal or spatial scale of the
activities.
There are two stocks for which the
estimated instances of take appear high
when compared to the stock abundance
(Table 10)—the California/Oregon/
Washington Dall’s porpoise stock and
the Northern Oregon/Washington Coast
harbor porpoise stock. However, when
other qualitative factors are used to
inform an assessment of the likely
number of individual marine mammals
taken, the resulting numbers are
appropriately considered small. We
discuss these in further detail below.
For all other stocks (aside from the
two referenced above and described
below), the authorized take is less than
one-third of the best available stock
abundance (recognizing that some of
those takes may be repeats of the same
individual, thus rendering the actual
percentage even lower). Additionally,
we note that the authorized take is
compared to the stock abundance for
MMPA designated stocks, which for
many species are limited to U.S. waters
and do not include animals within the
Canadian EEZ. Therefore, for species
with transboundary populations, the
actual percentage of the population
affected is lower than that shown in
Table 10.
The expected take of the California/
Oregon/Washington stock of Dall’s
porpoises, as a proportion of the
population abundance, is 36.94 percent,
if all takes are assumed to occur for
unique individuals. In reality, it is
unlikely that all takes would occur to
different individuals. L–DEO’s survey
area represents a small portion of the
stock’s overall range (Caretta et al.,
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2017), and it is more likely that there
will be multiple takes of a smaller
number of individuals within the action
area. In addition, Best et al. (2015)
estimated the population of Dall’s
porpoise in British Columbia to be 5,303
porpoises based on systematic linetransect surveys of the Strait of Georgia,
Johnstone Strait, Queen Charlotte
Sound, Hecate Strait, and Dixon
Entrance between 2004 and 2007. In
consideration of the greater abundance
estimate combining the U.S. stock and
animals in British Columbia, and the
likelihood of repeated takes of
individuals, it is unlikely that more than
one-third of the stock will be exposed to
the seismic survey.
When assuming all estimated takes of
harbor porpoise (8,241 total takes by
Level A and B harassment) will occur to
the Northern Oregon/Washington Coast
stock, the take appears high relative to
stock abundance (38.35 percent). In
reality, takes will occur to both the
Northern Oregon/Washington Coast and
Northern California/Southern Oregon
stocks, and therefore, the number of
takes of each stock will be much lower.
NMFS has no commonly used method
to estimate the relative proportion of
each stock that will experience take, but
here we propose to apportion the takes
between the two stocks based on the
stock boundary (Lincoln City, Oregon)
and the approximate proportion of the
survey area that will occur on either
side of the stock boundary. North of
Lincoln City, Oregon, harbor porpoises
belong to the Northern Oregon/
Washington Coast stock, and south of
Lincoln City, harbor porpoises belong to
the Northern California/Southern
Oregon stock. Approximately one-third
of the planned survey occurs south of
Lincoln City, therefore one-third of the
total estimated takes are assumed to be
from the Northern California/Southern
Oregon stock. The remaining two-thirds
of the estimated takes are assumed to be
from the Northern Oregon/Washington
Coast stock. The estimated one-third of
total takes assigned to the Northern
California/Southern Oregon stock (2,747
total Level A and Level B takes)
represent 7.68 percent of the stock
abundance, which NMFS considers to
be small relative to the stock abundance.
In addition, the survey area represents
a small portion of the stock’s range, and
it is likely that there will be multiple
takes of a small portion of individuals,
further reducing the number of
individuals exposed. The estimated
two-thirds of total takes assigned to the
Northern Oregon/Washington Coast
stock (5,494 takes) represent 25.57
percent of the stock abundance, which
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NMFS considers to be small relative to
the stock abundance. Additionally, the
Northern Oregon/Washington Coast
stock abundance estimate does not
include animals in Canadian waters
(Caretta et al., 2017). Best et al. (2015)
estimated a population abundance of
8,091 harbor porpoises in British
Columbia. The estimated takes of
animals in the northern portion of the
survey area (north of Lincoln City)
represent 18.57 percent of the combined
British Columbia and Northern Oregon/
Washington Coast abundance estimates,
which NMFS considers to be small
relative to the stock abundance.
Based on the analysis contained
herein of the planned activity (including
the required mitigation and monitoring
measures) and the anticipated take of
marine mammals, NMFS finds that
small numbers of marine mammals will
be taken relative to the population size
of the affected species or stocks.
Unmitigable Adverse Impact Analysis
and Determination
There are no relevant subsistence uses
of the affected marine mammal stocks or
species implicated by this action.
Therefore, NMFS has determined that
the total taking of affected species or
stocks will not have an unmitigable
adverse impact on the availability of
such species or stocks for taking for
subsistence purposes.
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National Environmental Policy Act
To comply with the National
Environmental Policy Act of 1969
(NEPA; 42 U.S.C. 4321 et seq.) and
NOAA Administrative Order (NAO)
216–6A, NMFS must review our
proposed action (i.e., the issuance of an
incidental harassment authorization)
with respect to potential impacts on the
human environment.
Accordingly, NMFS has adopted the
NSF’s EA, as we have determined that
it includes adequate information
analyzing the effects on the human
environment of issuing the IHA, and
prepared a FONSI. NSF’s EA is available
at https://www.nsf.gov/geo/oce/
envcomp/, and NMFS’ FONSI is
available at https://www.fisheries.
noaa.gov/national/marine-mammalprotection/incidental-takeauthorizations-research-and-otheractivities.
Endangered Species Act (ESA)
Section 7(a)(2) of the Endangered
Species Act of 1973 (ESA: 16 U.S.C.
1531 et seq.) requires that each Federal
agency insure that any action it
authorizes, funds, or carries out is not
likely to jeopardize the continued
existence of any endangered or
threatened species or result in the
destruction or adverse modification of
designated critical habitat. To ensure
ESA compliance for the issuance of
IHAs, NMFS consults internally
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29133
whenever we propose to authorize take
for endangered or threatened species.
The NMFS Office of Protected
Resources ESA Interagency Cooperation
Division issued a Biological Opinion
under section 7 of the ESA, on the
issuance of an IHA to L–DEO under
section 101(a)(5)(D) of the MMPA by the
NMFS OPR Permits and Conservation
Division. The Biological Opinion
concluded that the proposed action is
not likely to jeopardize the continued
existence of ESA-listed blue whales, fin
whales, sei whales, sperm whales,
Central America DPS humpback whales,
Mexico DPS humpback whales,
Southern Resident killer whale DPS,
and Guadalupe fur seals, and is not
likely to destroy or adversely modify
designated Steller sea lion or humpback
whale critical habitat. There is no
designated critical habitat in the action
area for the other ESA-listed species.
Authorization
As a result of these determinations,
NMFS has issued an IHA to L–DEO for
conducting a marine geophysical survey
in the northeast Pacific Ocean beginning
in June 2021, provided the previously
mentioned mitigation, monitoring, and
reporting requirements are incorporated.
Dated: May 24, 2021.
Catherine Marzin,
Acting Director, Office of Protected Resources,
National Marine Fisheries Service.
[FR Doc. 2021–11375 Filed 5–27–21; 8:45 am]
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[Federal Register Volume 86, Number 102 (Friday, May 28, 2021)]
[Notices]
[Pages 29090-29133]
From the Federal Register Online via the Government Publishing Office [www.gpo.gov]
[FR Doc No: 2021-11375]
[[Page 29089]]
Vol. 86
Friday,
No. 102
May 28, 2021
Part III
Department of Commerce
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National Oceanic and Atmospheric Administration
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Takes of Marine Mammals Incidental to Specified Activities; Taking
Marine Mammals Incidental to a Marine Geophysical Survey in the
Northeast Pacific Ocean; Notice
��Federal Register / Vol. 86, No. 102 / Friday, May 28, 2021 /
Notices��
[[Page 29090]]
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DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric Administration
[RTID 0648-XA144]
Takes of Marine Mammals Incidental to Specified Activities;
Taking Marine Mammals Incidental to a Marine Geophysical Survey in the
Northeast Pacific Ocean
AGENCY: National Marine Fisheries Service (NMFS), National Oceanic and
Atmospheric Administration (NOAA), Commerce.
ACTION: Notice; issuance of an incidental harassment authorization.
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SUMMARY: In accordance with the regulations implementing the Marine
Mammal Protection Act (MMPA) as amended, notification is hereby given
that NMFS has issued an incidental harassment authorization (IHA) to
Lamont-Doherty Earth Observatory of Columbia University (L-DEO) to
incidentally harass, by Level A and Level B harassment, marine mammals
during a marine geophysical survey in the northeast Pacific Ocean.
DATES: This Authorization is effective from May 19, 2021 through May
18, 2022.
FOR FURTHER INFORMATION CONTACT: Amy Fowler, Office of Protected
Resources, NMFS, (301) 427-8401. Electronic copies of the application
and supporting documents, as well as a list of the references cited in
this document, may be obtained online at: https://www.fisheries.noaa.gov/permit/incidental-take-authorizations-under-marine-mammal-protection-act. In case of problems accessing these
documents, please call the contact listed above.
SUPPLEMENTARY INFORMATION:
Background
The MMPA prohibits the ``take'' of marine mammals, with certain
exceptions. Sections 101(a)(5)(A) and (D) of the MMPA (16 U.S.C. 1361
et seq.) direct the Secretary of Commerce (as delegated to NMFS) to
allow, upon request, the incidental, but not intentional, taking of
small numbers of marine mammals by U.S. citizens who engage in a
specified activity (other than commercial fishing) within a specified
geographical region if certain findings are made and either regulations
are issued or, if the taking is limited to harassment, a notice of a
proposed incidental take authorization may be provided to the public
for review.
Authorization for incidental takings shall be granted if NMFS finds
that the taking will have a negligible impact on the species or
stock(s) and will not have an unmitigable adverse impact on the
availability of the species or stock(s) for taking for subsistence uses
(where relevant). Further, NMFS must prescribe the permissible methods
of taking and other ``means of effecting the least practicable adverse
impact'' on the affected species or stocks and their habitat, paying
particular attention to rookeries, mating grounds, and areas of similar
significance, and on the availability of the species or stocks for
taking for certain subsistence uses (referred to in shorthand as
``mitigation''); and requirements pertaining to the mitigation,
monitoring and reporting of the takings are set forth.
Summary of Request
On November 8, 2019, NMFS received a request from L-DEO for an IHA
to take marine mammals incidental to a marine geophysical survey of the
Cascadia Subduction Zone off the coasts of Washington, Oregon, and
British Columbia, Canada. The application was deemed adequate and
complete on March 6, 2020. L-DEO's request is for take of small numbers
of 31 species of marine mammals by Level A and Level B harassment. NMFS
published a notice of proposed IHA for public review and comment on
April 7, 2020 (85 FR 19580). On May 29, 2020, L-DEO informed NMFS that
the project had been delayed by one year and would begin in June 2021.
Description of Proposed Activity
Overview
Researchers from L-DEO, Woods Hole Oceanographic Institution
(WHOI), and the University of Texas at Austin Institute of Geophysics
(UTIG), with funding from the National Science Foundation (NSF), and in
collaboration with researchers from Dalhousie University and Simon
Fraser University (SFU) plan to conduct a high-energy seismic survey
from the Research Vessel (R/V) Marcus G Langseth (Langseth) in the
northeast Pacific Ocean beginning in June 2021. The seismic survey will
be conducted at the Cascadia Subduction Zone off the coasts of Oregon,
Washington, and British Columbia, Canada. The proposed two-dimensional
(2-D) seismic survey will occur within the Exclusive Economic Zones
(EEZs) of Canada and the United States, including U.S. state waters and
Canadian territorial waters. The survey will use a 36-airgun towed
array with a total discharge volume of ~6,600 cubic inches (in\3\) as
an acoustic source, acquiring return signals using both a towed
streamer as well ocean bottom seismometers (OBSs) and ocean bottom
nodes (OBNs).
The planned study will use 2-D seismic surveying and OBSs and OBNs
to investigate the Cascadia Subduction Zone and provide data necessary
to illuminate the depth, geometry, and physical properties of the
seismogenic portion and updip extent of the megathrust zone between the
subducting Juan de Fuca plate and the overlying accretionary wedge/
North American plate. These data will provide essential constraints for
earthquake and tsunami hazard assessment in this heavily populated
region of the Pacific Northwest. The primary objectives of the survey
planned by researchers from L-DEO, WHOI, and UTIG is to characterize:
(1) The deformation and topography of the incoming plate; (2) the
depth, topography, and reflectivity of the megathrust; (3) sediment
properties and amount of sediment subduction; and (4) the structure and
evolution of the accretionary wedge, including geometry and
reflectivity of fault networks, and how these properties vary along
strike, spanning the full length of the margin and down dip across what
may be the full width of the Cascadia Subduction Zone.
Dates and Duration
The survey is expected to last for 40 days, with 37 days of seismic
operations, 2 days of equipment deployment, and 1 day of transit. R/V
Langseth will likely leave out of and return to port in Newport,
Oregon, during June-July 2021.
Specific Geographic Region
The survey will occur within ~42-51[deg] N, ~124-130[deg] W.
Planned survey tracklines are shown in Figure 1. Some deviation in
actual track lines, including the order of survey operations, could be
necessary for reasons such as science drivers, poor data quality,
inclement weather, or mechanical issues with the research vessel and/or
equipment. The survey will occur within the EEZs of the United States
and Canada, as well as in U.S. state waters and Canadian territorial
waters, ranging in depth 60-4400 meters (m). A maximum of 6,540
kilometers (km) of transect lines will be surveyed. Most of the survey
(69 percent) will occur in deep water (>1,000 m), 28 percent will occur
in intermediate water (100-1,000 m deep), and 3 percent will take place
in shallow water <100 m deep. Approximately 3.6 percent of the transect
lines (234 km) will be undertaken in Canadian territorial waters (from
0-12 nautical miles (22.2 km) from shore), with most
[[Page 29091]]
effort in intermediate water depths. NMFS cannot authorize the
incidental take of marine mammals in the territorial seas of foreign
nations, as the MMPA does not apply in those waters. However, NMFS has
still calculated the level of incidental take in the entire activity
area (including Canadian territorial waters) as part of the analysis
supporting our determination under the MMPA that the activity will have
a negligible impact on the affected species.
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Detailed Description of Specific Activity
The procedures to be used for the planned survey will be similar to
those used during previous seismic surveys by L-DEO and will use
conventional seismic methodology. The surveys will involve one source
vessel, R/V Langseth. R/V Langseth will deploy an array of 36 airguns
as an energy source with a total volume of ~6,600 in\3\. The array
consists of 20 Bolt 1500LL airguns with volumes of 180 to 360 in\3\ and
16 Bolt 1900LLX airguns with volumes of 40 to 120 in\3\. The airgun
array configuration is illustrated in Figure 2-11 of NSF and USGS's
Programmatic Environmental Impact Statement (PEIS; NSF-USGS, 2011). The
vessel speed during seismic operations will be approximately 4.2 knots
(~7.8 km/hour) during the survey and the airgun array will be towed at
a depth of 12 m. The receiving system will consist of one 15-km long
hydrophone streamer, OBSs, and OBNs. R/V Oceanus, which is owned by NSF
and operated by Oregon State University, will be used to deploy the
OBSs and OBNs. As the airguns are towed along the survey lines, the
hydrophone streamer will transfer the data to the on-board processing
system, and the OBSs and OBNs will receive and store the returning
acoustic signals internally for later analysis.
Long 15-km-offset multichannel seismic (MCS) data will be acquired
along numerous 2-D profiles oriented perpendicular to the margin and
located to provide coverage in areas inferred to be rupture patches
during past earthquakes and their boundary zones. The survey will also
include several strike lines including one continuous line along the
continental shelf centered roughly over gravity-inferred fore-arc
basins to investigate possible segmentation near the down-dip limit of
the seismogenic zone. The margin normal lines will extend ~50 km
seaward of the deformation front to image the region of subduction bend
faulting in the incoming oceanic plate, and landward of the deformation
front to as close to the shoreline as can be safely maneuvered. L-DEO
plans to survey the southern transects off Oregon first, followed by
the profiles off Washington and Vancouver Island, British Columbia.
The OBSs will consist of short-period multi-component OBSs from the
Ocean Bottom Seismometer Instrument Center (OBSIC) and a large-N array
of OBNs from a commercial provider to record shots along ~11 MCS
margin-perpendicular profiles. OBSs will be deployed at 10-km spacing
along ~10 profiles from Vancouver Island to Oregon, and OBNs will be
deployed at a 500-m spacing along a portion of three profiles off
Oregon. Two OBS deployments will occur with a total of 115 instrumented
locations. 60 OBSs will be deployed to instrument seven profiles off
Oregon, followed by a second deployment of 55 OBSs to instrument four
profiles off Washington and Vancouver Island. The first deployment off
Oregon will occur prior to the start of the planned survey, after which
R/V Langseth will acquire data in the southern portion of the study
area. R/V Oceanus will start recovering the OBSs from deployment 1, and
then re-deploy 55 OBSs off Washington and Vancouver Island, so that R/V
Langseth can acquire data in the northern portion of the survey area.
The OBSs have a height and diameter of ~1 m, and an ~80 kilogram (kg)
anchor. To retrieve OBSs, an acoustic release transponder (pinger) is
used to interrogate the instrument at a frequency of 8-11 kilohertz
(kHz), and a response is received at a frequency of 11.5-13 kHz. The
burn-wire release assembly is then activated, and the instrument is
released to float to the surface from the anchor, which is not
retrieved.
A total of 350 OBNs will be deployed: 179 nodes along one transect
off northern Oregon, 107 nodes along a second transect off central
Oregon, and 64 nodes along a third transect off southern Oregon. The
nodes are not connected to each other; each node is independent from
each other, and there are no cables attached to them. Each node has
internal batteries; all data is recorded and stored internally. The
nodes weigh 21 kg in air (9.5 kg in water). As the OBNs are small (330
millimeters (mm) x 289 mm x 115 mm), compact, not buoyant, and lack an
anchor-release mechanism, they cannot be deployed by free-fall as with
the OBSs. The nodes will be deployed and retrieved using a remotely
operated vehicle (ROV); the ROV will be deployed from R/V Oceanus. OBNs
will be deployed approximately 17 days prior to the start of the R/V
Langseth cruise. The ROV will be fitted with a skid with capacity for
32 units, lowered to the seafloor, and towed at a speed of 0.6 knots at
5-10 m above the seafloor between deployment sites. After the 32 units
are deployed, the ROV will be retrieved, the skid will be reloaded with
another 32 units, and sent back to the seafloor for deployment, and so
on. The ROV will recover the nodes 3 days after the completion of the
R/V Langseth cruise. The nodes will be recovered one by one by a
suction mechanism. Take of marine mammals is not expected to occur
incidental to L-DEO's use of OBSs and OBNs.
In addition to the operations of the airgun array, a multibeam
echosounder (MBES), a sub-bottom profiler (SBP), and an Acoustic
Doppler Current Profiler (ADCP) will be operated from R/V Langseth
continuously during the seismic surveys, but not during transit to and
from the survey area. All planned geophysical data acquisition
activities will be conducted by L-DEO with on-board assistance by the
scientists who have planned the studies. The vessel will be self-
contained, and the crew will live aboard the vessel. Take of marine
mammals is not expected to occur incidental to use of the MBES, SBP, or
ADCP because they will be operated only during seismic acquisition, and
it is assumed that, during simultaneous operations of the airgun array
and the other sources, any marine mammals close enough to be affected
by the MBES, SBP, and ADCP would already be affected by the airguns.
However, whether or not the airguns are operating simultaneously with
the other sources, given their characteristics (e.g., narrow downward-
directed beam), marine mammals would experience no more than one or two
brief ping exposures, if any exposure were to occur. Mitigation,
monitoring, and reporting measures are described in detail later in
this document (please see Mitigation and Monitoring and Reporting).
Comments and Responses
A notice of NMFS's proposal to issue an IHA to L-DEO was published
in the Federal Register on April 7, 2020 (85 FR 19580). During the
public comment period, NMFS received comment letters from the Marine
Mammal Commission (Commission), Ecojustice (on behalf of the David
Suzuki Foundation, Georgia Strait Alliance, Raincoast Conservation
Foundation, and World Wildlife Fund Canada), Deep Green Wilderness, and
a group of environmental non-governmental organizations (ENGOs)
including the Center for Biological Diversity (CBD), Natural Resources
Defense Council, Orca Relief Citizens Alliance, Friends of the San
Juans, Whale and Dolphin Conservation, Friends of the Earth, Oceana,
and Orca Conservancy. NMFS has posted the comments online at: https://www.fisheries.noaa.gov/national/marine-mammal-protection/incidental-take-authorizations-research-and-other-activities. Please see the
letters for full details and rationale. A summary of the comments and
our responses are provided here.
Comment 1: Ecojustice requested NMFS deny L-DEO's request for an
IHA
[[Page 29093]]
because the survey will affect Southern Resident killer whale critical
habitat (e.g., Swiftsure and La Perouse Banks) designated in Canada
under the Canadian Species at Risk Act (SARA). The commenter asserts
that noise production in these areas will both harm or harass
individuals and constitute destruction of a portion of Canadian
critical habitat.
Response: This comment is beyond the scope of NMFS' proposed
action, which is to authorize take of marine mammals incidental to the
proposed survey. NMFS does not allow or deny the survey itself, and
NMFS' action of authorizing incidental take does not cause effects to
critical habitat (in Canada or the U.S.). However, as part of their
consultation with Canada's Department of Fisheries and Oceans (DFO)
under Canada's SARA, L-DEO has removed all survey tracklines with
associated ensonified areas that overlap with Canadian designated
killer whale critical habitat at Swiftsure and La Perouse Bank (see
Figure 1); therefore, the Canadian critical habitat will not be subject
to destruction.
Comment 2: Ecojustice asserts that the critically endangered status
of Southern Resident killer whales means there is no acceptable level
of take for the species. Similarly, the ENGOs recommended NMFS not
issue any take authorization until it has effectively reduced the take
of Southern Resident killer whales to zero, citing concern that
behavioral disturbance can interfere with reproduction and survival due
to lost foraging time.
Response: NMFS disagrees that there is no acceptable level of take
for Southern Resident killer whales, and the commenters have not
demonstrated that any level of taking of Southern Resident killer
whales would result in greater than a negligible impact on the stock.
However, we do agree that additional effort to reduce impacts to
Southern Resident killer whales is warranted to minimize to the extent
practicable the amount of taking as well as the impact of taking that
is authorized. In addition to removing tracklines within Canadian
designated Southern Resident killer whale critical habitat at Swiftsure
and La Perouse Banks (discussed above), L-DEO has removed and modified
tracklines between Tillamook Head, Oregon and Barkley Sound, British
Columbia, the area in which Southern Resident killer whales have the
highest estimated densities (U.S. Navy 2019) and high-use foraging
areas (NMFS 2019). The effect of these modifications to the survey plan
is that, between these landmarks, the estimated Level B harassment
ensonified area will not extend into water shallower than the 100-m
depth contour. As a result, the total estimated take of Southern
Resident killer whales has been reduced from 43 takes by Level B
harassment in the proposed IHA (with an additional two takes within
Canadian territorial waters, outside NMFS' jurisdiction) to 10 takes by
Level B harassment (plus one take by Level B harassment within Canadian
territorial waters), which is less than the population of any pod in
the Southern Resident stock. This estimated take represents either 10
individual Southern Resident killer whales taken by Level B harassment
once over the course of the survey, or a smaller number of individuals
taken multiple times (e.g., a single matriline of five animals taken by
Level B harassment on two separate days). By avoiding surveying in the
areas with highest expected Southern Resident killer whale presence and
foraging rates, the likelihood of survey activities resulting in
interference in feeding and migration that could result in lost feeding
opportunities or necessitate additional energy expenditure to find
other good foraging opportunities or migration routes is greatly
reduced. Procedural mitigations that avoid the likelihood of injury,
such as shutdown measures, also further reduce the likelihood of more
severe behavioral responses.
Comment 3: The ENGOs assert that NMFS inadequately considered the
impacts of the proposed action on prey availability for Southern
Resident killer whales, citing studies showing responses of fish to
sound from seismic surveys. The ENGOs also state that NMFS must also
consider the fitness of salmon being indirectly affected by the
survey's impacts on herring, a key prey species for Pacific salmon.
Response: NMFS disagrees with the suggestion that we ignored
effects to prey species. In fact, we considered relevant literature
(including that cited by the ENGOs) in finding that the most likely
impact of survey activity to prey species such as fish and
invertebrates would be temporary avoidance of an area, with a rapid
return to pre-survey distribution and behavior, and minimal impacts to
recruitment or survival anticipated. While there is a lack of specific
scientific information to allow an assessment of the duration,
intensity, or distribution of effects to prey in specific locations at
specific times and in response to specific surveys, NMFS' review of the
available information does not indicate that such effects could be
significant enough to impact marine mammal prey to the extent that
marine mammal fitness would be affected. We agree that seismic surveys
could affect certain marine mammal prey species, and addressed these
potential effects, as well as the potential for those effects to impact
marine mammal populations, in our notice of proposed IHA (85 FR 19580;
April 7, 2020). As stated in the notice of proposed IHA, our review of
the available information and the specific nature of the activities
considered herein suggest that L-DEO's proposed survey activities are
not likely to have more than short-term adverse effects on any prey
habitat or populations of prey species. Further, any impacts to prey
species are not expected to result in significant or long-term
consequences for individual marine mammals, or to contribute to adverse
impacts on their populations.
For additional information on the effects of L-DEO's proposed
survey on salmon species present in the survey area, we refer the
reader to the Biological Opinion issued by the NMFS Office of Protected
Resources, Interagency Cooperation Division (available at https://www.fisheries.noaa.gov/national/marine-mammal-protection/incidental-take-authorizations-research-and-other-activities). In summary, fish
react to sounds which are especially strong and/or intermittent low-
frequency sounds, and behavioral responses such as flight or avoidance
are the most likely effects. However, the reaction of fish to airguns
depends on the physiological state of the fish, past exposures,
motivation (e.g., feeding, spawning, migration), and other
environmental factors. While we agree that some studies have
demonstrated that airgun sounds might affect the distribution and
behavior of some fishes, potentially impacting foraging opportunities
or increasing energetic costs (e.g., Fewtrell and McCauley, 2012;
Pearson et al., 1992; Skalski et al., 1992; Santulli et al., 1999;
Paxton et al., 2017), our review shows that the weight of evidence
indicates either no or only a slight reaction to noise (e.g., Miller
and Cripps, 2013; Dalen and Knutsen, 1987; Pena et al., 2013; Chapman
and Hawkins, 1969; Wardle et al., 2001; Sara et al., 2007; Jorgenson
and Gyselman, 2009; Blaxter et al., 1981; Cott et al., 2012; Boeger et
al., 2006), and that, most commonly, while there may be impacts to fish
as a result of noise from nearby airguns, any effects will be
temporary. For example, investigators reported significant, short-term
declines in commercial fishing catch rate of gadid fishes during and
for up to five days after seismic survey operations, but the catch rate
subsequently returned to normal (Engas
[[Page 29094]]
et al., 1996; Engas and Lokkeborg, 2002). Other studies have reported
similar findings (e.g., Hassel et al., 2004). Skalski et al. (1992)
also found a reduction in catch rates--for rockfish (Sebastes spp.) in
response to controlled airgun exposure--but suggested that the
mechanism underlying the decline was not dispersal but rather decreased
responsiveness to baited hooks associated with an alarm behavioral
response. A companion study showed that alarm and startle responses
were not sustained following the removal of the sound source (Pearson
et al., 1992). Therefore, Skalski et al. (1992) suggested that the
effects on fish abundance may be transitory, primarily occurring during
the sound exposure itself. In some cases, effects on catch rates are
variable within a study, which may be more broadly representative of
temporary displacement of fish in response to airgun noise (i.e., catch
rates may increase in some locations and decrease in others) than any
long-term damage to the fish themselves (Streever et al., 2016).
Sound pressure levels (SPLs) of sufficient strength have been known
to cause injury to fish and fish mortality and, in some studies, fish
auditory systems have been damaged by airgun noise (McCauley et al.,
2003; Popper et al., 2005; Song et al., 2008). However, in most fish
species, hair cells in the ear continuously regenerate and loss of
auditory function likely is restored when damaged cells are replaced
with new cells. Halvorsen et al. (2012) showed that a temporary
threshold shift (TTS) of 4-6 decibel (dB) was recoverable within 24
hours for one species. Impacts would be most severe when the individual
fish is close to the source and when the duration of exposure is long--
both of which are conditions unlikely to occur for surveys that are
necessarily transient in any given location and likely result in brief,
infrequent noise exposure to prey species in any given area. For these
surveys, the sound source is constantly moving, and most fish would
likely avoid the sound source prior to receiving sound of sufficient
intensity to cause physiological or anatomical damage. In addition,
ramp-up may allow certain fish species the opportunity to move further
away from the sound source.
NMFS considered the research referenced by the ENGOs and disagrees
with the assertion that ``[NMFS] irrationally discounts those
impacts,'' as well as with the commenters' interpretation of the
literature. A recent comprehensive review (Carroll et al., 2017) found
that results are mixed as to the effects of airgun noise on the prey of
marine mammals. While some studies suggest a change in prey
distribution and/or a reduction in prey abundance following the use of
seismic airguns, others suggest no effects or even positive effects in
prey abundance. Regarding Paxton et al. (2017), which describes
findings related to the effects of a 2014 seismic survey on a reef off
of North Carolina, while the study did show a 78 percent decrease in
observed nighttime abundance for certain species, it is important to
note that the evening hours during which the decline in fish habitat
use was recorded (via video recording) occurred on the same day that
the seismic survey passed, and no subsequent data is presented to
support an inference that the response was long-lasting. Additionally,
given that the finding is based on video images, the lack of recorded
fish presence does not support a conclusion that the fish actually
moved away from the site or suffered any serious impairment because
fish may remain present yet not be recorded on video. In summary, this
particular study corroborates prior studies demonstrating a startle
response or short-term displacement.
The Carroll et al. (2017) review article concluded that, while
laboratory results provide scientific evidence for high-intensity and
low-frequency sound-induced physical trauma and other negative effects
on some fish and invertebrates, the sound exposure scenarios in some
cases are not realistic to those encountered by marine organisms during
routine seismic operations. The review finds that there has been no
evidence of reduced catch or abundance following seismic activities for
invertebrates, and that there is conflicting evidence for fish with
catch observed to increase, decrease, or remain the same. Further,
where there is evidence for decreased catch rates in response to airgun
noise, these findings provide no information about the underlying
biological cause of catch rate reduction (Carroll et al., 2017).
In summary, the scientific literature demonstrates that impacts of
seismic surveys on marine mammal prey species will likely be limited to
behavioral responses, the majority of prey species will be capable of
moving out of the area during surveys, a rapid return to normal
recruitment, distribution, and behavior for prey species is
anticipated, and, overall, impacts to prey species, if any, will be
minor and temporary. Prey species exposed to sound might move away from
the sound source, experience TTS, experience masking of biologically
relevant sounds, or show no obvious direct effects. Mortality from
decompression injuries is possible in close proximity to a sound, but
only limited data on mortality in response to airgun noise exposure are
available (Hawkins et al., 2014). The most likely impacts for most prey
species in a given survey area would be temporary avoidance of the
area. Surveys using towed airgun arrays move through an area relatively
quickly, limiting exposure to multiple impulsive sounds. In all cases,
sound levels would return to ambient once a survey moves out of the
area or ends and the noise source is shut down and, when exposure to
sound ends, behavioral and/or physiological responses are expected to
end relatively quickly (McCauley et al., 2000b). The duration of fish
avoidance of a given area after survey effort stops is unknown, but a
rapid return to normal recruitment, distribution, and behavior is
anticipated. While the potential for disruption of spawning
aggregations or schools of important prey species can be meaningful on
a local scale, the mobile and temporary nature of most surveys and the
likelihood of temporary avoidance behavior suggest that impacts would
be minor.
NMFS believes that no evidence is presented to contradict our
conclusions regarding likely impacts to marine mammals due to effects
on prey species, i.e., that impacts of the specified activity are not
likely to have more than short-term adverse effects on any prey habitat
or populations of prey species, and that any effects that do occur are
not expected to result in significant or long-term consequences for
individual marine mammals, or to contribute to adverse impacts on their
populations.
Finally, we note that the National Science Foundation (NSF) is
funding a study run by Oregon State University to assess the effects of
L-DEO's survey activities on rockfish, Dungeness crab, and longnose
skate. While the species chosen for this study do not represent
important prey species for Southern Resident killer whales, which were
the primary concern of the ENGOs, the study will provide important
information on the effects of seismic surveys on nearshore species.
Comment 4: The ENGOs commented that in making the negligible impact
determination, NMFS underestimated the potential harm to the relevant
stocks and distinct population segments (DPSs) of humpback whales,
adding that the stock definitions for humpback whales are outdated and
should match the DPSs as defined under the Endangered Species Act. The
ENGOs assert that the takes proposed by NMFS are more than
[[Page 29095]]
negligible for the California/Oregon/Washington stock because the
annual rate of serious injury and mortality (40.2 humpback whales per
year) exceeds the potential biological removal (PBR; 33.4 humpbacks per
year). Additionally, for both humpback and blue whales, the ENGOs
assert that take by Level A harassment in the form of permanent hearing
impairment amounts to serious injury, therefore the negligible impact
determination overly relies on the assumption that there will be no
serious injury or mortality from the seismic survey.
Response: First, NMFS agrees that the alignment of MMPA stocks and
Endangered Species Act (ESA) DPSs of humpback whales is important, and
is actively working on rectifying the differences between stocks and
DPSs. However, this issue is outside the scope of the action considered
here. NMFS disagrees with the ENGOs' assertion that the authorized take
of humpback or blue whales (or any species of marine mammal) by Level A
harassment constitutes serious injury or has any relation to the PBR of
the stock. PBR is defined in the MMPA (16 U.S.C. 1362(20)) as ``the
maximum number of animals, not including natural mortalities, that may
be removed from a marine mammal stock while allowing that stock to
reach or maintain its optimum sustainable population'' and is a measure
to be considered when evaluating the effects of mortality or serious
injury on a marine mammal species or stock. There is no evidence that
permanent threshold shift (PTS) can lead to mortality such that it
should be considered ``serious injury'' or ``removing'' an individual
from a stock. Therefore, it is not appropriate to use the PBR metric to
directly evaluate the effects of Level A harassment (e.g., PTS) on a
stock in the manner suggested by the ENGOs. Given the short duration of
exposure, only low levels of hearing impairment are likely to occur,
and would not affect the fitness of individual marine mammals or
populations.
As noted above, the PBR metric concerns levels of allowable
removals from a population. Therefore, the PBR metric is not directly
related to an assessment of negligible impact for this specified
activity, which does not involve any expected potential for serious
injury or mortality. PBR is not an appropriate metric with which to
evaluate Level B harassment. However, we appropriately do consider
levels of ongoing anthropogenic mortality from other sources, such as
vessel strike, in relation to calculated PBR values as an important
contextual factor in our negligible impact analysis, but a direct
comparison of takes by harassment to the PBR value is not germane.
While it is conceptually possible to link disturbance to potential
fitness impacts to individuals over time (e.g., population consequences
of disturbance), we have no evidence that is the case here and the take
authorized here is not expected to affect the reproduction or
survivorship of any individual marine mammals.
Comment 5: The ENGOs assert that the negligible impact
determination also relies on an expectation that marine mammals would
be likely to move away from the sound source, which contradicts other
statements from the notice of proposed IHA that avoidance is not
assumed to occur because ``the extent to which marine mammals would
move away from the sound source is difficult to quantify and is
therefore not accounted for in the take estimates.'' The commenters go
on to state that animals avoiding the sound source still provokes an
adverse behavioral reaction which displaces the animal from preferred
habitat and potentially toward predators or shore with a risk of
stranding.
Response: NMFS does not rely on avoidance behaviors to make its
negligible impact determination. NMFS agrees that avoidance of
preferred habitat may temporarily limit optimal feeding or other
biologically important behaviors. NMFS does not adjust take estimates
based on the assumption that marine mammals would avoid the area, as
the avoidance itself may constitute behavioral harassment. However,
avoiding the sound source prevents the animal from exposure to the
highest source levels, reducing the likelihood of temporary (Level B
harassment) or permanent hearing impairment (Level A harassment), and
reducing the intensity and/or duration of the harassment event. The
avoidance is expected to be temporary, and animals are likely to return
to the area after the survey vessel has passed through. In
consideration of the likelihood of animals to independently avoid the
sound source, and the mitigation requirements to shut down the airgun
array if animals do approach within a certain distance, NMFS finds that
the level of take expected to result from the survey is unlikely to
have any impact on fitness or reproduction of individual animals, let
alone populations.
Comment 6: Citing studies suggesting that blue whales are
especially sensitive to high intensity anthropogenic noise, such as
mid-frequency sonar (e.g., Goldbogen et al., 2013), the ENGOs suggest
that NMFS' consideration of the impact of the proposed activities on
blue whales may underestimate the adverse impacts on the stock.
Response: As discussed in the notice of proposed IHA, Goldbogen et
al. (2013) found blue whales feeding on highly concentrated prey in
shallow depths were less likely to respond and cease foraging than
whales feeding on deep, dispersed prey when exposed to simulated sonar
sources, suggesting that the benefits of feeding for blue whales
foraging on high-density prey may outweigh perceived harm from the
acoustic stimulus, such as the seismic survey. Southall et al. (2019b)
observed that after exposure to simulated and operational mid-frequency
active sonar, more than 50 percent of blue whales in deep-diving states
responded to the sonar, while no behavioral response was observed in
shallow-feeding blue whales. Southall et al. (2019b) noted that the
behavioral responses they observed were generally brief, of low to
moderate severity, and highly dependent on exposure context (behavioral
state, source-to-whale horizontal range, and prey availability). The
proposed survey area does not represent a major feeding area for blue
whales and any disruption of feeding is likely to be short-term and of
low to sometimes moderate severity, with no anticipated effect on
reproduction or survival for individual whales or the population as a
whole.
Comment 7: Deep Green Wilderness and the ENGOs noted that North
Pacific right whales have been documented within the survey area, and
recommended NMFS consider the potential effects of the survey on the
species. Deep Green Wilderness referred to sightings of a North Pacific
right whale at Swiftsure Bank in 2013, and the ENGOs noted an account
of a sighting of a North Pacific right whale off northern Vancouver
Island in May 2020.
Response: We thank the organizations for providing information on
recent observations of North Pacific right whales in the survey area.
NMFS shares the commenters' concern regarding the status of this
endangered species. Although sightings have been reported in the survey
area, the rate of sightings is less than one per year and NMFS has
determined the likelihood of the proposed 37-day survey encountering a
North Pacific right whale is discountable. However, in the very
unlikely event a North Pacific right whale is detected during the
survey, at any distance, L-DEO must immediately shut down the airgun
array to prevent exposure to potentially injurious sound levels and to
minimize the intensity and
[[Page 29096]]
duration of any sound exposure, and must immediately report the
observation to NMFS and Canada's DFO to further inform research on the
distribution of the species.
Comment 8: The ENGOs challenge NMFS' preliminary finding that the
proposed take numbers are of no more than small numbers of marine
mammals. The ENGOs reference a court decision that they assert supports
a lower ``small numbers'' threshold, and highlight certain species for
which the commenters deem the take to be too high.
Response: The reference to a supposed take limit of 12 percent for
small numbers comes from a 2003 district court opinion (Natural
Resources Defense Council v. Evans, 279 F. Supp. 2d 1129 (N.D. Cal.
2003)). However, given the particular administrative record and
circumstances in that case, including the fact that our small numbers
finding for the challenged incidental take rule was based on an invalid
regulatory definition of small numbers, we view the district court's
opinion regarding 12 percent as dicta. Moreover, since that time the
Ninth Circuit Court of Appeals has upheld a small numbers finding that
was not based on a quantitative calculation. Center for Biological
Diversity v. Salazar, 695 F.3d 893 (9th Cir. 2012). To maintain an
interpretation of small numbers as a proportion of a species or stock
that does not conflate with negligible impact, we use the following
framework. A plain reading of ``small'' implies as corollary that there
also could be ``medium'' or ``large'' numbers of animals from the
species or stock taken. We therefore use a simple approach that
establishes equal bins corresponding to small, medium, and large
proportions of the population abundance.
NMFS's practice for making small numbers determinations is to
compare the number of individuals estimated and authorized to be taken
(often using estimates of total instances of take, without regard to
whether individuals are exposed more than once) against the best
available abundance estimate for that species or stock. We note,
however, that although NMFS's implementing regulations require
applications for incidental take to include an estimate of the marine
mammals to be taken, there is nothing in paragraphs (A) or (D) of
section 101(a)(5) that requires NMFS to quantify or estimate numbers of
marine mammals to be taken for purposes of evaluating whether the
number is small. (See CBD v. Salazar.) While it can be challenging to
predict the numbers of individual marine mammals that will be taken by
an activity (again, many models calculate instances of take and are
unable to account for repeated exposures of individuals), in some cases
we are able to generate a reasonable estimate utilizing a combination
of quantitative tools and qualitative information. When it is possible
to predict with relative confidence the number of individual marine
mammals of each species or stock that are likely to be taken, the small
numbers determination should be based directly upon whether or not
these estimates exceed one third of the stock abundance. In other
words, consistent with past practice, when the estimated number of
individual animals taken (which may or may not be assumed as equal to
the total number of takes, depending on the available information) is
up to, but not greater than, one third of the species or stock
abundance, NMFS will determine that the numbers of marine mammals taken
of a species or stock are small.
Finally, regarding the species highlighted by the ENGOs with
proposed take above 20 percent of the stock (Pacific white-sided
dolphin, Risso's dolphin, pygmy and dwarf sperm whale, Dall's porpoise,
harbor porpoise, northern fur seal and harbor seal), the revised take
estimates for all of the aforementioned stocks aside from the
California/Oregon/Washington stock of Dall's porpoise and Northern
Oregon/Washington Coast stock of harbor porpoise represent under one-
third of the stock. The analysis of these two stocks is discussed
further in the Small Numbers section of this notice.
Comment 9: The ENGOs further object to NMFS' small numbers
determination for the Southern Resident killer whale, for which NMFS
proposed to authorize take of more than 57 percent of the stock.
Regarding the Southern Resident killer whale take estimate, the ENGOs
disagree with NMFS' assumption that the number of individual Southern
Resident killer whales taken by Level B harassment will be fewer than
the total estimated instances of take due to the historical pattern of
Southern Resident killer whales occupying the inland waters of the
Salish Sea during the summer months. Additionally, because they travel
in pods, the commenters assert that there is risk of exposure of an
entire pod to airgun blasting, and state that they are unclear whether
such aggregation has been considered.
Response: The ENGO's objection to NMFS' small numbers threshold was
addressed in the previous response, but we also note here that using
the revised survey tracklines, the authorized take of Southern Resident
killer whales represents only 13.7 percent of the stock, which falls
under NMFS' threshold for small numbers, even if all takes represent
different individuals taken by Level B harassment. The authorized take
is less than the size of any pod of Southern Residents (J, K, or L
pods), and is more likely to represent a single matriline (typically
two to nine killer whales; Weiss et al., 2020) exposed to the survey on
one or two days of the survey. NMFS agrees that the seasonal
distribution of Southern Resident killer whales in recent years has
deviated from the historical pattern of residency within the Salish Sea
(e.g., Shields et al., 2018), but note that our discussion of the
distribution of Southern Resident killer whales was in the context of
the U.S. Navy density models used to estimate take, which were created
with the assumption that the entire population was either within the
Salish Sea or outside the Salish Sea on the outer coast at any given
time (U.S. Navy 2019). Southern Resident killer whales may be
encountered during the survey along the coast, but the revised
tracklines are expected to reduce the likelihood of whole pods being
exposed to sound from the seismic survey by avoiding surveying in areas
of expected high Southern Resident killer whale occurrence.
Additionally, L-DEO is required to shut down the airgun array if killer
whales (of any ecotype) are observed at any distance. Killer whales are
highly visible animals, especially when traveling as large pods as the
ENGOs suggest, and we expect PSOs will be able to detect killer whales
at sufficient distances to implement shutdown procedures to avoid
exposing large pods of killer whales to sounds from the survey.
Comment 10: The ENGOs commented that NMFS must include estimated
takes off Canada in making the small numbers determination, adding that
since the take prohibition applies outside U.S. waters, the Service
must make a small numbers determination that analyzes all of the
estimated take. The commenters state that, accordingly, NMFS must
demonstrate compliance with these standards and may not issue the
authorization without fully analyzing and authorizing all take
contemplated under this action. The commenters also state that it is
unclear in the small numbers determination whether the takes in
Canadian waters have been taken into consideration. The ENGOs also
expressed concern that the small numbers determination was based on 1
year of activities and did not consider
[[Page 29097]]
the potential renewal of the authorization.
Response: NMFS has not authorized any take of marine mammals within
the territorial waters of Canada. An estimate of take that may occur
within Canadian territorial waters is presented in Table 11, and the
take has been considered in our negligible impact determination as part
of the larger implications of the survey on the marine mammal
populations and habitat in the survey area. However, our small numbers
analysis applies only to the take we have authorized. NMFS has made the
necessary small numbers and negligible impact determinations for this
authorization.
The ENGOs appear to misunderstand the context in which a potential
renewal IHA could be issued for this activity, as well as the
requirements for issuing a renewal IHA. Although renewal IHAs in
general may be issued in appropriate circumstances for up to another
year of identical or nearly identical activities as were covered by the
initial IHA, this context is not relevant to the proposed seismic
survey. L-DEO would not conduct the survey as planned and then
duplicate the survey activities in a subsequent year. Regardless, NMFS
would not grant a renewal IHA in those circumstances. However, if the
planned survey were unexpectedly delayed for another year, NMFS could
consider a request for issuance of a renewal IHA. In order to do so,
NMFS would need to review all relevant information, including the
status of the affected species or stocks and any other pertinent
information, such as information relevant to the small numbers
determination. In short, potential consideration of a renewal in this
context would necessarily be associated with the same activity
associated with this IHA, in the event that it is not conducted during
the period of effectiveness for this IHA, and would entail a review of
all relevant information to ensure that the findings NMFS has made in
support of issuance of this initial IHA remain valid.
Comment 11: The ENGOs recommended NMFS analyze the effects of L-
DEO's use of a multi-beam echosounder (MBES) associated with the
survey, noting that the proposed equipment (the Kongsberg Simrad E122)
is similar to another Kongsberg system that was closely associated with
a 2008 mass stranding of melon-headed whales in Madagascar. The ENGOs
recommended NMFS apply its take threshold for continuous noise sources
(120 dB) rather than its threshold for intermittent sources (160 dB) to
the proposed system and revise its take estimates accordingly. Further,
NMFS should not assume, for purposes of making its negligible impact
determinations, that the severity of impacts from an airgun array
operating concurrently with such an echosounder system would be
equivalent to that of an airgun array operating alone.
Response: Although it is correct that an investigation of the
stranding event referenced by the ENGOs indicated that use of a high-
frequency mapping system (12-kilohertz (kHz) MBES) was the most
plausible and likely initial behavioral trigger of the event (with the
caveat that there was no unequivocal and easily identifiable single
cause), the panel also noted several site- and situation-specific
secondary factors that may have contributed to the avoidance responses
that led to the eventual entrapment and mortality of the whales
(Southall et al., 2013). Specifically, regarding survey patterns prior
to the event and in relation to bathymetry, the vessel transited in a
north-south direction on the shelf break parallel to the shore,
ensonifying deep-water habitat prior to operating intermittently in a
concentrated area offshore from the stranding site. This may have
trapped the animals between the sound source and the shore, thus
driving them towards the lagoon system. Shoreward-directed surface
currents and elevated chlorophyll levels in the area preceding the
event may also have played a role. The risk of similar events recurring
is expected to be very low, given the extensive use of active acoustic
systems used for scientific and navigational purposes worldwide on a
daily basis and the lack of direct evidence of such responses
previously reported. The only report of a stranding that may be
associated with this type of sound source is the one reported in
Madagascar.
NMFS disagrees with the recommendation that the 120 dB threshold
should be applied to estimate takes incidental to use of the MBES.
Sound sources can be divided into broad categories based on various
criteria or for various purposes. As discussed by Richardson et al.
(1995), source characteristics include strength of signal amplitude,
distribution of sound frequency and, importantly in context of these
thresholds, variability over time. With regard to temporal properties,
sounds are generally considered to be either continuous or transient
(i.e., intermittent). Continuous sounds, which are produced by the
industrial noise sources for which the 120-dB behavioral harassment
threshold was selected, are simply those whose sound pressure level
remains above ambient sound during the observation period (ANSI, 2005).
Intermittent sounds are defined as sounds with interrupted levels of
low or no sound (NIOSH, 1998). Simply put, a continuous noise source
produces a signal that continues over time, while an intermittent
source produces signals of relatively short duration having an obvious
start and end with predictable patterns of bursts of sound and silent
periods (i.e., duty cycle) (Richardson and Malme, 1993). It is this
fundamental temporal distinction that is most important for
categorizing sound types in terms of their potential to cause a
behavioral response. For example, Gomez et al. (2016) found a
significant relationship between source type and marine mammal
behavioral response when sources were split into continuous (e.g.,
shipping, icebreaking, drilling) versus intermittent (e.g., sonar,
seismic, explosives) types. In addition, there have been various
studies noting differences in responses to intermittent and continuous
sound sources for other species (e.g., Neo et al., 2014; Radford et
al., 2016; Nichols et al., 2015).
Sound sources may also be categorized based on their potential to
cause physical damage to auditory structures and/or result in threshold
shifts. In contrast to the temporal distinction discussed above, the
most important factor for understanding the differing potential for
these outcomes across source types is simply whether the sound is
impulsive or not. Impulsive sounds, such as those produced by airguns,
are defined as sounds which are typically transient, brief (<1 second
(sec)), broadband, and consist of a high peak pressure with rapid rise
time and rapid decay (ANSI, 1986; NIOSH, 1998). These sounds are
generally considered to have greater potential to cause auditory injury
and/or result in threshold shifts. Non-impulsive sounds can be
broadband, narrowband or tonal, brief or prolonged, continuous or
intermittent, and typically do not have the high peak pressure with
rapid rise/decay time that impulsive sounds do (ANSI, 1995; NIOSH,
1998). Because the selection of the 160-dB behavioral threshold was
focused largely on airgun signals, it has historically been commonly
referred to as the ``impulse noise'' threshold (including by NMFS).
However, this longstanding confusion in terminology--i.e., the
erroneous impulsive/continuous dichotomy--presents a narrow view of the
sound sources to which the thresholds apply, and inappropriately
implies a limitation in scope of applicability for the 160-dB
behavioral threshold in particular.
[[Page 29098]]
An impulsive sound is by definition intermittent; however, not all
intermittent sounds are impulsive. Many sound sources for which it is
generally appropriate to consider the authorization of incidental take
are in fact either impulsive (and intermittent) (e.g., impact pile
driving) or continuous (and non-impulsive) (e.g., vibratory pile
driving). However, scientific sonars (such as MBESs) present a less
common case where the sound produced is considered intermittent but
non-impulsive. We note also the commenters' assertion that the system
produces ``virtually continuous noise output'' in support of their
recommendation to apply the continuous noise threshold to evaluation of
this source. In context of marine mammal hearing, this would mean that
the interval between signals would not be discernible to the animal,
rendering them effectively continuous. However, echosounder signals are
emitted in a similar fashion as odontocete echolocation click trains.
Research indicates that marine mammals, in general, have extremely fine
auditory temporal resolution and can detect each signal separately
(e.g., Au et al., 1988; Dolphin et al., 1995; Supin and Popov, 1995;
Mooney et al., 2009), especially for species with echolocation
capabilities. Therefore, it is highly unlikely that marine mammals
would perceive echosounder signals as being continuous.
Given the existing paradigm--dichotomous thresholds appropriate for
generic use in evaluating the potential for behavioral harassment
resulting from exposure to continuous or intermittent sound sources--
the ENGOs do not adequately explain why potential harassment from an
intermittent sound source should be evaluated using a threshold
developed for use with continuous sound sources. Therefore, we have not
reevaluated L-DEO's use of the MBES using the 120 dB continuous noise
threshold.
As discussed in the notice of proposed IHA, due to the lower source
level of the MBES relative to the R/V Langseth's airgun array, sounds
from the MBES are expected to be effectively subsumed by the sounds
from the airgun array when both sources are operational. Thus, NMFS has
determined that any marine mammal potentially exposed to sounds from
the MBES would already have been exposed to sounds from the airgun
array, which are expected to propagate further in the water, when both
sources are operational. NMFS has determined that, given the movement
and speed of the vessel and the intermittent and narrow downward-
directed nature of the sounds emitted by the MBES (each ping emitted by
the MBES consists of eight (in water >1,000 m deep) or four (<1,000 m)
successive fan-shaped transmissions, each ensonifying a sector that
extends 1[deg] fore-aft), the MBES would result in no more than one or
two brief ping exposures to any individual marine mammal, if any
exposure were to occur. The ENGOs do not offer any evidence in support
of their contention that potentially greater impacts than we have
considered should be assumed likely in relation to use of this source.
Comment 12: The ENGOs comment that NMFS has failed to implement
``means of effecting the least practicable impact'' on marine mammals
and assert that NMFS relies on mitigation measures that are known to be
ineffective (e.g., real-time detection-based measures).
Response: Under section 101(a)(5)(D) of the MMPA, NMFS must set
forth the permissible methods of taking by harassment pursuant to such
activity, and other means of effecting the least practicable impact on
such species or stock and its habitat, paying particular attention to
rookeries, mating grounds, and areas of similar significance, and on
the availability of such species or stock for taking for subsistence
uses (hereinafter referred to as least practicable adverse impact).
NMFS does not have a regulatory definition for least practicable
adverse impact.
NMFS disagrees with the assertion that we have failed to meet the
least practicable adverse impact standard in this case. NMFS considered
all recommended mitigation in the context of both the reduction of
impacts on marine mammal species and stocks and their habitat and the
practicability of such mitigation in reaching the required set of
measures that we believe satisfy the least practicable adverse impact
standard.
NMFS' evaluation of potential mitigation measures includes
consideration of two primary factors:
(1) The manner in which, and the degree to which, implementation of
the potential measure(s) is expected to reduce adverse impacts to
marine mammal species or stocks, their habitat, and their availability
for subsistence uses (where relevant). This analysis considers such
things as the nature of the potential adverse impact (such as
likelihood, scope, and range), the likelihood that the measure will be
effective if implemented, and the likelihood of successful
implementation.
(2) The practicability of the measures for applicant
implementation. Practicability of implementation may consider such
things as cost, impact on activities, personnel safety, and
practicality of implementation.
While the language of the least practicable adverse impact standard
calls for minimizing impacts to affected species or stocks and their
habitat, NMFS recognizes that the reduction of impacts to those species
or stocks accrues through the application of mitigation measures that
limit impacts to individual animals. Accordingly, NMFS' analysis
focuses on measures that are designed to avoid or minimize impacts on
individual marine mammals that are likely to increase the probability
or severity of population-level effects.
While direct evidence of impacts to species or stocks from a
specified activity is rarely available, and additional study is still
needed to understand how specific disturbance events affect the fitness
of individuals of certain species, there have been improvements in
understanding the process by which disturbance effects are translated
to the population. With recent scientific advancements (both marine
mammal energetic research and the development of energetic frameworks),
the relative likelihood or degree of impacts on species or stocks may
often be inferred given a detailed understanding of the activity, the
environment, and the affected species or stocks. This same information
is used in the development of mitigation measures and helps us
understand how mitigation measures contribute to lessening effects (or
the risk thereof) to species or stocks. NMFS also acknowledges that
there is always the potential that new information, or a new
recommendation that had not previously been considered, becomes
available and necessitates re-evaluation of mitigation measures to see
if further reductions of population impacts are possible and
practicable.
In the evaluation of specific measures, the details of the
specified activity will necessarily inform each of the two primary
factors discussed above (expected reduction of impacts and
practicability) and are carefully considered to determine the types of
mitigation that are appropriate under the least practicable adverse
impact standard. Analysis of how a potential mitigation measure may
reduce adverse impacts on a marine mammal stock or species and
practicability of implementation are not issues that can be
meaningfully evaluated through a yes/no lens. The manner in which, and
the degree to which, implementation of a measure is expected to reduce
impacts, as well as its practicability, can
[[Page 29099]]
vary widely. For example, a time-area restriction could be of very high
value for reducing the potential for, or severity of, population-level
impacts (e.g., avoiding disturbance of feeding females in an area of
established biological importance) or it could be of lower value (e.g.,
decreased disturbance in an area of high productivity but of less
firmly established biological importance). Regarding practicability, a
measure might involve restrictions in an area or time that impede the
operator's ability to acquire necessary data (higher impact), or it
could mean incremental delays that increase operational costs but still
allow the activity to be conducted (lower impact). A responsible
evaluation of ``least practicable adverse impact'' will consider the
factors along these realistic scales. Expected effects of the activity
and of the mitigation as well as status of the stock all weigh into
these considerations. Accordingly, the greater the likelihood that a
measure will contribute to reducing the probability or severity of
adverse impacts to the species or stock or their habitat, the greater
the weight that measure is given when considered in combination with
practicability to determine the appropriateness of the mitigation
measure, and vice versa. Consideration of these factors is discussed in
greater detail below.
1. Reduction of Adverse Impacts to Marine Mammal Species or Stocks and
Their Habitat
The emphasis given to a measure's ability to reduce the impacts on
a species or stock considers the degree, likelihood, and context of the
anticipated reduction of impacts to individuals (and how many
individuals) as well as the status of the species or stock.
The ultimate impact on any individual from a disturbance event
(which informs the likelihood of adverse species- or stock-level
effects) is dependent on the circumstances and associated contextual
factors, such as duration of exposure to stressors. Though any proposed
mitigation needs to be evaluated in the context of the specific
activity and the species or stocks affected, measures with the
following types of effects have greater value in reducing the
likelihood or severity of adverse species- or stock-level impacts:
Avoiding or minimizing injury or mortality; limiting interruption of
known feeding, breeding, mother/young, or resting behaviors; minimizing
the abandonment of important habitat (temporally and spatially);
minimizing the number of individuals subjected to these types of
disruptions; and limiting degradation of habitat. Mitigating these
types of effects is intended to reduce the likelihood that the activity
will result in energetic or other types of impacts that are more likely
to result in reduced reproductive success or survivorship. It is also
important to consider the degree of impacts that are expected in the
absence of mitigation in order to assess the added value of any
potential measures. Finally, because the least practicable adverse
impact standard gives NMFS discretion to weigh a variety of factors
when determining appropriate mitigation measures and because the focus
of the standard is on reducing impacts at the species or stock level,
the least practicable adverse impact standard does not compel
mitigation for every kind of take, or every individual taken, if that
mitigation is unlikely to meaningfully contribute to the reduction of
adverse impacts on the species or stock and its habitat, even when
practicable for implementation by the applicant.
The status of the species or stock is also relevant in evaluating
the appropriateness of potential mitigation measures in the context of
least practicable adverse impact. The following are examples of factors
that may (either alone, or in combination) result in greater emphasis
on the importance of a mitigation measure in reducing impacts on a
species or stock: The stock is known to be decreasing or status is
unknown, but believed to be declining; the known annual mortality (from
any source) is approaching or exceeding the PBR level; the affected
species or stock is a small, resident population; or the stock is
involved in a UME or has other known vulnerabilities, such as
recovering from an oil spill.
Habitat mitigation, particularly as it relates to rookeries, mating
grounds, and areas of similar significance, is also relevant to
achieving the standard and can include measures such as reducing
impacts of the activity on known prey utilized in the activity area or
reducing impacts on physical habitat. As with species- or stock-related
mitigation, the emphasis given to a measure's ability to reduce impacts
on a species or stock's habitat considers the degree, likelihood, and
context of the anticipated reduction of impacts to habitat. Because
habitat value is informed by marine mammal presence and use, in some
cases there may be overlap in measures for the species or stock and for
use of habitat.
NMFS considers available information indicating the likelihood of
any measure to accomplish its objective. If evidence shows that a
measure has not typically been effective nor successful, then either
that measure should be modified or the potential value of the measure
to reduce effects should be lowered.
2. Practicability
Factors considered may include those costs, impact on activities,
personnel safety, and practicality of implementation.
In carrying out the MMPA's mandate for this action, NMFS applies
the previously described context-specific balance between the manner in
which and the degree to which measures are expected to reduce impacts
to the affected species or stocks and their habitat and practicability
for operators. The effects of concern (i.e., those with the potential
to adversely impact species or stocks and their habitat), addressed
previously in the Potential Effects of the Specified Activity on Marine
Mammals and Their Habitat section of the notice of proposed IHA,
include auditory injury, severe behavioral reactions, disruptions of
critical behaviors, and to a lesser degree, masking and impacts on
acoustic habitat. Here, we focus on measures with proven or reasonably
presumed ability to avoid or reduce the intensity of acute exposures
that have potential to result in these anticipated effects with an
understanding of the drawbacks or costs of these requirements, as well
as time-area restrictions that would avoid or reduce both acute and
chronic impacts. To the extent of the information available to NMFS, we
considered practicability concerns, as well as potential undesired
consequences of the measures, e.g., extended periods using the acoustic
source due to the need to reshoot lines. NMFS also recognizes that
instantaneous protocols, such as shutdown requirements, are not capable
of avoiding all acute effects, and are not suitable for avoiding many
cumulative or chronic effects and do not provide targeted protection in
areas of greatest importance for marine mammals. Therefore, in addition
to a basic suite of seismic mitigation protocols, we also consider
measures that may or may not be appropriate for other activities (e.g.,
survey plan modifications specific to the action discussed herein), but
that are warranted here given the potential for impacts to a stock of
particular concern (i.e., Southern Resident killer whales) (see
Negligible Impact Analysis and Determination), and the information we
have regarding habitat for certain species.
We appreciate the ENGOs suggestions for additional mitigation and
monitoring
[[Page 29100]]
requirements. However, we note that many of the recommendations require
a scale of effort that is not commensurate to the scale of either the
underlying activities or the anticipated impacts of the activities on
marine mammals covered by this authorization. In other words, many of
the recommended measures would necessitate complex and expensive survey
designs and methods that are not reasonable in the context of an
activity that consists of one mobile source moving across a large area
and that will last for only 37 days. As described in the Mitigation
Measures Considered but Eliminated section of this notice, out of
concern for the status of Southern Resident killer whales and proposed
critical habitat, NMFS considered implementing a closure area and
prohibiting L-DEO from conducting survey operations between the 200-m
isobath and the coastline. However, as the main goal of L-DEO's survey
is to examine the geologic features of the Cascadia subduction zone
along the coastal shelf, NMFS determined that this exclusion would not
be practicable. NMFS did ultimately incorporate mitigation measures
that are specific to this action and beyond that which is typically
required for L-DEO's surveys. Specifically, we have required L-DEO to
revise their proposed tracklines to avoid surveying in waters less than
100 m deep in areas with highest estimated Southern Resident killer
whale occurrence. We have determined this measure, which will
significantly reduce impacts to Southern Resident killer whales while
allowing L-DEO to complete its survey objectives, to be practicable.
Additionally, L-DEO must use a second vessel traveling ahead of the R/V
Langseth with additional PSOs to increase the likelihood of detecting
Southern Resident killer whales and, therefore, allowing for greater
efficacy in implementing shutdown procedures to minimize impacts to
animals that may be in the area. Regardless of whether other monitoring
plans suggested by the ENGOs would also suffice, NMFS has determined
that the mitigation and monitoring required as part of this
authorization meets the MMPA requirement for least practicable adverse
impact.
Comment 13: The ENGOs suggested NMFS should work with L-DEO and
explore ways to conduct the survey without ensonifying designated and
proposed Southern Resident killer whale critical habitat, or at
minimum, prohibit ramp-up in the proposed and designated critical
habitat unless the location of all three pods of Southern Resident
killer whales is known to be within the Salish Sea or in an area not
impacted by survey activity on each day of the survey.
Response: As discussed above, NMFS considered prohibiting L-DEO
from operating within the proposed critical habitat for Southern
Resident killer whales, but determined that the exclusion was not
practicable, as it would prevent L-DEO from completing their survey
objectives. NMFS has worked with L-DEO to revise the survey tracklines
to avoid ensonifying waters less than 100 m deep above the Level B
harassment threshold, between Tillamook Head, Oregon and Barkley Sound,
British Columbia. As stated above, this area contains the highest
estimated density of Southern Resident killer whales. NMFS has not
required L-DEO to confirm the location of Southern Resident killer
whales before beginning survey activities each day as the location of
all three pods is often unknown and waiting for confirmation would not
allow L-DEO to complete their research objectives. L-DEO is required to
contact several entities (including NMFS, Canada's DFO, Orca Network,
and the Whale Museum) on each day of the survey to obtain any recent
reports of Southern Resident killer whales in the survey area.
Comment 14: The ENGOs suggested NMFS should consider closures or
limits on survey activity in proposed humpback whale critical habitat
and biologically important areas for blue whales.
Response: The revised tracklines mentioned above, while primarily
intended to avoid areas of highest Southern Resident killer whale
occurrence, also reduce survey tracklines in recently finalized
humpback whale critical habitat (86 FR 21082; April 21, 2021) and BIAs
for humpback whales and other marine mammals (we note that no BIAs for
blue whales have been identified in the survey area). Eliminating all
tracklines in humpback whale critical habitat would prevent L-DEO from
completing their research objectives, as the proposed critical habitat
occupies most of the continental shelf area off of the west coast of
the U.S., the key area for L-DEO's research. Additionally, the ENGOs do
not provide any substantive reasoning for why prohibiting L-DEO from
operating within humpback whale critical habitat or BIAs is warranted.
As discussed in the Negligible Impact Analysis and Determination
section of this notice, L-DEO's activity is not expected to have a
lasting physical impact on humpback whale critical habitat, prey within
it, or overall humpback whale fitness.
Comment 15: In addition to vessel-based passive acoustic monitoring
(PAM), the ENGOs suggested NMFS should require the use of existing
moored passive acoustic monitoring systems and installation of
temporary hydrophones or sonabuoys in the survey area to monitor marine
mammal presence.
Response: NMFS appreciates the suggestions regarding increasing
acoustic monitoring. However, the existing network of acoustic
recorders along the Washington coast is comprised of archival
recorders, which are not monitored in real-time. While the deployment
of temporary hydrophones and sonabuoys in the survey area may aid in
detection and monitoring of marine mammals, NMFS does not expect that
any additional protection would outweigh the cost and practicability
concerns associated with additional personnel required to monitor the
systems and relay detections to the research vessel. The use of on-
board PAM will adequately alert L-DEO of vocalizing marine mammals in
the immediate vicinity of the survey activity.
Comment 16: The ENGOs recommended NMFS should require the use of a
support vessel traveling ahead of the R/V Langseth in proposed critical
habitat for humpback whales and biologically important areas (BIAs) for
other cetaceans.
Response: The support vessel referenced by the ENGOs is required to
travel approximately 5 km ahead of the R/V Langseth while surveying in
waters 200 m or less between Tillamook Head, Oregon and Barkley Sound,
British Columbia (see Mitigation section of this notice). This area
encompasses much of the critical habitat for humpback whales and
biologically important areas for other species (e.g., gray whale BIA
for migration). The area of the humpback whale critical habitat
expected to be surveyed on a given day is only a small portion of the
overall critical habitat along the coast. Any impacts to marine mammals
in this area are expected to be minor and temporary, and any additional
protection that may be provided by requiring L-DEO to use the support
vessel outside of the 200-m isobath is not warranted in the context of
the expected effects and practicability concerns.
Comment 17: The ENGOs suggested NMFS should prohibit survey
activity in low-visibility conditions.
Response: NMFS disagrees that survey activity should be prohibited
in low-visibility conditions. Any requirement to cease operations
during low visibility conditions, including at
[[Page 29101]]
night, would not only be impracticable, it would also likely result in
greater impacts to marine mammals, as such a measure would require
operations to continue for significantly more time, to make up for lost
operations during low-visibility times. Ramp-up of the acoustic source,
when necessary, may occur at times of poor visibility (including
nighttime), assuming that a pre-clearance period has been observed. If
the pre-clearance period occurs at nighttime, the pre-clearance watch
would be conducted only by the acoustic observer.
Comment 18: The ENGOs suggested NMFS should consider whether aerial
observations would have less impact (than the support vessel).
Response: Similar to the suggestion of deploying additional PAM
systems above, NMFS has determined it is not practicable to require L-
DEO to use aerial monitoring systems. NMFS does not expect that any
additional protection would outweigh the cost and practicability of
additional personnel required to monitor the systems and relay
detections to the research vessel.
Comment 19: The ENGOs suggested the 1,500-meter exclusion zone,
which is required for beaked whales, should apply for other marine
mammal species that they suggest are particularly sensitive -- such as
harbor porpoises, Steller sea lions, baleen whales (except gray whales)
and Southern Resident killer whales. The commenters suggest that the
presence of Southern Residents should trigger a shut-down whenever they
are detected, regardless of distance.
Response: NMFS disagrees that a larger standard exclusion zone is
warranted for the species and groups suggested by the ENGOs. The
standard exclusion zone for all marine mammals included in the IHA is
500 m, with larger exclusion zones or shutdown requirements for certain
species and/or scenarios. NMFS' intent in prescribing a standard
exclusion zone distance is to (1) encompass zones for most species
within which auditory injury could occur on the basis of instantaneous
exposure; (2) provide additional protection from the potential for more
severe behavioral reactions (e.g., panic, antipredator response) for
marine mammals at relatively close range to the acoustic source; (3)
provide consistency and ease of implementation for protected species
observers (PSOs), who need to monitor and implement the exclusion zone;
and (4) define a distance within which detection probabilities are
reasonably high for most species under typical conditions. The use of
500 m as the zone is not based directly on any quantitative
understanding of the range at which auditory injury would be entirely
precluded or any range specifically related to disruption of behavioral
patterns. Rather, NMFS believes it is based on a reasonable combination
of factors. In summary, a practicable criterion such as this has the
advantage of familiarity and simplicity while still providing in most
cases a zone larger than relevant auditory injury zones, given
realistic movement of source and receiver. Increased shutdowns, without
a firm idea of the outcome the measure seeks to avoid, simply displace
survey activity in time and increase the total duration of acoustic
influence as well as total sound energy in the water, which NMFS seeks
to avoid. In keeping with the four broad goals outlined above, and in
context of the information given here, the standard 500-m exclusion
zone is appropriate. The ENGOs do not provide any substantive reasoning
for a larger zone.
The proposed IHA included the requirement to shut down the airgun
array if killer whales (of any ecotype) are visually or acoustically
detected at any distance and NMFS has retained this requirement in the
final authorization.
Comment 20: The ENGOs suggested NMFS should require L-DEO to use
the lowest practicable source level for airgun usage.
Response: L-DEO has selected the equipment necessary to achieve
their research objectives. We have evaluated the specified activity as
defined by the applicant, including changes agreed-upon with NMFS in
order to provide additional protection for Southern Resident killer
whales, and made the necessary findings to authorize taking of marine
mammals incidental to L-DEO's survey activities. We also note that an
expert panel was convened by the Bureau of Ocean Energy Management to
determine whether it would be feasible to develop standards to
determine a lowest practicable source level. The panel determined that
it would not be reasonable or practicable to develop such metrics (see
Appendix L in BOEM, 2017).
Comment 21: The ENGOs suggested NMFS should require in situ sound
source verification to determine accurate exclusion zones. Similarly,
the Commission recommended NMFS require L-DEO analyze the data recorded
on the OBSs and OBNs to determine the extents of the Level B harassment
zones in shallow-, intermediate-, and deep-water depths and specify how
the in-situ zones compare to the Level B harassment zones specified in
the final authorization.
Response: As stated above, the exclusion zones are not necessarily
based on specific acoustic parameters, thus sound source verification
is not necessary in the context of exclusion zones. Regarding the
Commission's recommendation to conduct analysis of OBS data, L-DEO has
not previously undertaken the type of analysis suggested by the
Commission, and indicated to NMFS that it does not have the expertise
or capability to do so at this time. In addition, we note that the
Commission's recommendation is vague; detailed direction would be
needed from the Commission on how to accomplish the recommended effort.
This would need to include agreement on the analytical approach in
order to meet expectations and to ensure acceptance of results. The
Commission's recommendation does not acknowledge the time it would take
to perform the analysis or the level of effort and cost that would be
involved, e.g., experts needed to obtain and review data, performing
detailed comparative analysis, preparation of a report. Based on these
concerns, NMFS believes that the recommendation is not practicable.
Also, implementation of this recommendation would not provide any
additional conservation value (e.g., improvement in mitigation
effectiveness) for the proposed survey. The analysis would be
retrospective and could be used to help inform analysis of future
surveys in the same area. NSF is considering funding a survey of the
Queen Charlotte Fault, north of the planned survey area for this
action, but the survey would be completed before the acoustic data from
this survey suggested by the Commission could be analyzed. NMFS is not
aware of any other NSF-proposed seismic surveys on the R/V Langseth for
this region in the foreseeable future that could incorporate the in
situ data, if analyzed.
Comment 22: The ENGOs suggested NMFS should prohibit the use of the
Kongsberg Simrad 122 MBES in shallow water because the system's lower
frequencies were designed for use in deeper water.
Response: The ENGOs provide no justification for prohibiting the
use of the MBES in shallow water aside from describing its
characteristics. As discussed in previous comment responses, NMFS has
determined the MBES is not likely to result in take of marine mammals
and has no reason to believe that the use of the Kongsberg Simrad 122
in shallow water is cause for concern. The ENGOs do not provide any
substantive argument to the contrary.
[[Page 29102]]
Comment 23: The ENGOs suggested NMFS should require L-DEO to
immediately cease survey activities if any authorized take limits are
exceeded or if a take of an unauthorized species occurs (e.g., take of
a North Pacific right whale).
Response: NMFS agrees with the ENGOs that L-DEO must shut down the
airgun array if a marine mammal species for which take was not
authorized, or a species for which authorization was granted but the
takes have been met, approaches the Level A or Level B harassment
zones. This requirement was included in the notice of proposed IHA but
was inadvertently omitted from the draft IHA. The final authorization
includes this requirement.
Comment 24: The ENGOs suggested NMFS should require L-DEO to
immediately cease survey activities if a take of an unauthorized level
or intensity occurs, (e.g., serious injury or mortality of any species
or take of a Southern Resident killer whale by Level A harassment). The
ENGOs further suggest that if take is found to have been exceeded, then
there should be an investigation and additional mitigation to avoid any
additional take before activities can resume. Similarly, the Commission
recommended NMFS include in all draft and final authorizations an
explicit requirement to cease activities if a marine mammal is injured
or killed during the specified activities, including by vessel strike,
until NMFS reviews the circumstances involving any injury or death that
is likely attributable to the activities and determines what additional
measures are necessary to minimize additional injuries or death.
Response: NMFS does not expect that the proposed activities have
the potential to result in injury or mortality to marine mammals and
therefore does not agree that a blanket requirement for project
activities to cease would be warranted. NMFS does not agree that a
requirement for a vessel that is operating on the open water to
suddenly stop operating is practicable, and it is unclear what
mitigation benefit would result from such a requirement in relation to
vessel strike. The Commission does not suggest what measures other than
those prescribed in this IHA would potentially prove more effective in
reducing the risk of strike. Therefore, we have not included this
requirement in the authorization. NMFS retains authority to modify the
IHA and cease all activities immediately based on a vessel strike and
will exercise that authority if warranted.
With respect to the Commission's recommendation that NMFS include
these requirements in all proposed and final IHAs, NMFS determines the
requirements for mitigation measures in each authorization based on
numerous case-specific factors, including the practicability of the
measures for applicant implementation, which may consider such things
as cost, impact on operations, and, in the case of a military readiness
activity, personnel safety, practicality of implementation, and impact
on the effectiveness of the military readiness activity. As NMFS must
make these determinations on a case by case basis, we therefore do not
agree with this recommendation.
Comment 25: The ENGOs suggested NMFS impose a ship speed limit of
10 knots or less at all times to reduce noise and prevent ship strikes,
with an exception for rare emergency or safety necessities. While the
vessel conducting the survey is likely to be traveling well under 10
knots, NMFS should make this a requirement of any crew-transfer vessels
used in the project.
Response: NMFS has analyzed the potential for ship strike resulting
from L-DEO's planned activity and has determined that the mitigation
measures specific to ship strike avoidance are sufficient to avoid the
potential for ship strike. These include: A requirement that all vessel
operators reduce vessel speed to 10 knots (18.5 km/hour) or less when
any large whale, any mother/calf pairs, pods, or large assemblages of
non-delphinoid cetaceans are observed within 100 m of an underway
vessel; a requirement that all survey vessels maintain a separation
distance of 100 m or greater from all large whales, and 500 m or
greater from any sighted North Pacific right whale (if a whale is
observed but cannot be confirmed as a species other than a right whale,
the vessel operator must assume that it is a right whale and take
appropriate action); a requirement that if protected species are
sighted while a vessel is underway, the vessel must take action as
necessary to avoid violating the relevant separation distance (e.g.,
attempt to remain parallel to the animal's course, avoid excessive
speed or abrupt changes in direction until the animal has left the
area); and a requirement that if marine mammals are sighted within the
relevant separation distance, the vessel must reduce speed and shift
the engine to neutral, not engaging the engines until animals are clear
of the area. Finally, we note that all crew will be aboard the R/V
Langseth through the entire survey, and there will not be any crew
transfer vessels. We have determined that the ship strike avoidance
measures are sufficient to ensure the least practicable adverse impact
on species or stocks and their habitat and therefore we do not include
the 10 knot ship speed limit recommended by the ENGOs.
Comment 26: The ENGOs recommended NMFS require L-DEO to minimize
the use of lines and cables and ensure that they are not flexible to
reduce entanglement risk.
Response: As discussed in the notice of proposed IHA, no incidents
of entanglement of marine mammals with seismic survey gear have been
documented in over 54,000 nautical miles (nmi; 100,000 km) of previous
NSF-funded seismic surveys when observers were aboard (e.g., Holst and
Smultea 2008; RPS 2019; RPS 2021). Although entanglement with the
streamer is theoretically possible, it has not been documented during
tens of thousands of miles of NSF-sponsored seismic cruises or, to our
knowledge, during hundreds of thousands of miles of industrial seismic
cruises. Entanglement in OBSs and OBNs is also not expected to occur.
There are a relative few deployed devices, and no interaction between
marine mammals and any such device has been recorded during prior NSF
surveys using the devices. There are no meaningful entanglement risks
posed by the proposed survey, and therefore although we encourage L-DEO
to use lines and cables that minimize entanglement risk, NMFS has not
included the recommended requirement as a condition in the final
authorization.
Comment 27: The ENGOs state that marine mammal strandings are most
likely to result when a sound source is moving directly toward the
shore. Therefore, the ENGOs suggested NMFS should require reconfigured
tracklines to avoid these approaches when the airguns are firing.
Response: There is no conclusive evidence that exposure to airgun
noise results in behaviorally-mediated forms of injury (i.e., mass
stranding events). Behaviorally-mediated injury has been primarily
associated with beaked whales exposed to mid-frequency active (MFA)
naval sonar. As described in the notice of proposed IHA, tactical sonar
is very different from the noise produced by airguns. One should
therefore not expect the same reaction to airgun noise as to these
other sources. The ENGOs reference a survey conducted by L-DEO in 2002
that was contemporaneous with and reasonably associated spatially with
the stranding of two Cuvier's beaked whales. However, the event was not
considered a ``true atypical mass stranding'' (according to Frantzis
(1998)) as used in the analysis of Castellote and Llorens (2016). While
we agree with the
[[Page 29103]]
authors that this lack of evidence should not be considered conclusive,
it is clear that there is very little evidence that seismic surveys
should be considered as posing a significant risk of acute harm to
beaked whales or other mid-frequency cetaceans. Although NMFS does not
expect that stranding is a potential outcome of this survey activity,
we also note that certain tracklines closest to shore (i.e., in waters
less than 100 m deep in areas with highest estimated Southern Resident
killer whale occurrence) have been eliminated, further reducing the
risk of this outcome. We have considered the potential for the proposed
surveys to result in marine mammal stranding and have concluded that,
based on the best available information, stranding is not expected to
occur. Therefore, we have not adopted the ENGOs recommendation to
reconfigure the survey tracklines.
Comment 28: Both the ENGOs and Commission object to NMFS' potential
consideration of a renewal IHA for this action, and in general. The
ENGOs assert that IHA renewals are not permissible under the MMPA and
instead recommend that applicants request a multi-year permit and
accordingly reevaluate the effects of the action based on multiple
years of take. The Commission recommended NMFS refrain from issuing IHA
renewals for any authorization and instead use an abbreviated Federal
Register notice process, which is similarly expeditious and fulfills
NMFS' intent to maximize efficiencies. If NMFS continues to propose to
issue IHA renewals, the Commission recommends that NMFS (1) stipulate
that a renewal is a one-time opportunity (a) in all Federal Register
notices requesting comments on the possibility of a renewal, (b) on its
web page detailing the renewal process, and (c) in all draft and final
authorizations that include a term and condition for a renewal and (2)
if NMFS declines to adopt this recommendation, explain fully its
rationale for not doing so.
Response: NMFS' IHA renewal process meets all statutory
requirements. All IHAs issued, whether an initial IHA or a renewal IHA,
are valid for a period of not more than one year. In addition, the
public has at least 30 days to comment on all proposed IHAs, with a
cumulative total of 45 days for IHA renewals. As noted above, the
Request for Public Comments section of the notice of proposed IHA made
clear that the agency was seeking comment on both the initial proposed
IHA and the potential issuance of a renewal for this project. Because
any renewal (as explained in the Request for Public Comments section of
the notice of proposed IHA) is limited to another year of identical or
nearly identical activities in the same location (as described in the
Description of Proposed Activity section) or the same activities that
were not completed within the 1 year period of the initial IHA,
reviewers have the information needed to effectively comment on both
the immediate proposed IHA and a possible 1 year renewal, should the
IHA holder choose to request one in the coming months.
While there will be additional documents submitted with a renewal
request, for a qualifying renewal these will be limited to
documentation that NMFS will make available and use to verify that the
activities are identical to those in the initial IHA, are nearly
identical such that the changes would have either no effect on impacts
to marine mammals or decrease those impacts, or are a subset of
activities already analyzed and authorized but not completed under the
initial IHA. NMFS will also confirm, among other things, that the
activities will occur in the same location; involve the same species
and stocks; provide for continuation of the same mitigation,
monitoring, and reporting requirements; and that no new information has
been received that would alter the prior analysis. The renewal request
will also contain a preliminary monitoring report, but that is to
verify that effects from the activities do not indicate impacts of a
scale or nature not previously analyzed. The additional 15-day public
comment period provides the public an opportunity to review these few
documents, provide any additional pertinent information and comment on
whether they think the criteria for a renewal have been met. Between
the initial 30-day comment period on these same activities and the
additional 15 days, the total comment period for a renewal is 45 days.
In addition to the IHA renewal process being consistent with all
requirements under section 101(a)(5)(D), it is also consistent with
Congress' intent for issuance of IHAs to the extent reflected in
statements in the legislative history of the MMPA. Through the
provision for renewals in the regulations, description of the process
and express invitation to comment on specific potential renewals in the
Request for Public Comments section of each proposed IHA, the
description of the process on NMFS' website, further elaboration on the
process through responses to comments such as these, posting of
substantive documents on the agency's website, and provision of 30 or
45 days for public review and comment on all proposed initial IHAs and
renewals respectively, NMFS has ensured that the public ``is invited
and encouraged to participate fully in the agency decision-making
process.''
NMFS does not agree with the Commission and therefore does not
adopt the Commission's recommendation that NMFS use an abbreviated
Federal Register notice instead of IHA renewal. NMFS has previously
provided responses to this specific recommendation in multiple notices,
including 84 FR 52464 (October 2, 2019). NMFS does agree with the
Commission's recommendation that NMFS specify that IHA renewals are a
one-time opportunity in all Federal Register notices requesting
comments on the possibility of an IHA renewal, in all associated
proposed and final IHAs, and on our website. NMFS has specified this in
the final IHA for L-DEO's activities and has been including this in
Federal Register notices and proposed and final authorizations since
last year.
Comment 29: The ENGOs recommended NMFS and L-DEO explore whether
the proposed research could be conducted using alternative technologies
or approaches that are less harmful to marine mammals. More broadly,
and beyond the scope of this action, the ENGOs recommended NMFS engage
with NSF to invest in research that explores alternative technologies.
Response: NMFS agrees with the ENGOs that development and use of
technologies that reduce the environmental impact of geophysical
surveys is a laudable objective and may be warranted in some cases.
Alternative technologies are in various stages of development, and none
of the systems with the potential to replace airguns as a seismic
source are currently commercially available for use on a scale of
activity such as that considered herein. Although some alternative
technologies are available now, or will be in the next several years,
for select uses, none are at a stage where they can replace airgun
arrays outright. However, some may be used in select environments when
commercially available. Such technologies may be evaluated in the
future as they become commercially available and on a scale
commensurate to the need. In summary, while we agree that alternative
technologies may be beneficial, the ENGOs do not suggest any specific
technologies or approaches and the suggestion that NMFS engage with NSF
to research these methods is outside the authority provided to NMFS by
the MMPA. However, NMFS would consider participating in related efforts
[[Page 29104]]
by the ENGOs or other entities interested in these technologies.
Comment 30: The ENGOs and the Commission recommended NMFS require
L-DEO to use the method proposed by the Commission to estimate take and
apply relevant corrections for airgun activity in daylight vs nighttime
(including dawn and dusk) to better estimate the numbers of marine
mammals taken by Level A and B harassment. The Commission further
recommends that NMFS require L-DEO to specify in the final monitoring
report (1) the number of days on which the airgun array was active and
(2) the percentage of time and total time the array was active during
daylight vs nighttime hours (including dawn and dusk).
Response: NMFS appreciates the Commission's development of a
recommended approach to better estimate the numbers of marine mammals
that may have been taken during geophysical survey activities,
including marine mammals that were not detected. The ``Commission's
method'' (see the Commission's letter for additional discussion and
citation to a full description provided in an addendum to a May 1, 2019
Commission comment letter) involves correction of marine mammal
sightings data through use of proxies for marine mammal detectability
(f (0)) and platform/observer bias on marine mammal detection (g (0)),
and extrapolation of corrected marine mammal sightings data based on
the assumed extent of the Level B harassment zones.
However, NMFS does not concur with the recommendation to require L-
DEO to implement this approach because we do not have confidence in the
reliability of estimates of potential marine mammal take that would
result from use of the approach. The Commission does not address the
multiple assumptions that must be made in order to have confidence in
the estimates that would be produced through application of the method.
For example, the assumption that the application of proxy values for g
(0) and f (0) is appropriate is not justified (including application of
f (0) values to species for which no value is available and assuming
that application of f (0) to species in a wholly different region is
appropriate). Notably, g (0) values are typically derived on a
platform-specific basis, and even for specific observers--not
generalized across platforms, as the Commission's method would require.
Separately, the appropriate application of distance sampling
methods requires that certain assumptions are valid, and the Commission
does not explain why these assumptions should be assumed to be valid
during a seismic survey, as compared with typical line-transect surveys
operating without an active acoustic source. For example, a key
underlying concept of distance sampling methodology is that the
probability of detecting an animal decreases as its distance from the
observer increases. This cannot be assumed true during an active
seismic survey. NMFS believes it unlikely that the numerous assumptions
inherent to application of the Commission's method would be accepted in
a research context (where distance sampling approaches are typically
applied).
Furthermore, the area over which observations are to be
extrapolated through the Commission's method is a modeled ensonified
area. We do not believe it appropriate to assume a modeled ensonified
area is always accurate for purposes of estimating total take. In
purporting to estimate total takes, the method ignores the fact that
marine mammals exposed to a level of received sound assumed to cause
take for analytical purposes may not in fact respond behaviorally in a
way that equates to take, especially at great distance from the source.
NMFS believes it is important to focus on collection and reporting
of empirical data that can directly inform an assessment of the effects
of a specified activity on the affected species or stock. While there
may be value in an assessment of potential unobserved take, we need to
proceed cautiously in the development of derived values given our low
confidence in multiple inputs. NMFS is currently more broadly
evaluating monitoring requirements, including data collection,
interpretation, and reporting, as well as the specific issue the
Commission has raised, and is committed to developing improved
approaches.
NMFS does concur with the Commission's recommendation that NMFS
require L-DEO to specify in the final monitoring report (1) the number
of days on which the airgun array was active and (2) the percentage of
time and total time the array was active during daylight vs nighttime
hours (including dawn and dusk). This requirement has been added to the
final authorization.
Comment 31: The Commission asserts that L-DEO and other NSF-
affiliated entities have not complied with all of the requirements set
forth in certain final IHAs, and recommends that, should the alleged
shortcomings occur again, NMFS refrain from issuing any further
authorizations to L-DEO and other NSF-affiliated entities until such
time that the monitoring reports include all of the required
information.
Response: NMFS appreciates the Commission's concern and will
consider any future requests for incidental take authorization from
NSF-affiliated entities according to the requirements of the MMPA.
Comment 32: Noting its disagreement with L-DEO's approach to
estimating the size of various ensonified areas, the Commission
recommends that NMFS require L-DEO to either (1) re-estimate the
proposed Level A and B harassment zones and associated takes of marine
mammals using (a) both operational and site-specific environmental
parameters, (b) what the Commission believes to be a comprehensive
source model and (c) what the Commission believes to be an appropriate
sound propagation model for the proposed IHA or (2) collect or provide
the relevant acoustic data to substantiate that its modeling approach
is conservative for both deep- and intermediate-water depths beyond the
Gulf of Mexico. In addition, the Commission recommends that NMFS (1)
explain why sound channels with downward refraction, as well as
seafloor reflections, are not likely to occur during the geophysical
survey, (2) specify the degree to which both of those parameters would
affect the estimation (or underestimation) of Level B harassment zones
in deep- and intermediate- water depths, (3) explain why L-DEO's model
and other modeling approaches provide more accurate, realistic, and
appropriate Level A and B harassment zones than BELLHOP (a different
propagation model favored by the Commission), particularly for deep-
and intermediate-water depths, and (4) explain why, if L-DEO's model
and other modeling approaches are considered best available science,
other action proponents that conduct seismic surveys are not
implementing similar methods, particularly given their simplicity.
Response: As noted by the Commission, these comments reflect a
longstanding disagreement between NMFS and the Commission regarding L-
DEO's approach to modeling the output of their airgun array and its
propagation through the water column. NMFS has previously responded to
similar Commission comments on L-DEO's modeling approach. We refer the
reader to previous Federal Register notices providing responses rather
than repeat them here (e.g., 84 FR 60059, November 07, 2019; 84 FR
54849, October 11, 2019; 84 FR 35073, July 22, 2019). Regardless of the
addition of
[[Page 29105]]
slightly different points or modifications to the language with which
the Commission expresses these points, the gist of the Commission's
disagreement with L-DEO's modeling approach remains the same. NMFS
believes that its prior responses have adequately explained the
rationale for not following the Commission's recommendations and,
importantly, why L-DEO's modeling approach is adequate.
Comment 33: The ENGOs asserted that NMFS must prepare an
Environmental Impact Statement and cannot rely on the NSF's
Environmental Assessment (EA) because they believe that there are
significant environmental impacts. The CBD's comments on the NSF's
draft EA were incorporated by reference in the ENGOs' comment letter on
the proposed IHA. CBD's comments on NSF's draft EA primarily concerned
Southern Resident killer whales, similar to the concerns addressed
above.
Response: The NSF's draft EA, which NMFS adopted, was revised in
consideration of CBD's comments (and those of other public commenters)
and adequately analyzes the effects of the action. The commenters do
not provide any information to support their claim of significant
environmental impacts under NEPA. NMFS has reviewed the NSF's final EA,
determined it to be sufficient, and adopted that EA and signed a
Finding of No Significant Impact (FONSI).
Comment 34: The ENGOs expressed doubt that the proposed activities
were permissible under the ESA because they would jeopardize the
continued existence of Southern Resident killer whales, North Pacific
right whales, humpback whales, and blue whales, among other protected
species and adversely modify proposed critical habitat. The proposed
action clearly affects listed species as well as proposed and
designated critical habitat, and therefore both NMFS and the NSF must
undergo consultation under the ESA. The ENGOs urged NMFS to fulfill our
commitment to complete consultation before authorizing any take of
marine mammals, and requested a public comment period on the products
of the consultation. The ENGOs strongly believe that NMFS cannot
authorize the specified activities because they will jeopardize the
recovery and survival of Southern Resident killer whales and North
Pacific right whales.
Response: NMFS has completed consultation under the ESA on our
proposal to authorize take of listed marine mammals incidental to L-
DEO's survey activities. The NMFS Office of Protected Resources,
Interagency Cooperation Division issued a Biological Opinion concluding
that the proposed action is not likely to jeopardize the continued
existence of ESA-listed blue whales, fin whales, sei whales, sperm
whales, Central America DPS humpback whales, Mexico DPS humpback
whales, Southern Resident killer whale DPS, and Guadalupe fur seals and
is not likely to destroy or adversely modify Steller sea lion or
humpback whale critical habitat. There is no designated critical
habitat in the action area for the other listed species. The
Interagency Cooperation Division determined that a public comment
period on the Biological Opinion was not warranted. The final
Biological Opinion is available on our website at: https://www.fisheries.noaa.gov/national/marine-mammal-protection/incidental-take-authorizations-research-and-other-activities.
Comment 35: The ENGOs asserted that NMFS cannot approve the
proposed activity without first consulting with the states of
Washington and Oregon under the Coastal Zone Management Act (CZMA). The
CZMA authorizes states with federally approved coastal management
programs to review applications for Federal licenses or permits to
conduct activities in, or outside of, the coastal zone that affects
land uses, water uses, or natural resources within the coastal zone to
ensure the activity is fully consistent with the state's management
plan.
Response: The NSF submitted consistency determinations to
Washington and Oregon. Both the Washington State Department of Ecology
and Oregon Coastal Management Program, the respective CZMA authorities
for Washington and Oregon, concurred with the NSF's determinations.
NMFS' action of authorizing take of marine mammal is incidental to the
NSF's action of conducting the survey, therefore NMFS is not required
to independently submit consistency determinations under CZMA.
Comment 36: The ENGOs and Deep Green Wilderness expressed concern
that the proposed survey overlaps with Olympic Coast National Marine
Sanctuary (OCNMS). The ENGOs reference the National Marine Sanctuaries
Act (NMSA), which aims to maintain the natural biological communities
in the national marine sanctuaries, and to protect, and, where
appropriate, restore and enhance natural habitats, populations, and
ecological processes. To achieve these purposes, the NMSA requires that
Federal agency actions internal or external to a national marine
sanctuary, including private activities authorized by licenses, leases,
or permits that are likely to destroy, cause the loss of, or injure any
sanctuary resource are subject to consultation with the Secretary. The
ENGOs noted that the action agency must follow the recommendations of
the Secretary to avoid injury to any sanctuary resource or otherwise
act to prevent and mitigate damage to such resources.
Response: NMFS satisfied our responsibilities under section 304(d)
of the NMSA. NMFS and the NSF drafted a joint Sanctuary Resource
Statement (SRS) to consult with the NOAA Office of National Marine
Sanctuaries (ONMS) under the NMSA. ONMS provided two recommended
alternatives to minimize injury and to protect sanctuary resources: (1)
Limit operations in OCNMS to daylight hours only regardless of depth;
and 2) use of the secondary support vessel aiding in marine mammal
observations throughout the entire sanctuary. NMFS has included these
recommendations in the final IHA.
Changes From the Proposed IHA to Final IHA
There are numerous changes from the proposed IHA, starting with the
timing of the survey. The survey was initially proposed to occur in
summer 2020 but was delayed until summer 2021. Since conclusion of the
public comment period in May 2020, NMFS has reviewed newly available
information, including recent draft Stock Assessment Reports,
information on relevant Unusual Mortality Events, and other scientific
literature, and incorporated this information into our analysis of
impacts on marine mammals and their habitat.
In addition to the timing changes, the survey tracklines have been
modified to avoid surveying in the areas with the highest expected
occurrence of Southern Resident killer whales. Between Tillamook Head,
Oregon and Barkley Sound, British Columbia, L-DEO's planned tracklines
have been truncated or removed entirely such that the ensonified area
does not extend within the 100-meter (m) depth contour (see Estimated
Take section for description of the Level B harassment zones and
ensonified area). In addition to removing tracklines in nearshore
shallow waters along the coast, L-DEO also modified tracklines such
that the ensonified area will not extend within Canadian designated
Southern Resident and Northern Resident killer whale critical habitat.
Additionally, under consultation with Canada DFO, L-DEO removed all
tracklines in waters 100 m or less in Canadian waters. Thus north of
Tillamook Head, Oregon, no surveys
[[Page 29106]]
will occur in waters 100 m or less (see Figure 1). Based on informal
recommendations from the Commission, NMFS recalculated the densities of
Steller sea lions by applying the appropriate pup and non-pup growth
rates of the population in Washington and British Columbia. Takes of
all species and stocks have been recalculated using the revised
tracklines and resulting ensonified areas. Additionally, NMFS has
revised the mitigation requirements regarding use of a second support
vessel and daylight-only operations in waters 200 m or less. The
proposed IHA required the use of the support vessel and limited
operations to daylight only along the entire survey area in waters 200
m or less. In consideration of operational practicability, we have
revised that requirement to apply only between Tillamook Head, Oregon
and Barkley Sound, British Columbia. Based on consultation with the
Olympic Coast National Marine Sanctuary (OCNMS), the final IHA requires
L-DEO to use the support vessel and operate only during daylight hours
within the OCNMS, regardless of water depth. OCNMS has also been added
to the list of entities L-DEO must contact each day to obtain sightings
reports of Southern Resident killer whales in the survey area and, in
turn, report their own sightings of killer whales to the Sanctuary.
Finally, as recommended by the Commission, we have clarified the
required elements that must be included in L-DEO's monitoring report.
Description of Marine Mammals in the Area of Specified Activities
Sections 3 and 4 of the application summarize available information
regarding status and trends, distribution and habitat preferences, and
behavior and life history, of the potentially affected species.
Additional information regarding population trends and threats may be
found in NMFS's Stock Assessment Reports (SARs; https://www.fisheries.noaa.gov/national/marine-mammal-protection/marine-mammal-stock-assessments) and more general information about these species
(e.g., physical and behavioral descriptions) may be found on NMFS's
website (https://www.fisheries.noaa.gov/find-species).
Table 1 lists all species with expected potential for occurrence in
the survey area and summarizes information related to the population or
stock, including regulatory status under the MMPA and ESA and potential
biological removal (PBR), where known. For taxonomy, we follow
Committee on Taxonomy (2020). PBR is defined by the MMPA as the maximum
number of animals, not including natural mortalities, that may be
removed from a marine mammal stock while allowing that stock to reach
or maintain its optimum sustainable population (as described in NMFS's
SARs). While no mortality is anticipated or authorized here, PBR and
annual serious injury and mortality from anthropogenic sources are
included here as gross indicators of the status of the species and
other threats.
Marine mammal abundance estimates presented in this document
represent the total number of individuals that make up a given stock or
the total number estimated within a particular study or survey area.
NMFS's stock abundance estimates for most species represent the total
estimate of individuals within the geographic area, if known, that
comprises that stock. For some species, this geographic area may extend
beyond U.S. waters. All managed stocks in this region are assessed in
NMFS's U.S. Pacific and Alaska SARs. All MMPA stock information
presented in Table 1 is the most recent available at the time of
publication and is available in the 2019 SARs (Caretta et al., 2020;
Muto et al., 2020) and draft 2020 SARs (available online at: https://www.fisheries.noaa.gov/national/marine-mammal-protection/draft-marine-mammal-stock-assessment-reports). Where available, abundance and status
information is also presented for marine mammals in Canadian waters in
British Columbia.
Table 1--Marine Mammals That Could Occur in the Survey Area
--------------------------------------------------------------------------------------------------------------------------------------------------------
ESA/MMPA Stock abundance (CV,
status; Nmin, most recent Annual M/
Common name Scientific name Stock strategic (Y/N) abundance survey) PBR SI \3\
\1\ \2\
--------------------------------------------------------------------------------------------------------------------------------------------------------
Order Cetartiodactyla--Cetacea--Superfamily Mysticeti (baleen whales)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Family Eschrichtiidae:
Gray whale.................... Eschrichtius robustus Eastern North -/-; N 26,960 (0.05, 801 131
Pacific. 25,849, 2016).
Family Balaenopteridae (rorquals):
Humpback whale................ Megaptera California/Oregon/ -/-; Y 2,900 (0.05, 2,784, 16.7 >42.1
novaeangliae. Washington. 2014).
Central North -/-; Y 10,103 (0.30, 7,891, 83 26
Pacific. 2006).
Minke whale................... Balaenoptera California/Oregon/ -/-; N 636 (0.72, 369, 3.5 >1.3
acutorostrata. Washington. 2014).
Sei whale..................... Balaenoptera borealis Eastern North E/D; Y 519 (0.4, 374, 2014) 0.75 >0.2
Pacific.
Fin whale..................... Balaenoptera physalus California/Oregon/ E/D; Y 9,029 (0.12, 8,127, 81 >43.7
Washington. 2014).
Northeast Pacific... E/D; Y 3,168 (0.26, 2,554, 5.1 0.6
2013).
Blue whale.................... Balaenoptera musculus Eastern North E/D; Y 1,496 (0.44, 1,050, 1.2 >19.4
Pacific. 2014).
--------------------------------------------------------------------------------------------------------------------------------------------------------
Superfamily Odontoceti (toothed whales, dolphins, and porpoises)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Family Physeteridae:
Sperm whale................... Physeter California/Oregon/ E/D; Y 1,997 (0.57, 1,270, 2.5 0.4
macrocephalus. Washington. 2014).
Family Kogiidae:
Pygmy sperm whale............. Kogia breviceps...... California/Oregon/ -/-; N 4,111 (1.12, 1,924, 19 0
Washington. 2014).
Dwarf sperm whale............. Kogia sima........... California/Oregon/ -/-; N Unknown (Unknown, Undetermined 0
Washington. Unknown, 2014).
Family Ziphiidae (beaked whales):
Cuvier's beaked whale......... Ziphius cavirostris.. California/Oregon/ -/-; N 3,274 (0.67, 2,059, 21 <0.1
Washington. 2014).
[[Page 29107]]
Baird's beaked whale.......... Berardius bairdii.... California/Oregon/ -/-; N 2,697 (0.6, 1,633, 16 0
Washington. 2014).
Mesoplodont beaked whales..... Mesoplodon spp....... California/Oregon/ -/-; N 3,044 (0.54, 1,967, 20 0.1
Washington. 2014).
Family Delphinidae:
Bottlenose dolphin............ Tursiops truncatus... California/Oregon/ -/-; N 1,924 (0.54, 1,255, 11 >1.6
Washington offshore. 2014).
Striped dolphin............... Stenella coeruleoalba California/Oregon/ -/-; N 29,211 (0.2, 24,782, 238 >0.8
Washington. 2014).
Common dolphin................ Delphinus delphis.... California/Oregon/ -/-; N 969,861 (0.17, 8,393 >40
Washington. 839,325, 2014).
Pacific white-sided dolphin... Lagenorhynchus California/Oregon/ -/-; N 26,814 (0.28, 191 7.5
obliquidens. Washington. 21,195, 2014).
British Columbia \4\ N/A 22,160 (unknown, Unknown Unknown
16,522, 2008).
Northern right whale dolphin.. Lissodelphis borealis California/Oregon/ -/-; N 26,556 (0.44, 179 3.8
Washington. 18,608, 2014).
Risso's dolphin............... Grampus griseus...... California/Oregon/ -/-; N 6,336 (0.32, 4,817, 46 >3.7
Washington. 2014).
False killer whale............ Pseudorca crassidens. N/A................. N/A N/A................. N/A N/A
Killer whale.................. Orcinus orca......... Offshore............ -/-; N 300 (0.1, 276, 2012) 2.8 0
Southern Resident... E/D; Y 73 (N/A, 73, 2019).. 0.13 >0.4
Northern Resident... -/-; N 302 (N/A, 302, 2018) 2.2 0.2
West Coast Transient -/-; N 349 (N/A, 349, 2018) 3.5 0.4
Short-finned pilot whale...... Globicephala California/Oregon/ -/-; N 836 (0.79, 466, 4.5 1.2
macrorhynchus. Washington. 2014).
Family Phocoenidae (porpoises):
Harbor porpoise............... Phocoena phocoena.... Northern Oregon/ -/-; N 21,487 (0.44, 151 >3.0
Washington Coast. 15,123, 2011).
Northern California/ -/-; N 35,769 (0.52, 475 >0.6
Southern Oregon. 23,749, 2011).
British Columbia \4\ N/A 8,091 (unknown, Unknown Unknown
4,885, 2008).
Dall's porpoise................... Phocoenoides dalli... California/Oregon/ -/-; N 25,750 (0.45, 172 0.3
Washington. 17,954, 2014).
British Columbia \4\ N/A 5,303 (unknown, Unknown Unknown
4,638, 2008).
--------------------------------------------------------------------------------------------------------------------------------------------------------
Order Carnivora--Superfamily Pinnipedia
--------------------------------------------------------------------------------------------------------------------------------------------------------
Family Otariidae (eared seals and
sea lions):
Northern fur seal............. Callorhinus ursinus.. Eastern Pacific..... -/D; Y 608,143 (0.2, 11,067 387
514,738, 2018).
California.......... -/D; N 14,050 (N/A, 7,524, 451 1.8
2013).
California sea lion........... Zalophus U.S................. -/-; N 257,606 (N/A, 14,011 >321
californianus. 233,515, 2014).
Steller sea lion.............. Eumetopias jubatus... Eastern U.S......... -/-; N 43,201 (see SAR, 2,592 113
43,201, 2017).
British Columbia \4\ N/A 4,037 (unknown, Unknown Unknown
1,100, 2008).
Guadalupe fur seal............ Arctocephalus Mexico to California T/D; Y 34,187 (N/A, 31,019, 1,062 >3.8
philippii townsendi. 2013).
Family Phocidae (earless seals):
Harbor seal................... Phoca vitulina....... Oregon/Washington -/-; N Unknown (Unknown, Undetermined 10.6
Coastal. Unknown, 1999).
British Columbia \4\ N/A 24,916 (Unknown, Unknown Unknown
19,666, 2008).
Northern elephant seal........ Mirounga California Breeding. -/-; N 179,000 (N/A, 4,882 8.8
angustirostris. 81,368, 2010).
--------------------------------------------------------------------------------------------------------------------------------------------------------
1--Endangered Species Act (ESA) status: Endangered (E), Threatened (T)/MMPA status: Depleted (D). A dash (-) indicates that the species is not listed
under the ESA or designated as depleted under the MMPA. Under the MMPA, a strategic stock is one for which the level of direct human-caused mortality
exceeds PBR or which is determined to be declining and likely to be listed under the ESA within the foreseeable future. Any species or stock listed
under the ESA is automatically designated under the MMPA as depleted and as a strategic stock.
2--NMFS marine mammal stock assessment reports online at: https://www.fisheries.noaa.gov/national/marine-mammal-protection/marine-mammal-stock-assessments assessments. CV is coefficient of variation; Nmin is the minimum estimate of stock abundance. In some cases, CV is not applicable.
3--These values, found in NMFS's SARs, represent annual levels of human-caused mortality plus serious injury from all sources combined (e.g., commercial
fisheries, ship strike). Annual M/SI often cannot be determined precisely and is in some cases presented as a minimum value or range. A CV associated
with estimated mortality due to commercial fisheries is presented in some cases.
4--Best et al. (2015) total abundance estimates for animals in British Columbia based on surveys of the Strait of Georgia, Johnstone Strait, Queen
Charlotte Sound, Hecate Strait, and Dixon Entrance. These rows represent British Columbia abundance estimates, where available, but do not represent
additional stocks.
5--The California/Oregon/Washington stock of Mesoplodont beaked whales includes six species of beaked whales. Of the six species represented in this
stock, only Blainville's beaked whales, Hubbs' beaked whales, and Stejneger's beaked whales are expected to be encountered or taken.
[[Page 29108]]
All species that could potentially occur in the planned survey
areas are included in Table 1. However, additional species have been
recorded in the specified geographic region but are considered
sufficiently rare that take is not anticipated. The temporal and/or
spatial occurrence of North Pacific right whales (Eubalaena japonica)
is such that take is not expected to occur, and they are not discussed
further beyond the explanation provided here. Only 82 sightings of
right whales in the entire eastern North Pacific were reported from
1962 to 1999, with the majority of these occurring in the Bering Sea
and adjacent areas of the Aleutian Islands (Brownell et al., 2001).
Most sightings in the past 20 years have occurred in the southeastern
Bering Sea, with a few in the Gulf of Alaska (Wade et al., 2011).
Despite many miles of systematic aerial and ship-based surveys for
marine mammals off the coasts of Washington, Oregon and California over
several years, only seven documented sightings of right whales were
made from 1990 to 2000 (Waite et al., 2003), and NMFS only aware of two
documented sightings in the area since then. Because of the small
population size and the fact that North Pacific right whales spend the
summer feeding in high latitudes, the likelihood that the planned
survey would encounter a North Pacific right whale is discountable.
In addition, the Northern sea otter (Enhydra lutris kenyoni) may be
found in coastal waters of the survey area. However, sea otters are
managed by the U.S. Fish and Wildlife Service and are not considered
further in this document.
A detailed description of the species likely to be affected by L-
DEO's geophysical survey, including brief introductions to the species
and relevant stocks as well as available information regarding
population trends and threats, and information regarding local
occurrence, were provided in the Federal Register notice of proposed
IHA (85 FR 19580; April 7, 2020). Since that time, NMFS has published
the draft 2020 SARs with updated abundance, PBR, and/or mortality
information for the Eastern Pacific stock of northern fur seals, West
Coast Transient stock of killer whales, Central North Pacific stock of
humpback whales, Northeast Pacific and California/Oregon/Washington
stocks of fin whale, Eastern North Pacific Southern Resident stock of
killer whales, and Eastern North Pacific Stock and Pacific Coast
Feeding Group of gray whales. The relevant information for these stocks
has been updated in Table 1, however the status of these species and
stocks has not changed; therefore detailed descriptions are not
provided here. Please refer to the Federal Register notice of proposed
IHA for these descriptions. Please also refer to NMFS' website (https://www.fisheries.noaa.gov/find-species) for generalized species accounts.
Biologically Important Areas and Critical Habitat
Biologically Important Areas (BIAs) for feeding gray whales along
the coasts of Washington, Oregon, and California have been identified,
including northern Puget Sound, Northwestern Washington, and Grays
Harbor in Washington, Depoe Bay and Cape Blanco and Orford Reef in
Oregon, and Point St. George in California; most of these areas are of
importance from late spring through early fall (Calambokidis et al.,
2015). BIAs have also been identified for migrating gray whales along
the entire coasts of Washington, Oregon, and California; although most
whales travel within 10 km from shore, the BIAs were extended out to 47
km from the coastline (Calambokidis et al., 2015). The planned survey
will occur during the late spring/summer feeding season, when most
individuals from the eastern North Pacific stock occur farther north.
Nonetheless, individual gray whales, particularly those from the PCFG
could be encountered in nearshore waters of the project area.
Prior to 2016, humpback whales were listed under the ESA as an
endangered species worldwide. Following a 2015 global status review
(Bettridge et al., 2015), NMFS delineated 14 distinct population
segments (DPS) with different listing statuses (81 FR 62259; September
8, 2016) pursuant to the ESA. The DPSs that occur in U.S. waters do not
necessarily equate to the existing stocks designated under the MMPA and
shown in Table 1. Because MMPA stocks cannot be portioned, i.e., parts
managed as ESA-listed while other parts managed as not ESA-listed,
until such time as the MMPA stock delineations are reviewed in light of
the DPS designations, NMFS considers the existing humpback whale stocks
under the MMPA to be endangered and depleted for MMPA management
purposes (e.g., selection of a recovery factor, stock status).
Within the survey area, three DPSs may occur: The Hawaii DPS (not
listed), Mexico DPS (threatened), and Central America DPS (endangered).
On April 21, 2021, NMFS issued a final rule to designate critical
habitat in nearshore waters of the North Pacific Ocean for the
endangered Central America DPS and the threatened Mexico DPS of
humpback whale (86 FR 21082). Critical habitat for the Central America
DPS and Mexico DPS was established within the California Current
Ecosystem (CCE) off the coasts California, Oregon, and Washington,
representing areas of key foraging habitat. Off Washington and northern
Oregon, the critical habitat extends from the 50-m isobath out to the
1200-m isobath; off southern Oregon (south of 42[deg]10' N), it extends
out to the 2000-m isobath. L-DEO's easternmost planned tracklines occur
within designated humpback whale critical habitat along the coast.
Critical habitat for humpbacks has been designated under Canadian
law in four locations in British Columbia (DFO 2013), including in the
waters of the survey area off southwestern Vancouver Island. The other
three locations are located north of the survey area at Haida Gwaii
(Langara Island and Southeast Moresby Island) and at Gil Island (DFO
2013). These areas show persistent aggregations of humpback whales and
have features such as prey availability, suitable acoustic environment,
water quality, and physical space that allow for feeding, foraging,
socializing, and resting (DFO 2013). A small portion of L-DEO's planned
tracklines overlap with Canadian designated humpback whale critical
habitat off southwest Vancouver Island.
BIAs for feeding humpbacks along the coasts of Oregon and
Washington, which have been described from May to November, are all
within approximately 80 km from shore, and include the waters off
northern Washington, and Stonewall and Heceta Bank, Oregon
(Calambokidis et al., 2015). Some segments of L-DEO's planned
tracklines overlap with these BIAs.
The U.S. Southern Resident killer whale critical habitat designated
under the ESA currently includes inland waters of Washington relative
to a contiguous shoreline delimited by the line at a depth of 6.1 m
relative to extreme high water (71 FR 69054; November 29, 2006). On
September 19, 2019, NMFS published a proposed rule to revise designated
Southern Resident killer whale critical habitat to include 40,472.7
km\2\ of marine waters between the 6.1-m depth contour and the 200-m
depth contour from the U.S. international border with Canada south to
Point Sur, California (84 FR 49214; September 19, 2019). The planned
survey tracklines overlap with NMFS' proposed expanded Southern
Resident critical habitat.
In Canada, Southern Resident killer whales are listed as Endangered
under the Species at Risk Act (SARA), and critical habitat has been
designated in the trans-boundary waters in southern British Columbia,
including the
[[Page 29109]]
southern Strait of Georgia, Haro Strait, and Strait of Juan de Fuca
(SOR/2018-278, December 13, 2018; SOR/2009-68, February 19, 2009; DFO
2018). The continental shelf waters off southwestern Vancouver Island,
including Swiftsure and La P[eacute]rouse Banks have also been
designated as critical habitat for Southern Resident and Northern
Resident killer whales (SOR/2018-278, December 13, 2018). As discussed
above, L-DEO's initial proposed survey tracklines that overlapped with
Canadian designated critical habitat for killer whales have been
eliminated.
Federally designated critical habitat for Steller sea lions in
Oregon and California includes all rookeries (NMFS 1993). Although the
Eastern DPS was delisted from the ESA in 2013, the designated critical
habitat remains valid (NOAA 2019e). The critical habitat in Oregon is
located along the coast at Rogue Reef (Pyramid Rock) and Orford Reef
(Long Brown Rock and Seal Rock). The critical habitat area includes
aquatic zones that extend 0.9 km seaward and air zones extending 0.9 km
above these terrestrial and aquatic zones (NMFS 1993). L-DEO's planned
tracklines lie about 9 and 13 km away from the two Oregon units of
Steller sea lion critical habitat.
Unusual Mortality Events
On May 30, 2019, NMFS declared an unusual mortality event (UME) for
gray whales after elevated numbers of strandings occurred along the
U.S. west coast. As of April 5, 2021, a total of 430 stranded gray
whales have been reported, including 209 in the United States (93 in
Alaska, 50 in Washington, 9 in Oregon, and 57 in California), 205 in
Mexico, and 16 in Canada. Full or partial necropsy examinations were
conducted on a subset of the whales. Preliminary findings in several of
the whales have shown evidence of emaciation. These findings are not
consistent across all of the whales examined, so more research is
needed. The UME is ongoing, and NMFS continues to investigate the
cause(s). Additional information about the UME is available at https://www.fisheries.noaa.gov/national/marine-life-distress/2019-2020-gray-whale-unusual-mortality-event-along-west-coast.
Increased strandings of Guadalupe fur seals have occurred along the
entire coast of California. Guadalupe fur seal strandings began in
January 2015 and were eight times higher than the historical average.
Strandings have continued since 2015 and have remained well above
average through 2019. Strandings are seasonal and generally peak in
April through June of each year. Strandings in Oregon and Washington
became elevated starting in 2019 and have continued to present.
Strandings in these two states in 2019 are five times higher than the
historical average. Guadalupe fur seals have stranded alive and dead.
Those stranding are mostly weaned pups and juveniles (1-2 years old).
The majority of stranded animals showed signs of malnutrition with
secondary bacterial and parasitic infections. NMFS has declared a UME
for Guadalupe fur seals along the entire U.S. West Coast; the UME is
ongoing and NMFS is continuing to investigate the cause(s). For
additional information on the UME, see https://www.fisheries.noaa.gov/national/marine-life-distress/2015-2020-guadalupe-fur-seal-unusual-mortality-event-california.
Elevated strandings of California sea lion pups occurred in
Southern California between January 2013 and September 2016. As a
result, NMFS declared a UME. The UME was confined to pup and yearling
California sea lions, many of which were emaciated, dehydrated, and
underweight for their age. A change in the availability of sea lion
prey, especially sardines, a high value food source for nursing
mothers, was a likely contributor to the large number of strandings.
Sardine spawning grounds shifted further offshore in 2012 and 2013, and
while other prey were available (market squid and rockfish), these may
not have provided adequate nutrition in the milk of sea lion mothers
supporting pups, or for newly-weaned pups foraging on their own.
Although the pups showed signs of some viruses and infections, findings
indicate that this event was not caused by disease, but rather by the
lack of high quality, close-by food sources for nursing mothers.
Current evidence does not indicate that this UME was caused by a single
infectious agent, though a variety of disease-causing bacteria and
viruses were found in samples from sea lion pups. The investigative
team examined multiple potential explanations for the high numbers of
malnourished California sea lion pups observed on the island rookeries
and stranded on the mainland in 2013. For more information, see https://www.fisheries.noaa.gov/national/marine-life-distress/2013-2017-california-sea-lion-unusual-mortality-event-california.
Marine Mammal Hearing
Hearing is the most important sensory modality for marine mammals
underwater, and exposure to anthropogenic sound can have deleterious
effects. To appropriately assess the potential effects of exposure to
sound, it is necessary to understand the frequency ranges marine
mammals are able to hear. Current data indicate that not all marine
mammal species have equal hearing capabilities (e.g., Richardson et
al., 1995; Wartzok and Ketten, 1999; Au and Hastings, 2008). To reflect
this, Southall et al. (2007) recommended that marine mammals be divided
into functional hearing groups based on directly measured or estimated
hearing ranges on the basis of available behavioral response data,
audiograms derived using auditory evoked potential techniques,
anatomical modeling, and other data. Note that no direct measurements
of hearing ability have been successfully completed for mysticetes
(i.e., low-frequency cetaceans). Subsequently, NMFS (2018) described
generalized hearing ranges for these marine mammal hearing groups.
Generalized hearing ranges were chosen based on the approximately 65 dB
threshold from the normalized composite audiograms, with the exception
for lower limits for low-frequency cetaceans where the lower bound was
deemed to be biologically implausible and the lower bound from Southall
et al. (2007) retained. Marine mammal hearing groups and their
associated hearing ranges are provided in Table 2.
Table 2--Marine Mammal Hearing Groups (NMFS, 2018)
------------------------------------------------------------------------
Hearing group Generalized hearing range *
------------------------------------------------------------------------
Low-frequency (LF) cetaceans (baleen 7 Hz to 35 kHz.
whales).
Mid-frequency (MF) cetaceans (dolphins, 150 Hz to 160 kHz.
toothed whales, beaked whales, bottlenose
whales).
High-frequency (HF) cetaceans (true 275 Hz to 160 kHz.
porpoises, Kogia, river dolphins,
cephalorhynchid, Lagenorhynchus cruciger &
L. australis).
Phocid pinnipeds (PW) (underwater) (true 50 Hz to 86 kHz.
seals).
[[Page 29110]]
Otariid pinnipeds (OW) (underwater) (sea 60 Hz to 39 kHz.
lions and fur seals).
------------------------------------------------------------------------
* Represents the generalized hearing range for the entire group as a
composite (i.e., all species within the group), where individual
species' hearing ranges are typically not as broad. Generalized
hearing range chosen based on ~65 dB threshold from normalized
composite audiogram, with the exception for lower limits for LF
cetaceans (Southall et al. 2007) and PW pinniped (approximation).
The pinniped functional hearing group was modified from Southall et
al. (2007) on the basis of data indicating that phocid species have
consistently demonstrated an extended frequency range of hearing
compared to otariids, especially in the higher frequency range
(Hemil[auml] et al., 2006; Kastelein et al., 2009; Reichmuth and Holt,
2013).
For more detail concerning these groups and associated frequency
ranges, please see NMFS (2018) for a review of available information.
31 marine mammal species (25 cetacean and six pinniped (four otariid
and two phocid) species) have the reasonable potential to co-occur with
the planned survey activities. Please refer to Table 1. Of the cetacean
species that may be present, six are classified as low-frequency
cetaceans (i.e., all mysticete species), 15 are classified as mid-
frequency cetaceans (i.e., all delphinid and ziphiid species and the
sperm whale), and four are classified as high-frequency cetaceans
(i.e., porpoises and Kogia spp.).
Potential Effects of Specified Activities on Marine Mammals and Their
Habitat
The effects of underwater noise from L-DEO's geophysical survey
activities have the potential to result in behavioral harassment of
marine mammals in the vicinity of the survey area. The notice of
proposed IHA (85 FR 19580; April 7, 2020) included a discussion of the
effects of anthropogenic noise on marine mammals and the potential
effects of underwater noise from L-DEO's geophysical survey activities
on marine mammals and their habitat. That information and analysis is
incorporated by reference into this final IHA determination and is not
repeated here; please refer to the notice of proposed IHA (85 FR 19580;
April 7, 2020). The referenced information includes a summary and
discussion of the ways that the specified activity may impact marine
mammals and their habitat. Consistent with the analysis in our prior
Federal Register notices for similar L-DEO surveys and after
independently evaluating the analysis in L-DEO's application, we
determine that the survey is likely to result in the takes described in
the Estimated Take section of this document and that other forms of
take are not expected to occur.
The Estimated Take section later in this document includes a
quantitative analysis of the number of individuals that are expected to
be taken by this activity. The Negligible Impact Analysis and
Determination section considers the content of this section, the
Estimated Take section, and the Mitigation section, to draw conclusions
regarding the likely impacts of these activities on the reproductive
success or survivorship of individuals and how those impacts on
individuals are likely to impact marine mammal species or stocks.
Description of Active Acoustic Sound Sources
The notice of proposed IHA provided a brief technical background on
sound, on the characteristics of certain sound types, and on metrics
used in the proposal inasmuch as the information was relevant to the
specified activity and to a discussion of the potential effects of the
specified activity on marine mammals found later in this document.
Please see that document (85 FR 19580; April 7, 2020) for additional
information. For general information on sound and its interaction with
the marine environment, please see, e.g., Au and Hastings (2008);
Richardson et al. (1995); Urick (1983).
Estimated Take
This section provides an estimate of the number of incidental takes
authorized through this IHA, which will inform both NMFS' consideration
of ``small numbers'' and the negligible impact determination.
Harassment is the only type of take expected to result from these
activities. Except with respect to certain activities not pertinent
here, section 3(18) of the MMPA defines ``harassment'' as any act of
pursuit, torment, or annoyance, which (i) has the potential to injure a
marine mammal or marine mammal stock in the wild (Level A harassment);
or (ii) has the potential to disturb a marine mammal or marine mammal
stock in the wild by causing disruption of behavioral patterns,
including, but not limited to, migration, breathing, nursing, breeding,
feeding, or sheltering (Level B harassment).
Authorized takes will primarily be by Level B harassment, as use of
seismic airguns has the potential to result in disruption of behavioral
patterns for individual marine mammals. There is also some potential
for auditory injury (Level A harassment) for mysticetes and high
frequency cetaceans (i.e., porpoises, Kogia spp.). The mitigation and
monitoring measures are expected to minimize the severity of such
taking to the extent practicable.
As described previously, no serious injury or mortality is
anticipated or authorized for this activity. Below we describe how the
take is estimated.
Generally speaking, we estimate take by considering: (1) Acoustic
thresholds above which NMFS believes the best available science
indicates marine mammals will be behaviorally harassed or incur some
degree of permanent hearing impairment; (2) the area or volume of water
that will be ensonified above these levels in a day; (3) the density or
occurrence of marine mammals within these ensonified areas; and, (4)
and the number of days of activities. We note that while these basic
factors can contribute to a basic calculation to provide an initial
prediction of takes, additional information that can qualitatively
inform take estimates is also sometimes available (e.g., previous
monitoring results or average group size). Below, we describe the
factors considered here in more detail and present the take estimate.
Acoustic Thresholds
NMFS uses acoustic thresholds that identify the received level of
underwater sound above which exposed marine mammals would be reasonably
expected to be behaviorally harassed (equated to Level B harassment) or
to incur PTS of some degree (equated to Level A harassment).
Level B Harassment for non-explosive sources--Though significantly
driven by received level, the onset of behavioral disturbance from
anthropogenic noise exposure is also informed to varying degrees by
other factors related to the source (e.g., frequency, predictability,
duty cycle), the environment (e.g., bathymetry), and the receiving
animals (hearing, motivation, experience,
[[Page 29111]]
demography, behavioral context) and can be difficult to predict
(Southall et al., 2007, Ellison et al., 2012). NMFS uses a generalized
acoustic threshold based on received level to estimate the onset of
behavioral harassment. NMFS predicts that marine mammals are likely to
be behaviorally harassed in a manner we consider Level B harassment
when exposed to underwater anthropogenic noise above received levels of
120 dB re 1 microPascal ([mu]Pa) root mean square (rms) for continuous
(e.g., vibratory pile-driving, drilling) and above 160 dB re 1 [mu]Pa
(rms) for non-explosive impulsive (e.g., seismic airguns) or
intermittent (e.g., scientific sonar) sources. L-DEO's planned activity
includes the use of impulsive seismic sources. Therefore, the 160 dB re
1 [mu]Pa (rms) criteria is applicable for analysis of Level B
harassment.
Level A harassment for non-explosive sources--NMFS' Technical
Guidance for Assessing the Effects of Anthropogenic Sound on Marine
Mammal Hearing (Version 2.0) (Technical Guidance, 2018) identifies dual
criteria to assess auditory injury (Level A harassment) to five
different marine mammal groups (based on hearing sensitivity) as a
result of exposure to noise from two different types of sources
(impulsive or non-impulsive). L-DEO's planned seismic survey includes
the use of impulsive (seismic airguns) sources.
These thresholds are provided in the table below. The references,
analysis, and methodology used in the development of the thresholds are
described in NMFS 2018 Technical Guidance, which may be accessed at
https://www.fisheries.noaa.gov/national/marine-mammal-protection/marine-mammal-acoustic-technical-guidance.
Table 3--Thresholds Identifying the Onset of Permanent Threshold Shift
----------------------------------------------------------------------------------------------------------------
PTS onset acoustic thresholds \*\ (received level)
----------------------------------------------------------------------------------------------------------------
Hearing group Impulsive Non-impulsive
----------------------------------------------------------------------------------------------------------------
Low-Frequency (LF) Cetaceans........... Cell 1: Lpk,flat: 219 dB; Cell 2: LE,LF,24h: 199 dB.
LE,LF,24h: 183 dB..
Mid-Frequency (MF) Cetaceans........... Cell 3: Lpk,flat: 230 dB; Cell 4: LE,MF,24h: 198 dB.
LE,MF,24h: 185 dB.
High-Frequency (HF) Cetaceans.......... Cell 5: Lpk,flat: 202 dB; Cell 6: LE,HF,24h: 173 dB.
LE,HF,24h: 155 dB.
Phocid Pinnipeds (PW) (Underwater)..... Cell 7: Lpk,flat: 218 dB; Cell 8: LE,PW,24h: 201 dB.
LE,PW,24h: 185 dB.
Otariid Pinnipeds (OW) (Underwater).... Cell 9: Lpk,flat: 232 dB; Cell 10: LE,OW,24h: 219 dB.
LE,OW,24h: 203 dB.
----------------------------------------------------------------------------------------------------------------
* Dual metric acoustic thresholds for impulsive sounds: Use whichever results in the largest isopleth for
calculating PTS onset. If a non-impulsive sound has the potential of exceeding the peak sound pressure level
thresholds associated with impulsive sounds, these thresholds should also be considered.
Note: Peak sound pressure (Lpk) has a reference value of 1 [micro]Pa, and cumulative sound exposure level (LE)
has a reference value of 1[micro]Pa\2\s. In this Table, thresholds are abbreviated to reflect American
National Standards Institute standards (ANSI 2013). However, peak sound pressure is defined by ANSI as
incorporating frequency weighting, which is not the intent for this Technical Guidance. Hence, the subscript
``flat'' is being included to indicate peak sound pressure should be flat weighted or unweighted within the
generalized hearing range. The subscript associated with cumulative sound exposure level thresholds indicates
the designated marine mammal auditory weighting function (LF, MF, and HF cetaceans, and PW and OW pinnipeds)
and that the recommended accumulation period is 24 hours. The cumulative sound exposure level thresholds could
be exceeded in a multitude of ways (i.e., varying exposure levels and durations, duty cycle). When possible,
it is valuable for action proponents to indicate the conditions under which these acoustic thresholds will be
exceeded.
Ensonified Area
Here, we describe operational and environmental parameters of the
activity that will feed into identifying the area ensonified above the
acoustic thresholds, which include source levels and acoustic
propagation modeling.
L-DEO's modeling methodology is described in greater detail in the
IHA application (LGL 2019). The planned 2D survey will acquire data
using the 36-airgun array with a total discharge volume of 6,600 cubic
inches (in\3\) at a maximum tow depth of 12 m. L-DEO model results are
used to determine the 160-dBrms radius for the 36-airgun array in deep
water (>1,000 m) down to a maximum water depth of 2,000 m. Water depths
in the project area may be up to 4,400 m, but marine mammals are
generally not anticipated to dive below 2,000 m (Costa and Williams
1999). Received sound levels were predicted by L-DEO's model (Diebold
et al., 2010) which uses ray tracing for the direct wave traveling from
the array to the receiver and its associated source ghost (reflection
at the air-water interface in the vicinity of the array), in a
constant-velocity half-space (infinite homogeneous ocean layer,
unbounded by a seafloor). In addition, propagation measurements of
pulses from the 36-airgun array at a tow depth of 6 m have been
reported in deep water (approximately 1600 m), intermediate water depth
on the slope (approximately 600-1100 m), and shallow water
(approximately 50 m) in the Gulf of Mexico in 2007-2008 (Tolstoy et al.
2009; Diebold et al. 2010).
For deep and intermediate-water cases, the field measurements
cannot be used readily to derive Level A and Level B harassment
isopleths, as at those sites the calibration hydrophone was located at
a roughly constant depth of 350-500 m, which may not intersect all the
sound pressure level (SPL) isopleths at their widest point from the sea
surface down to the maximum relevant water depth for marine mammals of
~2,000 m. At short ranges, where the direct arrivals dominate and the
effects of seafloor interactions are minimal, the data recorded at the
deep and slope sites are suitable for comparison with modeled levels at
the depth of the calibration hydrophone. At longer ranges, the
comparison with the model--constructed from the maximum SPL through the
entire water column at varying distances from the airgun array--is the
most relevant.
In deep and intermediate-water depths, comparisons at short ranges
between sound levels for direct arrivals recorded by the calibration
hydrophone and model results for the same array tow depth are in good
agreement (Fig. 12 and 14 in Appendix H of NSF-USGS, 2011).
Consequently, isopleths falling within this domain can be predicted
reliably by the L-DEO model, although they may be imperfectly sampled
by measurements recorded at a single depth. At greater distances, the
calibration data show that seafloor-reflected and sub-seafloor-
refracted arrivals dominate, whereas the direct arrivals become weak
and/or incoherent. Aside from local topography effects, the region
around the critical distance is where the observed levels rise closest
to the model curve. However, the observed sound levels are found to
fall almost entirely below the
[[Page 29112]]
model curve. Thus, analysis of the Gulf of Mexico calibration
measurements demonstrates that although simple, the L-DEO model is a
robust tool for conservatively estimating isopleths. For deep water
(>1,000 m), L-DEO used the deep-water radii obtained from model results
down to a maximum water depth of 2,000 m.
A recent retrospective analysis of acoustic propagation from use of
the R/V Langseth sources during a 2012 survey off Washington (i.e., in
the same location) suggests that predicted (modeled) radii (using the
same approach as that used here) were 2-3 times larger than the
measured radii in shallow water. (Crone et al., 2014). Therefore,
because the modeled shallow-water radii were specifically demonstrated
to be overly conservative for the region in which the current survey is
planned, L-DEO used the received levels from multichannel seismic data
collected by the R/V Langseth during the 2012 survey to estimate Level
B harassment radii in shallow (<100 m) and intermediate (100-1,000 m)
depths (Crone et al., 2014). Streamer data in shallow water collected
in 2012 have the advantage of including the effects of local and
complex subsurface geology, seafloor topography, and water column
properties, and thus allow determination of radii more confidently than
using data from calibration experiments in the Gulf of Mexico.
The survey will acquire data with a four-string 6,600-in\3\ airgun
array at a tow depth of 12 m while the data collected in 2012 were
acquired with the same airgun array at a tow depth of 9 m. To account
for the differences in tow depth between the 2012 survey and the
planned 2021 survey, L-DEO calculated a scaling factor using the deep
water modeling (see Appendix D in L-DEO's IHA application). A scaling
factor of 1.15 was applied to the measured radii from the airgun array
towed at 9 m.
The estimated distances to the Level B harassment isopleth for the
R/V Langseth's 36-airgun array are shown in Table 4.
Table 4--Predicted Radial Distances to Isopleths Corresponding to Level B Harassment Threshold
----------------------------------------------------------------------------------------------------------------
Level B
Water depth harassment
Source and volume Tow depth (m) (m) zone (m) using
L-DEO model
----------------------------------------------------------------------------------------------------------------
36 airgun array, 6,600-in\3\.................................... 12 >1000 \a\ 6,733
100-1000 \b\ 9,468
<100 \b\ 12,650
----------------------------------------------------------------------------------------------------------------
\a\ Distance based on L-DEO model results.
\b\ Distance based on data from Crone et al. (2014).
Predicted distances to Level A harassment isopleths, which vary
based on marine mammal hearing groups, were calculated based on
modeling performed by L-DEO using the NUCLEUS source modeling software
program and the NMFS User Spreadsheet, described below. The acoustic
thresholds for impulsive sounds (e.g., airguns) contained in the
Technical Guidance were presented as dual metric acoustic thresholds
using both cumulative sound exposure level (SELcum) and peak
sound pressure metrics (NMFS 2018). As dual metrics, NMFS considers
onset of PTS (Level A harassment) to have occurred when either one of
the two metrics is exceeded (i.e., metric resulting in the largest
isopleth). The SELcum metric considers both level and
duration of exposure, as well as auditory weighting functions by marine
mammal hearing group. In recognition of the fact that the requirement
to calculate Level A harassment ensonified areas could be more
technically challenging to predict due to the duration component and
the use of weighting functions in the new SELcum thresholds,
NMFS developed an optional User Spreadsheet that includes tools to help
predict a simple isopleth that can be used in conjunction with marine
mammal density or occurrence to facilitate the estimation of take
numbers.
The values for SELcum and peak SPL for the R/V Langseth
airgun array were derived from calculating the modified far-field
signature (Table 5). The farfield signature is often used as a
theoretical representation of the source level. To compute the farfield
signature, the source level is estimated at a large distance below the
array (e.g., 9 km), and this level is back projected mathematically to
a notional distance of 1 m from the array's geometrical center.
However, when the source is an array of multiple airguns separated in
space, the source level from the theoretical farfield signature is not
necessarily the best measurement of the source level that is physically
achieved at the source (Tolstoy et al. 2009). Near the source (at short
ranges, distances <1 km), the pulses of sound pressure from each
individual airgun in the source array do not stack constructively, as
they do for the theoretical farfield signature. The pulses from the
different airguns spread out in time such that the source levels
observed or modeled are the result of the summation of pulses from a
few airguns, not the full array (Tolstoy et al. 2009). At larger
distances, away from the source array center, sound pressure of all the
airguns in the array stack coherently, but not within one time sample,
resulting in smaller source levels (a few dB) than the source level
derived from the farfield signature. Because the farfield signature
does not take into account the large array effect near the source and
is calculated as a point source, the modified farfield signature is a
more appropriate measure of the sound source level for distributed
sound sources, such as airgun arrays. L-DEO used the acoustic modeling
methodology as used for Level B harassment with a small grid step of 1
m in both the inline and depth directions. The propagation modeling
takes into account all airgun interactions at short distances from the
source, including interactions between subarrays, which are modeled
using the NUCLEUS software to estimate the notional signature and
MATLAB software to calculate the pressure signal at each mesh point of
a grid.
For a more complete explanation of this modeling approach, please
see ``Appendix A: Determination of Mitigation Zones'' in the IHA
application.
[[Page 29113]]
Table 5--Modeled Source Levels Based on Modified Farfield Signature for the 6,600-in \3\ Airgun Array
----------------------------------------------------------------------------------------------------------------
Phocid Otariid
Low frequency Mid frequency High frequency pinnipeds pinnipeds
cetaceans cetaceans cetaceans (underwater) (underwater)
(Lpk,flat: 219 (Lpk,flat: 230 (Lpk,flat: 202 (Lpk,flat: 218 (Lpk,flat: 232
dB; LE,LF,24h: dB; LE,MF,24h: dB; LE,HF,24h: dB; LE,HF,24h: dB; LE,HF,24h:
183 dB) 185 dB 155 dB) 185 dB) 203 dB)
----------------------------------------------------------------------------------------------------------------
6,600 in\3\ airgun array (Peak 252.06 252.65 253.24 252.25 252.52
SPLflat).......................
6,600 in\3\ airgun array 232.98 232.84 233.10 232.84 232.08
(SELcum).......................
----------------------------------------------------------------------------------------------------------------
In order to more realistically incorporate the Technical Guidance's
weighting functions over the seismic array's full acoustic band,
unweighted spectrum data for the R/V Langseth's airgun array (modeled
in 1 Hz bands) was used to make adjustments (dB) to the unweighted
spectrum levels, by frequency, according to the weighting functions for
each relevant marine mammal hearing group. These adjusted/weighted
spectrum levels were then converted to pressures ([mu]Pa) in order to
integrate them over the entire broadband spectrum, resulting in
broadband weighted source levels by hearing group that could be
directly incorporated within the User Spreadsheet (i.e., to override
the Spreadsheet's more simple weighting factor adjustment). Using the
User Spreadsheet's ``safe distance'' methodology for mobile sources
(described by Sivle et al., 2014) with the hearing group-specific
weighted source levels, and inputs assuming spherical spreading
propagation and source velocities (4.2 knots) and shot intervals (37.5
m) specific to the planned survey, potential radial distances to
auditory injury zones were then calculated for SELcum
thresholds.
Inputs to the User Spreadsheets in the form of estimated SLs are
shown in Table 5. User Spreadsheets used by L-DEO to estimate distances
to Level A harassment isopleths for the 36-airgun array for the surveys
are shown in Table A-3 in Appendix A of the IHA application. Outputs
from the User Spreadsheets in the form of estimated distances to Level
A harassment isopleths for the survey are shown in Table 6. As
described above, NMFS considers onset of PTS (Level A harassment) to
have occurred when either one of the dual metrics (SELcum
and Peak SPLflat) is exceeded (i.e., metric resulting in the
largest isopleth).
Table 6--Modeled Radial Distances (m) to Isopleths Corresponding to Level A Harassment Thresholds
--------------------------------------------------------------------------------------------------------------------------------------------------------
Level A harassment zone (m)
Source (volume) Threshold -------------------------------------------------------------------------------
LF cetaceans MF cetaceans HF cetaceans Phocids Otariids
--------------------------------------------------------------------------------------------------------------------------------------------------------
36-airgun array (6,600 in\3\)............. SELcum...................... 426.9 0 1.3 13.9 0
Peak........................ 38.9 13.6 268.3 43.7 10.6
--------------------------------------------------------------------------------------------------------------------------------------------------------
Note that because of some of the assumptions included in the
methods used (e.g., stationary receiver with no vertical or horizontal
movement in response to the acoustic source), isopleths produced may be
overestimates to some degree, which will ultimately result in some
degree of overestimation of Level A harassment. However, these tools
offer the best way to predict appropriate isopleths when more
sophisticated modeling methods are not available, and NMFS continues to
develop ways to quantitatively refine these tools and will
qualitatively address the output where appropriate. For mobile sources,
such as this seismic survey, the User Spreadsheet predicts the closest
distance at which a stationary animal would not incur PTS if the sound
source traveled by the animal in a straight line at a constant speed.
Auditory injury is unlikely to occur for mid-frequency cetaceans,
otariid pinnipeds, and phocid pinnipeds given very small modeled zones
of injury for those species (up to 43.7 m), in context of distributed
source dynamics. The source level of the array is a theoretical
definition assuming a point source and measurement in the far-field of
the source (MacGillivray, 2006). As described by Caldwell and Dragoset
(2000), an array is not a point source, but one that spans a small
area. In the far-field, individual elements in arrays will effectively
work as one source because individual pressure peaks will have
coalesced into one relatively broad pulse. The array can then be
considered a ``point source.'' For distances within the near-field,
i.e., approximately 2-3 times the array dimensions, pressure peaks from
individual elements do not arrive simultaneously because the
observation point is not equidistant from each element. The effect is
destructive interference of the outputs of each element, so that peak
pressures in the near-field will be significantly lower than the output
of the largest individual element. Here, the relevant peak isopleth
distances for these three hearing groups would in all cases be expected
to be within the near-field of the array where the definition of source
level breaks down. Therefore, actual locations within this distance of
the array center where the sound level exceeds the relevant criteria
would not necessarily exist. In general, Caldwell and Dragoset (2000)
suggest that the near-field for airgun arrays is considered to extend
out to approximately 250 m. For full discussion of these concepts,
please see our notice of proposed IHA (85 FR 19580; April 7, 2020).
In consideration of the received sound levels in the near-field as
described above, we expect the potential for Level A harassment of mid-
frequency cetaceans, otariid pinnipeds, and phocid pinnipeds to be de
minimis, even before the likely moderating effects of aversion and/or
other compensatory behaviors (e.g., Nachtigall et al., 2018) are
considered. We do not believe that Level A harassment is a likely
outcome for any mid-frequency cetacean, otariid pinniped, or phocid
pinniped and have not authorized any Level A harassment for these
species.
Marine Mammal Occurrence
In this section we provide the information about the presence,
density,
[[Page 29114]]
and group dynamics of marine mammals that will inform the take
calculations.
Extensive systematic aircraft- and ship-based surveys have been
conducted for marine mammals in offshore waters of Oregon and
Washington (e.g., Bonnell et al., 1992; Green et al., 1992, 1993;
Barlow 1997, 2003; Barlow and Taylor 2001; Calambokidis and Barlow
2004; Barlow and Forney 2007; Forney 2007; Barlow 2010). Ship surveys
for cetaceans in slope and offshore waters of Oregon and Washington
were conducted by NMFS' Southwest Fisheries Science Center (SWFSC) in
1991, 1993, 1996, 2001, 2005, 2008, and 2014 and synthesized by Barlow
(2016); these surveys were conducted from the coastline up to ~556 km
from shore from June or August to November or December. These data were
used by the SWFSC to develop spatial models of cetacean densities for
the California Current Ecosystem (CCE). Systematic, offshore, at-sea
survey data for pinnipeds are more limited (e.g., Bonnell et al., 1992;
Adams et al., 2014). In British Columbia, several systematic surveys
have been conducted in coastal waters (e.g., Williams and Thomas 2007;
Ford et al., 2010a; Best et al., 2015; Harvey et al., 2017). Surveys in
coastal as well as offshore waters were conducted by DFO during 2002 to
2008; however, little effort occurred off the west coast of Vancouver
Island during late spring/summer (Ford et al., 2010). Density estimates
for the survey areas outside the U.S. EEZ, i.e., in the Canadian EEZ,
were not readily available, so density estimates for U.S. waters were
applied to the entire survey area.
The U.S. Navy primarily used SWFSC habitat-based cetacean density
models to develop a marine species density database (MSDD) for the
Northwest Training and Testing (NWTT) Study Area for NWTT Phase III
activities (U.S. Navy 2019a), which encompasses the U.S. portion of the
survey area. For several cetacean species, the Navy updated densities
estimated by line-transect surveys or mark-recapture studies (e.g.,
Barlow 2016). These methods usually produce a single value for density
that is an averaged estimate across very large geographical areas, such
as waters within the U.S. EEZ off California, Oregon, and Washington
(referred to as a ``uniform'' density estimate). This is the general
approach applied in estimating cetacean abundance in the NMFS stock
assessment reports. The disadvantage of these methods is that they do
not provide spatially- or temporally-explicit density information. More
recently, a newer method called spatial habitat modeling has been used
to estimate cetacean densities that address some of these shortcomings
(e.g., Barlow et al., 2009; Becker et al., 2010; 2012a; 2014; Becker et
al., 2016; Ferguson et al., 2006; Forney et al., 2012; 2015; Redfern et
al., 2006). (Note that spatial habitat models are also referred to as
``species distribution models'' or ``habitat-based density models.'')
These models estimate density as a continuous function of habitat
variables (e.g., sea surface temperature, seafloor depth) and thus,
within the study area that was modeled, densities can be predicted at
all locations where these habitat variables can be measured or
estimated. Spatial habitat models therefore allow estimates of cetacean
densities on finer scales (spatially and temporally) than traditional
line-transect or mark-recapture analyses.
The methods used to estimate pinniped at-sea densities are
typically different than those used for cetaceans, because pinnipeds
are not limited to the water and spend a significant amount of time on
land (e.g., at rookeries). Pinniped abundance is generally estimated
via shore counts of animals on land at known haulout sites or by
counting number of pups weaned at rookeries and applying a correction
factor to estimate the abundance of the population (for example Harvey
et al., 1990; Jeffries et al., 2003; Lowry, 2002; Sepulveda et al.,
2009). Estimating in-water densities from land-based counts is
difficult given the variability in foraging ranges, migration, and
haulout behavior between species and within each species, and is driven
by factors such as age class, sex class, breeding cycles, and seasonal
variation. Data such as age class, sex class, and seasonal variation
are often used in conjunction with abundance estimates from known
haulout sites to assign an in-water abundance estimate for a given
area. The total abundance divided by the area of the region provides a
representative in-water density estimate for each species in a
different location. In addition to using shore counts to estimate
pinniped density, traditional line-transect derived estimates are also
used, particularly in open ocean areas.
The Navy's MSDD is currently the most comprehensive compendium for
density data available for the CCE. However, data products are
currently not publically available for the database; thus, in this
analysis the Navy's data products were used only for species for which
density data were not available from an alternative spatially-explicit
model (e.g., pinnipeds, Kogia spp., minke whales, sei whales, gray
whales, short-finned pilot whales, and Northern Resident, transient,
and offshore killer whales). For these species, a geographic
information system (GIS) was used to determine the areas expected to be
ensonified in each density category (i.e., distance from shore). For
pinnipeds, the densities from the Navy's MSDD were corrected by
projecting the most recent population growth and updated population
estimates to 2020, when available. Where available, the appropriate
seasonal density estimate from the MSDD was used in the estimation here
(i.e., summer).
NMFS obtained data products from the Navy for densities of Southern
Resident killer whales in the NWTT Offshore Study Area. The modeled
density estimates were available on the scale of 1 km by 1 km grid
cells. The densities from grid cells overlapping the ensonified area in
each depth category were multiplied by the corresponding area to
estimate potential exposures (Table 9).
For most other species, (i.e., humpback, blue, fin, sperm, Baird's
beaked, and other small beaked whales; bottlenose, striped, common,
Pacific white-sided, Risso's and northern right whale dolphins; and
Dall's porpoise), habitat-based density models from Becker et al.
(2016) were used. Becker et al. (2016) used seven years of SWFSC
cetacean line-transect survey data collected between 1991 and 2009 to
develop predictive habitat-based models of cetacean densities in the
CCE. The modeled density estimates were available on the scale of 7 km
by 10 km grid cells. The densities from all grid cells overlapping the
ensonified areas within each water depth category were averaged to
calculate a zone-specific density for each species.
Becker et al. (2016) did not develop a density model for the harbor
porpoise, so densities from Forney et al. (2014) were used for that
species. Forney et al. (2014) presented estimates of harbor porpoise
abundance and density along the Pacific coast of California, Oregon,
and Washington based on aerial line-transect surveys conducted between
2007 and 2012. Separate density estimates were provided for harbor
porpoises in Oregon south of 45[deg] N and Oregon/Washington north of
45[deg] N (i.e., within the boundaries of the Northern California/
Southern Oregon and Northern Oregon/Washington Coast stocks), so stock-
specific take estimates were generated (Forney et al., 2014).
Background information on the density calculations for each
species/guild (if different from the general methods from the Navy's
MSDD, Becker et al. (2016), or Forney et al. (2014)
[[Page 29115]]
described above) are reported here. Density estimates for each species/
guild (aside from Southern Resident killer whales, which are discussed
separately) are found in Table 7.
Gray Whale
DeAngelis et al. (2011) developed a migration model that provides
monthly, spatially explicit predictions of gray whale abundance along
the U.S. West Coast from December through June. These monthly density
estimates apply to a ``main migration corridor'' that extends from the
coast to 10 km offshore. A zone from the main migration corridor out to
47 km offshore is designated as an area of ``potential presence''. To
derive a density estimate for this area the Navy assumed that 1 percent
of the population could be within the 47-km ``potential presence'' area
during migration. Given the 2014 stock assessment population estimate
of 20,990 animals (Carretta et al., 2017b), approximately 210 gray
whales may use this corridor. Assuming the migration wave lasts 30
days, then 7 whales on average on any one day could occur in the
``potential presence'' area. The area from the main migration route
offshore to 47 km within the NWTT study area = 45,722.06 km\2\, so
density within this zone = 0.00015 whales/km\2\. From July-November,
gray whale occurrence off the coast is expected to consist primarily of
whales belonging to the Pacific Coast Feeding Group (PCFG).
Calambokidis et al. (2012) provided an updated analysis of the
abundance of the PCFG whales in the Pacific Northwest and recognized
that this group forms a distinct feeding aggregation. For the purposes
of establishing density, the Navy assumed that from July 1 to November
30 all the 209 PCFG whales could be present off the coast in the
Northern California/Oregon/Washington region (this accounts for the
potential that some PCFG whales may be outside of the area but that
there also may be some non-PCFG whales in the region as noted by
Calambokidis et al.(2012)). Given that the PCFG whales are found
largely nearshore, it was assumed that all the whales could be within
10 km of the coast. To capture the potential presence of whales further
offshore (e.g., Oleson et al., 2009), it was assumed that a percentage
of the whales could be present from 10 km out to 47 km off the coast;
the 47 km outer limit is consistent with the DeAngelis et al. (2011)
migration model. Since 77 percent of the PCFG sightings were within the
nearshore BIAs (Calambokidis et al., 2015), it was assumed that 23
percent (48 whales) could potentially be found further offshore. Two
strata were thus developed for the July-November gray whale density
layers: (1) From the coast to 10 km offshore, and (2) from 10 km to 47
km offshore. The density was assumed to be 0 animals/km\2\ for areas
offshore of 47 km.
Small Beaked Whale Guild
NMFS has developed habitat-based density models for a small beaked
whale guild in the CCE (Becker et al., 2012b; Forney et al., 2012). The
small beaked whale guild includes Cuvier's beaked whale and beaked
whales of the genus Mesoplodon, including Blainville's beaked whale,
Hubbs' beaked whale, and Stejneger's beaked whale. NMFS SWFSC developed
a CCE habitat-based density model for the small beaked whale guild
which provides spatially explicit density estimates off the U.S. West
Coast for summer and fall based on survey data collected between 1991
and 2009 (Becker et al., 2016).
False Killer Whale
False killer whales were not included in the Navy's MSDD, as they
are very rarely encountered in the northeast Pacific. Density estimates
for false killer whales were also not presented in Barlow (2016) or
Becker et al. (2016), as no sightings occurred during surveys conducted
between 1986 and 2008 (Ferguson and Barlow 2001, 2003; Forney 2007;
Barlow 2003, 2010). One sighting was made off of southern California
during 2014 (Barlow 2016). One pod of false killer whales occurred in
Puget Sound for several months during the 1990s (Navy 2015). Based on
the available information, NMFS does not believe false killer whales
are expected to be taken, but L-DEO has requested take of this species
so we are acting on that request.
Killer Whale
A combination of movement data (from both visual observations and
satellite-linked tags) and detections from stationary acoustic
recorders have provided information on the offshore distribution of the
Southern Resident stock (Hanson et al., 2018). These data have been
used to develop state space movement models that provide estimates of
the probability of occurrence (or relative density) of Southern
Residents in the offshore study area in winter and spring (Hanson et
al., 2018). Since the total number of animals that comprise each pod is
known, the relative density estimates were used in association with the
total abundance estimates to derive absolute density estimates (i.e.,
number of animals/km\2\) within the offshore study area. Given that the
K and L pods were together during all but one of the satellite tag
deployments, Hanson et al. (2018) developed two separate state space
models, one for the combined K and L pods and one for the J pod. The
absolute density estimates were thus derived based on a total of 53
animals for the K and L pods (K pod = 18 animals, L pod = 35 animals)
and 22 animals for the J pod (Center for Whale Research, 2019). Of the
three pods, the K and L pods appear to have a more extensive and
seasonally variable offshore coastal distribution, with rare sightings
as far south as Monterey Bay, California (Carretta et al., 2019; Ford
et al., 2000; Hanson et al., 2018). Two seasonal density maps were thus
developed for the K and L pods, one representing their distribution
from January to May (the duration of the tag deployments), and another
representing their distribution from June to December. Based on
stationary acoustic recording data, their excursions offshore from June
to December are more limited and typically do not extend south of the
Columbia River (Emmons 2019). To provide more conservative density
estimates, the Navy extended the June to December distribution to just
south of the Columbia River and redistributed the total K and L
populations (53 animals) within the more limited range boundaries. A
conservative approach was also adopted for the J pod since the January
to May density estimates were assumed to represent annual occurrence
patterns, despite information that this pod typically spends more time
in the inland waters during the summer and fall (Carretta et al., 2019;
Ford et al., 2000; Hanson et al., 2018). Further, for all seasons the
Navy assumed that all members of the three pods of Southern Residents
could occur either offshore or in the inland waters, so the total
number of animals in the stock was used to derive density estimates for
both study areas.
Due to the difficulties associated with reliably distinguishing the
different stocks of killer whales from at sea sightings, and
anticipated equal likelihood of occurrence among the stocks, density
estimates for the rest of the stocks are presented as a whole (i.e.,
includes the Offshore, West Coast Transient, and Northern Resident
stocks). Barlow (2016) presents density values for killer whales in the
CCE, with separate densities for waters off Oregon/Washington (i.e.,
north of the California border) and Northern California for summer/
fall. Density data are not available for the NWTT Offshore area
northwest of the CCE study area, so data
[[Page 29116]]
from the SWFSC Oregon/Washington area were used as representative
estimates. These values were used to represent density year-round.
Short-Finned Pilot Whale
Along the U.S. West Coast, short-finned pilot whales were once
common south of Point Conception, California (Carretta et al., 2017b;
Reilly & Shane, 1986), but now sightings off the U.S. West Coast are
infrequent and typically occur during warm water years (Carretta et
al., 2017b). Stranding records for this species from Oregon and
Washington waters are considered to be beyond the normal range of this
species rather than an extension of its range (Norman et al., 2004).
Density values for short-finned pilot whales are available for the
SWFSC Oregon/Washington and Northern California strata for summer/fall
(Barlow, 2016). Density data are not available for the NWTT Offshore
area northwest of the SWFSC strata, so data from the SWFSC Oregon/
Washington stratum were used as representative estimates. These values
were used to represent density year-round.
Guadalupe Fur Seal
Adult male Guadalupe fur seals are expected to be ashore at
breeding areas over the summer, and are not expected to be present
during the planned geophysical survey (Caretta et al., 2017b; Norris
2017b). Additionally, breeding females are unlikely to be present
within the Offshore Study Area as they remain ashore to nurse their
pups through the fall and winter, making only short foraging trips from
rookeries (Gallo-Reynoso et al., 2008; Norris 2017b; Yochem et al.,
1987). To estimate the total abundance of Guadalupe fur seals, the Navy
adjusted the population reported in the 2016 SAR (Caretta et al.,
2017b) of 20,000 seals by applying the average annual growth rate of
7.64 percent over the seven years between 2010 and 2017. The resulting
2017 projected abundance was 33,485 fur seals. Using the reported
composition of the breeding population of Guadalupe fur seals (Gallo-
Reynoso 1994) and satellite telemetry data (Norris 2017b), the Navy
established seasonal and demographic abundances of Guadalupe fur seals
expected to occur within the Offshore Study Area.
The distribution of Guadalupe fur seals in the Offshore Study Area
was stratified by distance from shore (or water depth) to reflect their
preferred pelagic habitat (Norris, 2017a). Ten percent of fur seals in
the Study Area are expected to use waters over the continental shelf
(approximated as waters with depths between 10 and 200 m). A depth of
10 m is used as the shoreward extent of the shelf (rather than
extending to shore), because Guadalupe fur seals in the Offshore Study
Area are not expected to haul out and would not be likely to come close
to shore. All fur seals (i.e., 100 percent) would use waters off the
shelf (beyond the 200-m isobath) out to 300 km from shore, and 25 of
percent of fur seals would be expected to use waters between 300 and
700 km from shore (including the planned geophysical survey area). The
second stratum (200 m to 300 km from shore) is the preferred habitat
where Guadalupe fur seals are most likely to occur most of the time.
Individuals may spend a portion of their time over the continental
shelf or farther than 300 km from shore, necessitating a density
estimate for those areas, but all Guadalupe fur seals would be expected
to be in the central stratum most of the time, which is the reason 100
percent is used in the density estimate for the central stratum
(Norris, 2017a). Spatial areas for the three strata were estimated in a
GIS and used to calculate the densities.
The Navy's density estimate for Guadalupe fur seals projected the
abundance through 2017, while L-DEO's survey was initially planned to
occur in 2020. Therefore, we have projected the abundance estimate in
2020 using the abundance estimate (34,187 animals) and population
growth rate (5.9 percent) presented in the 2019 draft SARs (Caretta et
al., 2019). This calculation yielded an increased density estimate of
Guadalupe fur seals than what was presented in the Navy's MSDD.
Northern Fur Seal
The Navy estimated the abundance of northern fur seals from the
Eastern Pacific stock and the California breeding stock that could
occur in the NWTT Offshore Study Area by determining the percentage of
time tagged animals spent within the Study Area and applying that
percentage to the population to calculate an abundance for adult
females, juveniles, and pups independently on a monthly basis. Adult
males are not expected to occur within the Offshore Study Area and the
planned survey area during the planned geophysical survey as they spend
the summer ashore at breeding areas in the Bering Sea and San Miguel
Island (Caretta et al., 2017b). Using the monthly abundances of fur
seals within the Offshore Study Area, the Navy created strata to
estimate the density of fur seals within three strata: 22 km to 70 km
from shore, 70 km to 130 km from shore, and 130 km to 463 km from shore
(the western Study Area boundary). L-DEO's planned survey is 423 km
from shore at the closest point. Based on satellite tag data and
historic sealing records (Olesiuk 2012; Kajimura 1984), the Navy
assumed 25 percent of the population present within the overall
Offshore Study Area may be within the 130 km to 463 km stratum.
The Navy's density estimates for northern fur seals did not include
the latest abundance data collected from Bogoslof Island or the
Pribilof Islands in 2015 and 2016. Incorporating the latest pup counts
yielded a slight decrease in the population abundance estimate, which
resulted in a slight decrease in the estimated densities of northern
fur seals in each depth stratum.
Steller Sea Lion
The Eastern stock of Steller sea lions has established rookeries
and breeding sites along the coasts of California, Oregon, British
Columbia, and southeast Alaska. A new rookery was recently discovered
along the coast of Washington at the Carroll Island and Sea Lion Rock
complete, where more than 100 pups were born in 2015 (Muto et al.,
2017; Wiles 2015). The 2017 SAR did not factor in pups born at sites
along the Washington coast (Muto et al., 2017). Considering that pups
have been observed at multiple breeding sites since 2013, specifically
at the Carroll Island and Sea Lion Rock complex (Wiles 2015), the 2017
SAR abundance of 1,407 Steller sea lions (non-pups only) for Washington
underestimates the total population. Wiles (2015) estimates that up to
2,500 Steller sea lions are present along the Washington coast, which
is the abundance estimate used by the Navy to calculate densities.
Approximately 30,000 Steller sea lions occur along the coast of British
Columbia, but these animals were not included in the Navy's
calculations. The Navy applied the annual growth rate for each regional
population (California, Oregon, Washington, and southeast Alaska),
reported in Muto et al. (2017), to each population to estimate the
stock abundance in 2017, and we further projected the population
estimate in 2020. The Commission noted that we had used the non-pup
population growth rate to project the population of both non-pups and
pups. Additionally, the Commission suggested we include the British
Columbia population in our projections. We have revised the population
projections and resulting density estimates accordingly.
Sea lions from northern California and southern Oregon rookeries
migrate north in September following the breeding season and winter in
northern
[[Page 29117]]
Oregon, Washington, and British Columbia waters. They disperse widely
following the breeding season, which extends from May through July,
likely in search of different types of prey, which may be concentrated
in areas where oceanic fronts and eddies persist (Fritz et al., 2016;
Jemison et al., 2013; Lander et al., 2010; Muto et al., 2017; NMFS
2013; Raum-Suryan et al., 2004; Sigler et al., 2017). Adults depart
rookeries in August. Females with pups remain within 500 km of their
rookery during the non-breeding season and juveniles of both sexes and
adult males disperse more widely but remain primarily over the
continental shelf (Wiles 2015).
Based on 11 sightings along the Washington coast, Steller sea lions
were observed at an average distance of 13 km from shore and 35 km from
the shelf break (defined as the 200-m isobath) (Oleson et al., 2009).
The mean water depth in the area of occurrence was 42 m, and surveys
were conducted out to approximately 60 km from shore. Wiles (2015)
estimated that Steller sea lions off the Washington coast primarily
occurred within 60 km of shore, favoring habitats over the continental
shelf. However, a few individuals may travel several hundred km
offshore (Merrick & Loughlin 1997; Wiles 2015). Based on these
occurrence and distribution data, two strata were used to estimate
densities for Steller sea lions. The spatial area extending from shore
to the 200-m isobath (i.e., over the continental shelf) was defined as
one stratum, and the second stratum extended from the 200-m isobath to
300 km from shore to account for reports of Steller sea lions occurring
several hundred km offshore. Ninety-five percent of the population of
Steller sea lions occurring in the NWTT Study Area were distributed
over the continental shelf stratum and the remaining five percent were
assumed to occur between the 200-m isobath and 300 km from shore.
The percentage of time Steller sea lions spend hauled out varies by
season, life stage, and geographic location. To calculated densities in
the Study Area, the projected population abundance was adjusted to
account for time spent hauled out. In spring and winter, sea lions were
estimated to be in the water 64 percent of the time. In summer, when
sea lions are more likely to be in the water, the percent of animals
estimated to be in the water was increased to 76 percent, and in fall,
sea lions were anticipated to be in the water 53 percent of the time
(U.S. Navy 2019). Densities were calculated for each depth stratum off
Washington and off Oregon.
California Sea Lion
Seasonal at-sea abundance of California sea lions is estimated from
strip transect survey data collected offshore along the California
coastline (Lowry & Forney 2005). The survey area was divided into seven
strata, labeled A through G. Abundance estimates from the two
northernmost strata (A and B) were used to estimate the abundance of
California sea lions occurring in the NWTT Study Area. While the
northernmost stratum (A) only partially overlaps with the Study Area,
this approach conservatively assumes that all sea lions from the two
strata would continue north into the Study Area.
The majority of male sea lions would be expected in the NWTT Study
Area from August to mid-June (Wright et al., 2010). In summer, males
are expected to be at breeding sites off of Southern California. In-
water abundance estimates of adult and sub-adult males in strata A and
B were extrapolated to estimate seasonal densities in the Study Area.
Approximately 3,000 male California sea lions are known to pass through
the NWTT Study Area in August as they migrate northward to the
Washington coast and inland waters (DeLong 2018a; Wright et al., 2010).
Nearly all male sea lions are expected to be on or near breeding sites
off California in July (DeLong et al., 2017; Wright et al., 2010). An
estimate of 3,000 male sea lions is used for the month of August.
Projected 2017 seasonal abundance estimates were derived by applying an
annual growth rate of 5.4 percent (Caretta et al., 2017b) between 1999
and 2017 to the abundance estimates from Lowry & Forney (2005).
The strata used to calculated densities in the NWTT Study Area were
based on distribution data from Wright et al. (2010) and Lowry & Forney
(2005) indicating that approximately 90 percent of California sea lions
occurred within 40 km of shore and 100 percent of sea lions were within
70 km of shore. A third stratum was added that extends from shore to
450 km offshore to account for anomalous conditions, such as changes in
sea surface temperature and upwelling associated with El Ni[ntilde]o,
during which California sea lions have been encountered farther from
shore, presumably seeking prey (DeLong & Jeffries 2017; Weise et al.,
2010). The Navy calculated densities for each stratum (0 to 40 km, 40
to 70 km, and 0 to 450 km) for each season, spring, summer, fall, and
winter, but noted that the density of California sea lions in all
strata for June and July was 0 animals/km\2\. The Navy's calculated
densities for August were conservatively used here, as sightings of
California sea lions have been reported on the continental shelf in
June and July (Adams et al., 2014).
Northern Elephant Seal
The most recent surveys supporting the abundance estimate for
northern elephant seals were conducted in 2010 (Caretta et al., 2017b).
By applying the average growth rate of 3.8 percent per year for the
California breeding stock over the 7 years from 2010 to 2017, the Navy
calculated a projected 2017 abundance estimate of 232,399 elephant
seals (Caretta et al., 2017b; Lowry et al., 2014). Male and female
distributions at sea differ both seasonally and spatially. Pup counts
reported by Lowry et al., (2014) and life tables compiled by Condit et
al., (2014) were used to determine the proportion of males and females
in the population, which was estimated to be 56 percent female and 44
percent male. Females are assumed to be at sea 100 percent of the time
within their seasonal distribution area in fall and summer (Robinson et
al., 2012). Males are at sea approximately 90 percent of the time in
fall and spring, remain ashore through the entire winter, and spend one
month ashore to molt in the summer (i.e., are at sea 66 percent of the
summer). Monthly distribution maps produced by Robinson et al. (2012)
showing the extent of foraging areas used by satellite tagged female
elephant seals were used to estimate the spatial areas to calculate
densities. Although the distributions were based on tagged female
seals, Le Boeuf et al. (2000) and Simmons et al. (2007) reported
similar tracks by males over broad spatial scales. The spatial areas
representing each monthly distribution were calculating using GIS and
then averaged to produce seasonally variable areas and resulting
densities.
As with other pinniped species above, NMFS used the population
growth rate reported by Caretta et al. (2017b) to project the estimated
abundance in 2020. The resulting population estimate and estimated
densities increased from those presented in the Navy's MSDD (U.S. Navy
2019).
Harbor Seal
Only harbor seals from the Washington and Oregon Coast stock would
be expected to occur in the survey area. The most recent abundance
estimate for the Washington and Oregon Coast stock is 24,732 harbor
seals (Caretta et al., 2017b). Survey data supporting this abundance
estimate are from 1999, which exceeds the 8 year limit beyond which
NMFS will not confirm abundance in a SAR (Caretta et
[[Page 29118]]
al., 2017b). However, based on logistical growth curves for the
Washington and Oregon Coast stock that leveled off in the early 1990s
(Caretta et al., 2017b) and unpublished data from the Washington
Department of Fish and Wildlife (DeLong & Jeffries 2017), an annual
growth rate of 0 percent (i.e., the population has remained stable) was
applied such that the 2017 abundance estimate used by the Navy, and
2020 estimate used here, was still 24,732 harbor seals. A haulout
factor of 33 percent was used to account for hauled-out seals (i.e.,
seals are estimated to be in the water 33 percent of the time) (Huber
et al., 2001). A single stratum extending from shore to 30 km offshore
was used to define the spatial area used by the Navy for calculating
densities off Washington and Oregon (Bailey et al., 2014; Oleson et
al., 2009).
No significant new information is available since we published the
notice of proposed IHA, and no changes have been made, other than those
described in the Changes from the Proposed IHA section, provided
previously in this document.
Marine Mammal Densities
Densities for most species are presented by depth stratum (shallow,
intermediate, and deep water) in Table 7. For species where densities
are available based on other categories (gray whale, harbor porpoise,
northern fur seal, Guadalupe fur seal, California sea lion, Steller sea
lion), category definitions are provided in the footnotes of Table 7.
Table 7--Marine Mammal Density Values in the Survey Area
----------------------------------------------------------------------------------------------------------------
Estimated density (#/km\2\)
------------------------------------------------
Species Intermediate Reference
Shallow <100 m/ 100-1,000 m/ Deep >1,000 m/
Category 1 Category 2 Category 3
----------------------------------------------------------------------------------------------------------------
LF Cetaceans:
Humpback whale.................... 0.0052405 0.0040200 0.0004830 Becker et al. (2016)
Blue whale........................ 0.0020235 0.0010518 0.0003576 Becker et al. (2016)
Fin whale......................... 0.0002016 0.0009306 0.0013810 Becker et al. (2016)
Sei whale......................... 0.0004000 0.0004000 0.0004000 U.S. Navy (2019)
Minke whale....................... 0.0013000 0.0013000 0.0013000 U.S. Navy (2019)
Gray whale a...................... 0.0155000 0.0010000 N.A. U.S. Navy (2019)
MF Cetaceans:
Sperm whale....................... 0.0000586 0.0001560 0.0013023 Becker et al. (2016)
Baird's beaked whale.............. 0.0001142 0.0002998 0.0014680 Becker et al. (2016)
Small beaked whale................ 0.0007878 0.0013562 0.0039516 Becker et al. (2016)
Bottlenose dolphin................ 0.0000007 0.0000011 0.0000108 Becker et al. (2016)
Striped dolphin................... 0.0000000 0.0000025 0.0001332 Becker et al. (2016)
Short-beaked common dolphin....... 0.0005075 0.0010287 0.0016437 Becker et al. (2016)
Pacific white-sided dolphin....... 0.0515230 0.0948355 0.0700595 Becker et al. (2016)
Northern right-whale dolphin...... 0.0101779 0.0435350 0.0621242 Becker et al. (2016)
Risso's dolphin................... 0.0306137 0.0308426 0.0158850 Becker et al. (2016)
False killer whale b.............. N.A. N.A. N.A.
Killer whale (all stocks except 0.0009200 0.0009200 0.0009200 U.S. Navy (2019)
Southern Residents).
Short-finned pilot whale.......... 0.0002500 0.0002500 0.0002500 U.S. Navy (2019)
HF Cetaceans:
Pygmy/dwarf sperm whale........... 0.0016300 0.0016300 0.0016300 U.S. Navy (2019)
Dall's porpoise................... 0.1450767 0.1610605 0.1131827 Becker et al. (2016)
Harbor porpoise c................. 0.6240000 0.4670000 N.A. Forney et al. (2014)
Otariids:
Northern fur seal d............... 0.0113247 0.1346441 0.0103424 U.S. Navy (2019)
Guadalupe fur seal e.............. 0.0234772 0.0262595 N.A. U.S. Navy (2019)
California sea lion f............. 0.0288000 0.0037000 0.0065000 U.S. Navy (2019)
Steller sea lion g................ 0.4804893 0.0035811 N.A. U.S. Navy (2019)
Phocids:
Northern elephant seal............ 0.0345997 0.0345997 0.0345997 U.S. Navy (2019)
Harbor seal h..................... 0.3424000 N.A. N.A. U.S. Navy (2019)
----------------------------------------------------------------------------------------------------------------
a Category 1 = 0-10 km offshore, Category 2 = 10-47 km offshore (U.S. Navy 2019).
b No density estimates available for false killer whales in the survey area, take is based on mean group size
from Mobley et al. (2000).
c Category 1 = South of 45[deg] N, Category 2 = North of 45[deg] N (Forney et al., 2014).
d Category 1 = 22-70 km offshore, Category 2 = 70-130 km offshore, Category 3 = 130-463 km offshore (U.S. Navy
2019).
e Category 1 = 10-200 m depth, Category 2 = 200 m depth-300 km offshore; No stock-specific densities are
available so these densities were applied to northern fur seals as a species (U.S. Navy 2019).
f Category 1 = 0-40 km offshore, Category 2 = 40-70 km offshore, Category 3 = 0-450 km offshore (U.S. Navy
2019).
g Category 1 = shore-200 m depth, Category 2 = 200 m depth-300 m offshore (U.S. Navy 2019).
h Category 1 = 0-30 km offshore (U.S. Navy 2019).
Take Calculation and Estimation
Here we describe how the information provided above is brought
together to produce a quantitative take estimate. In order to estimate
the number of marine mammals predicted to be exposed to sound levels
that would result in Level A or Level B harassment, radial distances
from the airgun array to predicted isopleths corresponding to the Level
A harassment and Level B harassment thresholds are calculated, as
described above. Those radial distances are then used to calculate the
area(s) around the airgun array predicted to be ensonified to sound
levels that exceed the Level A and Level B harassment thresholds. The
distance for the 160-dB threshold (based on L-DEO model results) was
used to draw a buffer
[[Page 29119]]
around every transect line in GIS to determine the total ensonified
area in each depth category (Table 8). The areas presented in Table 8
do not include areas ensonified within Canadian territorial waters
(from 0-12 nmi (22.2 km) from shore). As discussed above, NMFS cannot
authorize the incidental take of marine mammals in the territorial seas
of foreign nations, as the MMPA does not apply in those waters.
However, NMFS has still calculated the level of incidental take in the
entire activity area (including Canadian territorial waters) as part of
the analysis supporting our determination under the MMPA that the
activity will have a negligible impact on the affected species. The
total estimated take in U.S. and Canadian waters is presented in Table
11.
In past applications, to account for unanticipated delays in
operations, L-DEO has added 25 percent in the form of operational days,
which is equivalent to adding 25 percent to the proposed line km to be
surveyed. In this application, however, due to the strict operational
timelines and availability of the R/V Langseth, no additional time or
distance has been added to the survey calculations. 37 days is the
absolute maximum amount of time the R/V Langseth is available to
conduct seismic operations.
The ensonified areas in Table 8 were used to estimate take of
marine mammal species with densities available for the three depth
strata (shallow, intermediate, and deep waters). For other species
where densities are available based on other categories (i.e., gray
whale, harbor porpoise, northern fur seal, Guadalupe fur seal,
California sea lion, Steller sea lion; see Table 7), GIS was used to
determine the areas expected to be ensonified in each density category
(see L-DEO's EA for the ensonified areas in each category). The areas
provided in Tables 8 and 9 here have been updated from those provided
in Tables 8 and 9 of the notice of proposed IHA (85 FR 19580; April 7,
2020) based on the revised planned survey tracklines.
Table 8--Areas (km\2\) Estimated to be Ensonified to Level A and Level B Harassment Thresholds
----------------------------------------------------------------------------------------------------------------
Total
Survey zone Criteria Relevant ensonified
isopleth (m) area (km\2\)
----------------------------------------------------------------------------------------------------------------
Level B Harassment:
Shallow <100 m............................ 160 dB.......................... \a\ 12,650 3,580.73
Intermediate 100-1,000 m.................. 160 dB.......................... \b\ 9,468 23,562.43
Deep >1,000 m............................. 160 dB.......................... \b\ 6,733 52,438.71
Overall............................... ................................ .............. 79,581.85
Level A Harassment:
All depth zones........................... LF Cetacean..................... 426.9 5,334.55
MF Cetacean..................... 13.6 171.42
HF Cetacean..................... 268.3 3,363.99
Otariid......................... 10.6 133.61
Phocid.......................... 43.7 550.53
----------------------------------------------------------------------------------------------------------------
\a\ Based on L-DEO model results
\b\ Based on data from Crone et al. (2014)
Density estimates for Southern Resident killer whales from the U.S.
Navy's MSDD were overlaid with GIS layers of the Level B harassment
zones in each depth category to determine the areas expected to be
ensonified in each density category (Table 9).
Table 9--Southern Resident Killer Whale Densities and Corresponding
Ensonified Areas
------------------------------------------------------------------------
Density (animals/ Ensonified
Pod km\2\) area (km\2\)
------------------------------------------------------------------------
K/L............................... 0.000000 5,888
0.000001-0.002803 15,470
0.002804-0.005615 342
0.005616-0.009366 0
0.009367-0.015185 0
J................................. 0.000000 6,427
0.000001-0.001991 5,556
0.001992-0.005010 0
0.005011-0.009602 0
0.009603-0.018822 20
------------------------------------------------------------------------
The marine mammals predicted to occur within these respective
areas, based on estimated densities or other occurrence records, are
assumed to be incidentally taken. For species where NMFS expects take
by Level A harassment to potentially occur, the calculated Level A
harassment takes have been subtracted from the total within the Level B
harassment zone. Estimated exposures for the survey outside of Canadian
territorial waters are shown in Table 10. These numbers have changed
from those provided in Table 10 of the notice of proposed IHA (85 FR
19580; April 7, 2020) because of the revised planned survey tracklines.
[[Page 29120]]
Table 10--Estimated Taking by Level A and Level B Harassment, and Percentage of Population
--------------------------------------------------------------------------------------------------------------------------------------------------------
Estimated take Total
Species MMPA stock \a\ Stock -------------------------------- authorized Percent of
abundance Level 1B Level 1A take MMPA stock
--------------------------------------------------------------------------------------------------------------------------------------------------------
LF Cetaceans:
Central North Pacific....... 10,103 112 29 \b\ 141 1.40
Humpback whale........................ California/Oregon/Washington 2,900 .............. .............. .............. 4.86
Blue whale............................ Eastern North Pacific....... 1,647 40 11 51 3.10
Fin whale............................. California/Oregon/Washington 9,029 94 1 95 1.05
Northeast Pacific........... 3,168 .............. .............. .............. 3.00
Sei whale............................. Eastern North Pacific....... 27,197 30 2 32 0.12
Minke whale........................... California/Oregon/Washington 25,000 96 7 103 0.41
Gray whale............................ Eastern North Pacific....... 26,960 43 1 44 0.16
MF Cetaceans:
Sperm whale........................... California/Oregon/Washington 26,300 72 0 72 0.27
Baird's beaked whale.................. California/Oregon/Washington 2,697 84 0 84 3.12
Small beaked whale.................... California/Oregon/Washington 6,318 242 0 \c\ 242 3.83
Bottlenose dolphin.................... California/Oregon/Washington 1,924 1 0 \d\ 13 0.68
(offshore).
Striped dolphin....................... California/Oregon/Washington 29,211 7 0 \d\ 46 0.16
Short-beaked common dolphin........... California/Oregon/Washington 969,861 112 0 \d\ 179 0.02
Pacific white-sided dolphin........... California/Oregon/Washington 26,814 6,084 0 6,084 22.69
Northern right-whale dolphin.......... California/Oregon/Washington 26,556 4,318 0 4,318 16.26
Risso's dolphin....................... California/Oregon/Washington 6,336 1,664 0 1,664 26.26
False killer whale.................... n/a......................... Unknown n/a n/a \e\ 5 \f\ n/a
Killer whale.......................... Southern Resident........... 73 10 0 10 13.70
Northern Resident........... 302 73 0 73 24.17
West Coast Transient........ 349 .............. .............. .............. 20.92
Offshore.................... 300 .............. .............. .............. 24.33
Short-finned pilot whale.............. California/Oregon/Washington 836 20 0 \d\ 29 3.47
HF Cetaceans:
Pygmy/dwarf sperm whale............... California/Oregon/Washington 4,111 125 5 130 3.16
Dall's porpoise....................... California/Oregon/Washington 27,750 9,762 488 10,250 \g\ 36.94
Harbor porpoise....................... Northern Oregon/Washington 21,487 7,958 283 8,241 \g\ 38.35
Coast.
Northern California/Southern 35,769 .............. .............. .............. 23.04
Oregon.
Otariid Seals:
Northern fur seal..................... Eastern Pacific............. 608,143 4,592 0 4,592 0.76
California.................. 14,050 .............. .............. .............. 32.68
Guadalupe fur seal.................... Mexico to California........ 34,187 2,048 0 2,048 5.99
California sea lion................... U.S......................... 257,606 889 0 889 0.35
Steller sea lion...................... Eastern U.S................. 43,201 7,504 0 7,504 17.37
Phocid Seals:
Northern elephant seal................ California Breeding......... 179,000 2,754 0 2,754 1.54
Harbor seal........................... Oregon/Washington Coast..... \h\ 24,732 3,887 0 3,887 15.72
--------------------------------------------------------------------------------------------------------------------------------------------------------
\a\ In most cases, where multiple stocks are being affected, for the purposes of calculating the percentage of the stock impacted, the take is being
analyzed as if all authorized takes occurred within each stock.
\b\ Takes are allocated among the three DPSs in the area based on Wade et al. (2017) (Oregon: 32.7% Mexico DPS, 67.2% Central America DPS; Washington/
British Columbia: 27.9% Mexico DPS, 8.7% Central America DPS, 63.5% Hawaii DPS).
\c\ Total for small beaked whale guild (Appendix B of L-DEO's application describes potential take estimates of each species represented in the guild,
but we present the authorized take of small beaked whales as a whole).
\d\ Authorized take increased to mean group size from Barlow (2016).
\e\ Authorized take increased to mean group size from Mobley et al. (2000).
\f\ False killer whales that may be taken during this survey are not likely to belong to any designated stock. Therefore we cannot determine the percent
of stock that may be taken, but we assume that five individuals would be considered small relative to the abundance of the population they belong to.
\g\ The percentage of these stocks expected to experience take is discussed further in the Small Numbers section later in the document.
\h\ As noted in Table 1, there is no current estimate of abundance available for the Oregon/Washington Coast stock of harbor seal. The abundance
estimate from 1999, included here, is the best available.
[[Page 29121]]
Marine mammals would be expected to move away from a loud sound
source that represents an aversive stimulus, such as an airgun array,
potentially reducing the number of takes by Level A harassment.
However, the extent to which marine mammals would move away from the
sound source is difficult to quantify and is therefore not accounted
for in the take estimates. Also, note that in consideration of the
near-field soundscape of the airgun array, we have authorized a
different number of takes of mid-frequency cetaceans and pinnipeds by
Level A harassment than the number estimated by L-DEO (see Appendix B
in L-DEO's IHA application).
Mitigation
In order to issue an IHA under Section 101(a)(5)(D) of the MMPA,
NMFS must set forth the permissible methods of taking pursuant to the
activity, and other means of effecting the least practicable impact on
the species or stock and its habitat, paying particular attention to
rookeries, mating grounds, and areas of similar significance, and on
the availability of the species or stock for taking for certain
subsistence uses (latter not applicable for this action). NMFS
regulations require applicants for incidental take authorizations to
include information about the availability and feasibility (economic
and technological) of equipment, methods, and manner of conducting the
activity or other means of effecting the least practicable adverse
impact upon the affected species or stocks and their habitat (50 CFR
216.104(a)(11)).
In evaluating how mitigation may or may not be appropriate to
ensure the least practicable adverse impact on species or stocks and
their habitat, as well as subsistence uses where applicable, we
carefully consider two primary factors:
(1) The manner in which, and the degree to which, the successful
implementation of the measure(s) is expected to reduce impacts to
marine mammals, marine mammal species or stocks, and their habitat.
This considers the nature of the potential adverse impact being
mitigated (likelihood, scope, range). It further considers the
likelihood that the measure will be effective if implemented
(probability of accomplishing the mitigating result if implemented as
planned), the likelihood of effective implementation (probability
implemented as planned); and
(2) The practicability of the measures for applicant
implementation, which may consider such things as cost and impact on
operations.
L-DEO has reviewed mitigation measures employed during seismic
research surveys authorized by NMFS under previous incidental
harassment authorizations, as well as recommended best practices in
Richardson et al. (1995), Pierson et al. (1998), Weir and Dolman
(2007), Nowacek et al. (2013), Wright (2014), and Wright and Cosentino
(2015), and incorporated a suite of proposed mitigation measures into
their project description based on the above sources.
To reduce the potential for disturbance from acoustic stimuli
associated with the activities, L-DEO will implement mitigation
measures for marine mammals. Mitigation measures that will be adopted
during the planned surveys include (1) Vessel-based visual mitigation
monitoring; (2) Vessel-based passive acoustic monitoring; (3)
Establishment of an exclusion zone; (4) Shutdown procedures; (5) Ramp-
up procedures; and (6) Vessel strike avoidance measures.
Vessel-Based Visual Mitigation Monitoring
Visual monitoring requires the use of trained observers (herein
referred to as visual PSOs) to scan the ocean surface visually for the
presence of marine mammals. The area to be scanned visually includes
primarily the exclusion zone, within which observation of certain
marine mammals requires shutdown of the acoustic source, but also the
buffer zone. The buffer zone means an area beyond the exclusion zone to
be monitored for the presence of marine mammals that may enter the
exclusion zone. During pre-clearance monitoring (i.e., before ramp-up
begins), the buffer zone also acts as an extension of the exclusion
zone in that observations of marine mammals within the buffer zone
would also prevent airgun operations from beginning (i.e., ramp-up).
The buffer zone encompasses the area at and below the sea surface from
the edge of the 0-500 m exclusion zone, out to a radius of 1,000 m from
the edges of the airgun array (500-1,000 m). Visual monitoring of the
exclusion zone and adjacent waters is intended to establish and, when
visual conditions allow, maintain zones around the sound source that
are clear of marine mammals, thereby reducing or eliminating the
potential for injury and minimizing the potential for more severe
behavioral reactions for animals occurring closer to the vessel. Visual
monitoring of the buffer zone is intended to (1) provide additional
protection to na[iuml]ve marine mammals that may be in the area during
pre-clearance, and (2) during airgun use, aid in establishing and
maintaining the exclusion zone by alerting the visual observer and crew
of marine mammals that are outside of, but may approach and enter, the
exclusion zone.
L-DEO must use dedicated, trained, NMFS-approved Protected Species
Observers (PSOs). The PSOs must have no tasks other than to conduct
observational effort, record observational data, and communicate with
and instruct relevant vessel crew with regard to the presence of marine
mammals and mitigation requirements. PSO resumes must be provided to
NMFS for approval.
At least one of the visual and two of the acoustic PSOs (discussed
below) aboard the vessel must have a minimum of 90 days at-sea
experience working in those roles, respectively, during a deep
penetration (i.e., ``high energy'') seismic survey, with no more than
18 months elapsed since the conclusion of the at-sea experience. One
visual PSO with such experience must be designated as the lead for the
entire protected species observation team. The lead PSO must serve as
primary point of contact for the vessel operator and ensure all PSO
requirements per the IHA are met. To the maximum extent practicable,
the experienced PSOs should be scheduled to be on duty with those PSOs
with appropriate training but who have not yet gained relevant
experience.
During survey operations (e.g., any day on which use of the
acoustic source is planned to occur, and whenever the acoustic source
is in the water, whether activated or not), a minimum of two visual
PSOs must be on duty and conducting visual observations at all times
during daylight hours (i.e., from 30 minutes prior to sunrise through
30 minutes following sunset). Visual monitoring of the exclusion and
buffer zones must begin no less than 30 minutes prior to ramp-up and
must continue until one hour after use of the acoustic source ceases or
until 30 minutes past sunset. Visual PSOs must coordinate to ensure
360[deg] visual coverage around the vessel from the most appropriate
observation posts, and must conduct visual observations using
binoculars and the naked eye while free from distractions and in a
consistent, systematic, and diligent manner.
PSOs must establish and monitor the exclusion and buffer zones.
These zones must be based upon the radial distance from the edges of
the acoustic source (rather than being based on the center of the array
or around the vessel itself). During use of the acoustic source (i.e.,
anytime airguns are active, including
[[Page 29122]]
ramp-up), detections of marine mammals within the buffer zone (but
outside the exclusion zone) must be communicated to the operator to
prepare for the potential shutdown of the acoustic source.
During use of the airgun (i.e., anytime the acoustic source is
active, including ramp-up), detections of marine mammals within the
buffer zone (but outside the exclusion zone) should be communicated to
the operator to prepare for the potential shutdown of the acoustic
source. Visual PSOs must immediately communicate all observations to
the on duty acoustic PSO(s), including any determination by the PSO
regarding species identification, distance, and bearing and the degree
of confidence in the determination. Any observations of marine mammals
by crew members must be relayed to the PSO team. During good conditions
(e.g., daylight hours; Beaufort sea state (BSS) 3 or less), visual PSOs
must conduct observations when the acoustic source is not operating for
comparison of sighting rates and behavior with and without use of the
acoustic source and between acquisition periods, to the maximum extent
practicable.
While the R/V Langseth is surveying in water depths of 200 m or
less along the coast between Tillamook Head, Oregon and Barkley Sound,
British Columbia (between latitudes 45.9460903[deg] N and
48.780291[deg] N), and within the boundaries of Olympic Coast National
Marine Sanctuary, a second vessel with additional PSOs must travel
approximately 5 km ahead of the R/V Langseth. Two PSOs must be on watch
on the second vessel during all such survey operations and must alert
PSOs on the R/V Langseth of any marine mammal observations so that they
may be prepared to initiate shutdowns. This requirement has been
modified from what was included in the proposed IHA, which proposed
using the second vessel through the entire survey area in waters under
200 m. This requirement was primarily intended to increase the
likelihood of PSOs detecting Southern Resident killer whales. However,
L-DEO has described practicability concerns with the second vessel,
including high cost and limited availability for the time period
specified. NMFS carefully considered the area in which the second
vessel would effect the most reduction in impacts to Southern Resident
killer whales and, accordingly, the area requiring the second vessel
has been revised to reflect the areas of highest occurrence (based on
Navy, 2019), between Tillamook Head and Barkley Sound and within the
boundaries of Olympic Coast National Marine Sanctuary.
Visual PSOs on both vessels may be on watch for a maximum of four
consecutive hours followed by a break of at least one hour between
watches and may conduct a maximum of 12 hours of observation per 24-
hour period. Combined observational duties (visual and acoustic but not
at same time) may not exceed 12 hours per 24-hour period for any
individual PSO.
Passive Acoustic Monitoring
Acoustic monitoring means the use of trained personnel (sometimes
referred to as passive acoustic monitoring (PAM) operators, herein
referred to as acoustic PSOs) to operate PAM equipment to acoustically
detect the presence of marine mammals. Acoustic monitoring involves
acoustically detecting marine mammals regardless of distance from the
source, as localization of animals may not always be possible. Acoustic
monitoring is intended to further support visual monitoring (during
daylight hours) in maintaining an exclusion zone around the sound
source that is clear of marine mammals. In cases where visual
monitoring is not effective (e.g., due to weather, nighttime), acoustic
monitoring may be used to allow certain activities to occur, as further
detailed below.
Passive acoustic monitoring will take place in addition to the
visual monitoring program. Visual monitoring typically is not effective
during periods of poor visibility or at night, and even with good
visibility, is unable to detect marine mammals when they are below the
surface or beyond visual range. Acoustical monitoring can be used in
addition to visual observations to improve detection, identification,
and localization of cetaceans. The acoustic monitoring will serve to
alert visual PSOs (if on duty) when vocalizing cetaceans are detected.
It is only useful when marine mammals call, but it can be effective
either by day or by night, and does not depend on good visibility. It
will be monitored in real time so that the visual observers can be
advised when cetaceans are detected.
The R/V Langseth must use a towed PAM system, which must be
monitored by at a minimum one on duty acoustic PSO beginning at least
30 minutes prior to ramp-up and at all times during use of the acoustic
source. Acoustic PSOs may be on watch for a maximum of 4 consecutive
hours followed by a break of at least 1 hour between watches and may
conduct a maximum of 12 hours of observation per 24-hour period.
Combined observational duties (acoustic and visual but not at same
time) may not exceed 12 hours per 24-hour period for any individual
PSO.
Survey activity may continue for 30 minutes when the PAM system
malfunctions or is damaged, while the PAM operator diagnoses the issue.
If the diagnosis indicates that the PAM system must be repaired to
solve the problem, operations may continue for an additional five hours
without acoustic monitoring during daylight hours only under the
following conditions:
Sea state is less than or equal to BSS 4;
No marine mammals (excluding delphinids, other than killer
whales) detected solely by PAM in the applicable exclusion zone in the
previous 2 hours;
NMFS is notified via email as soon as practicable with the
time and location in which operations began occurring without an active
PAM system; and
Operations with an active acoustic source, but without an
operating PAM system, do not exceed a cumulative total of five hours in
any 24-hour period.
Establishment of Exclusion and Buffer Zones
An exclusion zone (EZ) is a defined area within which occurrence of
a marine mammal triggers mitigation action intended to reduce the
potential for certain outcomes, e.g., auditory injury, disruption of
critical behaviors. The PSOs must establish a minimum EZ with a 500-m
radius. The 500-m EZ must be based on radial distance from the edge of
the airgun array (rather than being based on the center of the array or
around the vessel itself). With certain exceptions (described below),
if a marine mammal appears within or enters this zone, the acoustic
source must be shut down.
The 500-m EZ is intended to be precautionary in the sense that it
would be expected to contain sound exceeding the injury criteria for
all cetacean hearing groups, (based on the dual criteria of
SELcum and peak SPL), while also providing a consistent,
reasonably observable zone within which PSOs would typically be able to
conduct effective observational effort. Additionally, a 500-m EZ is
expected to minimize the likelihood that marine mammals will be exposed
to levels likely to result in more severe behavioral responses.
Although significantly greater distances may be observed from an
elevated platform under good conditions, we believe that 500 m is
likely regularly attainable for PSOs using the naked eye during typical
conditions.
[[Page 29123]]
An extended EZ of 1,500 m must be enforced for all beaked whales,
and dwarf and pygmy sperm whales. No buffer zone is required.
Pre-Clearance and Ramp-Up
Ramp-up (sometimes referred to as ``soft start'') means the gradual
and systematic increase of emitted sound levels from an airgun array.
Ramp-up begins by first activating a single airgun of the smallest
volume, followed by doubling the number of active elements in stages
until the full complement of an array's airguns are active. Each stage
should be approximately the same duration, and the total duration
should not be less than approximately 20 minutes. The intent of pre-
clearance observation (30 minutes) is to ensure no protected species
are observed within the buffer zone prior to the beginning of ramp-up.
During pre-clearance is the only time observations of protected species
in the buffer zone would prevent operations (i.e., the beginning of
ramp-up). The intent of ramp-up is to warn protected species of pending
seismic operations and to allow sufficient time for those animals to
leave the immediate vicinity. A ramp-up procedure, involving a step-
wise increase in the number of airguns firing and total array volume
until all operational airguns are activated and the full volume is
achieved, is required at all times as part of the activation of the
acoustic source. All operators must adhere to the following pre-
clearance and ramp-up requirements:
The operator must notify a designated PSO of the planned
start of ramp-up as agreed upon with the lead PSO; the notification
time should not be less than 60 minutes prior to the planned ramp-up in
order to allow the PSOs time to monitor the exclusion and buffer zones
for 30 minutes prior to the initiation of ramp-up (pre-clearance);
Ramp-ups must be scheduled so as to minimize the time
spent with the source activated prior to reaching the designated run-
in;
One of the PSOs conducting pre-clearance observations must
be notified again immediately prior to initiating ramp-up procedures
and the operator must receive confirmation from the PSO to proceed;
Ramp-up may not be initiated if any marine mammal is
within the applicable exclusion or buffer zone. If a marine mammal is
observed within the applicable exclusion zone or the buffer zone during
the 30 minute pre-clearance period, ramp-up may not begin until the
animal(s) has been observed exiting the zones or until an additional
time period has elapsed with no further sightings (15 minutes for small
odontocetes and pinnipeds, and 30 minutes for all mysticetes and all
other odontocetes, including sperm whales, pygmy sperm whales, dwarf
sperm whales, beaked whales, pilot whales, false killer whales, and
Risso's dolphins);
Ramp-up must begin by activating a single airgun of the
smallest volume in the array and must continue in stages by doubling
the number of active elements at the commencement of each stage, with
each stage of approximately the same duration. Duration must not be
less than 20 minutes. The operator must provide information to the PSO
documenting that appropriate procedures were followed;
PSOs must monitor the exclusion and buffer zones during
ramp-up, and ramp-up must cease and the source must be shut down upon
detection of a marine mammal within the applicable exclusion zone. Once
ramp-up has begun, detections of marine mammals within the buffer zone
do not require shutdown, but such observation must be communicated to
the operator to prepare for the potential shutdown;
Ramp-up may occur at times of poor visibility, including
nighttime, if appropriate acoustic monitoring has occurred with no
detections in the 30 minutes prior to beginning ramp-up. Acoustic
source activation may only occur at times of poor visibility where
operational planning cannot reasonably avoid such circumstances;
If the acoustic source is shut down for brief periods
(i.e., less than 30 minutes) for reasons other than that described for
shutdown (e.g., mechanical difficulty), it may be activated again
without ramp-up if PSOs have maintained constant visual and/or acoustic
observation and no visual or acoustic detections of marine mammals have
occurred within the applicable exclusion zone. For any longer shutdown,
pre-clearance observation and ramp-up are required. For any shutdown at
night or in periods of poor visibility (e.g., BSS 4 or greater), ramp-
up is required, but if the shutdown period was brief and constant
observation was maintained, pre-clearance watch of 30 minutes is not
required; and
Testing of the acoustic source involving all elements
requires ramp-up. Testing limited to individual source elements or
strings does not require ramp-up but does require pre-clearance of 30
min.
Shutdown
The shutdown of an airgun array requires the immediate de-
activation of all individual airgun elements of the array. Any PSO on
duty has the authority to delay the start of survey operations or to
call for shutdown of the acoustic source if a marine mammal is detected
within the applicable EZ. The operator must also establish and maintain
clear lines of communication directly between PSOs on duty and crew
controlling the acoustic source to ensure that shutdown commands are
conveyed swiftly while allowing PSOs to maintain watch. When both
visual and acoustic PSOs are on duty, all detections must be
immediately communicated to the remainder of the on-duty PSO team for
potential verification of visual observations by the acoustic PSO or of
acoustic detections by visual PSOs. When the airgun array is active
(i.e., anytime one or more airguns is active, including during ramp-up)
and (1) a marine mammal appears within or enters the applicable
exclusion zone and/or (2) a marine mammal (other than delphinids, see
below) is detected acoustically and localized within the applicable
exclusion zone, the acoustic source must be shut down. When shutdown is
called for by a PSO, the acoustic source must be immediately
deactivated and any dispute resolved only following deactivation.
Additionally, shutdown must occur whenever PAM alone (without visual
sighting), confirms presence of marine mammal(s) in the EZ. If the
acoustic PSO cannot confirm presence within the EZ, visual PSOs must be
notified but shutdown is not required. L-DEO must also implement
shutdown of the airgun array if killer whale vocalizations are
detected, regardless of localization.
Following a shutdown, airgun activity must not resume until the
marine mammal has cleared the 500-m EZ. The animal would be considered
to have cleared the 500-m EZ if it is visually observed to have
departed the 500-m EZ, or it has not been seen within the 500-m EZ for
15 min in the case of small odontocetes and pinnipeds, or 30 min in the
case of mysticetes and large odontocetes, including sperm whales, pygmy
sperm whales, dwarf sperm whales, pilot whales, beaked whales, killer
whales, false killer whales, and Risso's dolphins.
The shutdown requirement can be waived for small dolphins if an
individual is visually detected within the exclusion zone. As defined
here, the small dolphin group is intended to encompass those members of
the Family Delphinidae most likely to voluntarily approach the source
vessel for purposes of interacting with the vessel and/or airgun array
(e.g., bow riding). This exception to the shutdown requirement
[[Page 29124]]
applies solely to specific genera of small dolphins--Tursiops,
Delphinus, Stenella, Lagenorhynchus, and Lissodelphis.
We include this small dolphin exception because shutdown
requirements for small dolphins under all circumstances represent
practicability concerns without likely commensurate benefits for the
animals in question. Small dolphins are generally the most commonly
observed marine mammals in the specific geographic region and would
typically be the only marine mammals likely to intentionally approach
the vessel. As described above, auditory injury is extremely unlikely
to occur for mid-frequency cetaceans (e.g., delphinids), as this group
is relatively insensitive to sound produced at the predominant
frequencies in an airgun pulse while also having a relatively high
threshold for the onset of auditory injury (i.e., permanent threshold
shift).
A large body of anecdotal evidence indicates that small dolphins
commonly approach vessels and/or towed arrays during active sound
production for purposes of bow riding, with no apparent effect observed
in those delphinoids (e.g., Barkaszi et al., 2012). The potential for
increased shutdowns resulting from such a measure would require the R/V
Langseth to revisit the missed track line to reacquire data, resulting
in an overall increase in the total sound energy input to the marine
environment and an increase in the total duration over which the survey
is active in a given area. Although other mid-frequency hearing
specialists (e.g., large delphinoids) are no more likely to incur
auditory injury than are small dolphins, they are much less likely to
approach vessels. Therefore, retaining a shutdown requirement for large
delphinoids would not have similar impacts in terms of either
practicability for the applicant or corollary increase in sound energy
output and time on the water. We do anticipate some benefit for a
shutdown requirement for large delphinoids in that it simplifies
somewhat the total range of decision-making for PSOs and may preclude
any potential for physiological effects other than to the auditory
system as well as some more severe behavioral reactions for any such
animals in close proximity to the source vessel.
Visual PSOs must use best professional judgment in making the
decision to call for a shutdown if there is uncertainty regarding
identification (i.e., whether the observed marine mammal(s) belongs to
one of the delphinid genera for which shutdown is waived or one of the
species with a larger exclusion zone).
Upon implementation of shutdown, the source may be reactivated
after the marine mammal(s) has been observed exiting the applicable
exclusion zone (i.e., animal is not required to fully exit the buffer
zone where applicable) or following 15 minutes for small odontocetes
and pinnipeds, and 30 minutes for mysticetes and all other odontocetes,
including sperm whales, pygmy sperm whales, dwarf sperm whales, beaked
whales, pilot whales, and Risso's dolphins, with no further observation
of the marine mammal(s).
L-DEO must implement shutdown if a marine mammal species for which
take was not authorized, or a species for which authorization was
granted but the takes have been met, approaches the Level A or Level B
harassment zones. L-DEO must also implement shutdown if any of the
following are observed at any distance:
Any large whale (defined as a sperm whale or any mysticete
species) with a calf (defined as an animal less than two-thirds the
body size of an adult observed to be in close association with an
adult;
An aggregation of six or more large whales;
A North Pacific right whale; and/or
A killer whale of any ecotype.
Vessel Strike Avoidance
These measures apply to all vessels associated with the planned
survey activity; however, we note that these requirements do not apply
in any case where compliance would create an imminent and serious
threat to a person or vessel or to the extent that a vessel is
restricted in its ability to maneuver and, because of the restriction,
cannot comply. These measures include the following:
1. Vessel operators and crews must maintain a vigilant watch for
all marine mammals and slow down, stop their vessel, or alter course,
as appropriate and regardless of vessel size, to avoid striking any
marine mammal. A single marine mammal at the surface may indicate the
presence of submerged animals in the vicinity of the vessel; therefore,
precautionary measures should be exercised when an animal is observed.
A visual observer aboard the vessel must monitor a vessel strike
avoidance zone around the vessel (specific distances detailed below),
to ensure the potential for strike is minimized. Visual observers
monitoring the vessel strike avoidance zone can be either third-party
observers or crew members, but crew members responsible for these
duties must be provided sufficient training to distinguish marine
mammals from other phenomena and broadly to identify a marine mammal to
broad taxonomic group (i.e., as a large whale or other marine mammal);
2. Vessel speeds must be reduced to 10 knots or less when mother/
calf pairs, pods, or large assemblages of any marine mammal are
observed near a vessel;
3. All vessels must maintain a minimum separation distance of 100 m
from large whales (i.e., sperm whales and all mysticetes);
4. All vessels must attempt to maintain a minimum separation
distance of 50 m from all other marine mammals, with an exception made
for those animals that approach the vessel; and
5. When marine mammals are sighted while a vessel is underway, the
vessel should take action as necessary to avoid violating the relevant
separation distance (e.g., attempt to remain parallel to the animal's
course, avoid excessive speed or abrupt changes in direction until the
animal has left the area). If marine mammals are sighted within the
relevant separation distance, the vessel should reduce speed and shift
the engine to neutral, not engaging the engines until animals are clear
of the area. This recommendation does not apply to any vessel towing
gear.
Operational Restrictions
While the R/V Langseth is surveying in waters 200 m deep or less
along the coast between Tillamook Head, Oregon and Barkley Sound,
British Columbia (between latitudes 45.9460903[deg] N and
48.780291[deg] N), and within the boundaries of Olympic Coast National
Marine Sanctuary, survey operations must occur in daylight hours only
(i.e., from 30 minutes prior to sunrise through 30 minutes following
sunset) to ensure the ability to use visual observation as a detection-
based mitigation tool and to implement shutdown procedures for species
or situations with additional shutdown requirements outlined above
(e.g., killer whale of any ecotype, North Pacific right whale,
aggregation of six or more large whales, large whale with a calf). The
proposed IHA included this requirement to operate only during daylight
hours in waters 200 m deep or less throughout the entire survey area.
We have revised that requirement to apply only between Tillamook Head
and Barkley Sound and within the boundaries of Olympic Coast National
Marine Sanctuary because those are the areas with the highest expected
Southern Resident killer whale
[[Page 29125]]
occurrence, and we determined that requiring this operational
restriction throughout the entire survey area was not practicable, in
consideration of cost and vessel availability concerns.
Communication
Each day of survey operations, L-DEO must contact NMFS Northwest
Fisheries Science Center, NMFS West Coast Region, The Whale Museum,
Orca Network, Canada's DFO, Olympic Coast National Marine Sanctuary,
and/or other sources to obtain near real-time reporting for the
whereabouts of Southern Resident killer whales.
Mitigation Measures in Canadian Waters
As stated above, NMFS cannot authorize the incidental take of
marine mammals in the territorial seas of foreign nations, as the MMPA
does not apply in those waters. Therefore, the mitigation requirements
described above do not apply within Canadian territorial waters. The
MMPA is applicable in the EEZs of foreign nations, and therefore, the
mitigation measures above apply within the Canadian EEZ. However, L-DEO
also consulted with Canada's DFO under the Canada Species at Risk Act
and must also comply with DFO's mitigation requirements within the
Canadian EEZ in order to avoid causing the death of fish or marine
mammals and/or the harmful alteration, disruption, or destruction of
fish habitat, or causing prohibited effects to aquatic species at risk.
Within the Canadian EEZ, L-DEO must:
Conduct seismic survey activities outside of designated
Killer Whale Critical Habitat (KWCH) with a setback that ensures that
the estimated sound pressure level has diminished to <=160 dB rms re: 1
[mu]Pa at the boundary of KWCH;
Initiate an immediate and complete shutdown of the airgun
array if a killer whale (all ecotypes), North Pacific right whale,
whale with calf (any species) or aggregation of whales (any species) is
observed;
Initiate an immediate and complete shutdown of the airgun
array if a sperm whale or a beaked whale (any species) is sighted
within 1,500 m of the airgun array;
For other observations of marine mammals, initiate an
immediate and complete shutdown of the airgun array if these animals
are observed within an established EZ with a radius of 1,000 m;
Refrain from conducting seismic surveys in waters less
than 100 m in depth;
Conduct seismic surveys in waters 100 to 200 m deep during
daylight hours only, with a second vessel having two marine mammal
observers on watch, positioned 5 km ahead of the R/V Langseth;
Combine enhanced visual observations (e.g., reticle and
big-eye binoculars, night vision devices and digital cameras) with non-
visual detection methods (e.g., infrared technology (FLIR) and passive
acoustic monitoring) to increase the likelihood of detecting marine
mammals during ramp up, Beaufort sea states >3, and nighttime survey
operations; and
Monitor the established EZ with a radius of 1,000 m for 60
minutes prior to initial start-up of the airgun array or resumption of
operations following a complete shutdown to allow for the detection of
deep diving animals.
While operating within the Canadian EEZ but outside Canadian
territorial waters, if mitigation requirements in the IHA differ from
the requirements established by DFO, L-DEO must adhere to the most
protective measure (e.g., larger EZ, visual monitoring procedures).
Mitigation Measures Considered But Eliminated
As stated above, in determining appropriate mitigation measures,
NMFS considers the practicability of the measures for applicant
implementation, which may include such things as cost or impact on
operations. NMFS has proposed expanding critical habitat for Southern
Resident killer whales to include marine waters between the 6.1-m depth
contour and the 200-m depth contour from the U.S. international border
with Canada south to Point Sur, California (84 FR 49214; September 19,
2019). Though the proposed expansion has not been finalized, due to the
habitat features of the area and the higher likelihood of occurrence
within the area, NMFS considered implementing a closure area and
prohibiting L-DEO from conducting survey operations between the 200-m
isobath and the coastline. However, this measure was eliminated from
consideration because the closure would not be practicable for L-DEO,
as the primary purpose of their survey is to investigate the geologic
features that occur within that area. Therefore, NMFS has not
prohibited L-DEO from operating in waters within the 200-m isobath for
this survey.
We have carefully evaluated the suite of mitigation measures
described here and considered a range of other measures in the context
of ensuring that we prescribe the means of effecting the least
practicable adverse impact on the affected marine mammal species and
stocks and their habitat. Based on our evaluation of the proposed
measures, as well as other measures considered by NMFS described above,
NMFS has determined that the mitigation measures provide the means
effecting the least practicable impact on the affected species or
stocks and their habitat, paying particular attention to rookeries,
mating grounds, and areas of similar significance.
Monitoring and Reporting
In order to issue an IHA for an activity, Section 101(a)(5)(D) of
the MMPA states that NMFS must set forth requirements pertaining to the
monitoring and reporting of such taking. The MMPA implementing
regulations at 50 CFR 216.104 (a)(13) indicate that requests for
authorizations must include the suggested means of accomplishing the
necessary monitoring and reporting that will result in increased
knowledge of the species and of the level of taking or impacts on
populations of marine mammals that are expected to be present in the
action area. Effective reporting is critical both to compliance as well
as ensuring that the most value is obtained from the required
monitoring.
Monitoring and reporting requirements prescribed by NMFS should
contribute to improved understanding of one or more of the following:
Occurrence of marine mammal species or stocks in the area
in which take is anticipated (e.g., presence, abundance, distribution,
density);
Nature, scope, or context of likely marine mammal exposure
to potential stressors/impacts (individual or cumulative, acute or
chronic), through better understanding of: (1) Action or environment
(e.g., source characterization, propagation, ambient noise); (2)
affected species (e.g., life history, dive patterns); (3) co-occurrence
of marine mammal species with the action; or (4) biological or
behavioral context of exposure (e.g., age, calving or feeding areas);
Individual marine mammal responses (behavioral or
physiological) to acoustic stressors (acute, chronic, or cumulative),
other stressors, or cumulative impacts from multiple stressors;
How anticipated responses to stressors impact either: (1)
Long-term fitness and survival of individual marine mammals; or (2)
populations, species, or stocks;
Effects on marine mammal habitat (e.g., marine mammal prey
species,
[[Page 29126]]
acoustic habitat, or other important physical components of marine
mammal habitat); and
Mitigation and monitoring effectiveness.
Vessel-Based Visual Monitoring
As described above, PSO observations must take place during daytime
airgun operations. During seismic operations, at least five visual PSOs
must be based aboard the R/V Langseth. Two visual PSOs must be on duty
at all time during daytime hours, with an additional two PSOs on duty
aboard a second scout vessel at all times during daylight hours when
operating in waters shallower than 200 m. Monitoring must be conducted
in accordance with the following requirements:
The operator must provide PSOs with bigeye binoculars
(e.g., 25 x 150; 2.7 view angle; individual ocular focus; height
control) of appropriate quality (i.e., Fujinon or equivalent) solely
for PSO use. These must be pedestal-mounted on the deck at the most
appropriate vantage point that provides for optimal sea surface
observation, PSO safety, and safe operation of the vessel; and
The operator must work with the selected third-party
observer provider to ensure PSOs have all equipment (including backup
equipment) needed to adequately perform necessary tasks, including
accurate determination of distance and bearing to observed marine
mammals.
PSOs must have the following requirements and qualifications:
PSOs must be independent, dedicated, trained visual and
acoustic PSOs and must be employed by a third-party observer provider;
PSOs must have no tasks other than to conduct
observational effort (visual or acoustic), collect data, and
communicate with and instruct relevant vessel crew with regard to the
presence of protected species and mitigation requirements (including
brief alerts regarding maritime hazards);
PSOs must have successfully completed an approved PSO
training course appropriate for their designated task (visual or
acoustic). Acoustic PSOs are required to complete specialized training
for operating PAM systems and are encouraged to have familiarity with
the vessel with which they will be working;
PSOs can act as acoustic or visual observers (but not at
the same time) as long as they demonstrate that their training and
experience are sufficient to perform the task at hand;
NMFS must review and approve PSO resumes accompanied by a
relevant training course information packet that includes the name and
qualifications (i.e., experience, training completed, or educational
background) of the instructor(s), the course outline or syllabus, and
course reference material as well as a document stating successful
completion of the course;
NMFS shall have one week to approve PSOs from the time
that the necessary information is submitted, after which PSOs meeting
the minimum requirements shall automatically be considered approved;
PSOs must successfully complete relevant training,
including completion of all required coursework and passing (80 percent
or greater) a written and/or oral examination developed for the
training program;
PSOs must have successfully attained a bachelor's degree
from an accredited college or university with a major in one of the
natural sciences, a minimum of 30 semester hours or equivalent in the
biological sciences, and at least one undergraduate course in math or
statistics; and
The educational requirements may be waived if the PSO has
acquired the relevant skills through alternate experience. Requests for
such a waiver must be submitted to NMFS and must include written
justification. Requests shall be granted or denied (with justification)
by NMFS within one week of receipt of submitted information. Alternate
experience that may be considered includes, but is not limited to (1)
secondary education and/or experience comparable to PSO duties; (2)
previous work experience conducting academic, commercial, or
government-sponsored protected species surveys; or (3) previous work
experience as a PSO; the PSO should demonstrate good standing and
consistently good performance of PSO duties.
For data collection purposes, PSOs must use standardized data
collection forms, whether hard copy or electronic. PSOs must record
detailed information about any implementation of mitigation
requirements, including the distance of animals to the acoustic source
and description of specific actions that ensued, the behavior of the
animal(s), any observed changes in behavior before and after
implementation of mitigation, and if shutdown was implemented, the
length of time before any subsequent ramp-up of the acoustic source. If
required mitigation was not implemented, PSOs should record a
description of the circumstances. At a minimum, the following
information must be recorded:
Vessel names (source vessel and other vessels associated
with survey) and call signs;
PSO names and affiliations;
Dates of departures and returns to port with port name;
Date and participants of PSO briefings;
Dates and times (Greenwich Mean Time) of survey effort and
times corresponding with PSO effort;
Vessel location (latitude/longitude) when survey effort
began and ended and vessel location at beginning and end of visual PSO
duty shifts;
Vessel heading and speed at beginning and end of visual
PSO duty shifts and upon any line change;
Environmental conditions while on visual survey (at
beginning and end of PSO shift and whenever conditions changed
significantly), including BSS and any other relevant weather conditions
including cloud cover, fog, sun glare, and overall visibility to the
horizon;
Factors that may have contributed to impaired observations
during each PSO shift change or as needed as environmental conditions
changed (e.g., vessel traffic, equipment malfunctions); and
Survey activity information, such as acoustic source power
output while in operation, number and volume of airguns operating in
the array, tow depth of the array, and any other notes of significance
(i.e., pre-clearance, ramp-up, shutdown, testing, shooting, ramp-up
completion, end of operations, streamers, etc.).
The following information should be recorded upon visual
observation of any protected species:
Watch status (sighting made by PSO on/off effort,
opportunistic, crew, alternate vessel/platform);
PSO who sighted the animal;
Time of sighting;
Vessel location at time of sighting;
Water depth;
Direction of vessel's travel (compass direction);
Direction of animal's travel relative to the vessel;
Pace of the animal;
Estimated distance to the animal and its heading relative
to vessel at initial sighting;
Identification of the animal (e.g., genus/species, lowest
possible taxonomic level, or unidentified) and the composition of the
group if there is a mix of species;
Estimated number of animals (high/low/best);
Estimated number of animals by cohort (adults, yearlings,
juveniles, calves, group composition, etc.);
[[Page 29127]]
Description (as many distinguishing features as possible
of each individual seen, including length, shape, color, pattern, scars
or markings, shape and size of dorsal fin, shape of head, and blow
characteristics);
Detailed behavior observations (e.g., number of blows/
breaths, number of surfaces, breaching, spyhopping, diving, feeding,
traveling; as explicit and detailed as possible; note any observed
changes in behavior);
Animal's closest point of approach (CPA) and/or closest
distance from any element of the acoustic source;
Platform activity at time of sighting (e.g., deploying,
recovering, testing, shooting, data acquisition, other); and
Description of any actions implemented in response to the
sighting (e.g., delays, shutdown, ramp-up) and time and location of the
action.
If a marine mammal is detected while using the PAM system, the
following information should be recorded:
An acoustic encounter identification number, and whether
the detection was linked with a visual sighting;
Date and time when first and last heard;
Types and nature of sounds heard (e.g., clicks, whistles,
creaks, burst pulses, continuous, sporadic, strength of signal); and
Any additional information recorded such as water depth of
the hydrophone array, bearing of the animal to the vessel (if
determinable), species or taxonomic group (if determinable),
spectrogram screenshot, and any other notable information.
Reporting
A report must be submitted to NMFS within 90 days after the end of
the cruise. The report must describe the operations that were conducted
and sightings of marine mammals near the operations. The report must
provide full documentation of methods, results, and interpretation
pertaining to all monitoring. The 90-day report must summarize the
dates and locations of seismic operations, and all marine mammal
sightings (dates, times, locations, activities, associated seismic
survey activities). The report must also include estimates of the
number and nature of exposures that occurred above the harassment
threshold based on PSO observations and including an estimate of those
that were not detected, in consideration of both the characteristics
and behaviors of the species of marine mammals that affect
detectability, as well as the environmental factors that affect
detectability.
The draft report must also include geo-referenced time-stamped
vessel tracklines for all time periods during which airguns were
operating. Tracklines should include points recording any change in
airgun status (e.g., when the airguns began operating, when they were
turned off, or when they changed from full array to single gun or vice
versa). GIS files must be provided in ESRI shapefile format and include
the UTC date and time, latitude in decimal degrees, and longitude in
decimal degrees. All coordinates must be referenced to the WGS84
geographic coordinate system. In addition to the report, all raw
observational data must be made available to NMFS. The report must
summarize the information submitted in interim monthly reports as well
as additional data collected as described above and in the IHA. A final
report must be submitted within 30 days following resolution of any
comments on the draft report.
Reporting Injured or Dead Marine Mammals
Discovery of injured or dead marine mammals--In the event that
personnel involved in survey activities covered by the authorization
discover an injured or dead marine mammal, the L-DEO must report the
incident to the Office of Protected Resources (OPR), NMFS and to the
NMFS West Coast Regional Stranding Coordinator as soon as feasible. The
report must include the following information:
Time, date, and location (latitude/longitude) of the first
discovery (and updated location information if known and applicable);
Species identification (if known) or description of the
animal(s) involved;
Condition of the animal(s) (including carcass condition if
the animal is dead);
Observed behaviors of the animal(s), if alive;
If available, photographs or video footage of the
animal(s); and
General circumstances under which the animal was
discovered.
Vessel strike--In the event of a ship strike of a marine mammal by
any vessel involved in the activities covered by the authorization, L-
DEO must report the incident to OPR, NMFS and to the NMFS West Coast
Regional Stranding Coordinator as soon as feasible. The report must
include the following information:
Time, date, and location (latitude/longitude) of the
incident;
Vessel's speed during and leading up to the incident;
Vessel's course/heading and what operations were being
conducted (if applicable);
Status of all sound sources in use;
Description of avoidance measures/requirements that were
in place at the time of the strike and what additional measures were
taken, if any, to avoid strike;
Environmental conditions (e.g., wind speed and direction,
Beaufort sea state, cloud cover, visibility) immediately preceding the
strike;
Species identification (if known) or description of the
animal(s) involved;
Estimated size and length of the animal that was struck
Description of the behavior of the animal immediately
preceding and following the strike;
If available, description of the presence and behavior of
any other marine mammals present immediately preceding the strike;
Estimated fate of the animal (e.g., dead, injured but
alive, injured and moving, blood or tissue observed in the water,
status unknown, disappeared); and
To the extent practicable, photographs or video footage of
the animal(s).
Actions To Minimize Additional Harm to Live-Stranded (or Milling)
Marine Mammals
In the event of a live stranding (or near-shore atypical milling)
event within 50 km of the survey operations, where the NMFS stranding
network is engaged in herding or other interventions to return animals
to the water, the Director of OPR, NMFS (or designee) will advise L-DEO
of the need to implement shutdown procedures for all active acoustic
sources operating within 50 km of the stranding. Shutdown procedures
for live stranding or milling marine mammals include the following: If
at any time, the marine mammal the marine mammal(s) die or are
euthanized, or if herding/intervention efforts are stopped, the
Director of OPR, NMFS (or designee) will advise the IHA-holder that the
shutdown around the animals' location is no longer needed. Otherwise,
shutdown procedures must remain in effect until the Director of OPR,
NMFS (or designee) determines and advises L-DEO that all live animals
involved have left the area (either of their own volition or following
an intervention).
If further observations of the marine mammals indicate the
potential for re-stranding, additional coordination with the IHA-holder
will be required to determine what measures are necessary to minimize
that likelihood (e.g.,
[[Page 29128]]
extending the shutdown or moving operations farther away) and to
implement those measures as appropriate.
Additional Information Requests--If NMFS determines that the
circumstances of any marine mammal stranding found in the vicinity of
the activity suggest investigation of the association with survey
activities is warranted, and an investigation into the stranding is
being pursued, NMFS will submit a written request to L-DEO indicating
that the following initial available information must be provided as
soon as possible, but no later than 7 business days after the request
for information:
Status of all sound source use in the 48 hours preceding
the estimated time of stranding and within 50 km of the discovery/
notification of the stranding by NMFS; and
If available, description of the behavior of any marine
mammal(s) observed preceding (i.e., within 48 hours and 50 km) and
immediately after the discovery of the stranding.
In the event that the investigation is still inconclusive, the
investigation of the association of the survey activities is still
warranted, and the investigation is still being pursued, NMFS may
provide additional information requests, in writing, regarding the
nature and location of survey operations prior to the time period
above.
Reporting Species of Concern
To support NMFS's goal of improving our understanding of occurrence
of marine mammal species or stocks in the area (e.g., presence,
abundance, distribution, density), L-DEO must immediately report
observations of Southern Resident killer whales and North Pacific right
whales to OPR, NMFS. L-DEO must also immediately report all sightings
of Southern Resident killer whales and North Pacific right whales
within Olympic Coast National Marine Sanctuary to the Sanctuary.
Negligible Impact Analysis and Determination
NMFS has defined negligible impact as an impact resulting from the
specified activity that cannot be reasonably expected to, and is not
reasonably likely to, adversely affect the species or stock through
effects on annual rates of recruitment or survival (50 CFR 216.103). A
negligible impact finding is based on the lack of likely adverse
effects on annual rates of recruitment or survival (i.e., population-
level effects). An estimate of the number of takes alone is not enough
information on which to base an impact determination. In addition to
considering estimates of the number of marine mammals that might be
``taken'' through harassment, NMFS considers other factors, such as the
likely nature of any responses (e.g., intensity, duration), the context
of any responses (e.g., critical reproductive time or location,
migration), as well as effects on habitat, and the likely effectiveness
of the mitigation. We also assess the number, intensity, and context of
estimated takes by evaluating this information relative to population
status. Consistent with the 1989 preamble for NMFS's implementing
regulations (54 FR 40338; September 29, 1989), the impacts from other
past and ongoing anthropogenic activities are incorporated into this
analysis via their impacts on the environmental baseline (e.g., as
reflected in the regulatory status of the species, population size and
growth rate where known, ongoing sources of human-caused mortality, or
ambient noise levels).
To avoid repetition, our analysis applies to all species listed in
Tables 10 and 11, given that NMFS expects the anticipated effects of
the planned geophysical survey to be similar in nature. Where there are
meaningful differences between species or stocks, or groups of species,
in anticipated individual responses to activities, impact of expected
take on the population due to differences in population status, or
impacts on habitat, NMFS has identified species-specific factors to
inform the analysis. As described above, we have authorized only the
takes estimated to occur outside of Canadian territorial waters (Table
10); however, for the purposes of our negligible impact analysis and
determination, we consider the total number of takes that are
anticipated to occur as a result of the entire survey (including the
portion of the survey that would occur within the Canadian territorial
waters (approximately six percent of the survey) (Table 11).
Table 11--Total Estimated Take Including Canadian Territorial Waters
--------------------------------------------------------------------------------------------------------------------------------------------------------
Estimated take (excluding Estimated take (within Total estimated take
Canadian territorial waters) Canadian territorial waters) -------------------------------
Species ----------------------------------------------------------------
Level B Level A Level B Level A Level B Level A
--------------------------------------------------------------------------------------------------------------------------------------------------------
LF Cetaceans:
Humpback whale...................................... 112 29 21 1 133 30
Blue whale.......................................... 40 11 7 1 47 11
Fin whale........................................... 94 1 2 0 96 1
Sei whale........................................... 30 2 2 0 31 2
Minke whale......................................... 96 7 6 0 101 7
Gray whale.......................................... 43 1 23 1 66 2
MF Cetaceans:
Sperm whale......................................... 72 0 1 0 73 0
Baird's beaked whale................................ 84 0 1 0 85 0
Small beaked whale.................................. 242 0 5 0 247 0
Bottlenose dolphin.................................. 1 0 0 0 1 0
Striped dolphin..................................... 7 0 0 0 7 0
Short-beaked common dolphin......................... 112 0 4 0 116 0
Pacific white-sided dolphin......................... 6093 0 333 0 6426 0
Northern right-whale dolphin........................ 4320 0 118 0 4438 0
Risso's dolphin..................................... 1669 0 145 0 1814 0
False killer whale.................................. 5 0 0 0 5 0
Killer whale (Southern Resident).................... 10 0 1 0 11 0
Killer whale (Northern Resident).................... 73 0 4 0 77 0
Killer whale (West Coast Transient).................
Killer whale (Offshore).............................
[[Page 29129]]
Short-finned pilot whale............................ 20 0 1 0 21 0
HF Cetaceans:
Pygmy/dwarf sperm whale............................. 125 5 8 0 134 6
Dall's porpoise..................................... 9762 488 696 23 10457 511
Harbor porpoise..................................... 7958 283 2403 87 10361 369
Otariid Pinnipeds:
Northern fur seal................................... 4424 0 54 0 4478 0
Guadalupe fur seal.................................. 2048 0 113 0 2161 0
California sea lion................................. 889 0 137 0 1026 0
Steller sea lion.................................... 7504 0 1920 0 9424 0
Phocid Pinnipeds:
Northern elephant seal.............................. 2754 0 164 0 2918 0
Harbor seal......................................... 3887 0 1623 0 5510 0
--------------------------------------------------------------------------------------------------------------------------------------------------------
NMFS does not anticipate that serious injury or mortality will
occur as a result of L-DEO's planned survey, even in the absence of
mitigation, and none are authorized. As discussed in the Potential
Effects section of the notice of proposed IHA (85 FR 19580; April 7,
2020), non-auditory physical effects, stranding, and vessel strike are
not expected to occur.
We have authorized a limited number of instances of Level A
harassment of nine species (low- and high-frequency cetacean hearing
groups only) and Level B harassment of 31 marine mammal species.
However, we believe that any PTS incurred in marine mammals as a result
of the planned activity would be in the form of only a small degree of
PTS, not total deafness, because of the constant movement relative to
each other of both the R/V Langseth and of the marine mammals in the
project areas, as well as the fact that the vessel is not expected to
remain in any one area in which individual marine mammals would be
expected to concentrate for an extended period of time (i.e., since the
duration of exposure to loud sounds will be relatively short) and,
further, would be unlikely to affect the fitness of any individuals.
Also, as described above, we expect that marine mammals would be likely
to move away from a sound source that represents an aversive stimulus,
especially at levels that would be expected to result in PTS, given
sufficient notice of the R/V Langseth's approach due to the vessel's
relatively low speed when conducting seismic surveys. We expect that
the majority of takes would be in the form of short-term Level B
behavioral harassment in the form of temporary avoidance of the area or
decreased foraging (if such activity were occurring), reactions that
are considered to be of low severity and with no lasting biological
consequences (e.g., Southall et al., 2007, Ellison et al., 2012).
Potential impacts to marine mammal habitat were discussed in detail
in the Potential Effects of the Specified Activity on Marine Mammals
and their Habitat section of the notice of proposed IHA (85 FR 19580;
April 7, 2020). Marine mammal habitat may be impacted by elevated sound
levels, but these impacts would be temporary. Prey species are mobile
and are broadly distributed throughout the project areas; therefore,
marine mammals that may be temporarily displaced during survey
activities are expected to be able to resume foraging once they have
moved away from areas with disturbing levels of underwater noise.
Because of the relatively short duration (37 days) and temporary nature
of the disturbance, the availability of similar habitat and resources
in the surrounding area, the impacts to marine mammals and the food
sources that they utilize are not expected to cause significant or
long-term consequences for individual marine mammals or their
populations.
The tracklines of this survey either traverse or are proximal to
BIAs for humpback and gray whales (Ferguson et al., 2015). The entire
U.S. West Coast within 47 km of the coast is a BIA for migrating gray
whale potential presence from January to July and October to December.
The BIA for northbound gray whale migration is broken into two phases,
Phase A (within 8 km of shore) and Phase B (within 5 km of shore),
which are active from January to July and March to July, respectively.
The BIA for southbound migration includes waters within 10 km of shore
and is active from October to March. There are four gray whale feeding
BIAs within the survey area: The Grays Harbor gray whale feeding BIA is
used between April and November; the Northwest Washington gray whale
feeding BIA is used between May and November; and the Depoe Bay and
Cape Blanco and Orford Reef gray whale feeding BIAs off Oregon are each
used between June and November. There are also two humpback whale
feeding BIAs within the survey area: The Stonewall and Heceta Bank
humpback whale feeding BIA off central Oregon and the northern
Washington BIA off the Washington Olympic Peninsula are each used
between May and November.
For the humpback whale feeding and gray whale feeding and
northbound migration BIAs, L-DEO's survey beginning in June 2021 could
overlap with a period where BIAs represent an important habitat.
However, only a portion of seismic survey days would actually occur in
or near these BIAs, and all survey efforts would be completed by mid-
July, still in the early window of primary use for these BIAs. Gray
whales are most commonly seen migrating northward between March and May
and southward between November and January. As planned, there is no
possibility that L-DEO's survey impacts the southern migration, and
presence of northern migrating individuals should be below peak during
survey operations beginning in June 2021.
Although migrating gray whales may slightly alter their course in
response to the survey, the exposure would not substantially impact
their migratory behavior (Malme et al., 1984; Malme and Miles 1985;
Richardson et al., 1995), and Yazvenko et al. (2007b) reported no
apparent changes in the frequency of feeding activity in Western gray
whales exposed to airgun sounds in their feeding grounds near Sakhalin
Island. Goldbogen et al. (2013) found
[[Page 29130]]
blue whales feeding on highly concentrated prey in shallow depths (such
as the conditions expected within humpback feeding BIAs) were less
likely to respond and cease foraging than whales feeding on deep,
dispersed prey when exposed to simulated sonar sources, suggesting that
the benefits of feeding for humpbacks foraging on high-density prey may
outweigh perceived harm from the acoustic stimulus, such as the seismic
survey (Southall et al., 2016). Additionally, L-DEO must shut down the
airgun array upon observation of an aggregation of six or more large
whales, which would reduce impacts to cooperatively foraging animals.
For all habitats, no physical impacts to BIA habitat are anticipated
from seismic activities. While SPLs of sufficient strength have been
known to cause injury to fish and fish and invertebrate mortality, in
feeding habitats, the most likely impact to prey species from survey
activities would be temporary avoidance of the affected area and any
injury or mortality of prey species would be localized around the
survey and not of a degree that would adversely impact marine mammal
foraging. The duration of fish avoidance of a given area after survey
effort stops is unknown, but a rapid return to normal recruitment,
distribution and behavior is expected. Given the short operational
seismic time near or traversing BIAs, as well as the ability of
cetaceans and prey species to move away from acoustic sources, NMFS
expects that there would be, at worst, minimal impacts to animals and
habitat within the designated BIAs.
Critical habitat has been established on the U.S. West Coast for
the eastern DPS of Steller sea lions (58 FR 45269; August 27, 1993) and
in inland waters of Washington for Southern Resident killer whales (71
FR 69054; November 29, 2006). Critical habitat for the Mexico and
Central America DPSs of humpback whales has been established along the
U.S. West Coast (86 FR 21082; April 21, 2021), and NMFS has proposed
expanding Southern Resident killer whale critical habitat to include
coastal waters of Washington, Oregon, and California (84 FR 49214;
September 19, 2019). Only a small portion of L-DEO's seismic survey
will occur in or near these established or proposed critical habitats.
Critical habitat for Steller sea lions has been established at two
rookeries on the Oregon coast, at Rogue Reef (Pyramid Rock) and Orford
Reef (Long Brown Rock and Seal Rock). The critical habitat area
includes aquatic zones that extend 0.9 km seaward and air zones
extending 0.9 km above these rookeries (NMFS 1993). Steller sea lions
occupy rookeries and pup from late-May through early-July (NMFS 2008),
which coincides with L-DEO's survey. The Orford Reef and Rogue Reef
critical habitats are located 7 km and 9 km from the nearest planned
seismic transect line, respectively. Impacts to Steller sea lions
within these areas, and throughout the survey area, are expected to be
limited to short-term behavioral disturbance, with no lasting
biological consequences.
Critical habitat for the threatened Mexico DPS and endangered
Central America DPS humpback whales has been established along the U.S.
West Coast (86 FR 21082; April 21, 2021). The critical habitat
encompasses the humpback whale feeding BIAs described above and
generally includes waters between the 50-m isobath and the 1,200-m
isobath, though some areas extend further offshore. NMFS determined
that prey within humpback whale feeding areas are essential to the
conservation of each of the three DPSs of humpback whales for which
critical habitat was established (Mexico, Central America, and Western
North Pacific DPSs). Critical habitat was therefore designated in
consideration of importance that the whales not only have reliable
access to prey within their feeding areas, but that prey are of a
sufficient density to support feeding and the build-up of energy
reserves. Although humpback whales are generalist predators and prey
availability can very seasonally and spatially, substantial data
indicate that the humpback whales' diet is consistently dominated by
euphausiid species (of genus Euphausia, Thysanoessa, Nyctiphanes, and
Nematoscelis) and small pelagic fishes, such as northern anchovy
(Engraulis mordax), Pacific herring (Clupea pallasii), Pacific sardine
(Sardinops sagax), and capelin (Mallotus villosus) (Nemoto 1957, 1959;
Klumov 1963; Rice Krieger and Wing 1984; Baker 1985; Kieckhefer 1992;
Clapham et al., 1997; Neilson et al., 2015). While there are possible
impacts of seismic activity on plankton and fish species (e.g.,
McCauley et al., 2017; Hastings and Popper 2005), the areas expected to
be affected by L-DEO's activities are small relative to the greater
habitat areas available. Additionally, humpback whales feeding on high-
density prey may be less likely to cease foraging when the benefit of
energy intake outweighs the perceived harm from acoustic stimulus
(Southall et al., 2016). Therefore, this seismic activity is not
expected to have a lasting physical impact on humpback whale critical
habitat, prey within it, or overall humpback whale fitness. Any impact
would be a temporary increase in sound levels when the survey is
occurring in or near the critical habitat and resulting temporary
avoidance of prey or marine mammals themselves due these elevated sound
levels. As stated above, L-DEO must shut down the airgun array upon
observation of an aggregation of six or more large whales, which would
reduce direct impacts to groups of humpback whales that may be
cooperatively feeding in the area.
As discussed earlier, in response to comments from the ENGOs, we
acknowledge ongoing concern over the health and growth of the
California/Oregon/Washington stock of humpback whales, due to vessel
strikes and other factors. As described above, though, impacts from
this seismic survey are not expected to impact the fitness of any
individuals and thereby will not alone, or incrementally in combination
with other baseline stressors, adversely affect the stock through
impacts on rates of recruitment or survival.
Southern Resident Killer Whales
In acknowledgment of our concern regarding the status of Southern
Resident killer whales, including low abundance and a decreasing trend,
we address impacts to this stock separately in this section.
L-DEO's planned tracklines do not overlap with existing Southern
Resident killer whale habitat, but NMFS has proposed expanding Southern
Resident critical habitat to include waters between the 6.1-m and 200-m
depth contours from the U.S. international border with Canada south to
Point Sur, California (84 FR 49214; September 19, 2019). The proposed
expanded critical habitat areas were identified in consideration of
physical and biological features essential to conservation of Southern
Resident killer whales (essential features): (1) Water quality to
support growth and development; (2) Prey species of sufficient
quantity, quality, and availability to support individual growth,
reproduction, and development, as well as overall population growth;
and (3) Passage conditions to allow for migration, resting, and
foraging. NMFS did not identify in-water sound levels as a separate
essential feature of existing or proposed expanded critical habitat
areas, though anthropogenic sound is recognized as one of the primary
threats to Southern Resident killer whales (NMFS 2019). Exposure to
vessel noise and presence of whale watching boats can significantly
affect the foraging behavior of Southern Resident killer
[[Page 29131]]
whales (Williams et al., 2006; Lusseau et al., 2009; Giles and Cendak
2010; Senigaglia et al., 2016). Nutritional stress has also been
identified as a primary cause of Southern Resident killer whale decline
(Ayres et al., 2012; Wasser et al., 2017), suggesting that reduced
foraging effort may have a greater impact than behavioral disturbance
alone. However, these studies have primarily focused on effects of
whale watch vessels operating in close proximity to Southern Resident
killer whales, and commercial shipping traffic in the Salish Sea (i.e.,
the inland waters of Washington and British Columbia). Commercial whale
watch and private recreational vessels operating in the waters around
the San Juan Islands in summer months number in the dozens (Erbe 2002),
and at least 400 piloted vessels (commercial vessels over 350 gross
tons and pleasure craft over 500 gross tons that are required to be
guided in and out of the Port of Vancouver by British Columbia Coast
Pilots) transit through Haro Strait each month (Joy et al., 2002).
Concentration of vessel traffic on the outer coast, where the survey
area occurs, is much lower than in the inland waters (Cominelli et al.,
2018), suggesting that effects from vessel noise may be lower than in
inland waters. Increased noise levels from the survey in any specific
area would be short-term due to the mobile nature of the survey, unlike
the near-constant vessel presence in inland waters.
Approximately 30 percent of L-DEO's total tracklines occur within
the 200-m isobath along the coast of Oregon, Washington, and British
Columbia. L-DEO is required to shut down seismic airguns immediately
upon visual observation or acoustic detection of killer whales of any
ecotype at any distance to minimize potential exposures of Southern
Resident killer whales, and must operate within the 200-m isobath in
daylight hours only, to increase the ability to visually detect killer
whales and implement shutdowns. Southern Resident killer whales exposed
to elevated sound levels from the R/V Langseth and the airgun array may
reduce foraging time, but no survey tracklines or ensonified area
overlap with the areas of highest estimated densities of Southern
Resident killer whales (see Table 9 of this notice and Figures 7-9 and
7-11 in the U.S. Navy's MSDD (U.S. Navy 2019)). While Southern Resident
killer whales may be encountered outside of these areas of highest
density, the likelihood is significantly decreased and the relatively
small amount of time of altered behavior would not likely affect their
overall foraging ability. Short-term impacts to foraging ability are
not likely to result in significant or lasting consequences for
individual Southern Resident killer whales or the population as a whole
(Ayres et al., 2012). Due to the mobile nature of the survey, animals
would not be exposed to elevated sounds for an extended period, and the
proposed critical habitat contains a large area of suitable habitat
that would allow Southern Resident killer whales to forage away from
the survey. Noren et al. (2016) reported that although resident killer
whales increase energy expenditure in response to vessel presence, the
increase is considered to be negligible.
No permanent hearing impairment (Level A harassment) is anticipated
or authorized. Authorized takes of Southern Resident killer whales
would be limited to Level B harassment in the form of behavioral
disturbance. We anticipate 11 instances of Level B harassment of
Southern Resident killer whales (10 takes by Level B harassment
authorized in this IHA and one take by Level B harassment within
Canadian territorial waters), which we expect would likely occur to a
smaller subset of the population on only a few days. Limited, short
term behavioral disturbance of the nature expected here would not be
expected to result in fitness-level effects to individual Southern
Resident killer whales or the population as a whole.
Negligible Impact Conclusions
The survey will be of short duration (37 days of seismic
operations), and the acoustic ``footprint'' of the survey is small
relative to the ranges of the marine mammals that will potentially be
affected. Sound levels will increase in the marine environment in a
relatively small area surrounding the vessel compared to the range of
the marine mammals within the survey area. Short term exposures to
survey operations are not likely to significantly disrupt marine mammal
behavior, and the potential for longer-term avoidance of important
areas is limited.
The prescribed mitigation measures are expected to reduce the
number and/or severity of takes by allowing for detection of marine
mammals in the vicinity of the vessel by visual and acoustic observers,
and by minimizing the severity of any potential exposures via shutdowns
of the airgun array. Based on previous monitoring reports for
substantially similar activities that have been previously authorized
by NMFS, we expect that the required mitigation will be effective in
preventing, at least to some extent, potential PTS in marine mammals
that may otherwise occur in the absence of the mitigation (although all
authorized PTS has been accounted for in this analysis). Further, for
Southern Resident Killer Whales (as described above), additional
mitigation (e.g., second monitoring vessel, daylight only surveys) is
expected to increase the ability of PSOs to detect killer whales and
shut down the airgun array to reduce the instances and severity of
behavioral disturbance.
While operating within the Canadian EEZ, L-DEO will implement
certain measures prescribed by Canada's DFO that are more protective
than those prescribed by NMFS under the MMPA. These include a
requirement to avoid operating within or nearby designated Southern
Resident or Northern Resident killer whale critical habitat such that
the ensonified area above the 160 dB rms threshold does not extend
inside critical habitat, shutting down the airgun array if a sperm
whale or a beaked whale (any species) is observed within 1,500 m, and
shutting down the airgun array if any species of marine mammal is
observed within 1,000 m of the array. Additionally, throughout the
entire survey area within the Canadian EEZ, L-DEO will not conduct
survey operations in waters 100 m or less and will conduct seismic
surveys in waters 100 to 200 m deep during daylight hours only, with a
second vessel having two marine mammal observers on watch, positioned 5
km ahead of the R/V Langseth. L-DEO must also combine enhanced visual
observations (e.g., reticle and big-eye binoculars, night vision
devices and digital cameras) with non-visual detection methods (e.g.,
infrared technology (FLIR) and PAM) to increase the likelihood of
detecting marine mammals during ramp up, Beaufort sea states >3, and
night time survey operations. Finally, L-DEO must monitor the
established exclusion zone with a radius of 1,000 m for 60 minutes
prior to initial start-up of the airgun array or resumption of
operations following a complete shutdown to allow for the detection of
deep diving animals.
NMFS concludes that exposures to marine mammal species and stocks
due to L-DEO's planned survey will result in only short-term (temporary
and short in duration) effects to individuals exposed, over relatively
small areas of the affected animals' ranges. Animals may temporarily
avoid the immediate area, but are not expected to permanently abandon
the area. Major shifts in habitat use, distribution, or foraging
success are not expected. NMFS does not anticipate the
[[Page 29132]]
authorized take to impact annual rates of recruitment or survival.
In summary and as described above, the following factors primarily
support our determination that the impacts resulting from this activity
are not expected to adversely affect the species or stock through
effects on annual rates of recruitment or survival:
No serious injury or mortality is anticipated or
authorized;
The planned activity is temporary and of relatively short
duration (37 days);
The anticipated impacts of the activity on marine mammals
will primarily be temporary behavioral changes due to avoidance of the
area around the survey vessel;
The number of instances of potential PTS that may occur
are expected to be very small in number. Instances of potential PTS
that are incurred in marine mammals are expected to be of a low level,
due to constant movement of the vessel and of the marine mammals in the
area, and the nature of the survey design (not concentrated in areas of
high marine mammal concentration);
The availability of alternate areas of similar habitat
value for marine mammals to temporarily vacate the survey area during
the planned survey to avoid exposure to sounds from the activity;
The potential adverse effects on fish or invertebrate
species that serve as prey species for marine mammals from the survey
will be temporary and spatially limited, and impacts to marine mammal
foraging will be minimal; and
The mitigation requirements, including visual and acoustic
monitoring, shutdowns, and enhanced measures for areas of biological
importance (e.g., additional monitoring vessel, daylight operations
only) are expected to minimize potential impacts to marine mammals
(both amount and severity).
Additionally as described above for Southern Resident
killer whales specifically, anticipated impacts are limited to few days
of behavioral disturbance for any one individual and additional
mitigation (e.g., additional monitoring vessel, survey timing,
shutdowns) are expected to ensure that both the numbers and severity of
impacts to this stock are minimized, and, therefore the authorization
of Southern Resident killer whale take is not expected to impact the
fitness of any individuals, much less rates of recruitment or survival.
Based on the analysis contained herein of the likely effects of the
specified activity on marine mammals and their habitat, and taking into
consideration the implementation of the prescribed mitigation and
monitoring measures, NMFS finds that the total marine mammal take from
the planned activity will have a negligible impact on all affected
marine mammal species or stocks.
Small Numbers
As noted above, only small numbers of incidental take may be
authorized under Sections 101(a)(5)(A) and (D) of the MMPA for
specified activities other than military readiness activities. The MMPA
does not define small numbers and so, in practice, where estimated
numbers are available, NMFS compares the number of individuals taken to
the most appropriate estimation of abundance of the relevant species or
stock in our determination of whether an authorization is limited to
small numbers of marine mammals. Additionally, other qualitative
factors may be considered in the analysis, such as the temporal or
spatial scale of the activities.
There are two stocks for which the estimated instances of take
appear high when compared to the stock abundance (Table 10)--the
California/Oregon/Washington Dall's porpoise stock and the Northern
Oregon/Washington Coast harbor porpoise stock. However, when other
qualitative factors are used to inform an assessment of the likely
number of individual marine mammals taken, the resulting numbers are
appropriately considered small. We discuss these in further detail
below.
For all other stocks (aside from the two referenced above and
described below), the authorized take is less than one-third of the
best available stock abundance (recognizing that some of those takes
may be repeats of the same individual, thus rendering the actual
percentage even lower). Additionally, we note that the authorized take
is compared to the stock abundance for MMPA designated stocks, which
for many species are limited to U.S. waters and do not include animals
within the Canadian EEZ. Therefore, for species with transboundary
populations, the actual percentage of the population affected is lower
than that shown in Table 10.
The expected take of the California/Oregon/Washington stock of
Dall's porpoises, as a proportion of the population abundance, is 36.94
percent, if all takes are assumed to occur for unique individuals. In
reality, it is unlikely that all takes would occur to different
individuals. L-DEO's survey area represents a small portion of the
stock's overall range (Caretta et al., 2017), and it is more likely
that there will be multiple takes of a smaller number of individuals
within the action area. In addition, Best et al. (2015) estimated the
population of Dall's porpoise in British Columbia to be 5,303 porpoises
based on systematic line-transect surveys of the Strait of Georgia,
Johnstone Strait, Queen Charlotte Sound, Hecate Strait, and Dixon
Entrance between 2004 and 2007. In consideration of the greater
abundance estimate combining the U.S. stock and animals in British
Columbia, and the likelihood of repeated takes of individuals, it is
unlikely that more than one-third of the stock will be exposed to the
seismic survey.
When assuming all estimated takes of harbor porpoise (8,241 total
takes by Level A and B harassment) will occur to the Northern Oregon/
Washington Coast stock, the take appears high relative to stock
abundance (38.35 percent). In reality, takes will occur to both the
Northern Oregon/Washington Coast and Northern California/Southern
Oregon stocks, and therefore, the number of takes of each stock will be
much lower. NMFS has no commonly used method to estimate the relative
proportion of each stock that will experience take, but here we propose
to apportion the takes between the two stocks based on the stock
boundary (Lincoln City, Oregon) and the approximate proportion of the
survey area that will occur on either side of the stock boundary. North
of Lincoln City, Oregon, harbor porpoises belong to the Northern
Oregon/Washington Coast stock, and south of Lincoln City, harbor
porpoises belong to the Northern California/Southern Oregon stock.
Approximately one-third of the planned survey occurs south of Lincoln
City, therefore one-third of the total estimated takes are assumed to
be from the Northern California/Southern Oregon stock. The remaining
two-thirds of the estimated takes are assumed to be from the Northern
Oregon/Washington Coast stock. The estimated one-third of total takes
assigned to the Northern California/Southern Oregon stock (2,747 total
Level A and Level B takes) represent 7.68 percent of the stock
abundance, which NMFS considers to be small relative to the stock
abundance. In addition, the survey area represents a small portion of
the stock's range, and it is likely that there will be multiple takes
of a small portion of individuals, further reducing the number of
individuals exposed. The estimated two-thirds of total takes assigned
to the Northern Oregon/Washington Coast stock (5,494 takes) represent
25.57 percent of the stock abundance, which
[[Page 29133]]
NMFS considers to be small relative to the stock abundance.
Additionally, the Northern Oregon/Washington Coast stock abundance
estimate does not include animals in Canadian waters (Caretta et al.,
2017). Best et al. (2015) estimated a population abundance of 8,091
harbor porpoises in British Columbia. The estimated takes of animals in
the northern portion of the survey area (north of Lincoln City)
represent 18.57 percent of the combined British Columbia and Northern
Oregon/Washington Coast abundance estimates, which NMFS considers to be
small relative to the stock abundance.
Based on the analysis contained herein of the planned activity
(including the required mitigation and monitoring measures) and the
anticipated take of marine mammals, NMFS finds that small numbers of
marine mammals will be taken relative to the population size of the
affected species or stocks.
Unmitigable Adverse Impact Analysis and Determination
There are no relevant subsistence uses of the affected marine
mammal stocks or species implicated by this action. Therefore, NMFS has
determined that the total taking of affected species or stocks will not
have an unmitigable adverse impact on the availability of such species
or stocks for taking for subsistence purposes.
National Environmental Policy Act
To comply with the National Environmental Policy Act of 1969 (NEPA;
42 U.S.C. 4321 et seq.) and NOAA Administrative Order (NAO) 216-6A,
NMFS must review our proposed action (i.e., the issuance of an
incidental harassment authorization) with respect to potential impacts
on the human environment.
Accordingly, NMFS has adopted the NSF's EA, as we have determined
that it includes adequate information analyzing the effects on the
human environment of issuing the IHA, and prepared a FONSI. NSF's EA is
available at https://www.nsf.gov/geo/oce/envcomp/, and NMFS' FONSI is
available at https://www.fisheries.noaa.gov/national/marine-mammal-protection/incidental-take-authorizations-research-and-other-activities.
Endangered Species Act (ESA)
Section 7(a)(2) of the Endangered Species Act of 1973 (ESA: 16
U.S.C. 1531 et seq.) requires that each Federal agency insure that any
action it authorizes, funds, or carries out is not likely to jeopardize
the continued existence of any endangered or threatened species or
result in the destruction or adverse modification of designated
critical habitat. To ensure ESA compliance for the issuance of IHAs,
NMFS consults internally whenever we propose to authorize take for
endangered or threatened species.
The NMFS Office of Protected Resources ESA Interagency Cooperation
Division issued a Biological Opinion under section 7 of the ESA, on the
issuance of an IHA to L-DEO under section 101(a)(5)(D) of the MMPA by
the NMFS OPR Permits and Conservation Division. The Biological Opinion
concluded that the proposed action is not likely to jeopardize the
continued existence of ESA-listed blue whales, fin whales, sei whales,
sperm whales, Central America DPS humpback whales, Mexico DPS humpback
whales, Southern Resident killer whale DPS, and Guadalupe fur seals,
and is not likely to destroy or adversely modify designated Steller sea
lion or humpback whale critical habitat. There is no designated
critical habitat in the action area for the other ESA-listed species.
Authorization
As a result of these determinations, NMFS has issued an IHA to L-
DEO for conducting a marine geophysical survey in the northeast Pacific
Ocean beginning in June 2021, provided the previously mentioned
mitigation, monitoring, and reporting requirements are incorporated.
Dated: May 24, 2021.
Catherine Marzin,
Acting Director, Office of Protected Resources, National Marine
Fisheries Service.
[FR Doc. 2021-11375 Filed 5-27-21; 8:45 am]
BILLING CODE 3510-22-P
