Marine Mammals; Incidental Take During Specified Activities; Proposed Incidental Harassment Authorization for Southcentral Alaska Stock of Northern Sea Otters in Whittier, Alaska, 37556-37571 [2023-12233]

Download as PDF ddrumheller on DSK120RN23PROD with NOTICES1 37556 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices improvement and program management purposes and is not intended for release outside of the agency (if released, procedures outlined in Question 16 will be followed); • Information gathered will not be used for the purpose of substantially informing influential policy decisions 1; • Information gathered will yield qualitative information; the collections will not be designed or expected to yield statistically reliable results or used as though the results are generalizable to the population of study; • The collections are voluntary; • The collections are low-burden for respondents (based on considerations of total burden hours, total number of respondents, or burden-hours per respondent) and are low-cost for both the respondents and the Federal Government; • The collections are noncontroversial and do not raise issues of concern to other Federal agencies; • Any collection is targeted to the solicitation of opinions from respondents who have experience with the program or may have experience with the program in the near future; and • With the exception of information needed to provide renumeration for participants of focus groups and cognitive laboratory studies, personally identifiable information (PII) is collected only to the extent necessary and is not retained. 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Title: Generic Information Collection: USSS Customer Satisfaction Surveys. OMB Number: 1620–NEW. PO 00000 Frm 00052 Fmt 4703 Sfmt 4703 Frequency: On Occasion. Affected Public: Stakeholders/ participants who engage with USSS programs, investigations, and inspections; including, individuals/ households and Federal, State, and Local governments. Number of Respondents: 160,000. Estimated Time per Respondent: 2 Minutes. Total Burden Hours: 5,333 Hours. Frances Humphrey, Information Technology Program Manager, Office of the Chief information Officer. [FR Doc. 2023–12204 Filed 6–7–23; 8:45 am] BILLING CODE 9110–18–P DEPARTMENT OF THE INTERIOR Fish and Wildlife Service [Docket No. FWS–R7–ES–2023–0030; FXES111607MRG01–234–FF07CAMM00] Marine Mammals; Incidental Take During Specified Activities; Proposed Incidental Harassment Authorization for Southcentral Alaska Stock of Northern Sea Otters in Whittier, Alaska Fish and Wildlife Service, Interior. ACTION: Notice of receipt of application; proposed incidental harassment authorization; draft environmental assessment; request for comments. AGENCY: We, the U.S. Fish and Wildlife Service, in response to a request under the Marine Mammal Protection Act of 1972, as amended, from Turnagain Marine Construction, propose to authorize nonlethal, incidental take by harassment of small numbers of the Southcentral Alaska stock of northern sea otters (Enhydra lutris kenyoni) for 1 year from the date of issuance of the incidental harassment authorization. The applicant has requested this authorization for take by harassment that may result from activities associated with pile driving and marine construction activities on the western shore of Passage Canal in Whittier, Alaska. We estimate that this project may result in the nonlethal incidental take by harassment of up to 44 northern sea otters from the Southcentral stock. This proposed authorization, if finalized, will be for up to 70 takes of 7 northern sea otters by Level A harassment and 544 takes of 37 northern sea otters by Level B harassment. No lethal take is requested, or expected, and no such take will be authorized. SUMMARY: Comments on this proposed incidental harassment authorization and DATES: E:\FR\FM\08JNN1.SGM 08JNN1 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices the accompanying draft environmental assessment must be received by July 10, 2023. ADDRESSES: Document availability: You may view this proposed incidental harassment authorization, the application package, supporting information, draft environmental assessment, and the list of references cited herein at https:// www.regulations.gov under Docket No. FWS–R7–ES–2023–0030 or these documents may be requested from the person listed under FOR FURTHER INFORMATION CONTACT. Comment submission: You may submit comments on the proposed authorization by one of the following methods: • U.S. mail: Public Comments Processing, Attn: Docket No. FWS–R7– ES–2023–0030, U.S. Fish and Wildlife Service, MS: PRB (JAO/3W), 5275 Leesburg Pike, Falls Church, VA 22041– 3803. • Electronic submission: Federal eRulemaking Portal at: https:// www.regulations.gov. Follow the instructions for submitting comments to Docket No. FWS–R7–ES–2023–0030. We will post all comments at https:// www.regulations.gov. You may request that we withhold personal identifying information from public review; however, we cannot guarantee that we will be able to do so. See Request for Public Comments for more information. FOR FURTHER INFORMATION CONTACT: Sierra Franks, U.S. Fish and Wildlife Service, MS 341, 1011 East Tudor Road, Anchorage, Alaska 99503, by email at R7mmmregulatory@fws.gov or by telephone at 1–800–362–5148. Individuals in the United States who are deaf, deafblind, hard of hearing, or have a speech disability may dial 711 (TTY, TDD, or TeleBraille) to access telecommunications relay services. Individuals outside the United States should use the relay services offered within their country to make international calls to the point-ofcontact in the United States. SUPPLEMENTARY INFORMATION: ddrumheller on DSK120RN23PROD with NOTICES1 Background Section 101(a)(5)(D) of the Marine Mammal Protection Act of 1972 (MMPA; 16 U.S.C. 1361, et seq.) authorizes the Secretary of the Interior (Secretary) to allow, upon request, the incidental, but not intentional, taking by harassment of small numbers of marine mammals in response to requests by U.S. citizens (as defined in title 50 of the Code of Federal Regulations (CFR) in part 18, at 50 CFR 18.27(c)) engaged in a specified activity (other than VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 commercial fishing) in a specified geographic region during a period of not more than 1 year. The Secretary has delegated authority for implementation of the MMPA to the U.S. Fish and Wildlife Service (‘‘Service’’ or ‘‘we’’). According to the MMPA, the Service shall allow this incidental taking if we make findings that the total of such taking for the 1-year period: (1) is of small numbers of marine mammals of a species or stock; (2) will have a negligible impact on such species or stocks; and (3) will not have an unmitigable adverse impact on the availability of these species or stocks for taking for subsistence use by Alaska Natives. If the requisite findings are made, we issue an authorization that sets forth the following, where applicable: (a) permissible methods of taking; (b) means of effecting the least practicable adverse impact on the species or stock and its habitat and the availability of the species or stock for subsistence uses; and (c) requirements for monitoring and reporting of such taking by harassment, including, in certain circumstances, requirements for the independent peer review of proposed monitoring plans or other research proposals. The term ‘‘take’’ means to harass, hunt, capture, or kill, or to attempt to harass, hunt, capture, or kill any marine mammal. ‘‘Harassment’’ means any act of pursuit, torment, or annoyance which (i) has the potential to injure a marine mammal or marine mammal stock in the wild (the MMPA defines this as ‘‘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 (the MMPA defines this as ‘‘Level B harassment’’). The terms ‘‘negligible impact’’ and ‘‘unmitigable adverse impact’’ are defined in 50 CFR 18.27 (i.e., regulations governing small takes of marine mammals incidental to specified activities) as follows: ‘‘Negligible impact’’ is 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. ‘‘Unmitigable adverse impact’’ means an impact resulting from the specified activity: (1) that is likely to reduce the availability of the species to a level insufficient for a harvest to meet subsistence needs by (i) causing the marine mammals to abandon or avoid hunting areas, (ii) directly displacing PO 00000 Frm 00053 Fmt 4703 Sfmt 4703 37557 subsistence users, or (iii) placing physical barriers between the marine mammals and the subsistence hunters; and (2) that cannot be sufficiently mitigated by other measures to increase the availability of marine mammals to allow subsistence needs to be met. The term ‘‘small numbers’’ is also defined in 50 CFR 18.27. However, we do not rely on that definition here as it conflates ‘‘small numbers’’ with ‘‘negligible impacts.’’ We recognize ‘‘small numbers’’ and ‘‘negligible impacts’’ as two separate and distinct considerations when reviewing requests for incidental harassment authorizations (IHA) under the MMPA (see Natural Res. Def. Council, Inc. v. Evans, 232 F. Supp. 2d 1003, 1025 (N.D. Cal. 2003)). Instead, for our small numbers determination, we estimate the likely number of takes of marine mammals and evaluate if that take is small relative to the size of the species or stock. The term ‘‘least practicable adverse impact’’ is not defined in the MMPA or its enacting regulations. For this IHA, we ensure the least practicable adverse impact by requiring mitigation measures that are effective in reducing the impact of project activities, but they are not so restrictive as to make project activities unduly burdensome or impossible to undertake and complete. If the requisite findings are made, we shall issue an IHA, which may set forth the following, where applicable: (i) permissible methods of taking; (ii) 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 subsistence uses by coastaldwelling Alaska Natives (if applicable); and (iii) requirements for monitoring and reporting take by harassment. Summary of Request On September 16, 2022, Turnagain Marine Construction (hereafter ‘‘TMC’’ or ‘‘the applicant’’) submitted a request to the Service for authorization to take by Level A and Level B harassment a small number of northern sea otters (Enhydra lutris kenyoni) (hereafter ‘‘sea otters’’ or ‘‘otters’’ unless another species is specified) from the Southcentral Alaska stock. The Service sent requests for additional information on November 1, November 30, and December 14, 2022. We received updated versions of the request on November 11, November 23, December 1, and December 22, 2022. The Service determined the December 22, 2022, application to be adequate and complete. TMC expects take by E:\FR\FM\08JNN1.SGM 08JNN1 37558 harassment may occur during the construction of their cruise ship berth and associated facilities on the western shore of Passage Canal in Whittier, Alaska. Description of Specified Activities and Specified Geographic Region ddrumheller on DSK120RN23PROD with NOTICES1 The specified activity (hereafter ‘‘project’’) will include installation and removal of piles for the construction of a 152-by-21 meter (m) (500-by-70-foot (ft)) floating cruise ship dock in Whittier, Alaska (figure 1) between April 2023 and April 2024. TMC will install and remove 72 91-centimeter Description of Marine Mammals in the Specified Geographic Region Sea Otter Biology There are three sea otter stocks in Alaska: Southeast Alaska stock, Southcentral Alaska stock, and the Southwest Alaska stock. Only the Southcentral Alaska stock is represented in the project area. Detailed information VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 (cm) (36-inch (in)) diameter steel piles and will permanently install the following types of piles: 36 91-cm (36in) diameter steel piles, 16 107-cm (42in) diameter steel piles, and 20 122-cm (48-in) diameter steel piles. Dock components that will be installed out of water include bull rail, fenders, mooring cleat, pre-cast concrete dock surface, and mast lights. Pile-driving activities will occur over 129 non-consecutive days for approximately 321 hours during the course of 1 year from date of issuance of the IHA. If the IHA is issued after TMC’s intended start date in April 2023, its schedule for conducting the specified activities may be adjusted accordingly. Pile installation will be done with a combination of impact, vibratory, and down-the-hole (DTH) drilling. Temporary piles will be removed with the vibratory hammer. Materials and equipment will be transported via barges, and workers will be transported to and from the barge work platform via skiff. Additional project details may be reviewed in the application materials available as described under ADDRESSES or may also be requested as described under FOR FURTHER INFORMATION CONTACT. about the biology of this stock can be found in the most recent Southcentral Alaska draft stock assessment report (USFWS 2023), which can be found at https://www.regulations.gov/document/ FWS-R7-ES-2022-0155-0004 and was announced in the Federal Register at 88 FR 7992, February 7, 2023. Sea otters may be distributed anywhere within the specified project area other than upland areas; however, they generally occur in shallow water near the shoreline. They are most commonly observed within the 40-m (131-ft) depth contour (USFWS 2023), although they can be found in areas with deeper water. Ocean depth is generally correlated with distance to shore, and sea otters typically remain PO 00000 Frm 00054 Fmt 4703 Sfmt 4703 E:\FR\FM\08JNN1.SGM 08JNN1 EN08JN23.001</GPH> Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices within 1 to 2 kilometers (km) (0.62 to 1.24 miles (mi)) of shore (Riedman and Estes 1990). They tend to be found closer to shore during storms, but venture farther out during good weather and calm seas (Lensink 1962; Kenyon 1969). Sea otters are nonmigratory and generally do not disperse over long distances (Garshelis and Garshelis 1984), usually remaining within a few kilometers of their established feeding grounds (Kenyon 1981). Breeding males stay for all or part of the year in a breeding territory covering up to 1 km (0.62 mi) of coastline, while adult females maintain home ranges of approximately 8 to 16 km (5 to 10 mi), which may include one or more male territories. Juveniles move greater distances between resting and foraging areas (Lensink 1962; Kenyon 1969; Riedman and Estes 1990; Tinker and Estes 1996). Although sea otters generally remain local to an area, they are capable of long-distance travel. Sea otters in Alaska have shown daily movement distances greater than 3 km (1.9 mi) at speeds up to 5.5 km per hour (hr) (km/hr; 3.4 mi/hr) (Garshelis and Garshelis 1984). Southcentral Alaska Sea Otter Stock The Southcentral Alaska sea otter stock occurs in the center of the sea otter range in Alaska and extends from Cape Yakataga in the east to Cook Inlet in the west, including Prince William Sound, the eastern Kenai Peninsula coast, and Kachemak Bay (USFWS 2023). Between 2014 and 2019, aerial surveys were conducted in three regions of the Southcentral Alaska sea otter stock: (1) Eastern Cook Inlet, (2) Outer Kenai Peninsula, and (3) Prince William Sound by aerial transects flown at 91 m (298.56 ft) of altitude. The combined estimates of the three regions resulted in approximately 21,617 (SE = 2,190) sea otters and an average density of 1.96 sea otters per square kilometer (km2) for the Southcentral Alaska stock (Esslinger et al. 2021). We applied the average density of sea otters in Prince William Sound, 2.03 sea otters/km2 (Esslinger et al. 2021). ddrumheller on DSK120RN23PROD with NOTICES1 Potential Impacts of the Specified Activities on Marine Mammals Effects of Noise on Sea Otters We characterized ‘‘noise’’ as sound released into the environment from human activities that exceeds ambient levels or interferes with normal sound production or reception by sea otters. The terms ‘‘acoustic disturbance’’ or ‘‘acoustic harassment’’ are disturbances or harassment events resulting from VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 noise exposure. Potential effects of noise exposure are likely to depend on the distance of the sea otter from the sound source, the level and intensity of sound the sea otter receives, background noise levels, noise frequency, noise duration, and whether the noise is pulsed or continuous. The actual noise level perceived by individual sea otters will also depend on whether the sea otter is above or below water and atmospheric and environmental conditions. Temporary disturbance of sea otters or localized displacement reactions are the most likely effects to occur from noise exposure. Sea Otter Hearing Pile driving and marine construction activities will fall within the hearing range of sea otters. Controlled sound exposure trials on southern sea otters (Enhydra lutris nereis) indicate that sea otters can hear frequencies between 125 hertz (Hz) and 38 kilohertz (kHz) with best sensitivity between 1.2 and 27 kHz (Ghoul and Reichmuth 2014). Aerial and underwater audiograms for a captive adult male southern sea otter in the presence of ambient noise suggest the sea otter’s hearing was less sensitive to high-frequency (greater than 22 kHz) and low-frequency (less than 2 kHz) sound than terrestrial mustelids but was similar to that of a California sea lion (Zalophus californianus). However, the sea otter was still able to hear lowfrequency sounds, and the detection thresholds for sounds between 0.125–1 kHz were between 116–101 decibels (dB), respectively. Dominant frequencies of southern sea otter vocalizations are between 3 and 8 kHz, with some energy extending above 60 kHz (McShane et al. 1995, Ghoul and Reichmuth 2012). Exposure to high levels of sound may cause changes in behavior, masking of communications, temporary or permanent changes in hearing sensitivity, discomfort, and injury to marine mammals. Unlike other marine mammals, sea otters do not rely on sound to orient themselves, locate prey, or communicate under water; therefore, masking of communications by anthropogenic sound is less of a concern than for other marine mammals. However, sea otters, especially mothers and pups, do use sound for communication in air (McShane et al. 1995), and sea otters may monitor underwater sound to avoid predators (Davis et al. 1987). Exposure Thresholds Noise exposure criteria for identifying underwater noise levels capable of causing Level A harassment to marine PO 00000 Frm 00055 Fmt 4703 Sfmt 4703 37559 mammal species, including sea otters, have been established using the same methods as those used by the National Marine Fisheries Service (NMFS) (Southall et al. 2019). These criteria are based on estimated levels of sound exposure capable of causing a permanent shift in sensitivity of hearing (i.e., a permanent threshold shift (PTS) (NMFS 2018)). PTS occurs when noise exposure causes hairs within the inner ear system to die (Ketten 2012). Although the effects of PTS are, by definition, permanent, PTS does not equate to total hearing loss. Sound exposure thresholds incorporate two metrics of exposure: the peak level of instantaneous exposure likely to cause PTS and the cumulative sound exposure level (SELCUM) during a 24-hour period. They also include weighting adjustments for the sensitivity of different species to varying frequencies. PTS-based injury criteria were developed from theoretical extrapolation of observations of temporary threshold shifts (TTS) detected in lab settings during sound exposure trials (Finneran 2015). Southall and colleagues (2019) predict PTS for sea otters, which are included in the ‘‘other marine carnivores’’ category, will occur at 232 dB peak or 203 dB SELCUM for impulsive underwater sound and 219 dB SELCUM for nonimpulsive (continuous) underwater sound. Thresholds based on TTS have been used as a proxy for Level B harassment (i.e., 70 FR 1871, January 11, 2005; 71 FR 3260, January 20, 2006; 73 FR 41318, July 18, 2008). Southall et al. (2007) derived TTS thresholds for pinnipeds based on 212 dB peak and 171 dB SELCUM. Exposures resulting in TTS in pinnipeds were found to range from 152 to 174 dB (183 to 206 dB SEL) (Kastak et al. 2005), with a persistent TTS, if not a PTS, after 60 seconds of 184 dB SEL (Kastak et al. 2008). Kastelein et al. (2012) found small but statistically significant TTSs at approximately 170 dB SEL (136 dB, 60 minutes (min)) and 178 dB SEL (148 dB, 15 min). Based on these findings, Southall et al. (2019) developed TTS thresholds for sea otters, which are included in the ‘‘other marine carnivores’’ category, of 188 dB SELCUM for impulsive sounds and 199 dB SELCUM for nonimpulsive sounds. The NMFS (2018) criteria do not identify thresholds for avoidance of Level B harassment. For pinnipeds (seals and sea lions), NMFS has adopted a 160-dB threshold for Level B harassment from exposure to impulsive noise and a 120-dB threshold for continuous noise (NMFS 1998, HESS 1999, NMFS 2018). These thresholds E:\FR\FM\08JNN1.SGM 08JNN1 37560 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices were developed from observations of mysticete (baleen) whales responding to airgun operations (e.g., Malme et al. 1983; Malme and Miles 1983; Richardson et al. 1986, 1995) and from equating Level B harassment with noise levels capable of causing TTS in lab settings. Southall et al. (2007, 2019) assessed behavioral response studies and found considerable variability among pinnipeds. The authors determined that exposures between approximately 90 to 140 dB generally do not appear to induce strong behavioral responses from pinnipeds in water. However, they found behavioral effects, including avoidance, become more likely in the range between 120 to 160 dB, and most marine mammals showed some, albeit variable, responses to sound between 140 to 180 dB. Wood et al. (2012) adapted the approach identified in Southall et al. (2007) to develop a probabilistic scale for marine mammal taxa at which 10 percent, 50 percent, and 90 percent of individuals exposed are assumed to produce a behavioral response. For many marine mammals, including pinnipeds, these response rates were set at sound pressure levels of 140, 160, and 180 dB, respectively. We have evaluated these thresholds and determined that the Level B threshold of 120 dB for nonimpulsive noise is not applicable to sea otters. The 120-dB threshold is based on studies in which gray whales (Eschrichtius robustus) were exposed to experimental playbacks of industrial noise (Malme et al. 1983; Malme and Miles 1983). During these playback studies, southern sea otter responses to industrial noise were also monitored (Riedman 1983, 1984). Gray whales exhibited avoidance to industrial noise at the 120-dB threshold; however, there was no evidence of disturbance reactions or avoidance in southern sea otters. Thus, given the different range of frequencies to which sea otters and gray whales are sensitive, the NMFS 120-dB threshold based on gray whale behavior is not appropriate for predicting sea otter behavioral responses, particularly for low-frequency sound. Based on the lack of sea otter disturbance response or any other reaction to the playback studies from the 1980s, as well as the absence of a clear pattern of disturbance or avoidance behaviors attributable to underwater sound levels up to about 160 dB resulting from low-frequency broadband noise, we assume 120 dB is not an appropriate behavioral response threshold for sea otters exposed to continuous underwater noise. Based on the best available scientific information about sea otters, and closely related marine mammals when sea otter data are limited, the Service has set 160 dB of received underwater sound as a threshold for Level B harassment by disturbance for sea otters for this proposed IHA. Exposure to unmitigated in-water noise levels between 125 Hz and 38 kHz that are greater than 160 dB—for both impulsive and nonimpulsive sound sources—will be considered by the Service as Level B harassment. Thresholds for Level A harassment (which entails the potential for injury) will be 232 dB peak or 203 dB SEL for impulsive sounds and 219 dB SEL for continuous sounds (table 1). Airborne Sounds The NMFS (2018) guidance neither addresses thresholds for preventing injury or disturbance from airborne noise, nor provides thresholds for avoidance of Level B harassment. Southall et al. (2007) suggested thresholds for PTS and TTS for sea lions exposed to nonpulsed airborne noise of 172.5 and 159 dB re (20 mPa)2-s SEL. Conveyance of underwater noise into the air is of little concern since the effects of pressure release and interference at the water’s surface reduce underwater noise transmission into the air. For activities that create both in-air and underwater sounds, we will estimate take based on parameters for underwater noise transmission. Considering sound energy travels more efficiently through water than through air, this estimation will also account for exposures to sea otters at the surface. TABLE 1—TEMPORARY THRESHOLD SHIFT (TTS) AND PERMANENT THRESHOLD SHIFT (PTS) THRESHOLDS ESTABLISHED BY SOUTHALL ET AL. (2019) THROUGH MODELING AND EXTRAPOLATION FOR ‘‘OTHER MARINE CARNIVORES,’’ WHICH INCLUDES SEA OTTERS [Values are weighted for other marine carnivores’ hearing thresholds and given in cumulative sound exposure level (SELCUM dB re (20 micropascal (μPa) in air and SELCUM dB re 1 μPa in water) for impulsive and nonimpulsive sounds and unweighted peak sound pressure level (SPL) in air (dB re 20 μPa) and water (dB 1 μPa) (impulsive sounds only).] TTS Nonimpulsive SELCUM Air ............................................................. Water ........................................................ ddrumheller on DSK120RN23PROD with NOTICES1 Sea otters may be more resistant to the effects of sound disturbance and human activities than other marine mammals. For example, observers have noted no changes from southern sea otters in regard to their presence, density, or behavior in response to underwater sounds from industrial noise recordings at 110 dB and a frequency range of 50 Hz to 20 kHz and airguns, even at the closest distance of 0.5 nautical miles (<1 km or 0.6 mi) (Riedman 1983). Southern sea otters did not respond noticeably to VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 Impulsive SELCUM 157 199 Evidence From Sea Otter Studies PTS Nonimpulsive Peak SPL 146 188 170 226 noise from a single 1,638 cubic centimeters (cm3) (100 cubic inches [in3]) airgun, and no sea otter disturbance reactions were evident when a 67,006 cm3 (4,089 in3) airgun array was as close as 0.9 km (0.6 mi) to sea otters (Riedman 1983, 1984). However, southern sea otters displayed slight reactions to airborne engine noise (Riedman 1983). Northern sea otters were observed to exhibit a limited response to a variety of airborne and underwater sounds, including a warble tone, sea otter pup calls, calls from PO 00000 Frm 00056 Fmt 4703 Sfmt 4703 SELCUM 177 219 Impulsive SELCUM 161 203 Peak SPL 176 232 killer whales (Orcinus orca) (which are predators to sea otters), air horns, and an underwater noise harassment system designed to drive marine mammals away from crude oil spills (Davis et al. 1988). These sounds elicited reactions from northern sea otters, including startle responses and movement away from noise sources. However, these reactions were observed only when northern sea otters were within 100 to 200 m (328 to 656 ft) of noise sources. Further, northern sea otters appeared to become habituated to the noises within E:\FR\FM\08JNN1.SGM 08JNN1 ddrumheller on DSK120RN23PROD with NOTICES1 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices 2 hours or, at most, 3–4 days (Davis et al. 1988). Noise exposure may be influenced by the amount of time sea otters spend at the water’s surface. Noise at the water’s surface can be attenuated by turbulence from wind and waves more quickly compared to deeper water, reducing potential noise exposure (Greene and Richardson 1988, Richardson et al. 1995). Additionally, turbulence at the water’s surface limits the transference of sound from water to air. A sea otter with its head above water will be exposed to only a small fraction of the sound energy traveling through the water beneath it. The average amount of time that sea otters spend above the water each day while resting and grooming varies between males and females and across seasons (Esslinger et al. 2014, Zellmer et al. 2021). For example, female sea otters foraged for an average of 8.78 hours per day compared to male sea otters, which foraged for an average of 7.85 hours per day during the summer months (Esslinger et al. 2014). Male and female sea otters spend an average of 63 to 67 percent of their day at the surface resting and grooming during the summer months (Esslinger et al. 2014). Few studies have evaluated foraging times during the winter months. Garshelis et al. (1986) found that foraging times increased from 5.1 hours per day to 16.6 hours per day in the winter; however, Gelatt et al. (2002) did not find a significant difference in seasonal foraging times. It is likely that seasonal variation is determined by seasonal differences in energetic demand and the quality and availability of prey sources (Esslinger et al. 2014). These findings suggest that the large portion of the day sea otters spend at the surface may help limit sea otters’ exposure during noise-generating operations. Sea otter sensitivity to industrial activities may be influenced by the overall level of human activity within the sea otter population’s range. In locations that lack frequent human activity, sea otters appear to have a lower threshold for disturbance. Sea otters in Alaska exhibited escape behaviors in response to the presence and approach of vessels (Udevitz et al. 1995). Behaviors included diving or actively swimming away from a vessel, entering the water from haulouts, and disbanding groups with sea otters swimming in multiple different directions (Udevitz et al. 1995). Sea otters in Alaska were also observed to avoid areas with heavy boat traffic in the summer and return to these areas during seasons with less vessel traffic (Garshelis and Garshelis 1984). In Cook VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 Inlet, sea otters drifting on a tide trajectory that would have taken them within 500 m (0.3 mi) of an active offshore drilling rig were observed to swim in order to avoid a close approach of the drilling rig despite near-ambient noise levels (BlueCrest 2013). Individual sea otters in Passage Canal will likely show a range of responses to noise from pile-driving activities. Some sea otters will likely dive, show startle responses, change direction of travel, or prematurely surface. Sea otters reacting to pile-driving activities may divert time and attention from biologically important behaviors, such as feeding and nursing pups. Sea otter responses to disturbance can result in energetic costs, which increases the amount of prey required by sea otters (Barrett 2019). This increased prey consumption may impact sea otter prey availability and cause sea otters to spend more time foraging and less time resting (Barrett 2019). Some sea otters may abandon the project area and return when the disturbance has ceased. Based on the observed movement patterns of sea otters (i.e., Lensink 1962; Kenyon 1969, 1981; Garshelis and Garshelis 1984; Riedman and Estes 1990; Tinker and Estes 1996), we expect some individuals will respond to pile-driving activities by dispersing to nearby areas of suitable habitat; however, other sea otters, especially territorial adult males, are less likely to be displaced. Consequences of Disturbance The reactions of wildlife to disturbance can range from short-term behavioral changes to long-term impacts that affect survival and reproduction. When disturbed by noise, animals may respond behaviorally (e.g., escape response) or physiologically (e.g., increased heart rate, hormonal response) (Harms et al. 1997; Tempel and Gutie´rrez 2003). Theoretically, the energy expense and associated physiological effects from repeated disturbance could ultimately lead to reduced survival and reproduction (Gill and Sutherland 2000; Frid and Dill 2002). For example, South American sea lions (Otaria byronia) visited by tourists exhibited an increase in the state of alertness and a decrease in maternal attendance and resting time on land, thereby potentially reducing population size (Pavez et al. 2015). In another example, killer whales that lost feeding opportunities due to boat traffic faced a substantial (18 percent) estimated decrease in energy intake (Williams et al. 2006). In severe cases, such disturbance effects could have population-level consequences. For example, increased disturbance by PO 00000 Frm 00057 Fmt 4703 Sfmt 4703 37561 tourism vessels has been associated with a decline in abundance of bottlenose dolphins (Tursiops spp.) (Bejder et al. 2006; Lusseau et al. 2006). However, these examples evaluated sources of disturbance that were longer term and more consistent than the temporary and intermittent nature of the specified project activities. These examples illustrate direct effects on survival and reproductive success, but disturbances can also have indirect effects. Response to noise disturbance is considered a nonlethal stimulus that is similar to an antipredator response (Frid and Dill 2002). Sea otters are susceptible to predation, particularly from killer whales and eagles, and have a welldeveloped antipredator response to perceived threats. For example, the presence of a harbor seal (Phoca vitulina) did not appear to disturb southern sea otters, but they demonstrated a fear response in the presence of a California sea lion by actively looking above and beneath the water (Limbaugh 1961). Although an increase in vigilance or a flight response is nonlethal, a tradeoff occurs between risk avoidance and energy conservation. An animal’s reactions to noise disturbance may cause stress and direct an animal’s energy away from fitness-enhancing activities such as feeding and mating (Frid and Dill 2002; Goudie and Jones 2004). For example, southern sea otters in areas with heavy recreational boat traffic demonstrated changes in behavioral time budgeting, showing decreased time resting and changes in haulout patterns and distribution (Benham 2006; Maldini et al. 2012). Chronic stress can also lead to weakened reflexes, lowered learning responses (Welch and Welch 1970; van Polanen Petel et al. 2006), compromised immune function, decreased body weight, and abnormal thyroid function (Selye 1979). Changes in behavior resulting from anthropogenic disturbance can include increased agonistic interactions between individuals or temporary or permanent abandonment of an area (Barton et al. 1998). Additionally, the extent of previous exposure to humans (Holcomb et al. 2009), the type of disturbance (Andersen et al. 2012), and the age or sex of the individuals (Shaughnessy et al. 2008; Holcomb et al. 2009) may influence the type and extent of response in individual sea otters. Vessel Activities Vessel collisions with marine mammals can result in death or serious injury. Wounds resulting from vessel E:\FR\FM\08JNN1.SGM 08JNN1 ddrumheller on DSK120RN23PROD with NOTICES1 37562 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices strike may include massive trauma, hemorrhaging, broken bones, or propeller lacerations (Knowlton and Kraus 2001). An animal may be harmed by a vessel when the vessel runs over the animal at the surface, the animal hits the bottom of a vessel while the animal is surfacing, or the animal is cut by a vessel’s propeller. Vessel strike has been documented as a cause of death across all three stocks of northern sea otters in Alaska. Since 2002, the Service has conducted 1,433 sea otter necropsies to determine cause of death, disease incidence, and the general health status of sea otters in Alaska. Vessel strike or blunt trauma was identified as a definitive or presumptive cause of death in 65 cases (4 percent) (USFWS 2020). In most of these cases, trauma was determined to be the ultimate cause of death; however, there was a contributing factor, such as disease or biotoxin exposure, which incapacitated the sea otter and made it more vulnerable to vessel strike (USFWS 2023). Vessel speed influences the likelihood of vessel strikes involving sea otters. The probability of death or serious injury to a marine mammal increases as vessel speed increases (Laist et al. 2001, Vanderlaan and Taggart 2007). Sea otters spend a considerable portion of their time at the water’s surface (Esslinger et al. 2014). They are typically visually aware of approaching vessels and can move away if a vessel is not traveling too quickly. Mitigation measures to be applied to vessel operations to prevent collisions or interactions are included below in the proposed authorization portion of this document under Avoidance and Minimization. Sea otters exhibit behavioral flexibility in response to vessels, and their responses may be influenced by the intensity and duration of the vessel’s activity. As noted above, sea otter populations in Alaska were observed to avoid areas with heavy vessel traffic but return to those same areas during seasons with less vessel traffic (Garshelis and Garshelis 1984). Sea otters have also shown signs of disturbance or escape behaviors in response to the presence and approach of survey vessels including sea otters diving and/or actively swimming away from a vessel, sea otters on haulouts entering the water, and groups of sea otters disbanding and swimming in multiple different directions (Udevitz et al. 1995). Additionally, sea otter responses to vessels may be influenced by the sea otter’s previous experience with vessels. Groups of southern sea otters in two VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 locations in California showed markedly different responses to kayakers approaching to within specific distances, suggesting a different level of tolerance between the groups (Gunvalson 2011). Benham (2006) found evidence that the sea otters exposed to high levels of recreational activity may have become more tolerant than individuals in less-disturbed areas. Sea otters off the California coast showed only mild interest in vessels passing within hundreds of meters and appeared to have habituated to vessel traffic (Riedman 1983, Curland 1997). These findings indicate that sea otters may adjust their responses to vessel activities depending on the level of activity. Vessel activity during the project includes the transit of three barges for materials and construction, all of which will remain onsite, mostly stationary, to support the work; additionally, two skiffs will be used during the project: one for transporting workers short distances to the crane barge and the other for marine mammal monitoring during pile driving. Vessels will not be used extensively or over a long duration during the planned work; therefore, we do not anticipate that sea otters will experience changes in behavior indicative of tolerance or habituation. Effects on Sea Otter Habitat and Prey Physical and biological features of habitat essential to the conservation of sea otters include the benthic invertebrates that sea otters eat and the shallow rocky areas and kelp beds that provide cover from predators. Sea otter habitat in the project area includes coastal areas within the 40-m (131-ft) depth contour where high densities of sea otters have been detected. Industrial activities, such as pile driving, may generate in-water noise at levels that can temporarily displace sea otters from important habitat and impact sea otter prey species. The primary prey species for sea otters are sea urchins (Strongylocentrotus spp. and Mesocentrotus spp.), abalone (Haliotis spp.), clams (e.g., Clinocardium nuttallii, Leukoma staminea, and Saxidomus gigantea), mussels (Mytilus spp.), crabs (e.g., Metacarcinus magister, Pugettia spp., Telemessus cheiragonus, and Cancer spp.), and squid (Loligo spp.) (Tinker and Estes 1996, LaRoche et al. 2021). When preferential prey are scarce, sea otters will also eat kelp, slow-moving benthic fishes, sea cucumbers (e.g., Apostichopus californicus), egg cases of rays, turban snails (Tegula spp.), octopuses (e.g., Octopus spp.), barnacles (Balanus spp.), sea stars (e.g., PO 00000 Frm 00058 Fmt 4703 Sfmt 4703 Pycnopodia helianthoides), scallops (e.g., Patinopecten caurinus), rock oysters (Saccostrea spp.), worms (e.g., Eudistylia spp.), and chitons (e.g., Mopalia spp.) (Riedman and Estes 1990, Davis and Bodkin 2021). Several studies have addressed the effects of noise on invertebrates (Tidau and Briffa 2016, Carroll et al. 2017). Behavioral changes, such as an increase in lobster (Homarus americanus) feeding levels (Payne et al. 2007), an increase in avoidance behavior by wildcaught captive reef squid (Sepioteuthis australis) (Fewtrell and McCauley 2012), and deeper digging by razor clams (Sinonovacula constricta) (Peng et al. 2016) have been observed following experimental exposures to sound. Physical changes have also been observed in response to increased sound levels, including changes in serum biochemistry and hepatopancreatic cells in lobsters (Payne et al. 2007) and longterm damage to the statocysts required for hearing in several cephalopod species (Andre´ et al. 2011, Sole´ et al. 2013). De Soto et al. (2013) found impaired embryonic development in scallop (Pecten novaezelandiae) larvae when exposed to 160 dB. Christian et al. (2003) noted a reduction in the speed of egg development of bottom-dwelling crabs following exposure to noise; however, the sound level (221 dB at 2 m or 6.6 ft) was far higher than the planned project activities will produce. Industrial noise can also impact larval settlement by masking the natural acoustic settlement cues for crustaceans and fish (Pine et al. 2012, Simpson et al. 2016, Tidau and Briffa 2016). While these studies provide evidence of deleterious effects to invertebrates as a result of increased sound levels, Carroll et al. (2017) caution that there is a wide disparity between results obtained in field and laboratory settings. In experimental settings, changes were observed only when animals were housed in enclosed tanks, and many were exposed to prolonged bouts of continuous, pure tones. We would not expect similar results in open marine conditions. It is unlikely that noises generated by project activities will have any lasting effect on sea otter prey given the short-term duration of sounds produced by each component of the planned work. Noise-generating activities that interact with the seabed can produce vibrations, resulting in the disturbance of sediment and increased turbidity in the water. Although turbidity is likely to have little impact on sea otters and prey species (Todd et al. 2015), there may be some impacts from vibrations and increased sedimentation. For example, E:\FR\FM\08JNN1.SGM 08JNN1 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices mussels (Mytilus edulis) exhibited changes in valve gape and oxygen demand, and hermit crabs (Pagurus bernhardus) exhibited limited behavioral changes in response to vibrations caused by pile driving (Roberts et al. 2016). Increased sedimentation is likely to reduce sea otter visibility, which may result in reduced foraging efficiency and a potential shift to less-preferred prey species. These outcomes may cause sea otters to spend more energy on foraging or processing the prey items; however, the impacts of a change in energy expenditure are not likely seen at the population level (Newsome et al. 2015). Additionally, the benthic invertebrates may be impacted by increased sedimentation, resulting in higher abundances of opportunistic species that recover quickly from industrial activities that increase sedimentation (Kotta et al. 2009). Although sea otter foraging could be impacted by industrial activities that cause vibrations and increased sedimentation, it is more likely that sea otters would be temporarily displaced from the project area due to impacts from noise rather than vibrations and sedimentation. ddrumheller on DSK120RN23PROD with NOTICES1 Potential Impacts of the Specified Activities on Subsistence Uses The planned specified activities will occur near marine subsistence harvest areas used by Alaska Natives from Whittier and the surrounding areas. The majority of sea otter harvest in this area occurs more than 3.2 km (2 mi) outside of Whittier. Since 2012, there have been 75 sea otters harvested in the Whittier area, and most of those were taken prior to 2017. From 2018 through 2021, only eight sea otters were harvested from the Whittier area. The planned project would occur within the Whittier city limits, where firearm use is prohibited. The area potentially affected by the planned project does not significantly overlap with current subsistence harvest areas. Construction activities will not preclude access to hunting areas or interfere in any way with individuals wishing to hunt. Despite no conflict with subsistence use being anticipated, the Service will conduct outreach with potentially affected communities to see whether there are any questions, concerns, or potential conflicts regarding subsistence use in those areas. If any conflicts are identified in the future, TMC will develop a plan of cooperation specifying the steps necessary to minimize any effects the project may have on subsistence harvest. VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 Estimated Take Definitions of Incidental Take Under the Marine Mammal Protection Act Below we provide definitions of three potential types of take of sea otters. The Service does not anticipate and is not authorizing lethal take as a part of this proposed IHA; however, the definitions of these take types are provided for context and background: Lethal Take—Human activity may result in biologically significant impacts to sea otters. In the most serious interactions, human actions can result in mortality of sea otters. Level A Harassment—Human activity may result in the injury of sea otters. Level A harassment, for nonmilitary readiness activities, is defined as any act of pursuit, torment, or annoyance that has the potential to injure a marine mammal or marine mammal stock in the wild. Level B Harassment—Level B Harassment for nonmilitary readiness activities means any act of pursuit, torment, or annoyance that 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, feeding, or sheltering. Changes in behavior that disrupt biologically significant behaviors or activities for the affected animal are indicative of take by Level B harassment under the MMPA. The Service has identified the following sea otter behaviors as indicative of possible Level B harassment: • Swimming away at a fast pace on belly (i.e., porpoising); • Repeatedly raising the head vertically above the water to get a better view (spyhopping) while apparently agitated or while swimming away; • In the case of a pup, repeatedly spyhopping while hiding behind and holding onto its mother’s head; • Abandoning prey or feeding area; • Ceasing to nurse and/or rest (applies to dependent pups); • Ceasing to rest (applies to independent animals); • Ceasing to use movement corridors; • Ceasing mating behaviors; • Shifting/jostling/agitation in a raft so that the raft disperses; • Sudden diving of an entire raft; or • Flushing animals off a haulout. This list is not meant to encompass all possible behaviors; other behavioral responses may equate to take by Level B harassment. Relatively minor changes in behavior such as increased vigilance or a short-term change in direction of travel are not likely to disrupt PO 00000 Frm 00059 Fmt 4703 Sfmt 4703 37563 biologically important behavioral patterns, and the Service does not view such minor changes in behavior as indicative of a take by Level B harassment. Calculating Take We assumed all animals exposed to underwater sound levels that meet the acoustic exposure criteria defined above in Exposure Thresholds will experience take by Level A or Level B harassment due to exposure to underwater noise. Spatially explicit zones of ensonification were established around the planned construction location to estimate the number of otters that may be exposed to these sound levels. We determined the number of otters present in the ensonification zones using density information generated by Esslinger et al. (2021). The project can be divided into four major components: DTH drilling, vibratory drilling, pile driving using an impact driver, and skiff use to support construction. Each of these components will generate a different type of in-water noise. Vibratory drilling and the use of skiffs will produce nonimpulsive or continuous noise; impact driving will produce impulsive noise; and DTH drilling is considered to produce both impulsive and continuous noise (NMFS 2020). The level of sound anticipated from each project component was established using recorded data from several sources listed in tables 2 through 5. We used the NMFS Technical Guidance and User Spreadsheet (NMFS 2018, 2020) to determine the distance at which sound levels would attenuate to Level A harassment thresholds, and empirical data from the proxy projects were used to determine the distance at which sound levels would attenuate to Level B harassment thresholds (table 1). The weighting factor adjustment included in the NMFS user spreadsheet accounts for sounds created in portions of an organism’s hearing range where they have less sensitivity. We used the weighting factor adjustment for otariid pinnipeds as they are the closest available physiological and anatomical proxy for sea otters. The spreadsheet also incorporates a transmission loss coefficient, which accounts for the reduction in sound level outward from a sound source. We used the NMFSrecommended transmission loss coefficient of 15 for coastal pile-driving activities to indicate practical spread (NMFS 2020). We calculated the harassment zones for DTH drilling with input from NMFS. The sound pressure levels produced by DTH drilling were provided by NMFS in E:\FR\FM\08JNN1.SGM 08JNN1 37564 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices 2022 via correspondence with Solstice Alaska Consulting, who created the application for this IHA on behalf of TMC. We then used the NMFS Technical Guidance and User Spreadsheet (NMFS 2018, 2020) to determine the distance at which these sounds would attenuate to Level A harassment thresholds. To estimate the distances at which sounds would attenuate to Level B harassment thresholds, we used the NMFSrecommended transmission loss coefficient of 15 for coastal pile-driving activities in a practical spreading loss model (NMFS 2020) to determine the distance at which sound levels attenuate to 160 dB re 1 mPa. However, due to the differences in how PTS and TTS thresholds are calculated, as well as limited data of underwater sound pressure levels from DTH drilling, the resultant Level A isopleths are larger than the Level B isopleths. TABLE 2—SUMMARY OF SOUND LEVEL, TIMING OF SOUND PRODUCTION, DISTANCE FROM SOUND SOURCE TO BELOW LEVEL A HARASSMENT AND LEVEL B HARASSMENT THRESHOLDS, DAYS OF IMPACT, SEA OTTERS IN LEVEL A AND LEVEL B HARASSMENT ENSONIFICATION AREA, AND TOTAL OTTERS EXPECTED TO BE HARASSED THROUGH BEHAVIORAL DISTURBANCE BY VIBRATORY DRILLING Pile size 91-cm (36-in) (temporary)installation 91-cm (36-in) (temporary)removal 91-cm (36-in) (permanent) 107-cm (42-in) Total number of piles .......................... 72 ......................... 72 ......................... 36 ......................... 16 ......................... Sound level ......................................... 166 dB re 1μPa at 10 m (RMS) NAVFAC a Source ................................................. Timing per pile .................................... Maximum number of piles per day ..... Maximum number of days of activity .. 10 minutes/pile ..... 4 ........................... 18 ......................... a Naval Austin et al. 2016 15 minutes/pile ..... 4 ........................... 9 ........................... 15 minutes/pile ..... 4 ........................... 4 ........................... 15 minutes/pile. 2. 10. 2.03 sea otters/km2 Sea otter density ................................. Distance to below Level A harassment threshold. Level A area (km2) .............................. Potential sea otters affected by Level A sound per day. Potential sea otters affected by Level A sound per day (rounded). Total potential Level A harassment events. Distance to below Level B harassment threshold. Level B area (km2) .............................. Potential sea otters affected by Level B sound per day. Potential sea otters affected by Level B sound per day (rounded). Total potential Level B harassment events. 20. 168.2 dB re 1μPa at 10 m (RMS) 2015 10 minutes/pile ..... 4 ........................... 18 ......................... 122-cm (48-in) 0.5 meters ............ 0.5 meters ............ 0.6 meters ............ 0.9 meters ............ 0.6 meters. 0.000001 .............. 0.000002 .............. 0.000001 .............. 0.000002 .............. 0.000001 .............. 0.000002 .............. 0.000003 .............. 0.00001 ................ 0.000001. 0.000002. 0 ........................... 0 ........................... 0 ........................... 0 ........................... 0. 0 ........................... 0 ........................... 0 ........................... 0 ........................... 0. 25 meters ............. 25 meters ............. 25 meters ............. 35 meters ............. 35 meters. 0.0020 .................. 0.0041 .................. 0.0020 .................. 0.0041 .................. 0.0020 .................. 0.0041 .................. 0.0038 .................. 0.0077 .................. 0.0038. 0.0077. 0 ........................... 0 ........................... 0 ........................... 0 ........................... 0. 0 ........................... 0 ........................... 0 ........................... 0 ........................... 0. Facilities Engineering Command. ddrumheller on DSK120RN23PROD with NOTICES1 TABLE 3—SUMMARY OF SOUND LEVEL, TIMING OF SOUND PRODUCTION, DISTANCE FROM SOUND SOURCE TO BELOW LEVEL A HARASSMENT AND LEVEL B HARASSMENT THRESHOLDS, DAYS OF IMPACT, SEA OTTERS IN LEVEL A AND LEVEL B HARASSMENT ENSONIFICATION AREA, AND TOTAL OTTERS EXPECTED TO BE HARASSED THROUGH BEHAVIORAL DISTURBANCE BY IMPACT PILE DRIVING Pile size 91-cm (36-in) (permanent) 107-cm (42-in) 122-cm (48-in) Total number of piles ....................................................... Sound level ...................................................................... 36 ....................................... 184 dB (SEL)/192 dB (RMS)/211 dB (peak) re 1μPa at 10 m. 16 ....................................... 186.7 dB (SEL)/198.6 dB (RMS) re 1μPa at 10 m. 20. 186.7 dB (SEL)/198.6 dB (RMS)/212 dB (peak) re 1μPa at 10 m. Source ............................................................................. NAVFAC 2015 ................... Timing per pile ................................................................. 45 minutes/pile; 1,800 strikes/pile. 4 ......................................... 9 ......................................... Maximum number piles per day ...................................... Maximum number of days of activity .............................. VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 PO 00000 60 minutes/pile; 2,400 strikes/pile. 3 ......................................... 5.3 ...................................... 60 minutes/pile; 2,400 strikes/pile. 2. 10. 2.03 sea otters/km2 Sea otter density ............................................................. Distance to below Level A harassment threshold ........... Level A area (km2) .......................................................... Austin et al. 2016 169.2 meters ..................... 0.0718 ................................ Frm 00060 Fmt 4703 Sfmt 4703 256.0 meters ..................... 0.1786 ................................ E:\FR\FM\08JNN1.SGM 08JNN1 195.4 meters. 0.1199. 37565 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices TABLE 3—SUMMARY OF SOUND LEVEL, TIMING OF SOUND PRODUCTION, DISTANCE FROM SOUND SOURCE TO BELOW LEVEL A HARASSMENT AND LEVEL B HARASSMENT THRESHOLDS, DAYS OF IMPACT, SEA OTTERS IN LEVEL A AND LEVEL B HARASSMENT ENSONIFICATION AREA, AND TOTAL OTTERS EXPECTED TO BE HARASSED THROUGH BEHAVIORAL DISTURBANCE BY IMPACT PILE DRIVING—Continued Pile size 91-cm (36-in) (permanent) 107-cm (42-in) Potential sea otters affected by Level A sound per day Potential sea otters affected by Level A sound per day (rounded). Total potential Level A harassment events ..................... Distance to below Level B harassment threshold ........... Level B area (km2) .......................................................... Potential sea otters affected by Level B sound per day Potential sea otters affected by Level B sound per day (rounded). Total potential Level B harassment events ..................... 0.1458 ................................ 1 ......................................... 0.3626 ................................ 1 ......................................... 0.2434. 1. 9 ......................................... 1,359 meters ..................... 1.9161 ................................ 3.8897 ................................ 4 ......................................... 6 ......................................... 3,744 meters ..................... 7.3224 ................................ 14.8645 .............................. 15 ....................................... 10. 3,744 meters. 7.8846. 16.0057. 16. 36 ....................................... 80 ....................................... 160. 122-cm (48-in) TABLE 4—SUMMARY OF SOUND LEVEL, TIMING OF SOUND PRODUCTION, DISTANCE FROM SOUND SOURCE TO BELOW LEVEL A HARASSMENT AND LEVEL B HARASSMENT THRESHOLDS, DAYS OF IMPACT, SEA OTTERS IN LEVEL A AND LEVEL B HARASSMENT ENSONIFICATION AREA, AND TOTAL OTTERS EXPECTED TO BE HARASSED THROUGH BEHAVIORAL DISTURBANCE BY DOWN-THE-HOLE DRILLING Pile size 91-cm (36-in) (temporary) 91-cm (36-in) (permanent) 107-cm (42-in) Total number of piles ..................................... 36 (installation only) ... 36 ............................... 16 ............................... 20. Sound level .................................................... 164 dB (SEL)/167 dB (RMS) re 1μPa at 10 m 171 dB (SEL)/167 (RMS) dB re 1μPa at 10 m. Source ............................................................ Reyff and Heyvaert 2019; Reyff 2020; Denes et al. 2019; Heyvaert and Reyff 2021 SolsticeAK 2022; Heyvaert and Reyff 2021. Timing per pile ............................................... Maximum number piles per day .................... Maximum number of days of activity ............. 60 minutes/pile ........... 4 ................................. 9 ................................. 150 minutes/pile ......... 2 ................................. 18 ............................... Distance to below Level A harassment threshold a. Level A area (km2) ......................................... Potential sea otters affected by Level A sound per day. Potential sea otters affected by Level A sound per day (rounded). Total potential Level A harassment events ... Distance to below Level B harassment threshold a. Level B area (km2) ......................................... Potential sea otters affected by Level B sound per day. Potential sea otters affected by Level B sound per day (rounded). Total potential Level B harassment events ... a Due 150 minutes/pile ......... 2 ................................. 8 ................................. 150 minutes/pile. 2. 10. 2.03 sea otters/km2 Sea otter density ............................................ ddrumheller on DSK120RN23PROD with NOTICES1 122-cm (48-in) 57.9 meters ................ 67.1 meters ................ 67.1 meters ................ 196.6 meters. 0.0105 ........................ 0.0213 ........................ 0.0141 ........................ 0.0286 ........................ 0.0141 ........................ 0.0286 ........................ 0.1214. 0.2464. 1 ................................. 1 ................................. 1 ................................. 1. 9 ................................. 29 meters ................... 18 ............................... 29 meters ................... 8 ................................. 29 meters ................... 10. 29 meters. 0.0026 ........................ 0.0053 ........................ 0.0026 ........................ 0.0053 ........................ 0.0026 ........................ 0.0053 ........................ 0.0026. 0.0053. 0 ................................. 0 ................................. 0 ................................. 0. 0 ................................. 0 ................................. 0 ................................. 0. to differences in how PTS and TTS thresholds are calculated, the Level A isopleths are larger than the Level B isopleths. TABLE 5—SUMMARY OF SOUND LEVEL, TIMING OF SOUND PRODUCTION, DISTANCE FROM SOUND SOURCE TO BELOW LEVEL A HARASSMENT AND LEVEL B HARASSMENT THRESHOLDS, DAYS OF IMPACT, SEA OTTERS IN LEVEL A AND LEVEL B HARASSMENT ENSONIFICATION AREA, AND TOTAL OTTERS EXPECTED TO BE HARASSED THROUGH BEHAVIORAL DISTURBANCE BY USE OF SKIFFS Sound source Monitoring skiff Sound level .............................................................................................. 175 dB (RMS) re 1μPa at 1 m ...... Source ..................................................................................................... VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 PO 00000 Frm 00061 Fmt 4703 Worker transit skiff 175 dB (RMS) re 1μPa at 1 m. Richardson et al. 1995; Kipple and Gabriele 2007 Sfmt 4703 E:\FR\FM\08JNN1.SGM 08JNN1 37566 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices TABLE 5—SUMMARY OF SOUND LEVEL, TIMING OF SOUND PRODUCTION, DISTANCE FROM SOUND SOURCE TO BELOW LEVEL A HARASSMENT AND LEVEL B HARASSMENT THRESHOLDS, DAYS OF IMPACT, SEA OTTERS IN LEVEL A AND LEVEL B HARASSMENT ENSONIFICATION AREA, AND TOTAL OTTERS EXPECTED TO BE HARASSED THROUGH BEHAVIORAL DISTURBANCE BY USE OF SKIFFS—Continued Sound source Monitoring skiff Number of days of vessel use ................................................................ 129 ................................................. ddrumheller on DSK120RN23PROD with NOTICES1 Sound levels for all sources are unweighted and given in dB re 1mPa. Nonimpulsive sounds are in the form of mean maximum root mean square (RMS) sound pressure level (SPL) as it is more conservative than cumulative sound exposure level (SEL) or peak SPL for these activities. Impulsive sound sources are in the form of SEL for a single strike. To determine the number of sea otters that may experience in-water sounds >160 dB re 1mPa due to pile driving, we multiplied the area ensonified to >160 dB re 1mPa by the density of animals (2.03 sea otters/km2) derived from surveys conducted off Prince William Sound (Esslinger 2021). We applied the same methodology to determine the number of sea otters that may experience sounds capable of causing PTS. The number of sea otters expected to be exposed to such sound levels can be found in tables 2 through 5. To calculate the area ensonified for each type of pile-driving activity, the coordinates of the piles were mapped in ArcGIS Pro. We used a representative pile of each size around which to map the Level A and Level B harassment zones. We chose representative piles that were farthest from shore so that the zones that are intercepted by land have the largest in-water areas possible. The majority of these radii are small enough that their defined circles will fall entirely in the water, and in these instances, the area was calculated as pr2. The exceptions are the Level A and Level B zones generated by impact pile driving the 36-in permanent and 42-in piles, as well as the Level B zone generated by impact pile driving the 48in piles; for these, we used ArcGIS Pro to map and calculate the area of the water ensonified by those activities. VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 0 meters ......................................... 0 ..................................................... 0 ..................................................... 0 ..................................................... 0 ..................................................... 10 meters ....................................... 0.2832 ............................................ 0.5748 ............................................ 1 ..................................................... 129 ................................................. The area ensonified by the worker transit skiff was estimated by multiplying the vessel’s anticipated daily track length by twice the 160 dB radius plus pr2 to account for the rounded ends of the track line. It was estimated that the distance of each trip would be no more than 457.2 m (1,500 ft). The monitoring skiff will travel in a triangle of perimeter approximately 7 km (4.3 mi) between Emerald Island, the north shore of Passage Canal, and Gradual Point. To estimate the area ensonified by the monitoring skiff, we used ArcGIS Pro to plot the points of the triangle, map the track line between those points, and apply a buffer of 10 m (33 ft; the 160-dB radius) on either side of the track line. We assumed that the different types of activities would occur sequentially and that the total number of days of work would equal the sum of the number of days required to complete each type of activity. While it is possible that on some days more than one type of activity will take place, which would reduce the number of days of exposure within a year, we cannot know this information in advance. As such, the estimated number of days and, therefore, exposures per year is the maximum possible for the planned work. Where the number of exposures expected per day was zero to three or more decimal places (i.e., <0.00X), the number of exposures per day was assumed to be zero. In order to minimize exposure of sea otters to sounds above Level A harassment thresholds, TMC will implement shutdown zones ranging from 10 to 260 m (33 to 853 ft), based on the pile size and type of pile driving or marine construction activity, where PO 00000 Frm 00062 Fmt 4703 129. 2.03 sea otters/km2 Sea otter density ..................................................................................... Distance to below Level A harassment threshold .................................. Level A area (km2) .................................................................................. Potential sea otters affected by Level A sound per day ......................... Potential sea otters affected by Level A sound per day (rounded) ........ Total potential Level A harassment events ............................................. Distance to below Level B harassment threshold .................................. Level B area (km2) .................................................................................. Potential sea otters affected by Level B sound per day ......................... Potential sea otters affected by Level B sound per day (rounded) ........ Total potential Level B harassment events ............................................. Worker transit skiff Sfmt 4703 0 meters. 0. 0. 0. 0. 10 meters. 0.0095. 0.0192. 1. 129. operations will cease should a sea otter enter or approach the specified zone. Soft-start and zone clearance prior to startup will also limit the exposure of sea otters to sound levels that could cause PTS. However, TMC has requested, and the Service proposes to authorize, small numbers of take by Level A harassment during impact pile driving and DTH drilling. Critical Assumptions We estimate that 544 takes of 37 sea otters by Level B harassment and 70 takes of 7 sea otters by Level A harassment may occur due to TMC’s planned cruise ship dock construction activities. In order to conduct this analysis and estimate the potential amount of take by harassment, several critical assumptions were made. Level B harassment is equated herein with behavioral responses that indicate harassment or disturbance. There is likely a portion of animals that respond in ways that indicate some level of disturbance but do not experience significant biological consequences. We used the sea otter density for the Whittier area from surveys and analyses conducted by Esslinger (2021). Methods and assumptions for these surveys can be found in the original publication. We used sound source verification from recent pile-driving activities in a number of locations within and beyond Alaska to generate sound level estimates for construction activities. Environmental conditions in these locations, including water depth, substrate, and ambient sound levels are similar to those in the project location, but not identical. Further, estimation of ensonification zones were based on sound attenuation models using a practical spreading loss model. These factors may lead to actual sound values E:\FR\FM\08JNN1.SGM 08JNN1 37567 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices differing slightly from those estimated here. We assumed that all piles will be installed and removed while submerged in water. Some of the 36-in permanent piles supporting the approach trestle, and the associated temporary 36-in piles used for the templates to install the permanent piles, will be located in the intertidal zone. Work performed at lower tidal heights would likely result in decreased transmission of sounds to the water column. However, as the timing of pile installation and removal was not known in advance, we accounted for the possibility that all work may occur at a tidal height that allows for full sound transmission. Finally, the pile-driving activities described here will also create in-air noise. Because sea otters spend over half of their day with their heads above water (Esslinger et al. 2014), they will be exposed to an increase in-air noise from construction equipment. However, we have calculated Level B harassment with the assumption that an individual may be harassed only one time per 24hour period, and underwater sound levels will be more disturbing and extend farther than in-air noise. Thus, while sea otters may be disturbed by noise both in-air and underwater, we have relied on the more conservative underwater estimates. Sum of Harassment From All Sources The applicant plans to conduct pile driving and marine construction activities in Whittier, Alaska, over the course of a year from the date of issuance of the IHA. A summary of total estimated take during the project by source is provided in table 6. TABLE 6—TOTAL ESTIMATED TAKES BY SOURCE OF LEVEL A AND LEVEL B HARASSMENT OF SEA OTTERS ddrumheller on DSK120RN23PROD with NOTICES1 Source Vibratory drilling: 36-inch piles (temporary)—installation ......................... 36-inch piles (temporary)—removal ............................. 36-inch piles (permanent) ............................................. 42-inch piles .................................................................. 48-inch piles .................................................................. Impact drilling: 36-inch piles (permanent) ............................................. 42-inch piles .................................................................. 48-inch piles .................................................................. Down-the-hole drilling: 36-inch piles (temporary)—installation ......................... 36-inch piles (permanent) ............................................. 42-inch piles .................................................................. 48-inch piles .................................................................. Skiff use: Monitoring skiff .............................................................. Worker transit skiff ........................................................ Totals ..................................................................... Over the course of the project, we estimate 544 instances of take by Level B harassment of 37 northern sea otters from the Southcentral Alaska stock due to behavioral responses of TTS associated with noise exposure. Although multiple instances of Level B harassment of individual sea otters are possible, these events are unlikely to have significant consequences for the health, reproduction, or survival of affected animals and therefore would not rise to the level of an injury or Level A harassment. The use of soft-start procedures, zone clearance prior to startup, and shutdown zones is likely to decrease both the number of sea otters exposed to sounds above Level A harassment thresholds and the exposure time of any sea otters venturing into a Level A harassment zone. This reduces the likelihood of losses of hearing sensitivity that might impact the health, reproduction, or survival of affected VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 Sea otters exposed per day to Level A harassment Number of days of activity Total takes of sea otters by Level A harassment Frm 00063 Fmt 4703 Total takes of sea otters by Level B harassment 18 18 9 4 10 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 9 6 10 1 1 1 9 6 10 4 15 16 36 90 160 9 18 8 10 1 1 1 1 9 18 8 10 0 0 0 0 0 0 0 0 129 129 0 0 0 0 1 1 129 129 387 7 70 37 544 animals. Despite the implementation of mitigation measures, it is anticipated that some sea otters will experience Level A harassment via exposure to underwater sounds above threshold criteria during impact and DTH piledriving activities. Due to sea otters’ small body size and low profile in the water, as well as the relatively large size of the Level A harassment zone associated with these activities, we anticipate that sea otters will at times avoid detection before entering Level A harassment zones for those activities. We anticipate that PSOs will be able to reliably detect and prevent take by Level A harassment of sea otters up to 20 m away; conversely, we anticipate that at distances greater than 20 m, sea otters will at times avoid detection. Throughout the project, we estimate 70 instances of take by Level A harassment of 7 sea otters. PO 00000 Sea otters exposed per day to Level B harassment Sfmt 4703 Determinations and Findings Sea otters exposed to sound from the specified activities are likely to respond with temporary behavioral modification or displacement. The specified activities could temporarily interrupt the feeding, resting, and movement of sea otters. Because activities will occur during a limited amount of time and in a localized region, the impacts associated with the project are likewise temporary and localized. The anticipated effects are short-term behavioral reactions and displacement of sea otters near active operations. Sea otters that encounter the specified activity may exert more energy than they would otherwise due to temporary cessation of feeding, increased vigilance, and retreating from the project area. We expect that affected sea otters will tolerate this exertion without measurable effects on health or reproduction. Most of the anticipated takes will be due to short-term Level B E:\FR\FM\08JNN1.SGM 08JNN1 37568 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices harassment in the form of TTS, startling reactions, or temporary displacement. While mitigation measures incorporated into TMC’s request will reduce occurrences of Level A harassment to the extent practicable, a small number of takes by Level A harassment would be authorized for impact and DTH piledriving activities, which have Level A harassment zone radii ranging in size from 57.9 to 256 m (190 to 840 ft). With the adoption of the mitigation measures incorporated in TMC’s request and required by this proposed IHA, anticipated take was reduced. Those mitigation measures are further described below. ddrumheller on DSK120RN23PROD with NOTICES1 Small Numbers To assess whether the authorized incidental taking would be limited to ‘‘small numbers’’ of marine mammals, the Service uses a proportional approach that considers whether the estimated number of marine mammals to be subjected to incidental take is small relative to the population size of the species or stock. Here, predicted levels of take were determined based on the estimated density of sea otters in the project area and ensonification zones developed using empirical evidence from similar geographic areas. We estimate TMC’s specified activities in the specified geographic region will take no more than 544 takes of 37 sea otters by Level B harassment and 70 takes of 7 sea otters by Level A harassment during the 1-year period of this proposed IHA (see Sum of Take from All Sources). Take of 44 animals is 0.2 percent of the best available estimate of the current Southcentral Alaska stock size of 21,617 animals (Esslinger et al. 2021) ((44 ÷ 21,617) × 100 ≈ 0.2) and represents a ‘‘small number’’ of sea otters of that stock. Negligible Impact We propose a finding that any incidental take by harassment resulting from the specified activities cannot be reasonably expected to, and is not reasonably likely to, adversely affect the sea otter through effects on annual rates of recruitment or survival and will, therefore, have no more than a negligible impact on the Southcentral Alaska stock of northern sea otters. In making this finding, we considered the best available scientific information, including the biological and behavioral characteristics of the species, the most recent information on species distribution and abundance within the area of the specified activities, the current and expected future status of the stock (including existing and foreseeable human and natural VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 stressors), the potential sources of disturbance caused by the project, and the potential responses of marine mammals to this disturbance. In addition, we reviewed applicantprovided materials, information in our files and datasets, published reference materials, and species experts. Sea otters are likely to respond to planned activities with temporary behavioral modification or temporary displacement. These reactions are not anticipated to have consequences for the long-term health, reproduction, or survival of affected animals. Most animals will respond to disturbance by moving away from the source, which may cause temporary interruption of foraging, resting, or other natural behaviors. Affected animals are expected to resume normal behaviors soon after exposure with no lasting consequences. Each sea otter is estimated to be exposed to construction noise for between 4 and 129 days per year, resulting in repeated exposures. However, injuries (i.e., Level A harassment or PTS) due to chronic sound exposure is estimated to occur at a longer time scale (Southall et al. 2019). The area that will experience noise greater than Level B thresholds due to pile driving is small (less than 0.18 km2), and an animal that may be disturbed could escape the noise by moving to nearby quiet areas. Further, sea otters spend over half of their time above the surface during the summer months (Esslinger et al. 2014), and likely no more than 70 percent of their time foraging during winter months (Gelatt et al. 2002), thus their ears will not be exposed to continuous noise, and the amount of time it may take for permanent injury is considerably longer than that of mammals primarily under water. Some animals may exhibit some of the stronger responses typical of Level B harassment, such as fleeing, interruption of feeding, or flushing from a haulout. These responses could have temporary biological impacts for affected individuals but are not anticipated to result in measurable changes in survival or reproduction. The total number of animals affected and severity of impact is not sufficient to change the current population dynamics at the stock scale. Although the specified activities may result in approximately 614 incidental takes of 44 sea otters from the Southcentral Alaska stock, we do not expect this level of harassment to affect annual rates of recruitment or survival or result in adverse effects on the stock. Our proposed finding of negligible impact applies to incidental take associated with the specified activities PO 00000 Frm 00064 Fmt 4703 Sfmt 4703 as mitigated by the avoidance and minimization measures identified in TMC’s mitigation and monitoring plan. These mitigation measures are designed to minimize interactions with and impacts to sea otters. These measures and the monitoring and reporting procedures are required for the validity of our finding and are a necessary component of the proposed IHA. For these reasons, we propose a finding that the specified project will have a negligible impact on the Southcentral Alaska stock of northern sea otters. Least Practicable Adverse Impacts We find that the mitigation measures required by this proposed IHA will effect the least practicable adverse impacts on the stocks from any incidental take likely to occur in association with the specified activities. In making this finding, we considered the biological characteristics of sea otters, the nature of the specified activities, the potential effects of the activities on sea otters, the documented impacts of similar activities on sea otters, and alternative mitigation measures. In evaluating what mitigation measures are appropriate to ensure the least practicable adverse impact on species or stocks and their habitat, as well as subsistence uses, we considered the manner and degree to which the successful implementation of the measures are expected to achieve this goal. We considered the nature of the potential adverse impact being mitigated (likelihood, scope, range), the likelihood that the measures will be effective if implemented, and the likelihood of effective implementation. We also considered the practicability of the measures for applicant implementation (e.g., cost, impact on operations). We assessed whether any additional, practicable requirements could be implemented to further reduce effects, but did not identify any. To reduce the potential for disturbance from acoustic stimuli associated with the activities, TMC will implement mitigation measures, including the following: • Using the smallest diameter piles practicable while minimizing the overall number of piles; • Using a project design that does not include dredging or blasting; • Using pile caps made of highdensity polyethylene or ultra-highmolecular-weight polyethylene softening materials during impact pile driving; • Minimizing the use of the impact hammer to the extent possible by using E:\FR\FM\08JNN1.SGM 08JNN1 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices a vibratory hammer to advance piles as deeply as possible; • Employing an 18-m (60-ft) deep bubble curtain during all impact pile driving as well as during all pile-driving activities in less than 18 m (60 ft) of water to reduce noise impacts; • Not reducing sound source levels due to the planned use of pile caps and a bubble curtain to calculate the most conservative harassment and shutdown zones; • Development of a marine mammal monitoring and mitigation plan; • Establishment of shutdown and monitoring zones; • Visual mitigation monitoring by designated protected species observers (PSO); • Site clearance before startup; • Soft-start procedures; and • Shutdown procedures. The Service has not identified any additional (i.e., not already incorporated into TMC’s request) mitigation or monitoring measures that are practicable and would further reduce potential impacts to sea otters and their habitat. ddrumheller on DSK120RN23PROD with NOTICES1 Impact on Subsistence Use The project will not preclude access to harvest areas or interfere with the availability of sea otters for harvest. Additionally, the planned cruise ship berth and associated facilities are located within the City of Whittier, where firearm use is prohibited. We therefore propose a finding that TMC’s anticipated harassment will not have an unmitigable adverse impact on the availability of any stock of northern sea otters for taking for subsistence uses. In making this finding, we considered the timing and location of the planned activities and the timing and location of subsistence harvest activities in the project area. Monitoring and Reporting The purposes of the monitoring requirements are to document and provide data for assessing the effects of specified activities on sea otters; to ensure that take is consistent with that anticipated in the small numbers, negligible impact, and subsistence use analyses; and to detect any unanticipated effects on the species. Monitoring plans include steps to document when and how sea otters are encountered and their numbers and behaviors during these encounters. This information allows the Service to measure encounter rates and trends and to estimate numbers of animals potentially affected. To the extent possible, monitors will record group size, age, sex, reaction, duration of VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 interaction, and closest approach to the project activity. As proposed, monitoring activities will be summarized and reported in formal reports. TMC must submit monthly reports for all months during which noise-generating work takes place as well as a final monitoring report that must submitted no later than 90 days after the expiration of the IHA. We will require an approved plan for monitoring and reporting the effects of pile driving and marine construction activities on sea otters prior to issuance of an IHA. We will require approval of the monitoring results for continued operation under the IHA. We find that these proposed monitoring and reporting requirements to evaluate the potential impacts of planned activities will ensure that the effects of the activities remain consistent with the rest of the findings. Required Determinations National Environmental Policy Act (NEPA) We have prepared a draft environmental assessment in accordance with the NEPA (42 U.S.C. 4321 et seq.). We have preliminarily concluded that authorizing the nonlethal, incidental, unintentional take by Level B harassment of up to 544 takes of 37 sea otters and by Level A harassment of up to 70 takes of 7 sea otters from the Southcentral Alaska stock in the specified geographic region during the specified activities during the regulatory period would not significantly affect the quality of the human environment and, thus, preparation of an environmental impact statement for this proposed IHA is not required by section 102(2) of NEPA or its implementing regulations. We are accepting comments on the draft environmental assessment as specified above in DATES and ADDRESSES. Endangered Species Act (ESA) Under the ESA (16 U.S.C. 1536(a)(2)), all Federal agencies are required to ensure the actions they authorize are not likely to jeopardize the continued existence of any threatened or endangered species or result in destruction or adverse modification of critical habitat. The specified activities would occur entirely within the range of the Southcentral Alaska stock of northern sea otters, which is not listed as threatened or endangered under the ESA. The authorization of incidental take of sea otters and the measures included in the proposed IHA would not affect other listed species or designated critical habitat. PO 00000 Frm 00065 Fmt 4703 Sfmt 4703 37569 Government-to-Government Consultation It is our responsibility to communicate and work directly on a Government-to-Government basis with federally recognized Alaska Native Tribes in developing programs for healthy ecosystems. We seek their full and meaningful participation in evaluating and addressing conservation concerns for protected species. It is our goal to remain sensitive to Alaska Native culture, and to make information available to Alaska Natives. Our efforts are guided by the following policies and directives: (1) The Native American Policy of the Service (January 20, 2016); (2) The Alaska Native Relations Policy (currently in draft form); (3) Executive Order 13175 (January 9, 2000); (4) Department of the Interior Secretary’s Orders 3206 (June 5, 1997), 3225 (January 19, 2001), 3317 (December 1, 2011), and 3342 (October 21, 2016); (5) The Alaska Government-toGovernment Policy (a departmental memorandum issued January 18, 2001); and (6) The Department of the Interior’s policies on consultation with Alaska Native Tribes and organizations. We have evaluated possible effects of the specified activities on federally recognized Alaska Native Tribes and organizations. The Service has determined that, due to this project’s locations and activities, the Tribal organizations and communities near Whittier, Alaska, as well as relevant Alaska Native Claims Settlement Act corporations, will not be impacted by this project. Regardless, we will be reaching out to them to inform them of the availability of this proposed IHA and offer them the opportunity to consult. We invite continued discussion, either about the project and its impacts or about our coordination and information exchange throughout the IHA process. Proposed Authorization We propose to authorize the nonlethal, incidental take by Level A and Level B harassment of 614 takes of 44 sea otters from the Southcentral Alaska stock. Authorized take may be caused by pile driving and marine construction activities conducted by Turnagain Marine Construction (TMC) in Whittier, Alaska, over the course of a year from the date of issuance of the IHA. We do not anticipate or authorize any lethal take to sea otters resulting from these activities. E:\FR\FM\08JNN1.SGM 08JNN1 37570 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices ddrumheller on DSK120RN23PROD with NOTICES1 A. General Conditions for the Incidental Harassment Authorization (IHA) (1) Activities must be conducted in the manner described in the December 22, 2022, revised request from TMC for an IHA and in accordance with all applicable conditions and mitigation measures. The taking of sea otters whenever the required conditions, mitigation, monitoring, and reporting measures are not fully implemented as required by the IHA is prohibited. Failure to follow the measures specified both in the revised request and within this proposed authorization may result in the modification, suspension, or revocation of the IHA. (2) If project activities cause unauthorized take (i.e., greater than 614 takes of 44 of the Southcentral Alaska stock of northern sea otters, a form of take other than Level A or Level B harassment, or take of one or more sea otters through methods not described in the IHA), TMC must take the following actions: (i) cease its activities immediately (or reduce activities to the minimum level necessary to maintain safety); (ii) report the details of the incident to the Service within 48 hours; and (iii) suspend further activities until the Service has reviewed the circumstances and determined whether additional mitigation measures are necessary to avoid further unauthorized taking. (3) All operations managers, vehicle operators, and machine operators must receive a copy of this IHA and maintain access to it for reference at all times during project work. These personnel must understand, be fully aware of, and be capable of implementing the conditions of the IHA at all times during project work. (4) This IHA will apply to activities associated with the specified project as described in this document and in TMC’s revised request. Changes to the specified project without prior authorization may invalidate the IHA. (5) TMC’s revised request is approved and fully incorporated into this IHA unless exceptions are specifically noted herein. The request includes: (i) TMC’s original request for an IHA, dated September 16, 2022; (ii) Revised applications, dated November 11, November 23, December 1, and December 22, 2022; (iii) Marine Mammal Mitigation and Monitoring Plan; (iv) Google Earth package; (v) Bubble curtain schematics; and (vi) Pile coordinates. (6) Operators will allow Service personnel or the Service’s designated VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 representative to visit project worksites to monitor for impacts to sea otters and subsistence uses of sea otters at any time throughout project activities so long as it is safe to do so. ‘‘Operators’’ are all personnel operating under TMC’s authority, including all contractors and subcontractors. B. Avoidance and Minimization (7) Construction activities must be conducted using equipment that generates the lowest practicable levels of underwater sound within the range of frequencies audible to sea otters. (8) During all pile-installation activities, regardless of predicted sound levels, a physical interaction shutdown zone of 20 m (66 ft) must be enforced. If a sea otter enters the shutdown zone, in-water activities must be delayed until either the animal has been visually observed outside the shutdown zone, or 15 minutes have elapsed since the last observation time without redetection of the animal. (9) If the impact driver has been idled for more than 30 minutes, an initial set of three strikes from the impact driver must be delivered at reduced energy, followed by a 1-minute waiting period, before full-powered proofing strikes. (10) In-water activity must be conducted in daylight. If environmental conditions prevent visual detection of sea otters within the shutdown zone, inwater activities must be stopped until visibility is regained. (11) All in-water work along the shoreline must be conducted during low tide when the site is dewatered to the maximum extent practicable. C. Mitigation Measures for Vessel Operations Vessel operators must take every precaution to avoid harassment of sea otters when a vessel is operating near these animals. The applicant must carry out the following measures: (12) Vessels must remain at least 500 m (0.3 mi) from rafts of sea otters unless safety is a factor. Vessels must reduce speed and maintain a distance of 100 m (328 ft) from all sea otters unless safety is a factor. (13) Vessels must not be operated in such a way as to separate members of a group of sea otters from other members of the group and must avoid alongshore travel in shallow water (<20 m) whenever practicable. (14) When weather conditions require, such as when visibility drops, vessels must adjust speed accordingly to avoid the likelihood of injury to sea otters. (15) Vessel operators must be provided written guidance for avoiding PO 00000 Frm 00066 Fmt 4703 Sfmt 4703 collisions and minimizing disturbances to sea otters. Guidance will include measures identified in paragraphs (C)(12) through (15) of this section. D. Monitoring (16) Operators shall work with protected species observers (PSOs) to apply mitigation measures and shall recognize the authority of PSOs up to and including stopping work, except where doing so poses a significant safety risk to personnel. (17) Duties of the PSOs include watching for and identifying sea otters, recording observation details, documenting presence in any applicable monitoring zone, identifying and documenting potential harassment, and working with operators to implement all appropriate mitigation measures. (18) A sufficient number of PSOs will be available to meet the following criteria: 100 percent monitoring of exclusion zones during all daytime periods of underwater noise-generating work; a maximum of 4 consecutive hours on watch per PSO; a maximum of approximately 12 hours on watch per day per PSO. (19) All PSOs will complete a training course designed to familiarize individuals with monitoring and data collection procedures. A field crew leader with prior experience as a sea otter observer will supervise the PSO team. Initially, new or inexperienced PSOs will be paired with experienced PSOs so that the quality of marine mammal observations and data recording is kept consistent. Resumes for candidate PSOs will be made available for the Service to review. (20) Observers will be provided with reticule binoculars (7×50 or better), bigeye binoculars or spotting scopes (30×), inclinometers, and range finders. Field guides, instructional handbooks, maps, and a contact list will also be made available. (21) Observers will collect data using the following procedures: (i) All data will be recorded onto a field form or database. (ii) Global positioning system data, sea state, wind force, and weather will be collected at the beginning and end of a monitoring period, every hour in between, at the change of an observer, and upon sightings of sea otters. (iii) Observation records of sea otters will include date; time; the observer’s locations, heading, and speed (if moving); weather; visibility; number of animals; group size and composition (adults/juveniles); and the location of the animals (or distance and direction from the observer). E:\FR\FM\08JNN1.SGM 08JNN1 Federal Register / Vol. 88, No. 110 / Thursday, June 8, 2023 / Notices (iv) Observation records will also include initial behaviors of the sea otters, descriptions of project activities and underwater sound levels being generated, the position of sea otters relative to applicable monitoring and mitigation zones, any mitigation measures applied, and any apparent reactions to the project activities before and after mitigation. (v) For all sea otters in or near a mitigation zone, observers will record the distance from the sound source to the sea otter upon initial observation, the duration of the encounter, and the distance at last observation in order to monitor cumulative sound exposures. (vi) Observers will note any instances of animals lingering close to or traveling with vessels for prolonged periods of time. (22) Monitoring of the shutdown zone must continue for 30 minutes following completion of pile installation. ddrumheller on DSK120RN23PROD with NOTICES1 E. Measures To Reduce Impacts to Subsistence Users (23) Prior to conducting the work, TMC will take the following steps to reduce potential effects on subsistence harvest of sea otters: (i) Avoid work in areas of known sea otter subsistence harvest; (ii) Discuss the planned activities with subsistence stakeholders including Southcentral Alaska villages and traditional councils; (iii) Identify and work to resolve concerns of stakeholders regarding the project’s effects on subsistence hunting of sea otters; and (iv) If any concerns remain, develop a POC in consultation with the Service and subsistence stakeholders to address these concerns. F. Reporting Requirements (24) TMC must notify the Service at least 48 hours prior to commencement of activities. (25) Monthly reports will be submitted to the Service’s Marine Mammal Management office (MMM) for all months during which noisegenerating work takes place. The monthly report will contain and summarize the following information: dates, times, weather, and sea conditions (including the Beaufort Scale sea state and wind force conditions) when sea otters were sighted; the number, location, distance from the sound source, and behavior of the sea otters; the associated project activities; and a description of the implementation and effectiveness of mitigation measures with a discussion of any specific behaviors the sea otters exhibited in response to mitigation. VerDate Sep<11>2014 16:15 Jun 07, 2023 Jkt 259001 (26) A final report will be submitted to the Service’s MMM within 90 days after completion of work or expiration of the IHA. The report will include: (i) A summary of monitoring efforts (hours of monitoring, activities monitored, number of PSOs, and, if requested by the Service, the daily monitoring logs). (ii) A description of all project activities, along with any additional work yet to be done. Factors influencing visibility and detectability of marine mammals (e.g., sea state, number of observers, and fog and glare) will be discussed. (iii) A description of the factors affecting the presence and distribution of sea otters (e.g., weather, sea state, and project activities). An estimate will be included of the number of sea otters exposed to noise at received levels greater than or equal to 160 dB (based on visual observation). (iv) A description of changes in sea otter behavior resulting from project activities and any specific behaviors of interest. (v) A discussion of the mitigation measures implemented during project activities and their observed effectiveness for minimizing impacts to sea otters. Sea otter observation records will be provided to the Service in the form of electronic database or spreadsheet files. (27) Injured, dead, or distressed sea otters that are not associated with project activities (e.g., animals known to be from outside the project area, previously wounded animals, or carcasses with moderate to advanced decomposition or scavenger damage) must be reported to the Service within 24 hours of the discovery to either the Service’s MMM (1–800–362–5148, business hours); or the Alaska SeaLife Center in Seward (1–888–774–7325, 24 hours a day); or both. Photographs, video, location information, or any other available documentation must be provided to the Service. (28) All reports shall be submitted by email to fw7_mmm_reports@fws.gov. (29) TMC must notify the Service upon project completion or end of the work season. Request for Public Comments If you wish to comment on this proposed authorization, the associated draft environmental assessment, or both documents, you may submit your comments by either of the methods described in ADDRESSES. Please identify if you are commenting on the proposed authorization, draft environmental assessment, or both, make your comments as specific as possible, PO 00000 Frm 00067 Fmt 4703 Sfmt 4703 37571 confine them to issues pertinent to the proposed authorization, and explain the reason for any changes you recommend. Where possible, your comments should reference the specific section or paragraph that you are addressing. The Service will consider all comments that are received before the close of the comment period (see DATES). The Service does not anticipate extending the public comment period beyond the 30 days required under section 101(a)(5)(D)(iii) of the MMPA. Comments, including names and street addresses of respondents, will become part of the administrative record for this proposal. Before including your address, telephone number, email address, or other personal identifying information in your comment, be advised that your entire comment, including your personal identifying information, may be made publicly available at any time. While you can ask us in your comments to withhold from public review your personal identifying information, we cannot guarantee that we will be able to do so. Peter Fasbender, Assistant Regional Director for Fisheries and Ecological Services, Alaska Region. [FR Doc. 2023–12233 Filed 6–7–23; 8:45 am] BILLING CODE 4333–15–P DEPARTMENT OF THE INTERIOR Bureau of Land Management [BLM_AK_FRN_MO4500170694; AA–26417] Public Land Order No. 7925; Extension of a Withdrawal Created by Executive Order, Modified by Public Land Order No. 6458; Sitka Magnetic Observatory Site; Alaska Bureau of Land Management, Interior. ACTION: Public Land Order. AGENCY: This Public Land Order (PLO) extends the duration of the withdrawal created by Executive Order, as modified by PLO No. 6458 and extended by PLO No. 7581, for an additional 20-year term. The Executive Order as modified and extended withdrew 117.13 acres of public land from all forms of appropriation under the public land laws, including the mining laws, but not from the mineral leasing laws, for the Sitka Magnetic Observatory site, and reserved the site for use by the United States Geological Survey as a magnetic and seismological observatory in Sitka, Alaska. DATES: This PLO takes effect on September 6, 2023. SUMMARY: E:\FR\FM\08JNN1.SGM 08JNN1

Agencies

[Federal Register Volume 88, Number 110 (Thursday, June 8, 2023)]
[Notices]
[Pages 37556-37571]
From the Federal Register Online via the Government Publishing Office [www.gpo.gov]
[FR Doc No: 2023-12233]


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DEPARTMENT OF THE INTERIOR

Fish and Wildlife Service

[Docket No. FWS-R7-ES-2023-0030; FXES111607MRG01-234-FF07CAMM00]


Marine Mammals; Incidental Take During Specified Activities; 
Proposed Incidental Harassment Authorization for Southcentral Alaska 
Stock of Northern Sea Otters in Whittier, Alaska

AGENCY: Fish and Wildlife Service, Interior.

ACTION: Notice of receipt of application; proposed incidental 
harassment authorization; draft environmental assessment; request for 
comments.

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SUMMARY: We, the U.S. Fish and Wildlife Service, in response to a 
request under the Marine Mammal Protection Act of 1972, as amended, 
from Turnagain Marine Construction, propose to authorize nonlethal, 
incidental take by harassment of small numbers of the Southcentral 
Alaska stock of northern sea otters (Enhydra lutris kenyoni) for 1 year 
from the date of issuance of the incidental harassment authorization. 
The applicant has requested this authorization for take by harassment 
that may result from activities associated with pile driving and marine 
construction activities on the western shore of Passage Canal in 
Whittier, Alaska. We estimate that this project may result in the 
nonlethal incidental take by harassment of up to 44 northern sea otters 
from the Southcentral stock. This proposed authorization, if finalized, 
will be for up to 70 takes of 7 northern sea otters by Level A 
harassment and 544 takes of 37 northern sea otters by Level B 
harassment. No lethal take is requested, or expected, and no such take 
will be authorized.

DATES: Comments on this proposed incidental harassment authorization 
and

[[Page 37557]]

the accompanying draft environmental assessment must be received by 
July 10, 2023.

ADDRESSES: 
    Document availability: You may view this proposed incidental 
harassment authorization, the application package, supporting 
information, draft environmental assessment, and the list of references 
cited herein at https://www.regulations.gov under Docket No. FWS-R7-ES-
2023-0030 or these documents may be requested from the person listed 
under FOR FURTHER INFORMATION CONTACT.
    Comment submission: You may submit comments on the proposed 
authorization by one of the following methods:
     U.S. mail: Public Comments Processing, Attn: Docket No. 
FWS-R7-ES-2023-0030, U.S. Fish and Wildlife Service, MS: PRB (JAO/3W), 
5275 Leesburg Pike, Falls Church, VA 22041-3803.
     Electronic submission: Federal eRulemaking Portal at: 
https://www.regulations.gov. Follow the instructions for submitting 
comments to Docket No. FWS-R7-ES-2023-0030.
    We will post all comments at https://www.regulations.gov. You may 
request that we withhold personal identifying information from public 
review; however, we cannot guarantee that we will be able to do so. See 
Request for Public Comments for more information.

FOR FURTHER INFORMATION CONTACT: Sierra Franks, U.S. Fish and Wildlife 
Service, MS 341, 1011 East Tudor Road, Anchorage, Alaska 99503, by 
email at [email protected] or by telephone at 1-800-362-5148. 
Individuals in the United States who are deaf, deafblind, hard of 
hearing, or have a speech disability may dial 711 (TTY, TDD, or 
TeleBraille) to access telecommunications relay services. Individuals 
outside the United States should use the relay services offered within 
their country to make international calls to the point-of-contact in 
the United States.

SUPPLEMENTARY INFORMATION: 

Background

    Section 101(a)(5)(D) of the Marine Mammal Protection Act of 1972 
(MMPA; 16 U.S.C. 1361, et seq.) authorizes the Secretary of the 
Interior (Secretary) to allow, upon request, the incidental, but not 
intentional, taking by harassment of small numbers of marine mammals in 
response to requests by U.S. citizens (as defined in title 50 of the 
Code of Federal Regulations (CFR) in part 18, at 50 CFR 18.27(c)) 
engaged in a specified activity (other than commercial fishing) in a 
specified geographic region during a period of not more than 1 year. 
The Secretary has delegated authority for implementation of the MMPA to 
the U.S. Fish and Wildlife Service (``Service'' or ``we''). According 
to the MMPA, the Service shall allow this incidental taking if we make 
findings that the total of such taking for the 1-year period:
    (1) is of small numbers of marine mammals of a species or stock;
    (2) will have a negligible impact on such species or stocks; and
    (3) will not have an unmitigable adverse impact on the availability 
of these species or stocks for taking for subsistence use by Alaska 
Natives.
    If the requisite findings are made, we issue an authorization that 
sets forth the following, where applicable:
    (a) permissible methods of taking;
    (b) means of effecting the least practicable adverse impact on the 
species or stock and its habitat and the availability of the species or 
stock for subsistence uses; and
    (c) requirements for monitoring and reporting of such taking by 
harassment, including, in certain circumstances, requirements for the 
independent peer review of proposed monitoring plans or other research 
proposals.
    The term ``take'' means to harass, hunt, capture, or kill, or to 
attempt to harass, hunt, capture, or kill any marine mammal. 
``Harassment'' means any act of pursuit, torment, or annoyance which 
(i) has the potential to injure a marine mammal or marine mammal stock 
in the wild (the MMPA defines this as ``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 (the MMPA defines this as ``Level B harassment'').
    The terms ``negligible impact'' and ``unmitigable adverse impact'' 
are defined in 50 CFR 18.27 (i.e., regulations governing small takes of 
marine mammals incidental to specified activities) as follows: 
``Negligible impact'' is 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. ``Unmitigable adverse impact'' 
means an impact resulting from the specified activity: (1) that is 
likely to reduce the availability of the species to a level 
insufficient for a harvest to meet subsistence needs by (i) causing the 
marine mammals to abandon or avoid hunting areas, (ii) directly 
displacing subsistence users, or (iii) placing physical barriers 
between the marine mammals and the subsistence hunters; and (2) that 
cannot be sufficiently mitigated by other measures to increase the 
availability of marine mammals to allow subsistence needs to be met.
    The term ``small numbers'' is also defined in 50 CFR 18.27. 
However, we do not rely on that definition here as it conflates ``small 
numbers'' with ``negligible impacts.'' We recognize ``small numbers'' 
and ``negligible impacts'' as two separate and distinct considerations 
when reviewing requests for incidental harassment authorizations (IHA) 
under the MMPA (see Natural Res. Def. Council, Inc. v. Evans, 232 F. 
Supp. 2d 1003, 1025 (N.D. Cal. 2003)). Instead, for our small numbers 
determination, we estimate the likely number of takes of marine mammals 
and evaluate if that take is small relative to the size of the species 
or stock.
    The term ``least practicable adverse impact'' is not defined in the 
MMPA or its enacting regulations. For this IHA, we ensure the least 
practicable adverse impact by requiring mitigation measures that are 
effective in reducing the impact of project activities, but they are 
not so restrictive as to make project activities unduly burdensome or 
impossible to undertake and complete.
    If the requisite findings are made, we shall issue an IHA, which 
may set forth the following, where applicable: (i) permissible methods 
of taking; (ii) 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 subsistence 
uses by coastal-dwelling Alaska Natives (if applicable); and (iii) 
requirements for monitoring and reporting take by harassment.

Summary of Request

    On September 16, 2022, Turnagain Marine Construction (hereafter 
``TMC'' or ``the applicant'') submitted a request to the Service for 
authorization to take by Level A and Level B harassment a small number 
of northern sea otters (Enhydra lutris kenyoni) (hereafter ``sea 
otters'' or ``otters'' unless another species is specified) from the 
Southcentral Alaska stock. The Service sent requests for additional 
information on November 1, November 30, and December 14, 2022. We 
received updated versions of the request on November 11, November 23, 
December 1, and December 22, 2022. The Service determined the December 
22, 2022, application to be adequate and complete. TMC expects take by

[[Page 37558]]

harassment may occur during the construction of their cruise ship berth 
and associated facilities on the western shore of Passage Canal in 
Whittier, Alaska.

Description of Specified Activities and Specified Geographic Region

    The specified activity (hereafter ``project'') will include 
installation and removal of piles for the construction of a 152-by-21 
meter (m) (500-by-70-foot (ft)) floating cruise ship dock in Whittier, 
Alaska (figure 1) between April 2023 and April 2024. TMC will install 
and remove 72 91-centimeter (cm) (36-inch (in)) diameter steel piles 
and will permanently install the following types of piles: 36 91-cm 
(36-in) diameter steel piles, 16 107-cm (42-in) diameter steel piles, 
and 20 122-cm (48-in) diameter steel piles. Dock components that will 
be installed out of water include bull rail, fenders, mooring cleat, 
pre-cast concrete dock surface, and mast lights. Pile-driving 
activities will occur over 129 non-consecutive days for approximately 
321 hours during the course of 1 year from date of issuance of the IHA. 
If the IHA is issued after TMC's intended start date in April 2023, its 
schedule for conducting the specified activities may be adjusted 
accordingly. Pile installation will be done with a combination of 
impact, vibratory, and down-the-hole (DTH) drilling. Temporary piles 
will be removed with the vibratory hammer. Materials and equipment will 
be transported via barges, and workers will be transported to and from 
the barge work platform via skiff.
    Additional project details may be reviewed in the application 
materials available as described under ADDRESSES or may also be 
requested as described under FOR FURTHER INFORMATION CONTACT.
[GRAPHIC] [TIFF OMITTED] TN08JN23.001

Description of Marine Mammals in the Specified Geographic Region

Sea Otter Biology

    There are three sea otter stocks in Alaska: Southeast Alaska stock, 
Southcentral Alaska stock, and the Southwest Alaska stock. Only the 
Southcentral Alaska stock is represented in the project area. Detailed 
information about the biology of this stock can be found in the most 
recent Southcentral Alaska draft stock assessment report (USFWS 2023), 
which can be found at https://www.regulations.gov/document/FWS-R7-ES-2022-0155-0004 and was announced in the Federal Register at 88 FR 7992, 
February 7, 2023.
    Sea otters may be distributed anywhere within the specified project 
area other than upland areas; however, they generally occur in shallow 
water near the shoreline. They are most commonly observed within the 
40-m (131-ft) depth contour (USFWS 2023), although they can be found in 
areas with deeper water. Ocean depth is generally correlated with 
distance to shore, and sea otters typically remain

[[Page 37559]]

within 1 to 2 kilometers (km) (0.62 to 1.24 miles (mi)) of shore 
(Riedman and Estes 1990). They tend to be found closer to shore during 
storms, but venture farther out during good weather and calm seas 
(Lensink 1962; Kenyon 1969).
    Sea otters are nonmigratory and generally do not disperse over long 
distances (Garshelis and Garshelis 1984), usually remaining within a 
few kilometers of their established feeding grounds (Kenyon 1981). 
Breeding males stay for all or part of the year in a breeding territory 
covering up to 1 km (0.62 mi) of coastline, while adult females 
maintain home ranges of approximately 8 to 16 km (5 to 10 mi), which 
may include one or more male territories. Juveniles move greater 
distances between resting and foraging areas (Lensink 1962; Kenyon 
1969; Riedman and Estes 1990; Tinker and Estes 1996). Although sea 
otters generally remain local to an area, they are capable of long-
distance travel. Sea otters in Alaska have shown daily movement 
distances greater than 3 km (1.9 mi) at speeds up to 5.5 km per hour 
(hr) (km/hr; 3.4 mi/hr) (Garshelis and Garshelis 1984).

Southcentral Alaska Sea Otter Stock

    The Southcentral Alaska sea otter stock occurs in the center of the 
sea otter range in Alaska and extends from Cape Yakataga in the east to 
Cook Inlet in the west, including Prince William Sound, the eastern 
Kenai Peninsula coast, and Kachemak Bay (USFWS 2023). Between 2014 and 
2019, aerial surveys were conducted in three regions of the 
Southcentral Alaska sea otter stock: (1) Eastern Cook Inlet, (2) Outer 
Kenai Peninsula, and (3) Prince William Sound by aerial transects flown 
at 91 m (298.56 ft) of altitude. The combined estimates of the three 
regions resulted in approximately 21,617 (SE = 2,190) sea otters and an 
average density of 1.96 sea otters per square kilometer (km\2\) for the 
Southcentral Alaska stock (Esslinger et al. 2021). We applied the 
average density of sea otters in Prince William Sound, 2.03 sea otters/
km\2\ (Esslinger et al. 2021).

Potential Impacts of the Specified Activities on Marine Mammals

Effects of Noise on Sea Otters

    We characterized ``noise'' as sound released into the environment 
from human activities that exceeds ambient levels or interferes with 
normal sound production or reception by sea otters. The terms 
``acoustic disturbance'' or ``acoustic harassment'' are disturbances or 
harassment events resulting from noise exposure. Potential effects of 
noise exposure are likely to depend on the distance of the sea otter 
from the sound source, the level and intensity of sound the sea otter 
receives, background noise levels, noise frequency, noise duration, and 
whether the noise is pulsed or continuous. The actual noise level 
perceived by individual sea otters will also depend on whether the sea 
otter is above or below water and atmospheric and environmental 
conditions. Temporary disturbance of sea otters or localized 
displacement reactions are the most likely effects to occur from noise 
exposure.

Sea Otter Hearing

    Pile driving and marine construction activities will fall within 
the hearing range of sea otters. Controlled sound exposure trials on 
southern sea otters (Enhydra lutris nereis) indicate that sea otters 
can hear frequencies between 125 hertz (Hz) and 38 kilohertz (kHz) with 
best sensitivity between 1.2 and 27 kHz (Ghoul and Reichmuth 2014). 
Aerial and underwater audiograms for a captive adult male southern sea 
otter in the presence of ambient noise suggest the sea otter's hearing 
was less sensitive to high-frequency (greater than 22 kHz) and low-
frequency (less than 2 kHz) sound than terrestrial mustelids but was 
similar to that of a California sea lion (Zalophus californianus). 
However, the sea otter was still able to hear low-frequency sounds, and 
the detection thresholds for sounds between 0.125-1 kHz were between 
116-101 decibels (dB), respectively. Dominant frequencies of southern 
sea otter vocalizations are between 3 and 8 kHz, with some energy 
extending above 60 kHz (McShane et al. 1995, Ghoul and Reichmuth 2012).
    Exposure to high levels of sound may cause changes in behavior, 
masking of communications, temporary or permanent changes in hearing 
sensitivity, discomfort, and injury to marine mammals. Unlike other 
marine mammals, sea otters do not rely on sound to orient themselves, 
locate prey, or communicate under water; therefore, masking of 
communications by anthropogenic sound is less of a concern than for 
other marine mammals. However, sea otters, especially mothers and pups, 
do use sound for communication in air (McShane et al. 1995), and sea 
otters may monitor underwater sound to avoid predators (Davis et al. 
1987).

Exposure Thresholds

    Noise exposure criteria for identifying underwater noise levels 
capable of causing Level A harassment to marine mammal species, 
including sea otters, have been established using the same methods as 
those used by the National Marine Fisheries Service (NMFS) (Southall et 
al. 2019). These criteria are based on estimated levels of sound 
exposure capable of causing a permanent shift in sensitivity of hearing 
(i.e., a permanent threshold shift (PTS) (NMFS 2018)). PTS occurs when 
noise exposure causes hairs within the inner ear system to die (Ketten 
2012). Although the effects of PTS are, by definition, permanent, PTS 
does not equate to total hearing loss.
    Sound exposure thresholds incorporate two metrics of exposure: the 
peak level of instantaneous exposure likely to cause PTS and the 
cumulative sound exposure level (SELCUM) during a 24-hour 
period. They also include weighting adjustments for the sensitivity of 
different species to varying frequencies. PTS-based injury criteria 
were developed from theoretical extrapolation of observations of 
temporary threshold shifts (TTS) detected in lab settings during sound 
exposure trials (Finneran 2015). Southall and colleagues (2019) predict 
PTS for sea otters, which are included in the ``other marine 
carnivores'' category, will occur at 232 dB peak or 203 dB 
SELCUM for impulsive underwater sound and 219 dB 
SELCUM for nonimpulsive (continuous) underwater sound.
    Thresholds based on TTS have been used as a proxy for Level B 
harassment (i.e., 70 FR 1871, January 11, 2005; 71 FR 3260, January 20, 
2006; 73 FR 41318, July 18, 2008). Southall et al. (2007) derived TTS 
thresholds for pinnipeds based on 212 dB peak and 171 dB 
SELCUM. Exposures resulting in TTS in pinnipeds were found 
to range from 152 to 174 dB (183 to 206 dB SEL) (Kastak et al. 2005), 
with a persistent TTS, if not a PTS, after 60 seconds of 184 dB SEL 
(Kastak et al. 2008). Kastelein et al. (2012) found small but 
statistically significant TTSs at approximately 170 dB SEL (136 dB, 60 
minutes (min)) and 178 dB SEL (148 dB, 15 min). Based on these 
findings, Southall et al. (2019) developed TTS thresholds for sea 
otters, which are included in the ``other marine carnivores'' category, 
of 188 dB SELCUM for impulsive sounds and 199 dB 
SELCUM for nonimpulsive sounds.
    The NMFS (2018) criteria do not identify thresholds for avoidance 
of Level B harassment. For pinnipeds (seals and sea lions), NMFS has 
adopted a 160-dB threshold for Level B harassment from exposure to 
impulsive noise and a 120-dB threshold for continuous noise (NMFS 1998, 
HESS 1999, NMFS 2018). These thresholds

[[Page 37560]]

were developed from observations of mysticete (baleen) whales 
responding to airgun operations (e.g., Malme et al. 1983; Malme and 
Miles 1983; Richardson et al. 1986, 1995) and from equating Level B 
harassment with noise levels capable of causing TTS in lab settings. 
Southall et al. (2007, 2019) assessed behavioral response studies and 
found considerable variability among pinnipeds. The authors determined 
that exposures between approximately 90 to 140 dB generally do not 
appear to induce strong behavioral responses from pinnipeds in water. 
However, they found behavioral effects, including avoidance, become 
more likely in the range between 120 to 160 dB, and most marine mammals 
showed some, albeit variable, responses to sound between 140 to 180 dB. 
Wood et al. (2012) adapted the approach identified in Southall et al. 
(2007) to develop a probabilistic scale for marine mammal taxa at which 
10 percent, 50 percent, and 90 percent of individuals exposed are 
assumed to produce a behavioral response. For many marine mammals, 
including pinnipeds, these response rates were set at sound pressure 
levels of 140, 160, and 180 dB, respectively.
    We have evaluated these thresholds and determined that the Level B 
threshold of 120 dB for nonimpulsive noise is not applicable to sea 
otters. The 120-dB threshold is based on studies in which gray whales 
(Eschrichtius robustus) were exposed to experimental playbacks of 
industrial noise (Malme et al. 1983; Malme and Miles 1983). During 
these playback studies, southern sea otter responses to industrial 
noise were also monitored (Riedman 1983, 1984). Gray whales exhibited 
avoidance to industrial noise at the 120-dB threshold; however, there 
was no evidence of disturbance reactions or avoidance in southern sea 
otters. Thus, given the different range of frequencies to which sea 
otters and gray whales are sensitive, the NMFS 120-dB threshold based 
on gray whale behavior is not appropriate for predicting sea otter 
behavioral responses, particularly for low-frequency sound.
    Based on the lack of sea otter disturbance response or any other 
reaction to the playback studies from the 1980s, as well as the absence 
of a clear pattern of disturbance or avoidance behaviors attributable 
to underwater sound levels up to about 160 dB resulting from low-
frequency broadband noise, we assume 120 dB is not an appropriate 
behavioral response threshold for sea otters exposed to continuous 
underwater noise.
    Based on the best available scientific information about sea 
otters, and closely related marine mammals when sea otter data are 
limited, the Service has set 160 dB of received underwater sound as a 
threshold for Level B harassment by disturbance for sea otters for this 
proposed IHA. Exposure to unmitigated in-water noise levels between 125 
Hz and 38 kHz that are greater than 160 dB--for both impulsive and 
nonimpulsive sound sources--will be considered by the Service as Level 
B harassment. Thresholds for Level A harassment (which entails the 
potential for injury) will be 232 dB peak or 203 dB SEL for impulsive 
sounds and 219 dB SEL for continuous sounds (table 1).

Airborne Sounds

    The NMFS (2018) guidance neither addresses thresholds for 
preventing injury or disturbance from airborne noise, nor provides 
thresholds for avoidance of Level B harassment. Southall et al. (2007) 
suggested thresholds for PTS and TTS for sea lions exposed to nonpulsed 
airborne noise of 172.5 and 159 dB re (20 [micro]Pa)\2\-s SEL. 
Conveyance of underwater noise into the air is of little concern since 
the effects of pressure release and interference at the water's surface 
reduce underwater noise transmission into the air. For activities that 
create both in-air and underwater sounds, we will estimate take based 
on parameters for underwater noise transmission. Considering sound 
energy travels more efficiently through water than through air, this 
estimation will also account for exposures to sea otters at the 
surface.

   Table 1--Temporary Threshold Shift (TTS) and Permanent Threshold Shift (PTS) Thresholds Established by Southall et al. (2019) Through Modeling and
                                        Extrapolation for ``Other Marine Carnivores,'' Which Includes Sea Otters
     [Values are weighted for other marine carnivores' hearing thresholds and given in cumulative sound exposure level (SELCUM dB re (20 micropascal
  ([micro]Pa) in air and SELCUM dB re 1 [micro]Pa in water) for impulsive and nonimpulsive sounds and unweighted peak sound pressure level (SPL) in air
                                        (dB re 20 [micro]Pa) and water (dB 1 [micro]Pa) (impulsive sounds only).]
--------------------------------------------------------------------------------------------------------------------------------------------------------
                                                                                TTS                                             PTS
                                                         -----------------------------------------------------------------------------------------------
                                                           Nonimpulsive              Impulsive             Nonimpulsive              Impulsive
                                                         -----------------------------------------------------------------------------------------------
                                                              SELCUM          SELCUM         Peak SPL         SELCUM          SELCUM         Peak SPL
--------------------------------------------------------------------------------------------------------------------------------------------------------
Air.....................................................             157             146             170             177             161             176
Water...................................................             199             188             226             219             203             232
--------------------------------------------------------------------------------------------------------------------------------------------------------

Evidence From Sea Otter Studies

    Sea otters may be more resistant to the effects of sound 
disturbance and human activities than other marine mammals. For 
example, observers have noted no changes from southern sea otters in 
regard to their presence, density, or behavior in response to 
underwater sounds from industrial noise recordings at 110 dB and a 
frequency range of 50 Hz to 20 kHz and airguns, even at the closest 
distance of 0.5 nautical miles (<1 km or 0.6 mi) (Riedman 1983). 
Southern sea otters did not respond noticeably to noise from a single 
1,638 cubic centimeters (cm\3\) (100 cubic inches [in\3\]) airgun, and 
no sea otter disturbance reactions were evident when a 67,006 cm\3\ 
(4,089 in\3\) airgun array was as close as 0.9 km (0.6 mi) to sea 
otters (Riedman 1983, 1984). However, southern sea otters displayed 
slight reactions to airborne engine noise (Riedman 1983). Northern sea 
otters were observed to exhibit a limited response to a variety of 
airborne and underwater sounds, including a warble tone, sea otter pup 
calls, calls from killer whales (Orcinus orca) (which are predators to 
sea otters), air horns, and an underwater noise harassment system 
designed to drive marine mammals away from crude oil spills (Davis et 
al. 1988). These sounds elicited reactions from northern sea otters, 
including startle responses and movement away from noise sources. 
However, these reactions were observed only when northern sea otters 
were within 100 to 200 m (328 to 656 ft) of noise sources. Further, 
northern sea otters appeared to become habituated to the noises within

[[Page 37561]]

2 hours or, at most, 3-4 days (Davis et al. 1988).
    Noise exposure may be influenced by the amount of time sea otters 
spend at the water's surface. Noise at the water's surface can be 
attenuated by turbulence from wind and waves more quickly compared to 
deeper water, reducing potential noise exposure (Greene and Richardson 
1988, Richardson et al. 1995). Additionally, turbulence at the water's 
surface limits the transference of sound from water to air. A sea otter 
with its head above water will be exposed to only a small fraction of 
the sound energy traveling through the water beneath it. The average 
amount of time that sea otters spend above the water each day while 
resting and grooming varies between males and females and across 
seasons (Esslinger et al. 2014, Zellmer et al. 2021). For example, 
female sea otters foraged for an average of 8.78 hours per day compared 
to male sea otters, which foraged for an average of 7.85 hours per day 
during the summer months (Esslinger et al. 2014). Male and female sea 
otters spend an average of 63 to 67 percent of their day at the surface 
resting and grooming during the summer months (Esslinger et al. 2014). 
Few studies have evaluated foraging times during the winter months. 
Garshelis et al. (1986) found that foraging times increased from 5.1 
hours per day to 16.6 hours per day in the winter; however, Gelatt et 
al. (2002) did not find a significant difference in seasonal foraging 
times. It is likely that seasonal variation is determined by seasonal 
differences in energetic demand and the quality and availability of 
prey sources (Esslinger et al. 2014). These findings suggest that the 
large portion of the day sea otters spend at the surface may help limit 
sea otters' exposure during noise-generating operations.
    Sea otter sensitivity to industrial activities may be influenced by 
the overall level of human activity within the sea otter population's 
range. In locations that lack frequent human activity, sea otters 
appear to have a lower threshold for disturbance. Sea otters in Alaska 
exhibited escape behaviors in response to the presence and approach of 
vessels (Udevitz et al. 1995). Behaviors included diving or actively 
swimming away from a vessel, entering the water from haulouts, and 
disbanding groups with sea otters swimming in multiple different 
directions (Udevitz et al. 1995). Sea otters in Alaska were also 
observed to avoid areas with heavy boat traffic in the summer and 
return to these areas during seasons with less vessel traffic 
(Garshelis and Garshelis 1984). In Cook Inlet, sea otters drifting on a 
tide trajectory that would have taken them within 500 m (0.3 mi) of an 
active offshore drilling rig were observed to swim in order to avoid a 
close approach of the drilling rig despite near-ambient noise levels 
(BlueCrest 2013).
    Individual sea otters in Passage Canal will likely show a range of 
responses to noise from pile-driving activities. Some sea otters will 
likely dive, show startle responses, change direction of travel, or 
prematurely surface. Sea otters reacting to pile-driving activities may 
divert time and attention from biologically important behaviors, such 
as feeding and nursing pups. Sea otter responses to disturbance can 
result in energetic costs, which increases the amount of prey required 
by sea otters (Barrett 2019). This increased prey consumption may 
impact sea otter prey availability and cause sea otters to spend more 
time foraging and less time resting (Barrett 2019). Some sea otters may 
abandon the project area and return when the disturbance has ceased. 
Based on the observed movement patterns of sea otters (i.e., Lensink 
1962; Kenyon 1969, 1981; Garshelis and Garshelis 1984; Riedman and 
Estes 1990; Tinker and Estes 1996), we expect some individuals will 
respond to pile-driving activities by dispersing to nearby areas of 
suitable habitat; however, other sea otters, especially territorial 
adult males, are less likely to be displaced.

Consequences of Disturbance

    The reactions of wildlife to disturbance can range from short-term 
behavioral changes to long-term impacts that affect survival and 
reproduction. When disturbed by noise, animals may respond behaviorally 
(e.g., escape response) or physiologically (e.g., increased heart rate, 
hormonal response) (Harms et al. 1997; Tempel and Guti[eacute]rrez 
2003). Theoretically, the energy expense and associated physiological 
effects from repeated disturbance could ultimately lead to reduced 
survival and reproduction (Gill and Sutherland 2000; Frid and Dill 
2002). For example, South American sea lions (Otaria byronia) visited 
by tourists exhibited an increase in the state of alertness and a 
decrease in maternal attendance and resting time on land, thereby 
potentially reducing population size (Pavez et al. 2015). In another 
example, killer whales that lost feeding opportunities due to boat 
traffic faced a substantial (18 percent) estimated decrease in energy 
intake (Williams et al. 2006). In severe cases, such disturbance 
effects could have population-level consequences. For example, 
increased disturbance by tourism vessels has been associated with a 
decline in abundance of bottlenose dolphins (Tursiops spp.) (Bejder et 
al. 2006; Lusseau et al. 2006). However, these examples evaluated 
sources of disturbance that were longer term and more consistent than 
the temporary and intermittent nature of the specified project 
activities.
    These examples illustrate direct effects on survival and 
reproductive success, but disturbances can also have indirect effects. 
Response to noise disturbance is considered a nonlethal stimulus that 
is similar to an antipredator response (Frid and Dill 2002). Sea otters 
are susceptible to predation, particularly from killer whales and 
eagles, and have a well-developed antipredator response to perceived 
threats. For example, the presence of a harbor seal (Phoca vitulina) 
did not appear to disturb southern sea otters, but they demonstrated a 
fear response in the presence of a California sea lion by actively 
looking above and beneath the water (Limbaugh 1961).
    Although an increase in vigilance or a flight response is 
nonlethal, a tradeoff occurs between risk avoidance and energy 
conservation. An animal's reactions to noise disturbance may cause 
stress and direct an animal's energy away from fitness-enhancing 
activities such as feeding and mating (Frid and Dill 2002; Goudie and 
Jones 2004). For example, southern sea otters in areas with heavy 
recreational boat traffic demonstrated changes in behavioral time 
budgeting, showing decreased time resting and changes in haulout 
patterns and distribution (Benham 2006; Maldini et al. 2012). Chronic 
stress can also lead to weakened reflexes, lowered learning responses 
(Welch and Welch 1970; van Polanen Petel et al. 2006), compromised 
immune function, decreased body weight, and abnormal thyroid function 
(Selye 1979).
    Changes in behavior resulting from anthropogenic disturbance can 
include increased agonistic interactions between individuals or 
temporary or permanent abandonment of an area (Barton et al. 1998). 
Additionally, the extent of previous exposure to humans (Holcomb et al. 
2009), the type of disturbance (Andersen et al. 2012), and the age or 
sex of the individuals (Shaughnessy et al. 2008; Holcomb et al. 2009) 
may influence the type and extent of response in individual sea otters.

Vessel Activities

    Vessel collisions with marine mammals can result in death or 
serious injury. Wounds resulting from vessel

[[Page 37562]]

strike may include massive trauma, hemorrhaging, broken bones, or 
propeller lacerations (Knowlton and Kraus 2001). An animal may be 
harmed by a vessel when the vessel runs over the animal at the surface, 
the animal hits the bottom of a vessel while the animal is surfacing, 
or the animal is cut by a vessel's propeller.
    Vessel strike has been documented as a cause of death across all 
three stocks of northern sea otters in Alaska. Since 2002, the Service 
has conducted 1,433 sea otter necropsies to determine cause of death, 
disease incidence, and the general health status of sea otters in 
Alaska. Vessel strike or blunt trauma was identified as a definitive or 
presumptive cause of death in 65 cases (4 percent) (USFWS 2020). In 
most of these cases, trauma was determined to be the ultimate cause of 
death; however, there was a contributing factor, such as disease or 
biotoxin exposure, which incapacitated the sea otter and made it more 
vulnerable to vessel strike (USFWS 2023).
    Vessel speed influences the likelihood of vessel strikes involving 
sea otters. The probability of death or serious injury to a marine 
mammal increases as vessel speed increases (Laist et al. 2001, 
Vanderlaan and Taggart 2007). Sea otters spend a considerable portion 
of their time at the water's surface (Esslinger et al. 2014). They are 
typically visually aware of approaching vessels and can move away if a 
vessel is not traveling too quickly. Mitigation measures to be applied 
to vessel operations to prevent collisions or interactions are included 
below in the proposed authorization portion of this document under 
Avoidance and Minimization.
    Sea otters exhibit behavioral flexibility in response to vessels, 
and their responses may be influenced by the intensity and duration of 
the vessel's activity. As noted above, sea otter populations in Alaska 
were observed to avoid areas with heavy vessel traffic but return to 
those same areas during seasons with less vessel traffic (Garshelis and 
Garshelis 1984). Sea otters have also shown signs of disturbance or 
escape behaviors in response to the presence and approach of survey 
vessels including sea otters diving and/or actively swimming away from 
a vessel, sea otters on haulouts entering the water, and groups of sea 
otters disbanding and swimming in multiple different directions 
(Udevitz et al. 1995).
    Additionally, sea otter responses to vessels may be influenced by 
the sea otter's previous experience with vessels. Groups of southern 
sea otters in two locations in California showed markedly different 
responses to kayakers approaching to within specific distances, 
suggesting a different level of tolerance between the groups (Gunvalson 
2011). Benham (2006) found evidence that the sea otters exposed to high 
levels of recreational activity may have become more tolerant than 
individuals in less-disturbed areas. Sea otters off the California 
coast showed only mild interest in vessels passing within hundreds of 
meters and appeared to have habituated to vessel traffic (Riedman 1983, 
Curland 1997). These findings indicate that sea otters may adjust their 
responses to vessel activities depending on the level of activity. 
Vessel activity during the project includes the transit of three barges 
for materials and construction, all of which will remain onsite, mostly 
stationary, to support the work; additionally, two skiffs will be used 
during the project: one for transporting workers short distances to the 
crane barge and the other for marine mammal monitoring during pile 
driving. Vessels will not be used extensively or over a long duration 
during the planned work; therefore, we do not anticipate that sea 
otters will experience changes in behavior indicative of tolerance or 
habituation.

Effects on Sea Otter Habitat and Prey

    Physical and biological features of habitat essential to the 
conservation of sea otters include the benthic invertebrates that sea 
otters eat and the shallow rocky areas and kelp beds that provide cover 
from predators. Sea otter habitat in the project area includes coastal 
areas within the 40-m (131-ft) depth contour where high densities of 
sea otters have been detected.
    Industrial activities, such as pile driving, may generate in-water 
noise at levels that can temporarily displace sea otters from important 
habitat and impact sea otter prey species. The primary prey species for 
sea otters are sea urchins (Strongylocentrotus spp. and Mesocentrotus 
spp.), abalone (Haliotis spp.), clams (e.g., Clinocardium nuttallii, 
Leukoma staminea, and Saxidomus gigantea), mussels (Mytilus spp.), 
crabs (e.g., Metacarcinus magister, Pugettia spp., Telemessus 
cheiragonus, and Cancer spp.), and squid (Loligo spp.) (Tinker and 
Estes 1996, LaRoche et al. 2021). When preferential prey are scarce, 
sea otters will also eat kelp, slow-moving benthic fishes, sea 
cucumbers (e.g., Apostichopus californicus), egg cases of rays, turban 
snails (Tegula spp.), octopuses (e.g., Octopus spp.), barnacles 
(Balanus spp.), sea stars (e.g., Pycnopodia helianthoides), scallops 
(e.g., Patinopecten caurinus), rock oysters (Saccostrea spp.), worms 
(e.g., Eudistylia spp.), and chitons (e.g., Mopalia spp.) (Riedman and 
Estes 1990, Davis and Bodkin 2021).
    Several studies have addressed the effects of noise on 
invertebrates (Tidau and Briffa 2016, Carroll et al. 2017). Behavioral 
changes, such as an increase in lobster (Homarus americanus) feeding 
levels (Payne et al. 2007), an increase in avoidance behavior by wild-
caught captive reef squid (Sepioteuthis australis) (Fewtrell and 
McCauley 2012), and deeper digging by razor clams (Sinonovacula 
constricta) (Peng et al. 2016) have been observed following 
experimental exposures to sound. Physical changes have also been 
observed in response to increased sound levels, including changes in 
serum biochemistry and hepatopancreatic cells in lobsters (Payne et al. 
2007) and long-term damage to the statocysts required for hearing in 
several cephalopod species (Andr[eacute] et al. 2011, Sol[eacute] et 
al. 2013). De Soto et al. (2013) found impaired embryonic development 
in scallop (Pecten novaezelandiae) larvae when exposed to 160 dB. 
Christian et al. (2003) noted a reduction in the speed of egg 
development of bottom-dwelling crabs following exposure to noise; 
however, the sound level (221 dB at 2 m or 6.6 ft) was far higher than 
the planned project activities will produce. Industrial noise can also 
impact larval settlement by masking the natural acoustic settlement 
cues for crustaceans and fish (Pine et al. 2012, Simpson et al. 2016, 
Tidau and Briffa 2016).
    While these studies provide evidence of deleterious effects to 
invertebrates as a result of increased sound levels, Carroll et al. 
(2017) caution that there is a wide disparity between results obtained 
in field and laboratory settings. In experimental settings, changes 
were observed only when animals were housed in enclosed tanks, and many 
were exposed to prolonged bouts of continuous, pure tones. We would not 
expect similar results in open marine conditions. It is unlikely that 
noises generated by project activities will have any lasting effect on 
sea otter prey given the short-term duration of sounds produced by each 
component of the planned work.
    Noise-generating activities that interact with the seabed can 
produce vibrations, resulting in the disturbance of sediment and 
increased turbidity in the water. Although turbidity is likely to have 
little impact on sea otters and prey species (Todd et al. 2015), there 
may be some impacts from vibrations and increased sedimentation. For 
example,

[[Page 37563]]

mussels (Mytilus edulis) exhibited changes in valve gape and oxygen 
demand, and hermit crabs (Pagurus bernhardus) exhibited limited 
behavioral changes in response to vibrations caused by pile driving 
(Roberts et al. 2016). Increased sedimentation is likely to reduce sea 
otter visibility, which may result in reduced foraging efficiency and a 
potential shift to less-preferred prey species. These outcomes may 
cause sea otters to spend more energy on foraging or processing the 
prey items; however, the impacts of a change in energy expenditure are 
not likely seen at the population level (Newsome et al. 2015). 
Additionally, the benthic invertebrates may be impacted by increased 
sedimentation, resulting in higher abundances of opportunistic species 
that recover quickly from industrial activities that increase 
sedimentation (Kotta et al. 2009). Although sea otter foraging could be 
impacted by industrial activities that cause vibrations and increased 
sedimentation, it is more likely that sea otters would be temporarily 
displaced from the project area due to impacts from noise rather than 
vibrations and sedimentation.

Potential Impacts of the Specified Activities on Subsistence Uses

    The planned specified activities will occur near marine subsistence 
harvest areas used by Alaska Natives from Whittier and the surrounding 
areas. The majority of sea otter harvest in this area occurs more than 
3.2 km (2 mi) outside of Whittier. Since 2012, there have been 75 sea 
otters harvested in the Whittier area, and most of those were taken 
prior to 2017. From 2018 through 2021, only eight sea otters were 
harvested from the Whittier area.
    The planned project would occur within the Whittier city limits, 
where firearm use is prohibited. The area potentially affected by the 
planned project does not significantly overlap with current subsistence 
harvest areas. Construction activities will not preclude access to 
hunting areas or interfere in any way with individuals wishing to hunt. 
Despite no conflict with subsistence use being anticipated, the Service 
will conduct outreach with potentially affected communities to see 
whether there are any questions, concerns, or potential conflicts 
regarding subsistence use in those areas. If any conflicts are 
identified in the future, TMC will develop a plan of cooperation 
specifying the steps necessary to minimize any effects the project may 
have on subsistence harvest.

Estimated Take

Definitions of Incidental Take Under the Marine Mammal Protection Act

    Below we provide definitions of three potential types of take of 
sea otters. The Service does not anticipate and is not authorizing 
lethal take as a part of this proposed IHA; however, the definitions of 
these take types are provided for context and background:
    Lethal Take--Human activity may result in biologically significant 
impacts to sea otters. In the most serious interactions, human actions 
can result in mortality of sea otters.
    Level A Harassment--Human activity may result in the injury of sea 
otters. Level A harassment, for nonmilitary readiness activities, is 
defined as any act of pursuit, torment, or annoyance that has the 
potential to injure a marine mammal or marine mammal stock in the wild.
    Level B Harassment--Level B Harassment for nonmilitary readiness 
activities means any act of pursuit, torment, or annoyance that 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, feeding, or sheltering. 
Changes in behavior that disrupt biologically significant behaviors or 
activities for the affected animal are indicative of take by Level B 
harassment under the MMPA.
    The Service has identified the following sea otter behaviors as 
indicative of possible Level B harassment:
     Swimming away at a fast pace on belly (i.e., porpoising);
     Repeatedly raising the head vertically above the water to 
get a better view (spyhopping) while apparently agitated or while 
swimming away;
     In the case of a pup, repeatedly spyhopping while hiding 
behind and holding onto its mother's head;
     Abandoning prey or feeding area;
     Ceasing to nurse and/or rest (applies to dependent pups);
     Ceasing to rest (applies to independent animals);
     Ceasing to use movement corridors;
     Ceasing mating behaviors;
     Shifting/jostling/agitation in a raft so that the raft 
disperses;
     Sudden diving of an entire raft; or
     Flushing animals off a haulout.
    This list is not meant to encompass all possible behaviors; other 
behavioral responses may equate to take by Level B harassment. 
Relatively minor changes in behavior such as increased vigilance or a 
short-term change in direction of travel are not likely to disrupt 
biologically important behavioral patterns, and the Service does not 
view such minor changes in behavior as indicative of a take by Level B 
harassment.

Calculating Take

    We assumed all animals exposed to underwater sound levels that meet 
the acoustic exposure criteria defined above in Exposure Thresholds 
will experience take by Level A or Level B harassment due to exposure 
to underwater noise. Spatially explicit zones of ensonification were 
established around the planned construction location to estimate the 
number of otters that may be exposed to these sound levels. We 
determined the number of otters present in the ensonification zones 
using density information generated by Esslinger et al. (2021).
    The project can be divided into four major components: DTH 
drilling, vibratory drilling, pile driving using an impact driver, and 
skiff use to support construction. Each of these components will 
generate a different type of in-water noise. Vibratory drilling and the 
use of skiffs will produce nonimpulsive or continuous noise; impact 
driving will produce impulsive noise; and DTH drilling is considered to 
produce both impulsive and continuous noise (NMFS 2020).
    The level of sound anticipated from each project component was 
established using recorded data from several sources listed in tables 2 
through 5. We used the NMFS Technical Guidance and User Spreadsheet 
(NMFS 2018, 2020) to determine the distance at which sound levels would 
attenuate to Level A harassment thresholds, and empirical data from the 
proxy projects were used to determine the distance at which sound 
levels would attenuate to Level B harassment thresholds (table 1). The 
weighting factor adjustment included in the NMFS user spreadsheet 
accounts for sounds created in portions of an organism's hearing range 
where they have less sensitivity. We used the weighting factor 
adjustment for otariid pinnipeds as they are the closest available 
physiological and anatomical proxy for sea otters. The spreadsheet also 
incorporates a transmission loss coefficient, which accounts for the 
reduction in sound level outward from a sound source. We used the NMFS-
recommended transmission loss coefficient of 15 for coastal pile-
driving activities to indicate practical spread (NMFS 2020).
    We calculated the harassment zones for DTH drilling with input from 
NMFS. The sound pressure levels produced by DTH drilling were provided 
by NMFS in

[[Page 37564]]

2022 via correspondence with Solstice Alaska Consulting, who created 
the application for this IHA on behalf of TMC. We then used the NMFS 
Technical Guidance and User Spreadsheet (NMFS 2018, 2020) to determine 
the distance at which these sounds would attenuate to Level A 
harassment thresholds. To estimate the distances at which sounds would 
attenuate to Level B harassment thresholds, we used the NMFS-
recommended transmission loss coefficient of 15 for coastal pile-
driving activities in a practical spreading loss model (NMFS 2020) to 
determine the distance at which sound levels attenuate to 160 dB re 1 
[micro]Pa. However, due to the differences in how PTS and TTS 
thresholds are calculated, as well as limited data of underwater sound 
pressure levels from DTH drilling, the resultant Level A isopleths are 
larger than the Level B isopleths.

 Table 2--Summary of Sound Level, Timing of Sound Production, Distance From Sound Source to Below Level A Harassment and Level B Harassment Thresholds,
      Days of Impact, Sea Otters in Level A and Level B Harassment Ensonification Area, and Total Otters Expected To Be Harassed Through Behavioral
                                                            Disturbance by Vibratory Drilling
--------------------------------------------------------------------------------------------------------------------------------------------------------
                                          91-cm (36-in)
             Pile size                    (temporary)-            91-cm (36-in)          91-cm (36-in)          107-cm (42-in)         122-cm (48-in)
                                          installation        (temporary)- removal        (permanent)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Total number of piles..............  72....................  72....................  36...................  16...................  20.
                                    --------------------------------------------------------------------------------------------------------------------
Sound level........................                    166 dB re 1[micro]Pa at 10 m (RMS)
                                          168.2 dB re 1[micro]Pa at 10 m (RMS)
                                    --------------------------------------------------------------------------------------------------------------------
Source.............................                             NAVFAC \a\ 2015
                                                   Austin et al. 2016
                                    --------------------------------------------------------------------------------------------------------------------
Timing per pile....................  10 minutes/pile.......  10 minutes/pile.......  15 minutes/pile......  15 minutes/pile......  15 minutes/pile.
Maximum number of piles per day....  4.....................  4.....................  4....................  4....................  2.
Maximum number of days of activity.  18....................  18....................  9....................  4....................  10.
                                    --------------------------------------------------------------------------------------------------------------------
Sea otter density..................                                                 2.03 sea otters/km\2\
                                    --------------------------------------------------------------------------------------------------------------------
Distance to below Level A            0.5 meters............  0.5 meters............  0.6 meters...........  0.9 meters...........  0.6 meters.
 harassment threshold.
Level A area (km\2\)...............  0.000001..............  0.000001..............  0.000001.............  0.000003.............  0.000001.
Potential sea otters affected by     0.000002..............  0.000002..............  0.000002.............  0.00001..............  0.000002.
 Level A sound per day.
Potential sea otters affected by     0.....................  0.....................  0....................  0....................  0.
 Level A sound per day (rounded).
Total potential Level A harassment   0.....................  0.....................  0....................  0....................  0.
 events.
Distance to below Level B            25 meters.............  25 meters.............  25 meters............  35 meters............  35 meters.
 harassment threshold.
Level B area (km\2\)...............  0.0020................  0.0020................  0.0020...............  0.0038...............  0.0038.
Potential sea otters affected by     0.0041................  0.0041................  0.0041...............  0.0077...............  0.0077.
 Level B sound per day.
Potential sea otters affected by     0.....................  0.....................  0....................  0....................  0.
 Level B sound per day (rounded).
Total potential Level B harassment   0.....................  0.....................  0....................  0....................  0.
 events.
--------------------------------------------------------------------------------------------------------------------------------------------------------
\a\ Naval Facilities Engineering Command.


    Table 3--Summary of Sound Level, Timing of Sound Production, Distance From Sound Source to Below Level A
   Harassment and Level B Harassment Thresholds, Days of Impact, Sea Otters in Level A and Level B Harassment
   Ensonification Area, and Total Otters Expected To Be Harassed Through Behavioral Disturbance by Impact Pile
                                                     Driving
----------------------------------------------------------------------------------------------------------------
                                            91-cm (36-in)
              Pile size                      (permanent)             107-cm (42-in)           122-cm (48-in)
----------------------------------------------------------------------------------------------------------------
Total number of piles................  36.....................  16.....................  20.
Sound level..........................  184 dB (SEL)/192 dB      186.7 dB (SEL)/198.6 dB  186.7 dB (SEL)/198.6 dB
                                        (RMS)/211 dB (peak) re   (RMS) re 1[micro]Pa at   (RMS)/212 dB (peak) re
                                        1[micro]Pa at 10 m.      10 m.                    1[micro]Pa at 10 m.
                                                               -------------------------------------------------
Source...............................  NAVFAC 2015............                 Austin et al. 2016
                                                               -------------------------------------------------
Timing per pile......................  45 minutes/pile; 1,800   60 minutes/pile; 2,400   60 minutes/pile; 2,400
                                        strikes/pile.            strikes/pile.            strikes/pile.
Maximum number piles per day.........  4......................  3......................  2.
Maximum number of days of activity...  9......................  5.3....................  10.
                                      --------------------------------------------------------------------------
Sea otter density....................                            2.03 sea otters/km\2\
                                      --------------------------------------------------------------------------
Distance to below Level A harassment   169.2 meters...........  256.0 meters...........  195.4 meters.
 threshold.
Level A area (km\2\).................  0.0718.................  0.1786.................  0.1199.

[[Page 37565]]

 
Potential sea otters affected by       0.1458.................  0.3626.................  0.2434.
 Level A sound per day.
Potential sea otters affected by       1......................  1......................  1.
 Level A sound per day (rounded).
Total potential Level A harassment     9......................  6......................  10.
 events.
Distance to below Level B harassment   1,359 meters...........  3,744 meters...........  3,744 meters.
 threshold.
Level B area (km\2\).................  1.9161.................  7.3224.................  7.8846.
Potential sea otters affected by       3.8897.................  14.8645................  16.0057.
 Level B sound per day.
Potential sea otters affected by       4......................  15.....................  16.
 Level B sound per day (rounded).
Total potential Level B harassment     36.....................  80.....................  160.
 events.
----------------------------------------------------------------------------------------------------------------


    Table 4--Summary of Sound Level, Timing of Sound Production, Distance From Sound Source to Below Level A
   Harassment and Level B Harassment Thresholds, Days of Impact, Sea Otters in Level A and Level B Harassment
  Ensonification Area, and Total Otters Expected To Be Harassed Through Behavioral Disturbance by Down-the-Hole
                                                    Drilling
----------------------------------------------------------------------------------------------------------------
                                     91-cm (36-in)       91-cm (36-in)
            Pile size                 (temporary)         (permanent)       107-cm (42-in)      122-cm (48-in)
----------------------------------------------------------------------------------------------------------------
Total number of piles...........  36 (installation    36................  16................  20.
                                   only).
                                 ------------------------------------------------------------
Sound level.....................        164 dB (SEL)/167 dB (RMS) re 1[micro]Pa at 10 m       171 dB (SEL)/167
                                                                                               (RMS) dB re
                                                                                               1[micro]Pa at 10
                                                                                               m.
                                 ------------------------------------------------------------
Source..........................    Reyff and Heyvaert 2019; Reyff 2020; Denes et al. 2019;   SolsticeAK 2022;
                                                    Heyvaert and Reyff 2021                    Heyvaert and
                                                                                               Reyff 2021.
                                 ------------------------------------------------------------
Timing per pile.................  60 minutes/pile...  150 minutes/pile..  150 minutes/pile..  150 minutes/pile.
Maximum number piles per day....  4.................  2.................  2.................  2.
Maximum number of days of         9.................  18................  8.................  10.
 activity.
                                 -------------------------------------------------------------------------------
Sea otter density...............                               2.03 sea otters/km\2\
                                 -------------------------------------------------------------------------------
Distance to below Level A         57.9 meters.......  67.1 meters.......  67.1 meters.......  196.6 meters.
 harassment threshold \a\.
Level A area (km\2\)............  0.0105............  0.0141............  0.0141............  0.1214.
Potential sea otters affected by  0.0213............  0.0286............  0.0286............  0.2464.
 Level A sound per day.
Potential sea otters affected by  1.................  1.................  1.................  1.
 Level A sound per day (rounded).
Total potential Level A           9.................  18................  8.................  10.
 harassment events.
Distance to below Level B         29 meters.........  29 meters.........  29 meters.........  29 meters.
 harassment threshold \a\.
Level B area (km\2\)............  0.0026............  0.0026............  0.0026............  0.0026.
Potential sea otters affected by  0.0053............  0.0053............  0.0053............  0.0053.
 Level B sound per day.
Potential sea otters affected by  0.................  0.................  0.................  0.
 Level B sound per day (rounded).
Total potential Level B           0.................  0.................  0.................  0.
 harassment events.
----------------------------------------------------------------------------------------------------------------
\a\ Due to differences in how PTS and TTS thresholds are calculated, the Level A isopleths are larger than the
  Level B isopleths.


  Table 5--Summary of Sound Level, Timing of Sound Production, Distance
  From Sound Source to Below Level A Harassment and Level B Harassment
Thresholds, Days of Impact, Sea Otters in Level A and Level B Harassment
  Ensonification Area, and Total Otters Expected To Be Harassed Through
                 Behavioral Disturbance by Use of Skiffs
------------------------------------------------------------------------
                                                        Worker transit
          Sound source             Monitoring skiff          skiff
------------------------------------------------------------------------
Sound level.....................  175 dB (RMS) re     175 dB (RMS) re
                                   1[micro]Pa at 1 m.  1[micro]Pa at 1
                                                       m.
                                 ---------------------------------------
Source..........................    Richardson et al. 1995; Kipple and
                                               Gabriele 2007
                                 ---------------------------------------

[[Page 37566]]

 
Number of days of vessel use....  129...............  129.
                                 ---------------------------------------
Sea otter density...............           2.03 sea otters/km\2\
                                 ---------------------------------------
Distance to below Level A         0 meters..........  0 meters.
 harassment threshold.
Level A area (km\2\)............  0.................  0.
Potential sea otters affected by  0.................  0.
 Level A sound per day.
Potential sea otters affected by  0.................  0.
 Level A sound per day (rounded).
Total potential Level A           0.................  0.
 harassment events.
Distance to below Level B         10 meters.........  10 meters.
 harassment threshold.
Level B area (km\2\)............  0.2832............  0.0095.
Potential sea otters affected by  0.5748............  0.0192.
 Level B sound per day.
Potential sea otters affected by  1.................  1.
 Level B sound per day (rounded).
Total potential Level B           129...............  129.
 harassment events.
------------------------------------------------------------------------

    Sound levels for all sources are unweighted and given in dB re 
1[micro]Pa. Nonimpulsive sounds are in the form of mean maximum root 
mean square (RMS) sound pressure level (SPL) as it is more conservative 
than cumulative sound exposure level (SEL) or peak SPL for these 
activities. Impulsive sound sources are in the form of SEL for a single 
strike.
    To determine the number of sea otters that may experience in-water 
sounds >160 dB re 1[micro]Pa due to pile driving, we multiplied the 
area ensonified to >160 dB re 1[micro]Pa by the density of animals 
(2.03 sea otters/km\2\) derived from surveys conducted off Prince 
William Sound (Esslinger 2021). We applied the same methodology to 
determine the number of sea otters that may experience sounds capable 
of causing PTS. The number of sea otters expected to be exposed to such 
sound levels can be found in tables 2 through 5. To calculate the area 
ensonified for each type of pile-driving activity, the coordinates of 
the piles were mapped in ArcGIS Pro. We used a representative pile of 
each size around which to map the Level A and Level B harassment zones. 
We chose representative piles that were farthest from shore so that the 
zones that are intercepted by land have the largest in-water areas 
possible. The majority of these radii are small enough that their 
defined circles will fall entirely in the water, and in these 
instances, the area was calculated as [pi]r\2\. The exceptions are the 
Level A and Level B zones generated by impact pile driving the 36-in 
permanent and 42-in piles, as well as the Level B zone generated by 
impact pile driving the 48-in piles; for these, we used ArcGIS Pro to 
map and calculate the area of the water ensonified by those activities.
    The area ensonified by the worker transit skiff was estimated by 
multiplying the vessel's anticipated daily track length by twice the 
160 dB radius plus [pi]r\2\ to account for the rounded ends of the 
track line. It was estimated that the distance of each trip would be no 
more than 457.2 m (1,500 ft).
    The monitoring skiff will travel in a triangle of perimeter 
approximately 7 km (4.3 mi) between Emerald Island, the north shore of 
Passage Canal, and Gradual Point. To estimate the area ensonified by 
the monitoring skiff, we used ArcGIS Pro to plot the points of the 
triangle, map the track line between those points, and apply a buffer 
of 10 m (33 ft; the 160-dB radius) on either side of the track line.
    We assumed that the different types of activities would occur 
sequentially and that the total number of days of work would equal the 
sum of the number of days required to complete each type of activity. 
While it is possible that on some days more than one type of activity 
will take place, which would reduce the number of days of exposure 
within a year, we cannot know this information in advance. As such, the 
estimated number of days and, therefore, exposures per year is the 
maximum possible for the planned work. Where the number of exposures 
expected per day was zero to three or more decimal places (i.e., 
<0.00X), the number of exposures per day was assumed to be zero.
    In order to minimize exposure of sea otters to sounds above Level A 
harassment thresholds, TMC will implement shutdown zones ranging from 
10 to 260 m (33 to 853 ft), based on the pile size and type of pile 
driving or marine construction activity, where operations will cease 
should a sea otter enter or approach the specified zone. Soft-start and 
zone clearance prior to startup will also limit the exposure of sea 
otters to sound levels that could cause PTS. However, TMC has 
requested, and the Service proposes to authorize, small numbers of take 
by Level A harassment during impact pile driving and DTH drilling.

Critical Assumptions

    We estimate that 544 takes of 37 sea otters by Level B harassment 
and 70 takes of 7 sea otters by Level A harassment may occur due to 
TMC's planned cruise ship dock construction activities. In order to 
conduct this analysis and estimate the potential amount of take by 
harassment, several critical assumptions were made.
    Level B harassment is equated herein with behavioral responses that 
indicate harassment or disturbance. There is likely a portion of 
animals that respond in ways that indicate some level of disturbance 
but do not experience significant biological consequences.
    We used the sea otter density for the Whittier area from surveys 
and analyses conducted by Esslinger (2021). Methods and assumptions for 
these surveys can be found in the original publication.
    We used sound source verification from recent pile-driving 
activities in a number of locations within and beyond Alaska to 
generate sound level estimates for construction activities. 
Environmental conditions in these locations, including water depth, 
substrate, and ambient sound levels are similar to those in the project 
location, but not identical. Further, estimation of ensonification 
zones were based on sound attenuation models using a practical 
spreading loss model. These factors may lead to actual sound values

[[Page 37567]]

differing slightly from those estimated here.
    We assumed that all piles will be installed and removed while 
submerged in water. Some of the 36-in permanent piles supporting the 
approach trestle, and the associated temporary 36-in piles used for the 
templates to install the permanent piles, will be located in the 
intertidal zone. Work performed at lower tidal heights would likely 
result in decreased transmission of sounds to the water column. 
However, as the timing of pile installation and removal was not known 
in advance, we accounted for the possibility that all work may occur at 
a tidal height that allows for full sound transmission.
    Finally, the pile-driving activities described here will also 
create in-air noise. Because sea otters spend over half of their day 
with their heads above water (Esslinger et al. 2014), they will be 
exposed to an increase in-air noise from construction equipment. 
However, we have calculated Level B harassment with the assumption that 
an individual may be harassed only one time per 24-hour period, and 
underwater sound levels will be more disturbing and extend farther than 
in-air noise. Thus, while sea otters may be disturbed by noise both in-
air and underwater, we have relied on the more conservative underwater 
estimates.

Sum of Harassment From All Sources

    The applicant plans to conduct pile driving and marine construction 
activities in Whittier, Alaska, over the course of a year from the date 
of issuance of the IHA. A summary of total estimated take during the 
project by source is provided in table 6.

            Table 6--Total Estimated Takes By Source of Level A and Level B Harassment of Sea Otters
----------------------------------------------------------------------------------------------------------------
                                                    Sea otters      Total takes     Sea otters      Total takes
                                     Number of      exposed per    of sea otters    exposed per   of sea  otters
             Source                   days of      day to  Level    by  Level A    day to  Level    by  Level B
                                     activity      A  harassment    harassment     B  harassment    harassment
----------------------------------------------------------------------------------------------------------------
Vibratory drilling:
    36-inch piles (temporary)--               18               0               0               0               0
     installation...............
    36-inch piles (temporary)--               18               0               0               0               0
     removal....................
    36-inch piles (permanent)...               9               0               0               0               0
    42-inch piles...............               4               0               0               0               0
    48-inch piles...............              10               0               0               0               0
Impact drilling:
    36-inch piles (permanent)...               9               1               9               4              36
    42-inch piles...............               6               1               6              15              90
    48-inch piles...............              10               1              10              16             160
Down-the-hole drilling:
    36-inch piles (temporary)--                9               1               9               0               0
     installation...............
    36-inch piles (permanent)...              18               1              18               0               0
    42-inch piles...............               8               1               8               0               0
    48-inch piles...............              10               1              10               0               0
Skiff use:
    Monitoring skiff............             129               0               0               1             129
    Worker transit skiff........             129               0               0               1             129
                                 -------------------------------------------------------------------------------
        Totals..................             387               7              70              37             544
----------------------------------------------------------------------------------------------------------------

    Over the course of the project, we estimate 544 instances of take 
by Level B harassment of 37 northern sea otters from the Southcentral 
Alaska stock due to behavioral responses of TTS associated with noise 
exposure. Although multiple instances of Level B harassment of 
individual sea otters are possible, these events are unlikely to have 
significant consequences for the health, reproduction, or survival of 
affected animals and therefore would not rise to the level of an injury 
or Level A harassment.
    The use of soft-start procedures, zone clearance prior to startup, 
and shutdown zones is likely to decrease both the number of sea otters 
exposed to sounds above Level A harassment thresholds and the exposure 
time of any sea otters venturing into a Level A harassment zone. This 
reduces the likelihood of losses of hearing sensitivity that might 
impact the health, reproduction, or survival of affected animals. 
Despite the implementation of mitigation measures, it is anticipated 
that some sea otters will experience Level A harassment via exposure to 
underwater sounds above threshold criteria during impact and DTH pile-
driving activities. Due to sea otters' small body size and low profile 
in the water, as well as the relatively large size of the Level A 
harassment zone associated with these activities, we anticipate that 
sea otters will at times avoid detection before entering Level A 
harassment zones for those activities. We anticipate that PSOs will be 
able to reliably detect and prevent take by Level A harassment of sea 
otters up to 20 m away; conversely, we anticipate that at distances 
greater than 20 m, sea otters will at times avoid detection. Throughout 
the project, we estimate 70 instances of take by Level A harassment of 
7 sea otters.

Determinations and Findings

    Sea otters exposed to sound from the specified activities are 
likely to respond with temporary behavioral modification or 
displacement. The specified activities could temporarily interrupt the 
feeding, resting, and movement of sea otters. Because activities will 
occur during a limited amount of time and in a localized region, the 
impacts associated with the project are likewise temporary and 
localized. The anticipated effects are short-term behavioral reactions 
and displacement of sea otters near active operations.
    Sea otters that encounter the specified activity may exert more 
energy than they would otherwise due to temporary cessation of feeding, 
increased vigilance, and retreating from the project area. We expect 
that affected sea otters will tolerate this exertion without measurable 
effects on health or reproduction. Most of the anticipated takes will 
be due to short-term Level B

[[Page 37568]]

harassment in the form of TTS, startling reactions, or temporary 
displacement. While mitigation measures incorporated into TMC's request 
will reduce occurrences of Level A harassment to the extent 
practicable, a small number of takes by Level A harassment would be 
authorized for impact and DTH pile-driving activities, which have Level 
A harassment zone radii ranging in size from 57.9 to 256 m (190 to 840 
ft).
    With the adoption of the mitigation measures incorporated in TMC's 
request and required by this proposed IHA, anticipated take was 
reduced. Those mitigation measures are further described below.

Small Numbers

    To assess whether the authorized incidental taking would be limited 
to ``small numbers'' of marine mammals, the Service uses a proportional 
approach that considers whether the estimated number of marine mammals 
to be subjected to incidental take is small relative to the population 
size of the species or stock. Here, predicted levels of take were 
determined based on the estimated density of sea otters in the project 
area and ensonification zones developed using empirical evidence from 
similar geographic areas.
    We estimate TMC's specified activities in the specified geographic 
region will take no more than 544 takes of 37 sea otters by Level B 
harassment and 70 takes of 7 sea otters by Level A harassment during 
the 1-year period of this proposed IHA (see Sum of Take from All 
Sources). Take of 44 animals is 0.2 percent of the best available 
estimate of the current Southcentral Alaska stock size of 21,617 
animals (Esslinger et al. 2021) ((44 / 21,617) x 100 [ap] 0.2) and 
represents a ``small number'' of sea otters of that stock.

Negligible Impact

    We propose a finding that any incidental take by harassment 
resulting from the specified activities cannot be reasonably expected 
to, and is not reasonably likely to, adversely affect the sea otter 
through effects on annual rates of recruitment or survival and will, 
therefore, have no more than a negligible impact on the Southcentral 
Alaska stock of northern sea otters. In making this finding, we 
considered the best available scientific information, including the 
biological and behavioral characteristics of the species, the most 
recent information on species distribution and abundance within the 
area of the specified activities, the current and expected future 
status of the stock (including existing and foreseeable human and 
natural stressors), the potential sources of disturbance caused by the 
project, and the potential responses of marine mammals to this 
disturbance. In addition, we reviewed applicant-provided materials, 
information in our files and datasets, published reference materials, 
and species experts.
    Sea otters are likely to respond to planned activities with 
temporary behavioral modification or temporary displacement. These 
reactions are not anticipated to have consequences for the long-term 
health, reproduction, or survival of affected animals. Most animals 
will respond to disturbance by moving away from the source, which may 
cause temporary interruption of foraging, resting, or other natural 
behaviors. Affected animals are expected to resume normal behaviors 
soon after exposure with no lasting consequences. Each sea otter is 
estimated to be exposed to construction noise for between 4 and 129 
days per year, resulting in repeated exposures. However, injuries 
(i.e., Level A harassment or PTS) due to chronic sound exposure is 
estimated to occur at a longer time scale (Southall et al. 2019). The 
area that will experience noise greater than Level B thresholds due to 
pile driving is small (less than 0.18 km\2\), and an animal that may be 
disturbed could escape the noise by moving to nearby quiet areas. 
Further, sea otters spend over half of their time above the surface 
during the summer months (Esslinger et al. 2014), and likely no more 
than 70 percent of their time foraging during winter months (Gelatt et 
al. 2002), thus their ears will not be exposed to continuous noise, and 
the amount of time it may take for permanent injury is considerably 
longer than that of mammals primarily under water. Some animals may 
exhibit some of the stronger responses typical of Level B harassment, 
such as fleeing, interruption of feeding, or flushing from a haulout. 
These responses could have temporary biological impacts for affected 
individuals but are not anticipated to result in measurable changes in 
survival or reproduction.
    The total number of animals affected and severity of impact is not 
sufficient to change the current population dynamics at the stock 
scale. Although the specified activities may result in approximately 
614 incidental takes of 44 sea otters from the Southcentral Alaska 
stock, we do not expect this level of harassment to affect annual rates 
of recruitment or survival or result in adverse effects on the stock.
    Our proposed finding of negligible impact applies to incidental 
take associated with the specified activities as mitigated by the 
avoidance and minimization measures identified in TMC's mitigation and 
monitoring plan. These mitigation measures are designed to minimize 
interactions with and impacts to sea otters. These measures and the 
monitoring and reporting procedures are required for the validity of 
our finding and are a necessary component of the proposed IHA. For 
these reasons, we propose a finding that the specified project will 
have a negligible impact on the Southcentral Alaska stock of northern 
sea otters.

Least Practicable Adverse Impacts

    We find that the mitigation measures required by this proposed IHA 
will effect the least practicable adverse impacts on the stocks from 
any incidental take likely to occur in association with the specified 
activities. In making this finding, we considered the biological 
characteristics of sea otters, the nature of the specified activities, 
the potential effects of the activities on sea otters, the documented 
impacts of similar activities on sea otters, and alternative mitigation 
measures.
    In evaluating what mitigation measures are appropriate to ensure 
the least practicable adverse impact on species or stocks and their 
habitat, as well as subsistence uses, we considered the manner and 
degree to which the successful implementation of the measures are 
expected to achieve this goal. We considered the nature of the 
potential adverse impact being mitigated (likelihood, scope, range), 
the likelihood that the measures will be effective if implemented, and 
the likelihood of effective implementation. We also considered the 
practicability of the measures for applicant implementation (e.g., 
cost, impact on operations). We assessed whether any additional, 
practicable requirements could be implemented to further reduce 
effects, but did not identify any.
    To reduce the potential for disturbance from acoustic stimuli 
associated with the activities, TMC will implement mitigation measures, 
including the following:
     Using the smallest diameter piles practicable while 
minimizing the overall number of piles;
     Using a project design that does not include dredging or 
blasting;
     Using pile caps made of high-density polyethylene or 
ultra-high-molecular-weight polyethylene softening materials during 
impact pile driving;
     Minimizing the use of the impact hammer to the extent 
possible by using

[[Page 37569]]

a vibratory hammer to advance piles as deeply as possible;
     Employing an 18-m (60-ft) deep bubble curtain during all 
impact pile driving as well as during all pile-driving activities in 
less than 18 m (60 ft) of water to reduce noise impacts;
     Not reducing sound source levels due to the planned use of 
pile caps and a bubble curtain to calculate the most conservative 
harassment and shutdown zones;
     Development of a marine mammal monitoring and mitigation 
plan;
     Establishment of shutdown and monitoring zones;
     Visual mitigation monitoring by designated protected 
species observers (PSO);
     Site clearance before startup;
     Soft-start procedures; and
     Shutdown procedures.
    The Service has not identified any additional (i.e., not already 
incorporated into TMC's request) mitigation or monitoring measures that 
are practicable and would further reduce potential impacts to sea 
otters and their habitat.

Impact on Subsistence Use

    The project will not preclude access to harvest areas or interfere 
with the availability of sea otters for harvest. Additionally, the 
planned cruise ship berth and associated facilities are located within 
the City of Whittier, where firearm use is prohibited. We therefore 
propose a finding that TMC's anticipated harassment will not have an 
unmitigable adverse impact on the availability of any stock of northern 
sea otters for taking for subsistence uses. In making this finding, we 
considered the timing and location of the planned activities and the 
timing and location of subsistence harvest activities in the project 
area.

Monitoring and Reporting

    The purposes of the monitoring requirements are to document and 
provide data for assessing the effects of specified activities on sea 
otters; to ensure that take is consistent with that anticipated in the 
small numbers, negligible impact, and subsistence use analyses; and to 
detect any unanticipated effects on the species. Monitoring plans 
include steps to document when and how sea otters are encountered and 
their numbers and behaviors during these encounters. This information 
allows the Service to measure encounter rates and trends and to 
estimate numbers of animals potentially affected. To the extent 
possible, monitors will record group size, age, sex, reaction, duration 
of interaction, and closest approach to the project activity.
    As proposed, monitoring activities will be summarized and reported 
in formal reports. TMC must submit monthly reports for all months 
during which noise-generating work takes place as well as a final 
monitoring report that must submitted no later than 90 days after the 
expiration of the IHA. We will require an approved plan for monitoring 
and reporting the effects of pile driving and marine construction 
activities on sea otters prior to issuance of an IHA. We will require 
approval of the monitoring results for continued operation under the 
IHA.
    We find that these proposed monitoring and reporting requirements 
to evaluate the potential impacts of planned activities will ensure 
that the effects of the activities remain consistent with the rest of 
the findings.

Required Determinations

National Environmental Policy Act (NEPA)

    We have prepared a draft environmental assessment in accordance 
with the NEPA (42 U.S.C. 4321 et seq.). We have preliminarily concluded 
that authorizing the nonlethal, incidental, unintentional take by Level 
B harassment of up to 544 takes of 37 sea otters and by Level A 
harassment of up to 70 takes of 7 sea otters from the Southcentral 
Alaska stock in the specified geographic region during the specified 
activities during the regulatory period would not significantly affect 
the quality of the human environment and, thus, preparation of an 
environmental impact statement for this proposed IHA is not required by 
section 102(2) of NEPA or its implementing regulations. We are 
accepting comments on the draft environmental assessment as specified 
above in DATES and ADDRESSES.

Endangered Species Act (ESA)

    Under the ESA (16 U.S.C. 1536(a)(2)), all Federal agencies are 
required to ensure the actions they authorize are not likely to 
jeopardize the continued existence of any threatened or endangered 
species or result in destruction or adverse modification of critical 
habitat. The specified activities would occur entirely within the range 
of the Southcentral Alaska stock of northern sea otters, which is not 
listed as threatened or endangered under the ESA. The authorization of 
incidental take of sea otters and the measures included in the proposed 
IHA would not affect other listed species or designated critical 
habitat.

Government-to-Government Consultation

    It is our responsibility to communicate and work directly on a 
Government-to-Government basis with federally recognized Alaska Native 
Tribes in developing programs for healthy ecosystems. We seek their 
full and meaningful participation in evaluating and addressing 
conservation concerns for protected species. It is our goal to remain 
sensitive to Alaska Native culture, and to make information available 
to Alaska Natives. Our efforts are guided by the following policies and 
directives:
    (1) The Native American Policy of the Service (January 20, 2016);
    (2) The Alaska Native Relations Policy (currently in draft form);
    (3) Executive Order 13175 (January 9, 2000);
    (4) Department of the Interior Secretary's Orders 3206 (June 5, 
1997), 3225 (January 19, 2001), 3317 (December 1, 2011), and 3342 
(October 21, 2016);
    (5) The Alaska Government-to-Government Policy (a departmental 
memorandum issued January 18, 2001); and
    (6) The Department of the Interior's policies on consultation with 
Alaska Native Tribes and organizations.
    We have evaluated possible effects of the specified activities on 
federally recognized Alaska Native Tribes and organizations. The 
Service has determined that, due to this project's locations and 
activities, the Tribal organizations and communities near Whittier, 
Alaska, as well as relevant Alaska Native Claims Settlement Act 
corporations, will not be impacted by this project. Regardless, we will 
be reaching out to them to inform them of the availability of this 
proposed IHA and offer them the opportunity to consult.
    We invite continued discussion, either about the project and its 
impacts or about our coordination and information exchange throughout 
the IHA process.

Proposed Authorization

    We propose to authorize the nonlethal, incidental take by Level A 
and Level B harassment of 614 takes of 44 sea otters from the 
Southcentral Alaska stock. Authorized take may be caused by pile 
driving and marine construction activities conducted by Turnagain 
Marine Construction (TMC) in Whittier, Alaska, over the course of a 
year from the date of issuance of the IHA. We do not anticipate or 
authorize any lethal take to sea otters resulting from these 
activities.

[[Page 37570]]

A. General Conditions for the Incidental Harassment Authorization (IHA)

    (1) Activities must be conducted in the manner described in the 
December 22, 2022, revised request from TMC for an IHA and in 
accordance with all applicable conditions and mitigation measures. The 
taking of sea otters whenever the required conditions, mitigation, 
monitoring, and reporting measures are not fully implemented as 
required by the IHA is prohibited. Failure to follow the measures 
specified both in the revised request and within this proposed 
authorization may result in the modification, suspension, or revocation 
of the IHA.
    (2) If project activities cause unauthorized take (i.e., greater 
than 614 takes of 44 of the Southcentral Alaska stock of northern sea 
otters, a form of take other than Level A or Level B harassment, or 
take of one or more sea otters through methods not described in the 
IHA), TMC must take the following actions:
    (i) cease its activities immediately (or reduce activities to the 
minimum level necessary to maintain safety);
    (ii) report the details of the incident to the Service within 48 
hours; and
    (iii) suspend further activities until the Service has reviewed the 
circumstances and determined whether additional mitigation measures are 
necessary to avoid further unauthorized taking.
    (3) All operations managers, vehicle operators, and machine 
operators must receive a copy of this IHA and maintain access to it for 
reference at all times during project work. These personnel must 
understand, be fully aware of, and be capable of implementing the 
conditions of the IHA at all times during project work.
    (4) This IHA will apply to activities associated with the specified 
project as described in this document and in TMC's revised request. 
Changes to the specified project without prior authorization may 
invalidate the IHA.
    (5) TMC's revised request is approved and fully incorporated into 
this IHA unless exceptions are specifically noted herein. The request 
includes:
    (i) TMC's original request for an IHA, dated September 16, 2022;
    (ii) Revised applications, dated November 11, November 23, December 
1, and December 22, 2022;
    (iii) Marine Mammal Mitigation and Monitoring Plan;
    (iv) Google Earth package;
    (v) Bubble curtain schematics; and
    (vi) Pile coordinates.
    (6) Operators will allow Service personnel or the Service's 
designated representative to visit project worksites to monitor for 
impacts to sea otters and subsistence uses of sea otters at any time 
throughout project activities so long as it is safe to do so. 
``Operators'' are all personnel operating under TMC's authority, 
including all contractors and subcontractors.

B. Avoidance and Minimization

    (7) Construction activities must be conducted using equipment that 
generates the lowest practicable levels of underwater sound within the 
range of frequencies audible to sea otters.
    (8) During all pile-installation activities, regardless of 
predicted sound levels, a physical interaction shutdown zone of 20 m 
(66 ft) must be enforced. If a sea otter enters the shutdown zone, in-
water activities must be delayed until either the animal has been 
visually observed outside the shutdown zone, or 15 minutes have elapsed 
since the last observation time without redetection of the animal.
    (9) If the impact driver has been idled for more than 30 minutes, 
an initial set of three strikes from the impact driver must be 
delivered at reduced energy, followed by a 1-minute waiting period, 
before full-powered proofing strikes.
    (10) In-water activity must be conducted in daylight. If 
environmental conditions prevent visual detection of sea otters within 
the shutdown zone, in-water activities must be stopped until visibility 
is regained.
    (11) All in-water work along the shoreline must be conducted during 
low tide when the site is dewatered to the maximum extent practicable.

C. Mitigation Measures for Vessel Operations

    Vessel operators must take every precaution to avoid harassment of 
sea otters when a vessel is operating near these animals. The applicant 
must carry out the following measures:
    (12) Vessels must remain at least 500 m (0.3 mi) from rafts of sea 
otters unless safety is a factor. Vessels must reduce speed and 
maintain a distance of 100 m (328 ft) from all sea otters unless safety 
is a factor.
    (13) Vessels must not be operated in such a way as to separate 
members of a group of sea otters from other members of the group and 
must avoid alongshore travel in shallow water (<20 m) whenever 
practicable.
    (14) When weather conditions require, such as when visibility 
drops, vessels must adjust speed accordingly to avoid the likelihood of 
injury to sea otters.
    (15) Vessel operators must be provided written guidance for 
avoiding collisions and minimizing disturbances to sea otters. Guidance 
will include measures identified in paragraphs (C)(12) through (15) of 
this section.

D. Monitoring

    (16) Operators shall work with protected species observers (PSOs) 
to apply mitigation measures and shall recognize the authority of PSOs 
up to and including stopping work, except where doing so poses a 
significant safety risk to personnel.
    (17) Duties of the PSOs include watching for and identifying sea 
otters, recording observation details, documenting presence in any 
applicable monitoring zone, identifying and documenting potential 
harassment, and working with operators to implement all appropriate 
mitigation measures.
    (18) A sufficient number of PSOs will be available to meet the 
following criteria: 100 percent monitoring of exclusion zones during 
all daytime periods of underwater noise-generating work; a maximum of 4 
consecutive hours on watch per PSO; a maximum of approximately 12 hours 
on watch per day per PSO.
    (19) All PSOs will complete a training course designed to 
familiarize individuals with monitoring and data collection procedures. 
A field crew leader with prior experience as a sea otter observer will 
supervise the PSO team. Initially, new or inexperienced PSOs will be 
paired with experienced PSOs so that the quality of marine mammal 
observations and data recording is kept consistent. Resumes for 
candidate PSOs will be made available for the Service to review.
    (20) Observers will be provided with reticule binoculars (7x50 or 
better), big-eye binoculars or spotting scopes (30x), inclinometers, 
and range finders. Field guides, instructional handbooks, maps, and a 
contact list will also be made available.
    (21) Observers will collect data using the following procedures:
    (i) All data will be recorded onto a field form or database.
    (ii) Global positioning system data, sea state, wind force, and 
weather will be collected at the beginning and end of a monitoring 
period, every hour in between, at the change of an observer, and upon 
sightings of sea otters.
    (iii) Observation records of sea otters will include date; time; 
the observer's locations, heading, and speed (if moving); weather; 
visibility; number of animals; group size and composition (adults/
juveniles); and the location of the animals (or distance and direction 
from the observer).

[[Page 37571]]

    (iv) Observation records will also include initial behaviors of the 
sea otters, descriptions of project activities and underwater sound 
levels being generated, the position of sea otters relative to 
applicable monitoring and mitigation zones, any mitigation measures 
applied, and any apparent reactions to the project activities before 
and after mitigation.
    (v) For all sea otters in or near a mitigation zone, observers will 
record the distance from the sound source to the sea otter upon initial 
observation, the duration of the encounter, and the distance at last 
observation in order to monitor cumulative sound exposures.
    (vi) Observers will note any instances of animals lingering close 
to or traveling with vessels for prolonged periods of time.
    (22) Monitoring of the shutdown zone must continue for 30 minutes 
following completion of pile installation.

E. Measures To Reduce Impacts to Subsistence Users

    (23) Prior to conducting the work, TMC will take the following 
steps to reduce potential effects on subsistence harvest of sea otters:
    (i) Avoid work in areas of known sea otter subsistence harvest;
    (ii) Discuss the planned activities with subsistence stakeholders 
including Southcentral Alaska villages and traditional councils;
    (iii) Identify and work to resolve concerns of stakeholders 
regarding the project's effects on subsistence hunting of sea otters; 
and
    (iv) If any concerns remain, develop a POC in consultation with the 
Service and subsistence stakeholders to address these concerns.

F. Reporting Requirements

    (24) TMC must notify the Service at least 48 hours prior to 
commencement of activities.
    (25) Monthly reports will be submitted to the Service's Marine 
Mammal Management office (MMM) for all months during which noise-
generating work takes place. The monthly report will contain and 
summarize the following information: dates, times, weather, and sea 
conditions (including the Beaufort Scale sea state and wind force 
conditions) when sea otters were sighted; the number, location, 
distance from the sound source, and behavior of the sea otters; the 
associated project activities; and a description of the implementation 
and effectiveness of mitigation measures with a discussion of any 
specific behaviors the sea otters exhibited in response to mitigation.
    (26) A final report will be submitted to the Service's MMM within 
90 days after completion of work or expiration of the IHA. The report 
will include:
    (i) A summary of monitoring efforts (hours of monitoring, 
activities monitored, number of PSOs, and, if requested by the Service, 
the daily monitoring logs).
    (ii) A description of all project activities, along with any 
additional work yet to be done. Factors influencing visibility and 
detectability of marine mammals (e.g., sea state, number of observers, 
and fog and glare) will be discussed.
    (iii) A description of the factors affecting the presence and 
distribution of sea otters (e.g., weather, sea state, and project 
activities). An estimate will be included of the number of sea otters 
exposed to noise at received levels greater than or equal to 160 dB 
(based on visual observation).
    (iv) A description of changes in sea otter behavior resulting from 
project activities and any specific behaviors of interest.
    (v) A discussion of the mitigation measures implemented during 
project activities and their observed effectiveness for minimizing 
impacts to sea otters. Sea otter observation records will be provided 
to the Service in the form of electronic database or spreadsheet files.
    (27) Injured, dead, or distressed sea otters that are not 
associated with project activities (e.g., animals known to be from 
outside the project area, previously wounded animals, or carcasses with 
moderate to advanced decomposition or scavenger damage) must be 
reported to the Service within 24 hours of the discovery to either the 
Service's MMM (1-800-362-5148, business hours); or the Alaska SeaLife 
Center in Seward (1-888-774-7325, 24 hours a day); or both. 
Photographs, video, location information, or any other available 
documentation must be provided to the Service.
    (28) All reports shall be submitted by email to 
[email protected].
    (29) TMC must notify the Service upon project completion or end of 
the work season.

Request for Public Comments

    If you wish to comment on this proposed authorization, the 
associated draft environmental assessment, or both documents, you may 
submit your comments by either of the methods described in ADDRESSES. 
Please identify if you are commenting on the proposed authorization, 
draft environmental assessment, or both, make your comments as specific 
as possible, confine them to issues pertinent to the proposed 
authorization, and explain the reason for any changes you recommend. 
Where possible, your comments should reference the specific section or 
paragraph that you are addressing. The Service will consider all 
comments that are received before the close of the comment period (see 
DATES). The Service does not anticipate extending the public comment 
period beyond the 30 days required under section 101(a)(5)(D)(iii) of 
the MMPA.
    Comments, including names and street addresses of respondents, will 
become part of the administrative record for this proposal. Before 
including your address, telephone number, email address, or other 
personal identifying information in your comment, be advised that your 
entire comment, including your personal identifying information, may be 
made publicly available at any time. While you can ask us in your 
comments to withhold from public review your personal identifying 
information, we cannot guarantee that we will be able to do so.

Peter Fasbender,
Assistant Regional Director for Fisheries and Ecological Services, 
Alaska Region.
[FR Doc. 2023-12233 Filed 6-7-23; 8:45 am]
BILLING CODE 4333-15-P

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