Clean Water Act Methods Update Rule for the Analysis of Effluent, 56590-56624 [2019-22437]
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Federal Register / Vol. 84, No. 204 / Tuesday, October 22, 2019 / Proposed Rules
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identified by Docket ID No. EPA–HQ–
OW–2018–0826, by any of the following
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I.B ‘‘What Should I Consider as I
Prepare My Comments for the EPA’’
heading of the SUPPLEMENTARY
INFORMATION section of this document.
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ADDRESSES:
ENVIRONMENTAL PROTECTION
AGENCY
40 CFR Part 136
[EPA–HQ–OW–2018–0826; FRL–9995–22–
OW]
RIN 2040–AF84
Clean Water Act Methods Update Rule
for the Analysis of Effluent
Environmental Protection
Agency (EPA).
ACTION: Proposed rule.
AGENCY:
The Environmental Protection
Agency (EPA) is proposing changes to
its test procedures required to be used
by industries and municipalities when
analyzing the chemical, physical, and
biological properties of wastewater and
other environmental samples for
reporting under the EPA’s National
Pollutant Discharge Elimination System
(NPDES) permit program. The Clean
Water Act requires the EPA to
promulgate these test procedures
(analytical methods) for analysis of
pollutants. The EPA anticipates that
these proposed changes will provide
increased flexibility for the regulated
community in meeting monitoring
requirements while improving data
quality. In addition, this proposed
update to the CWA methods would
incorporate technological advances in
analytical technology. As such, the EPA
expects that there will be no negative
economic impacts resulting from these
proposed changes.
DATES: Comments on this proposed rule
must be received on or before December
23, 2019.
SUMMARY:
Business Information (CBI) or other
information whose disclosure is
restricted by statute. Certain other
material, such as copyrighted material,
will be publicly available only in hard
copy. Publicly available docket
materials are available either
electronically in www.regulations.gov or
in hard copy at the Water Docket in EPA
Docket Center, EPA/DC, EPA West
William J. Clinton Building, Room 3334,
1301 Constitution Avenue NW,
Washington, DC. The Public Reading
Room is open from 8:30 a.m. to 4:30
p.m., Monday through Friday, excluding
legal holidays. The telephone number
for the Public Reading Room is 202–
566–1744, and the telephone number for
the Water Docket is 202–566–2426.
FOR FURTHER INFORMATION CONTACT:
Meghan Hessenauer, Engineering and
Analysis Division (4303T), Office of
Water, Environmental Protection
Agency, 1200 Pennsylvania Avenue
NW, Washington, DC 20460–0001;
telephone: 202–566–1040; email:
Hessenauer.Meghan@epa.gov.
SUPPLEMENTARY INFORMATION:
Table of Contents
I. General Information
II. Overview
III. Statutory Authority
IV. Purpose and Summary of Proposed Rule
V. Statutory and Executive Order Reviews
I. General Information
A. Does this action apply to me?
Entities potentially affected by the
requirements of this proposed action
include:
Category
Examples of potentially affected entities
State, Territorial, and Indian Tribal Governments.
States, territories, and tribes authorized to administer the National Pollutant Discharge Elimination System (NPDES) permitting program; states, territories, and tribes providing certification under CWA section 401; state, territorial, and tribal-owned facilities that must conduct
monitoring to comply with NPDES permits.
Facilities that must conduct monitoring to comply with NPDES permits.
Publicly Owned Treatment Works (POTWs) or other municipality-owned facilities that must
conduct monitoring to comply with NPDES permits.
Industry ...............................................................
Municipalities ......................................................
This table is not exhaustive, but rather
provides a guide for readers regarding
entities likely to be affected by this
action. This table lists types of entities
that the EPA is now aware of that could
potentially be affected by this action.
Other types of entities not listed in the
table could also be affected. To
determine whether your facility is
affected by this action, you should
carefully examine the applicability
language at 40 CFR 122.1 (NPDES
purpose and scope), 40 CFR 136.1
(NPDES permits and CWA) and 40 CFR
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403.1 (pretreatment standards purpose
and applicability). If you have questions
regarding the applicability of this action
to a particular entity, consult the
appropriate person listed in the
preceding FOR FURTHER INFORMATION
CONTACT section.
B. What should I consider as I prepare
my comments for the EPA?
Submit your comments, identified by
Docket ID No. EPA–HQ–OW–2018–
0826, at https://www.regulations.gov
(preferred way of receiving comments),
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or the other means identified in the
section. Once submitted,
comments cannot be edited or removed
from the docket. The EPA may publish
any comment received to its public
docket. Do not submit electronically any
information you consider to be CBI or
other information whose disclosure is
restricted by statute. Do not submit CBI
to the EPA through www.regulations.gov
or email. Clearly mark the part or all of
the information that you claim to be
CBI. For CBI information in a disk that
you mail to the EPA, mark the outside
ADDRESSES
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of the disk as CBI and then identify
electronically within the disk the
specific information that is claimed as
CBI. In addition to one complete version
of the comment that includes
information claimed as CBI, a copy of
the comment that does not contain the
information claimed as CBI must be
submitted for inclusion in the public
docket. Information so marked will not
be disclosed except in accordance with
procedures for handling and protection
of CBI set forth in 40 CFR part 2.
Multimedia submissions (audio,
video, etc.) must be accompanied by a
written comment. The written comment
is considered the official comment and
should include discussion of all points
you wish to make. The EPA will
generally not consider comments or
comment contents located outside of the
primary submission (i.e., on the web,
cloud, or other file sharing system). For
additional submission means or
methods, the full EPA public comment
policy, information about CBI or
multimedia submissions, and general
guidance on making effective
comments, please visit https://
www.epa.gov/dockets/commenting-epadockets.
II. Overview
This preamble describes the reasons
for the proposed rule; the legal authority
for the proposed rule; a summary of the
proposed changes and clarifications;
and explanation of the abbreviations
and acronyms used in this document. In
addition, this preamble solicits
comment and data from the public.
Abbreviations and Acronyms Used in
the Preamble and Proposed Rule Text
2-CEVE: 2-Chloroethylvinyl ether
AA: Atomic Absorption
ADMI: American Dye Manufacturers Institute
ASTM: ASTM International 1
ATP: Alternate Test Procedure
BHI: Brain heart infusion
BOD5: 5-day Biochemical Oxygen Demand
CAS: Chemical Abstract Services
CATC: Cyanide Amenable to Chlorination
CCB: Continuing calibration blank
CCV: Continuing calibration verification
CFR: Code of Federal Regulations
COD: Chemical Oxygen Demand
CWA: Clean Water Act
EC-MUG: EC broth with 4methylumbelliferyl-b-D-glucuronide
EDTA: Ethylenediaminetetraacetic acid
ELAB: Environmental Laboratory Advisory
Board
EPA: Environmental Protection Agency
FLAA: Flame Atomic Absorption
Spectroscopy
GC: Gas Chromatography
1 Formerly
known as the American Society for
Testing and Materials (ASTM).
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GFAA: Graphite Furnace Atomic Absorption
Spectroscopy
ICP/AES: Inductively Coupled PlasmaAtomic Emission Spectroscopy
ICP/MS: Inductively Coupled Plasma-Mass
Spectrometry
ILI: Independent Laboratories Institute
IPR: Initial Precision and Recovery
LCS: Laboratory Control Sample
MDL: Method Detection Limit
MF: Membrane Filtration
MgCl2: Magnesium Chloride
MPN: Most Probable Number
MS/MSD: Matrix Spike/Matrix Spike
Duplicate
MS: Mass Spectrometry
NA-MUG: Nutrient Agar with 4methylumbelliferyl-b-D-glucuronide
NECi: A shortened name used by the Nitrate
Elimination Company, Inc.
NPDES: National Pollutant Discharge
Elimination System
NTTAA: National Technology Transfer and
Advancement Act
OPR: Ongoing Precision and Recovery
QC: Quality Control
STGFAA: Stabilized Temperature Graphite
Furnace Atomic Absorption Spectroscopy
TKN: Total Kjeldahl Nitrogen
TOC: Total Organic Carbon
USGS: United States Geological Survey
VCSB: Voluntary Consensus Standards Body
III. Statutory Authority
The EPA is proposing this regulation
under the authorities of sections 301(a),
304(h), and 501(a) of the CWA; 33
U.S.C. 1311(a), 1314(h), and 1361(a).
Section 301(a) of the CWA prohibits the
discharge of any pollutant into
navigable waters unless the discharge
complies with, among other provisions,
an NPDES permit issued under section
402 of the CWA. Section 304(h) of the
CWA requires the Administrator of the
EPA to ‘‘. . . promulgate guidelines
establishing test procedures for the
analysis of pollutants that shall include
the factors which must be provided in
any certification pursuant to [section
401 of the CWA] or permit application
pursuant to [section 402 of the CWA].’’
Section 501(a) of the CWA authorizes
the Administrator to ‘‘. . . prescribe
such regulations as are necessary to
carry out this function under [the
CWA].’’ The EPA generally has codified
its test procedure regulations (including
analysis and sampling requirements) for
CWA programs at 40 CFR part 136,
though some requirements are codified
in other parts (e.g., 40 CFR Chapter I,
Subchapters N and O).
IV. Purpose and Summary of Proposed
Rule
NPDES permits must include
conditions designed to ensure
compliance with the technology-based
and water quality-based requirements of
the CWA, including in many cases,
restrictions on the quantity of specific
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pollutants that can be discharged as
well as pollutant measurement and
reporting requirements. Often, entities
have a choice in deciding which
approved test procedure they will use
for a specific pollutant because the EPA
has approved the use of more than one
method.2
The procedures for the analysis of
pollutants required by CWA section
304(h) are a central element of the
NPDES permit program. Examples of
where these EPA-approved analytical
methods must be used include the
following: (1) Applications for NPDES
permits, (2) sampling or other reports
required under NPDES permits, (3)
other requests for quantitative or
qualitative effluent data under the
NPDES regulations, (4) State CWA 401
certifications and (5) sampling and
analysis required under the EPA’s
General Pretreatment Regulations for
Existing and New Sources of Pollution,
40 CFR 136.1 and 40 CFR
403.12(b)(5)(v).
Periodically, the EPA proposes to
update the approved methods in 40 CFR
part 136. In general, the changes
proposed in this action fall into the
following categories. The first is new or
revised methods published by the
VCSBs or the USGS that are similar to
methods previously adopted as EPAapproved methods in 40 CFR part 136.
The second category is methods the EPA
has reviewed under the Agency’s
national ATP program and preliminarily
concluded are appropriate for
nationwide use. Finally, the EPA is
proposing certain corrections or
amendments to the text and tables of 40
CFR part 136. The EPA is proposing
adoption of these revisions to improve
data quality, update methods to keep
current with technology advances, and
provide the regulated community with
greater flexibility. The following
paragraphs provide details on the
proposed revisions.
A. Changes to 40 CFR 136.3 To Include
New Versions of Previously Approved
EPA Methods
The EPA proposes to add the latest
version of EPA Method 1623 to Table
IH. The latest version of Method 1623
(labeled 1623.1) includes updated
acceptance criteria for IPR, OPR, and
MS/MSD, and clarifications and
revisions based on user questions and
feedback about Method 1623 over the
past 19 years.
2 NPDES permit regulations also specify that the
approved method needs to be sufficiently sensitive.
See 40 CFR 122.21.e.3.
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B. Methods Incorporated by Reference
Currently, hundreds of methods and
ATPs are incorporated by reference
within 40 CFR part 136. In most cases,
40 CFR part 136 contains multiple
approved methods for a single pollutant,
and regulated entities often have a
choice in selecting a method. The
proposed rule contains revisions to
VCSB methods that are currently
incorporated by reference. Two VCSBs
have made such revisions, Standard
Methods and ASTM. The proposed
VCSB methods are consistent with the
requirements of the National
Technology Transfer and Advancement
Act (NTTAA), under which federal
agencies use technical standards
developed or adopted by the VCSBs if
compliance would not be inconsistent
with applicable law or otherwise
impracticable (see Section V.I below).
The proposed VCSB methods are
available on their respective websites
(www.standardmethods.org/ and
www.astm.org) to everyone at a cost
determined by the VCSB, generally from
$40 to $80. Both organizations also offer
memberships or subscriptions that
allow unlimited access to their methods.
The cost of obtaining these methods is
not a significant financial burden for a
discharger or environmental laboratory,
making the methods reasonably
available. Finally, this proposal also
includes USGS methods and vendor
ATPs, all of which the EPA proposes to
incorporate by reference. The ATPs and
USGS methods are available free of
charge on their respective websites
(flowinjection.com, mn-net.com,
micrologylabs.com, and USGS.gov),
enabling the EPA to conclude that the
USGS methods and ATPs incorporated
by reference are reasonably available.
C. Changes to 40 CFR 136.3 To Include
New Versions of Approved Standard
Methods
The EPA is proposing to approve new
versions of Standard Methods methods
previously approved in 40 CFR part 136.
The newer versions provide
clarifications or make editorial
corrections. As was the case with the
previous methods update rule (82 FR
40836–40941, August 28, 2017), the
EPA generally proposes to approve and
include in 40 CFR part 136 only the
most recent version of a method
published by the Standard Methods
Committee. The EPA is proposing to list
only one version of the method with the
year of publication designated by the
last four digits in the method number
(e.g., Standard Methods Method 3111
B–2011). The date indicates the date of
the specific revision to the method. This
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allows use of a specific method in any
edition of the hard copy publication of
Standard Methods for the Examination
of Water & Wastewater (Standard
Methods) that includes a method with
the same method number and year of
publication.
The proposed revisions to Standard
Methods methods previously approved
in 40 CFR part 136 will not affect the
performance of the method. Below is a
list of the Standard Methods methods
the EPA is proposing to include in 40
CFR part 136. Each entry contains the
proposed Standard Methods number
and date, the parameter, and a brief
description of the analytical method.
The methods listed below are organized
according to the table at 40 CFR part 136
in which they appear.
The EPA proposes to make the
following changes to Tables IA and IH
at 40 CFR part 136:
1. Standard Methods Method 9221 (B,
E, F)–2014: Method 9221B–2014
Coliform (total); analyzes for total
coliforms in non-potable waters using
lauryl tryptose broth (LTB), all
presumptive growth LTB tubes are
confirmed in brilliant green lactose bile
broth (BGLB). Method 9221E–2014
Coliform (fecal); analyzes all
presumptive growth LTB tubes for fecal
coliform using EC broth. Method
9221F–2014 E. coli; analyzes all
presumptive growth LTB tubes for E.
coli using EC–MUG. The number of
positive tubes (BGLB, EC broth or EC–
MUG) is used to determine the most
probable number (MPN).
2. Standard Methods Method 9222 (B,
D, I)–2015: Method 9222B–2015
Coliform (total); analyzes for total
coliforms in non-potable waters by
filtration through a 0.45-mm membrane
filter and plated on mEndo or LES Endo
agar. Method 9222D–2015 Coliform
(fecal); analyzes for fecal coliforms in
non-potable waters by filtration through
a 0.45-mm membrane filter plated on
mFC medium. Method 9222 I–2015 E.
coli; membrane filtration (MF), analyzes
presumptive positive filters from
Method 9222B and 9222D using
nutrient agar plates with MUG (NA–
MUG) which are examined under a
longwave UV lamp.
3. Standard Methods Method 9223B–
2016, E. coli, multiple tube/multiple
well. This method analyzes non-potable
waters for E. coli using commercially
available enzyme substrate media that is
mixed with the sample and placed in
multiple tubes or multiple well trays,
incubated and examined under ambient
light for Coliform (total) and under a
longwave UV lamp for E. coli.
4. Standard Methods Method 9230 (B,
C)–2013: Method 9230B–2013 Fecal
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Streptococci; analyzes non-potable
waters for streptococci using azide
dextrose broth (ADB), Presumptive
positive ADB tubes are confirmed by
streaking onto bile esculin azide agar
(BEA). Method 9230C–2013
Enterococci; analyzes non-potable
waters by filtration through a 0.45-mm
membrane filter and plated on mE agar.
The EPA proposes to make the
following changes to Table IB at 40 CFR
part 136:
1. Standard Methods Methods:
Method 2540B–2015, total solids; a
sample aliquot is evaporated in a preweighed evaporating dish at 103–105
°C. Method 2540C–2015 filterable
residue (total dissolved solids); a sample
aliquot is filtered through a glass fiber
filter and the filtrate is evaporated on a
pre-weighed dish to constant weight at
180 °C. Method 2540D–2015 nonfilterable residue (total suspended
solids); a sample aliquot is filtered
through a pre-weighed glass fiber filter
which is then dried to constant weight
at 103–105 °C. Method 2540E–2015
volatile residue (fixed and volatile
solids); the residue obtained from the
determination of total (Method 2540B),
filterable (Method 2540C) or nonfilterable residue (Method 2540D) is
ignited at 550 °C in a muffle furnace.
Method 2540E–2015 settleable residue
(settleable solids); settleable matter is
measured with an Imhoff cone either
volumetrically or gravimetrically.
2. Standard Methods Method 4500–
CN¥ (B–G)–2016, cyanide: Cyanides are
measured after preliminary treatment of
samples to remove interferences (4500–
CN¥ B) and manual distillation with
magnesium chloride (MgCl2) (4500–
CN¥ C) followed by: Titration with
silver nitrate (4500–CN¥ D),
spectrophotometric measurement after
cyanide in the alkaline distillate is
converted to CNCl (4500–CN¥ E),
potentiometric measurement using an
ion selective electrode (4500–CN¥ F),
and cyanide amenable to chlorination
(CATC) in which a portion of the
sample is chlorinated at high pH and
cyanide levels in the chlorinated sample
are determined after manual distillation
followed by titrimetric or
spectrophotometric measurement.
Amenable cyanide is calculated by the
difference between the results for
cyanide in the unchlorinated sample
and the results for the chlorinated
sample (4500–CN¥ G).
3. Standard Methods Method 4500–
NO3¥ D–2016, nitrate (as nitrogen),
measured using an ion-selective
electrode (ISE) that develops a potential
across a thin, inert membrane holding in
place a water-immiscible liquid ion
exchanger.
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4. Standard Methods Method 4500–
NO3¥ (E, F, and H)–2016, nitrate-nitrite
(as nitrogen): Nitrate is reduced to
nitrite using a cadmium-copper column,
followed by diazotization to form a
colored azo dye, which is measured by
colorimetry either manually (4500
NO3¥ E) or automated (4500 NO3¥ F);
or by reduction of nitrate to nitrite using
hydrazine followed by automated
colorimetric measurement of nitrite after
diazotization (4500 NO3¥ H).
5. Standard Methods Method 4500–
NO3¥ (E and F)–2016, nitrite (as
nitrogen), colorimetric: Bypasses the
cadmium reduction step and measures
nitrite after diazotization either by
manual or automated colorimetric
analysis.
6. Standard Methods Method 4500–O
(B–F, and G)–2016, measurement of
oxygen (dissolved), using the Winkler
iodometric titration procedure with
modifications to eliminate or minimize
certain interferences if necessary based
on sample type (4500–O B through F),
or by use of polarographic or galvanic
membrane electrodes (4500–O G).
7. Standard Methods Method 5210 B–
2016, biochemical oxygen demand
(BOD5), dissolved oxygen depletion.
The BOD5 test is an indirect
measurement of organic matter; it
measures the change in DO
concentration caused by
microorganisms as they degrade organic
matter in a sample held in a stoppered
bottle incubated for 5 days in the dark
at 20 °C.
8. Standard Methods Method 5310 (B,
C)–2014, total organic carbon (TOC),
combustion, heated persulfate or UV
persulfate oxidation: Method 5310B–
2014, high-temperature combustion; a
sample aliquot is combusted,
transported in a carrier gas stream and
measured via a nondispersive infrared
analyzer, or titrated coulometrically
Method 5310C–2014, persulfate–
ultraviolet or heated-persulfate
oxidation method; persulfate oxidizes
organic carbon, the produced CO2 is
then purged and measured by either
nondispersive infrared (NDIR) analyzer,
be coulometrically titrated, or separated
from the liquid stream by a membrane
that specifically allows CO2 to pass into
high-purity water where the change in
the high-purity water’s conductivity
corresponds to the amount of CO2
passing the membrane.
The EPA is also proposing one
revision to a previously approved
Standard Methods method for which the
Standard Methods Committee has
adopted updates. This modification
includes minor procedural changes that
do not affect the performance of the
method.
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The EPA proposes to make the
following change to Table IA and Table
IH at 40 CFR part 136:
1. The EPA proposes that the MPN
method Standard Methods Method 9221
F.2–2014 be approved as an acceptable
method for detecting thermotolerant
coliforms and E. coli simultaneously.
This method analyzes Coliform (fecal)
and E. coli using EC broth with 4methylumbelliferyl-b-D-glucuronide
(EC–MUG) with inverted vials.
D. Changes to 40 CFR 136.3 To Include
New Standard Methods Methods Based
on Previously Approved Technologies
The EPA is proposing these changes
based on the National Technology
Transfer and Advancement Act of 1995
(NTTAA), Public Law 104–113, which
states that federal agencies and
departments shall use technical
standards developed or adopted by the
VCSBs if compliance would not be
inconsistent with applicable law or
otherwise impracticable. These methods
submitted by the Standard Methods
Committee are consistent with other
methods already approved at 40 CFR
part 136.
1. The EPA proposes to add Standard
Methods Method 4500–CN¥ N–2016 to
Table IB for Cyanide, total. Cyanide is
measured after preliminary treatment of
samples and manual distillation with
magnesium chloride (MgCl2) followed
by automated spectrophotometric
measurement after conversion to CNCl.
This method is similar to the currently
approved EPA Method 335.4, USGS
Method I–4302–85, and Lachat Method
10–204–00–1–X, and uses semiautomated spectrophotometric
measurement of cyanide.
2. The EPA proposes to add Standard
Methods Method 4500–NO3¥ I–2016 to
Table IB for combined nitrate-nitrite,
nitrite (bypass the reduction column)
and nitrate by subtraction. Nitrate is
reduced to nitrite using a cadmiumcopper column followed by
diazotization to form an azo dye which
is measured by colorimetry. The
cadmium reduction column may be bypassed for measurement of nitrite only.
The value obtained for nitrite may be
subtracted from the value obtained for
combined nitrate-nitrite to calculate the
concentration of nitrate. This method is
similar to the currently approved EPA
Method 353.2, Standard Methods
Method 4500–NO3¥ F–2011, ASTM
Method D3867–04 (A), and USGS
Method I–2545–90, and uses automated
cadmium reduction and
spectrophotometric measurement of
nitrite.
3. The EPA proposes to add Standard
Methods Method 4500–NO3¥ J–2018 to
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Table IB for measurement of combined
nitrate-nitrite, for measurement of
nitrite when bypassing the enzymatic
reduction step, and for measurement of
nitrate by subtraction. Nitrate is reduced
to nitrite by an enzymatic reaction. The
nitrite is diazotized to yield an azo dye
which is measured colorimetrically. The
enzyme reduction step may be bypassed for measurement of nitrite
singly. The value obtained for nitrite
may be subtracted from the value
obtained for combined nitrate-nitrite to
calculate the concentration of nitrate.
This method is similar to the currently
approved NECi Method N07–0003,
USGS Method I–2547–11, and USGS
Method I–2548–11.
4. The EPA proposes to add Standard
Methods Method 4500–O H–2016 to
Table IB for dissolved oxygen. This
method uses a luminescent-based sensor
for measurement of dissolved oxygen.
The method is similar to the currently
approved Hach Method 10360, In-Situ
Method 1002–8–2009, and ASTM
Method D888–09 (C).
E. Changes to 40 CFR 136.3 To Include
New Versions of Approved ASTM
Methods
The EPA is proposing to approve new
versions of ASTM methods previously
approved in 40 CFR part 136 for the
same reasons outlined in the first
paragraph of Section IV.C above. These
changes to currently approved ASTM
methods in 40 CFR part 136 include
minor clarifications and editorial
changes, and in some instances, minor
procedural changes. None of these
proposed changes will affect the
performance of the method. The
following describes the changes to
current ASTM methods that the EPA
proposes to include in 40 CFR part 136.
Each entry contains (in the following
order): Proposed ASTM method number
(the last two digits in the method
number represent the year ASTM
published), the parameter, a brief
description of the analytical technique,
and a brief description of any
procedural changes in this revision from
the last approved version of the method.
The methods listed below are organized
according to the table at 40 CFR part 136
in which they appear.
The EPA proposes the following
changes to Table IB at 40 CFR part 136:
1. ASTM Method D511–14 (A, B),
calcium and magnesium, titrimetric,
(EDTA), AA direct aspiration: Method
D511–14 A, titrimetric; the pH of the
sample is adjusted to 10 (for calcium),
then to 12–13 (for magnesium) and
titrated with ethylenediamine
tetraacetic acid (EDTA) to form
complexes with calcium and
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magnesium ions which react with an
indicator to form a colored product. The
volume of titrant used to affect the color
change is proportional to the
concentrations of calcium and
magnesium in the sample. Method
D511–14 B, AA direct aspiration; the
sample is acidified and analyzed by
atomic absorption. The concentrations
of calcium and magnesium in the
samples are proportional to the amount
of light absorbed during the analysis,
and are determined in comparison to a
standard curve.
This version adds specifications for
filter paper.
2. ASTM Method D512–12 chloride
ion (A, B), titrimetric (mercuric nitrate),
titration (silver nitrate): Method D512–
12A, titrimetric mercuric nitrate; the
sample is acidified and titrated with
mercuric nitrate in the presence of a
diphenylcarbazonebromophenol blue
indicator. Method D512–12B, titrimetric
silver nitrate; sample pH is adjusted to
phenolphthalein endpoint and titrated
with silver nitrate in the presence of
potassium chromate. The volume of
titrant used to affect the color change in
either method is proportional to the
concentration of chloride in the sample.
This version corrects one term in the
calculation of the chloride calculation.
3. ASTM Method D516–16, sulfate
ion, turbidimetric. In this method,
sulfate ions are converted to barium
sulfate to form a suspension. The
turbidity of the suspension is measured
with a nephelometer,
spectrophotometer, or photoelectric
colorimeter, and compared to a standard
curve to determine the sulfate
concentration in the sample. This
version adds specifications for filter
paper.
4. ASTM Method D858–17 (A–C),
manganese, atomic absorption (AA)
direct aspiration, AA furnace. The
sample is acid digested and analyzed by
direct aspiration atomic absorption or
graphite furnace atomic absorption. The
concentration of manganese in the
sample is proportional to the amount of
light absorbed and is determined in
comparison to a standard curve. There
are no procedural changes.
5. ASTM Method D859–16, silica,
colorimetric, manual. In this method,
soluble silica in the sample is reacted
with molybdate then reduced to form a
blue complex in solution. The intensity
of the blue complex is determined with
a spectrophotometer or filter photometer
and the concentration of silica is
determined by comparison with a
standard curve. There are no procedural
changes.
6. ASTM Method D888–12 (A–C)
dissolved oxygen, Winkler, electrode,
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luminescent-based sensor: Method
D888–12A measures dissolved oxygen
using the Winkler iodometric titration
procedure. The volume of titrant used is
proportional to the concentration of
dissolved oxygen in the sample. Method
D888–12B measures dissolved oxygen
in the sample with an electrochemical
probe that produces an electrical
potential which is logarithmically
proportional to the concentration of
dissolved oxygen in the sample. Method
D888–12C measures dissolved oxygen
with a luminescence-based sensor probe
that employs frequency domain
lifetime-based luminescence quenching
and signal processing. This version adds
information on a two-point calibration
and updated performance information
from an interlaboratory study to D888–
12C.
7. ASTM Method D1067–16, acidity
or alkalinity, electrometric endpoint or
phenolphthalein endpoint;
electrometric or colorimetric titration to
pH 4.5, manual. The acidity or
alkalinity of the sample is determined
by titration to a specific pH endpoint
which is determined by colorimetry or
with a pH electrode. The acidity or
alkalinity is proportional to the volume
of titrant required to affect the pH
change. There are no procedural
changes.
8. ASTM Method D1068–15 (A–C),
iron, AA direct aspiration; AA furnace;
colorimetric (Phenanthroline): The
sample is acid digested and analyzed by
either direct aspiration atomic
absorption, graphite furnace atomic
absorption, or colorimetry. The
concentration of iron in the sample is
proportional to the amount of light
absorbed and is determined in
comparison to a standard curve. This
version adds specifications for filter
paper.
9. ASTM Method D1126–17,
hardness, titrimetric (EDTA). The pH of
the sample is adjusted and an indicator
is added forming a red color. The
mixture is titrated until the color
changes from red to blue. The volume
of titrant used to affect the color change
is proportional to the hardness in the
sample. There are no procedural
changes.
10. ASTM Method D1179–16 (A, B);
fluoride ion, manual distillation,
electrode, manual: Method D1179A,
manual distillation; the sample is
distilled as hydrofluorosilic acid and
determined by ion-selective electrode.
Method D1179B, electrode; the fluoride
ion is determined potentiometrically
with an ion-selective electrode in
conjunction without sample distillation.
There are no procedural changes.
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11. ASTM Method D1246–16,
bromide ion, electrode. The bromide in
the sample is determined
potentiometrically with an ion-selective
electrode, either through comparison to
a standard curve or through a direct
readout on the instrument. There are no
procedural changes.
12. ASTM Method D1252–06 (A, B)
(Reapproved 2012), chemical oxygen
demand, titrimetric,
spectrophotometric. This is the 2012
reapproval of the 2006 ASTM method:
Method D1252–06A, titrimetric;
measures the loss of the hexavalent
dichromate ion by reflux digestion
followed by titration. The chemical
oxygen demand in the sample is
determined by comparison to a standard
curve. Method D1252–06B,
spectrophotometric; uses a
spectrophotometer to measure the loss
of the hexavalent dichromate ion at 420
nm or the increase in the trivalent
chromium ion at 600 nm, after closed
digestion and determines the chemical
oxygen demand by comparison to a
standard curve. There are no procedural
changes.
13. ASTM Method D1253–14, residual
chlorine, amperometric direct. The
concentration of chlorine in the sample
is determined by titration with
phenylarsine oxide, using an
amperometric probe that responds to
chlorine to determine when the titration
is complete. The chlorine concentration
in the sample is proportional to the
volume of titrant used. There are no
procedural changes.
14. ASTM Method D1426–15 (A, B),
ammonia nitrogen, Nesslerization,
electrode: Method D1426A,
Nesslerization; an aliquot is Nesslerized
and the ammonia content determined
colormetrically. Method D1426B,
electrode; ammonia is potentiometric
determined using a gas-permeable ionselective electrode, either through
comparison to a standard curve or
through a direct readout on the
instrument using. A lengthy section of
QC requirements was added to the
Nesslerization procedure (D1426A) that
parallels the QC discussion that was
already in the B procedure. Both
procedures added information on use of
commercially prepared standards and
filter paper.
15. ASTM Method D1687–17 (A–C),
chromium (total) and dissolved
hexavalent chromium, colorimetric
(diphenyl–carbazide); AA direct
aspiration; AA furnace: Method D1687–
17A, chromium (dissolved); measures
dissolved hexavalent chromium by
reacting it with diphenylcarbohydrazide to produce a reddishpurple color that is measured with a
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spectrophotometer or filter photometer.
The concentration in the sample is
proportional to the intensity of the
color. Method D1687–17B, chromium
(total); the sample is acid digested and
analyzed by direct aspiration atomic
absorption. Method D1687–17C,
chromium (total); the sample is acid
digested and analyzed by graphite
furnace atomic absorption. The
concentration of total chromium in the
sample is proportional to the amount of
light absorbed during the analysis and is
determined in comparison to a standard
curve. The changes mirror those for the
other metals methods. The QC
frequencies for method blank,
continuing calibration verification
(CCV), continuing calibration blank
(CCB), matrix spike, and duplicate
analyses are now based on a laboratorydefined batch of up to 20 samples.
16. ASTM Method D1688–17 (A–C),
copper, AA direct aspiration, AA
furnace. The sample is acid digested
and analyzed by direct aspiration
atomic absorption (D1688–17A and B)
or graphite furnace atomic absorption
(D1688–17B). The concentration of
copper in the sample is proportional to
the amount of light absorbed and is
determined in comparison to a standard
curve. The changes mirror those for the
other metals methods. The proposed
changes also clarify the requirements for
a multi-point calibration by discussing
it in the calibration section as well as
the QC section of all three procedures.
The QC frequencies for method blank,
CCV, CCB, matrix spike, and duplicate
analyses are now based on a laboratorydefined batch of up to 20 samples.
17. ASTM Method D1691–17 (A, B),
zinc, AA direct aspiration. Method
D1691–17A; the sample is acid digested
and analyzed by direct aspiration
atomic absorption. Method D1691–17B;
the sample is processed by chelationextraction and analyzed by atomic
absorption. The concentration of zinc in
the sample is proportional to the
amount of light absorbed and is
determined in comparison to a standard
curve. The changes mirror those for the
other metals methods. The QC
frequencies for method blank, CCV,
CCB, matrix spike, and duplicate
analyses are now based on a laboratorydefined batch of up to 20 samples.
18. ASTM Method D1783–01 (A, B)
(Reapproved 2012), phenols, manual
distillation followed by manual
colorimetric (4AAP). The sample is
distilled, the distillate pH is adjusted to
10.0, and reacted with 4aminoantipyrine to form a colored
product. In Method D1783–01A, the
colored product is extracted from the
sample with chloroform and measured
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with a photometer at 460 nm. In Method
D1783–01B, the colored product is
measured without extraction, using a
photometer at 510 nm. The
concentration of phenolics is
determined in comparison to a standard
curve. There are no procedural changes.
19. ASTM Method D1886–14 (A–C),
nickel AA direct aspiration, chelation
extraction AA and AA furnace. Method
D1886–14A, the sample is acid digested
and analyzed by direct aspiration
atomic absorption. Method D1886–14B,
the sample is acid digested and the
nickel chelated and extracted. The
extract is analyzed by direct aspiration
atomic absorption. Method D1886–14C,
the sample is acid digested and
analyzed by graphite furnace atomic
absorption. The concentration of nickel
in the sample is proportional to the
amount of light absorbed during the
analysis and is determined in
comparison to a standard curve. The
changes mirror those for the other
metals methods. The QC frequencies for
method blank, CCV, CCB, matrix spike,
and duplicate analyses are now based
on a laboratory-defined batch of up to
20 samples.
20. ASTM Method D2036–09 (A, B)
(Reapproved 2015), A, total cyanide,
manual distillation followed by gas
diffusion amperometry, titrimetric,
spectrophotometric, ion
chromatography, ion selective electrode,
B, available (amenable) cyanide, manual
distillation followed by titrimetric or
spectrophotometric. The cyanide in the
sample is distilled and trapped in a
sodium hydroxide solution. Method
D2036–09A, the cyanide is treated with
strong acid and a catalyst during
distillation and measured by titration,
gas diffusion amperometry,
spectrophotometry, ion-selective
electrode, ion chromatography, or flow
injection analysis. Method D2036–09B,
cyanide amenable to chlorination is
determined by comparing the results for
one sample aliquot analyzed for total
cyanide and a second aliquot that is
treated with calcium hypochlorite prior
to analysis by Method D2036–09A.
There are no procedural changes.
21. ASTM Method D2972–15 (A–C),
arsenic, colorimetric, AA gaseous
hydride, AA furnace. The sample is
digested with nitric and sulfuric acids.
Method D2972–15A, arsenic is trapped
in a solution of silver
diethyldithiocarbamate in pyridine
which produces a red-colored product
that is analyzed photometrically by
comparison to a standard curve. Method
D2972–15B, arsenic in the digested
sample is determined by hydride
generation atomic absorption. Method
D2972–15C, arsenic in the digested
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sample is determined by graphite
furnace atomic absorption. The changes
mirror those for the other metals
methods. The QC frequencies for
method blank, CCV, CCB, matrix spike,
and duplicate analyses are now based
on a laboratory-defined batch of up to
20 samples.
22. ASTM Method D3223–17, total
mercury, cold vapor, manual. Mercury
in the sample is converted to the
mercuric ion which is reduced to
elemental mercury, purged from the
sample, and analyzed by cold vapor
atomic absorption. The changes mirror
those for the other metals methods, but
this version changes the acceptance
limit for the CCV from 10% to 15% and
adds a requirement for a CCB. Given
that the most comparable EPA
procedure, Method 245.1, does not
include a CCV requirement or an
acceptance limit, the change of the
acceptance limit from 10% to 15% in
the revised ASTM method represents a
requirement that is more stringent than
that required in the EPA’s procedure
and therefore, the change to the ASTM
method is not an impediment to its
approval.
23. ASTM Method D3373–17,
vanadium, AA furnace. The sample is
digested with nitric acid and analyzed
by graphite furnace atomic absorption.
The concentration of vanadium in the
sample is proportional to the amount of
light absorbed during the graphite
furnace atomic absorption analysis and
is determined in comparison to a
standard curve. The changes mirror
those for the other metals methods. The
proposed changes clarify the
requirements for a multi-point
calibration by discussing it in the
calibration section as well as the QC
section of all three procedures. The QC
frequencies for method blank, CCV,
CCB, matrix spike, and duplicate
analyses are now based on a laboratorydefined batch of up to 20 samples.
24. ASTM Method D3557–17 (A–D),
cadmium, AA direct aspiration,
voltammetry, AA furnace. Method
D3557–17A, the sample is acid digested
and analyzed by direct aspiration
atomic absorption. Method D3557–17B,
the sample is acid digested, the
digestate is chelated and extracted. The
extract analyzed by direct aspiration
atomic absorption. Method D3557–17C,
the sample is acid digested and
analyzed by differential pulse anodic
stripping voltametry. Method D3557–
17D, the sample is digested with nitric
acid and analyzed by graphite furnace
atomic absorption. The concentration of
cadmium in the sample is determined in
comparison to a standard curve. The
changes mirror those for the other
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metals methods. The proposed changes
also clarify requirements for a multipoint calibration by discussing it in the
calibration section as well as the QC
section of all three procedures. The QC
frequencies for method blank, CCV,
CCB, matrix spike, and duplicate
analyses are now based on a laboratorydefined batch of up to 20 samples, as
opposed to 10 samples previously.
25. ASTM Method D3558–15 (A–C),
cobalt, AA direct aspiration, chelation
extraction AA, and AA furnace. Method
D3558–15A, the sample is acid digested
and analyzed by direct aspiration
atomic absorption. Method D3558–15B,
the sample is acid digested, chelated
and extracted. The extract is analyzed
by direct aspiration atomic absorption.
Method D3558–15C, the sample is acid
digested and analyzed by graphite
furnace atomic absorption. The
concentration of cobalt in the sample is
proportional to the amount of light
absorbed during the analysis and is
determined in comparison to a standard
curve. The changes mirror those for the
other metals methods. The proposed
changes also clarify the requirements for
a multi-point calibration by discussing
it in the calibration section as well as
the QC section of all three procedures.
The QC frequencies for method blank,
CCV, CCB, matrix spike, and duplicate
analyses are now based on a laboratorydefined batch of up to 20 samples, as
opposed to 10 samples previously.
26. ASTM Method D3559–15 (A–D),
lead, AA direct aspiration, voltammetry,
AA furnace. Method D3559–15A, the
sample is acid digested and analyzed by
direct aspiration atomic absorption.
Method D3559–15B, the sample is acid
digested, chelated and extracted. The
extract is analyzed by direct aspiration
atomic absorption. Method D3559–15C,
the sample is acid digested and
analyzed by differential pulse anodic
stripping voltametry. Method D3559–
15D, the sample is digested with nitric
acid and analyzed by graphite furnace
atomic absorption. The changes mirror
those for the other metals methods. The
proposed changes also clarify the
requirements for a multi-point
calibration by discussing it in the
calibration section as well as the QC
section of all three procedures. It also
adds a new section with the QC
requirements to the direct AA procedure
that was already present in the AA
furnace portion of this procedure
(D3559–15 [D]).
27. ASTM Method D3590–17 (A, B),
total Kjeldahl nitrogen, manual
digestion and distillation or gas
diffusion; semi-automated block
digester colorimetric (distillation not
required). Method D3590–17A, the
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sample is chemically processed to
covert nitrogenous compounds to
ammonia, then distilled or subjected to
a gas diffusion system which releases
the ammonia for analysis by
colorimetry, titrimetry, or
potentiometry. Method D3590–17B, the
digestion and distillation are
accomplished by a semi-automated
system and the resulting ammonia is
determined by colorimetry of the
salicylate/nitroprusside Berthelot
reaction product. This version changes
the acceptance limit for the CCV from
10% to 15% and adds a requirement for
a CCB. Given that neither the approved
Standard Methods method for
measuring ammonia after the TKN
digestion, nor the comparable EPA
Method 350.1, include a CCV
requirement or an acceptance limit, the
change of the acceptance limit from
10% to 15% in the revised ASTM
method represents a requirement that is
more stringent than that required in
other approved procedures and
therefore is not an impediment to its
approval.
28. ASTM Method D3645–15,
beryllium (A, B), AA direct aspiration
AA furnace. Method D3645–15A, the
sample is acid digested and analyzed by
direct aspiration atomic absorption.
Method D3645–15B, the sample is
digested with nitric acid and analyzed
by graphite furnace atomic absorption.
This version adds specifications for
filter paper. The proposed changes also
clarify the requirements for a threepoint calibration by discussing it in the
calibration section as well as the QC
section of both procedures. It also adds
a new section with the QC requirements
to the direct aspiration AA procedure
that was already present in the AA
furnace portion of this procedure
(D3645–15B).
29. ASTM Method D3859–15 (A, B),
selenium, AA gaseous hydride, AA
furnace. In Method D3859–15A, the
selenium in the sample is converted to
gaseous selenium hydride, which is
then analyzed by flame atomic
absorption. Method D3859–15B, the
selenium in the sample is converted to
gaseous selenium hydride and analyzed
by graphite furnace atomic absorption.
The changes to the gaseous hydride
portion of the method clarify the
requirement for a 6-point calibration
curve by discussing it in the calibration
section as well as the QC section. The
version adds an updated discussion of
block digesters. The QC frequencies for
method blank, CCV, CCB, matrix spike,
and duplicate analyses are now based
on a laboratory-defined batch, as
opposed to an otherwise undefined
‘‘batch.’’ The GFAA portion contains
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similar editorial and technical changes.
Technical changes also include
specifications for filter paper. The
calibration requirement for three
standards has been clarified by
discussing it in the calibration section
as well as the QC section.
30. ASTM Method D3867–16 (A, B)
nitrate-nitrite, nitrite and nitrate;
automated cadmium reduction, manual
cadmium reduction, bypass cadmium
reduction and subtraction. The
combination of nitrate and nitrite in the
sample is determined by reducing the
nitrate to nitrite using a cadmiumcopper column, diazotizing and
analyzing in either a manual or
automated spectrophotometric system.
A second aliquot of the sample can be
analyzed without use of the cadmium
reduction column to determine the
concentration of nitrate by difference.
The changes add more detailed QC
requirements, including specifically
calling out the laboratory control sample
(LCS), method blank, and matrix spike
analyses. The 2016 version adds
specifications for filter paper. It also
changes the LCS frequency from 10% of
samples to once per batch (up to 20) and
sets the CCB and CCV frequencies at
10%.
31. ASTM Method D4190–15,
dissolved elements and total recoverable
elements, direct current plasma. The
concentrations of various metal
elements are determined by acidifying
an aliquot of the sample and analyzing
it by direct current plasma
spectrometry, monitoring a specific
wavelength of light for each element.
There is one change that adds a
requirement to run at least four
calibration standards for all metals, as
opposed to running four standards for
only lithium to demonstrate linearity.
32. ASTM Method D4282–15, free
cyanide, manual micro-diffusion and
colorimetry. The sample is treated and
allow for free cyanide diffuse into a
sodium hydroxide solution. An aliquot
of that solution is treated to form a
colored product that is measured with a
spectrophotometer at 580 nm. There are
no procedural changes.
33. ASTM Method D4327–17,
inorganic anions (fluoride, bromide,
chloride, nitrite, nitrate,
orthophosphate, and sulfate), ion
chromatography. An aliquot of the
sample in injected into an ion
chromatograph equipped with an anion
exchange column and a conductivity
detector. The anions are identified
based on their retention times and
concentrations are determined by
comparison to a standard curve.
Changes include updating the
equipment and reagent descriptions to
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reflect more modern instrumentation,
such as the use of hydroxide eluents
and eluent regeneration systems.
34. ASTM Method D4382–18, barium,
AA furnace. The sample is digested
with nitric acid and analyzed by
graphite furnace atomic absorption. The
only procedural change is to the
description of the hot block digester
equipment. The new version specifies
the capability to heat samples between
65 and 95 degrees C, instead of
‘‘approximately 95 degrees C.’’ That
change recognizes the operational
characteristics of hot block digesters
that will experience a temperature drop
below 95 degrees when samples are
added. This should not adversely affect
use of this method for barium.
35. ASTM Method D4658–15, sulfide
ion, ion selective electrode. The sample
is treated with a sulfide antioxidant
buffer to create a highly alkaline
solution. Sulfide in the sample is
measured potentiometrically with an
ion-selective electrode. There are no
procedural changes.
36. ASTM Method D4839–03
(Reapproved 2017), total organic carbon;
heated persulfate or UV persulfate
oxidation. The sample is sparged with
an inert gas to remove dissolved
inorganic carbon and then treated with
persulfate and either heat or UV
radiation to convert organic carbon to
carbon dioxide. The carbon dioxide is
measured with an infra-red detector.
There are no procedural changes.
37. ASTM Method D5257–17,
dissolved hexavalent chromium, ion
chromatography. The sample is filtered
and buffered and an aliquot injected
into an ion chromatograph that
separates hexavalent chromium from
other ions. The eluent from the
chromatograph is treated with an acidic
solution of diphenylcarbohydrazide to
form a violet-colored product that is
measured with a photometric detector at
530 nm. The changes add a few
additional warnings or
recommendations.
38. ASTM Method D5673–16,
dissolved elements and totalrecoverable elements, ICP/MS. The
sample is acid digested and analyzed by
inductively coupled plasma/mass
spectrometry. Gold was added to the list
of target analytes. Some of the changes
address the analysis of gold.
39. ASTM Method D6508–15,
inorganic anions (fluoride, bromide,
chloride, nitrite, nitrate,
orthophosphate, and sulfate), capillary
ion electrophoresis with indirect UV
detection. An aliquot of the sample in
injected into a capillary ion
electrophoresis instrument where the
anions are separated in an applied
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electric field through a fused silica
capillary. The analytes are detected by
a UV detector and their concentrations
are determined by comparison to a
standard curve. There are no procedural
changes.
40. ASTM Method D6888–16,
available cyanide, flow injection and
ligand exchange, followed by gas
diffusion amperometry. An aliquot of
the sample is introduced into a flow
injection analysis instrument, where
available cyanide is acidified to form
hydrogen cyanide which diffuses
through a hydrophobic gas diffusion
membrane into an alkaline solution and
is detected amperometrically with a
silver electrode. This version adds a
new mixed ligand exchange reagent, but
also retains the original two ligand
reagents that had to be mixed together
during the testing.
41. ASTM Method D6919–17,
inorganic alkali and alkaline earth
cations and ammonium (ammonium,
calcium magnesium, potassium and
sodium), ion chromatography. An
aliquot of the sample in injected into an
ion chromatograph equipped with a
cation exchange column and a
conductivity detector. The cations are
identified based on their retention times
and concentrations are determined by
comparison to a standard curve. There
are no procedural changes.
42. ASTM Method D7237–15 (A), free
cyanide, flow injection, followed by gas
diffusion amperometry. An aliquot of
the sample is introduced into a flow
injection analysis instrument, where it
mixes with a phosphate buffer to release
hydrogen cyanide which diffuses
through a hydrophobic gas diffusion
membrane into an alkaline solution and
is detected amperometrically with a
silver electrode. There are a few
additions and changes to the newer
version of note. The statement of the
applicable range of the method in
Section 1.4 has been changed at the low
end, from 2 to 500 mg/L to 5 to 500 mg/
L. New information about interferences
from floatation reagents has been added
to Section 6.3. New materials in Section
8 discuss alternative reagents or
concentrations.
43. ASTM Method D7284–13
(Reapproved 2017), total cyanide,
manual distillation with MgCl2 followed
by flow injection, gas diffusion
amperometry. The sample is distilled
with acid and a magnesium chloride
catalyst to release cyanide to a sodium
hydroxide solution. An aliquot of the
sodium hydroxide solution is
introduced into a flow injection analysis
instrument, where it is acidified and the
hydrogen cyanide diffuses through a
hydrophobic gas diffusion membrane
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into an alkaline solution and is detected
amperometrically with a silver
electrode. There are no procedural
changes.
44. ASTM Method D7511–12
(Reapproved 2017), total cyanide,
segmented flow injection, in-line
ultraviolet digestion, followed by gas
diffusion amperometry. The sample is
introduced into a segmented flow
injection analysis instrument, where UV
light releases cyanide from cyanide
complexes. The sample is then acidified
in the instrument and the produced
cyanide gas is detected
amperometrically with a silver
electrode. There are no procedural
changes.
45. ASTM Method D7573–09
(Reapproved 2017), total organic carbon,
combustion. The sample is sparged with
an inert gas to remove dissolved
inorganic carbon, acidified, and then
combusted at high temperature convert
organic carbon to carbon dioxide. The
carbon dioxide is measured with an
infra-red detector. There are no
procedural changes.
The EPA proposes the following
changes to Table IC at 40 CFR part 136:
1. ASTM Method D7065–17,
nonylphenol, bisphenol A, p-tertoctylphenol, nonylphenol
monoethoxylate, nonylphenol
diethoxylate, gas chromatography/mass
spectrometry (GC/MS). The sample is
extracted with methylene chloride and
the extract is injected into a gas
chromatograph-mass spectrometer. The
target analytes are identified by
retention time and mass spectra and
quantified using internal standards and
a calibration curve. There are a large
number of editorial and structural
changes in the document. A new QC
section has been added.
F. Changes to 40 CFR 136.3 To Include
a New ASTM Method Based on
Previously Approved Technologies
The EPA is proposing these changes
based on the National Technology
Transfer and Advancement Act of 1995
(NTTAA), Public Law 104–113, which
states that federal agencies and
departments shall use technical
standards developed or adopted by the
VCSBs if compliance would not be
inconsistent with applicable law or
otherwise impracticable. This method
submitted by ASTM is consistent with
other already approved methods.
1. The EPA proposes to add ASTM
Method D7781–14 to Table IB for
nitrate-nitrite, nitrite (bypass the
enzymatic reduction step) and nitrate by
subtraction. Nitrate is reduced to nitrite
by an enzymatic reaction. The nitrite is
diazotized to yield an azo dye which is
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measured colorimetrically. The enzyme
reduction step may be by-passed for
measurement of nitrite singly. The value
obtained for nitrite may be subtracted
from the value obtained for combined
nitrate-nitrite to calculate the
concentration of nitrate. This method is
similar to the currently approved NECi
Method N07–0003, USGS Method I–
2547–11, and USGS Method I–2548–11.
G. Changes to 40 CFR 136.3 To Include
New United States Geological Survey
(USGS) Inorganic Methods Based on
Previously Approved Technologies
1. The EPA proposes to add USGS
Method I–2057–85 titled ‘‘Anions, ionexchange chromatographic, automated,’’
to Table IB for bromide. Method I–
2057–85 is an ion chromatography
method that lists several target analytes:
bromide, chloride, fluoride, nitrate,
nitrite, orthophosphate, and sulfate.
These are the same target analytes found
in EPA Methods 300.0 (Part A) and
300.1 (Part A). Both EPA methods are
approved in 40 CFR part 136 for the
target analytes listed in the methods.
USGS Method I–2057–85 is similar to
EPA Method 300.0, in that it uses ion
chromatography with a sodium
bicarbonate/sodium carbonate eluent
and has the same target analyte list. The
two methods specify different columns
and eluent concentrations, but rely on
essentially the same underlying
chemistry and determinative technique
as other ion chromatography methods
approved at 40 CFR part 136 for
measurement of bromide. That is, the
sample is introduced into an ion
chromatograph. The anions of interest
are separated and measured, using a
system comprised of a guard column,
analytical column, suppressor device,
and conductivity detector.
2. The EPA proposes to add USGS
Method I–2522–90 titled ‘‘Nitrogen,
ammonia, colorimetry, salicylatehypochlorite, automated-segmented
flow’’ to Table IB for ammonia. USGS
Method I–2522–90 uses the same
underlying chemistry and determinative
technique as other methods approved at
40 CFR part 136 for measurement of
ammonia. The method is similar to
other approved methods, such as EPA
Method 350.1, Standard Methods
Method 4500–NH3 G, and USGS
Method I–4523–85, which rely on the
Berthelot reaction. USGS Method I–
2522–90 uses a modified version of the
Berthelot reaction in which salicylate
and hypochlorite react with ammonia in
the presence of ferricyanide ions to form
the salicylic analog of indophenol blue
dye. The resulting color is directly
proportional to the concentration of
ammonia present and is measured using
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automated spectrophotometry. This is a
well-documented modification to the
Berthelot reaction used in EPA Method
351 and is specifically allowed in Table
IB.
3. The EPA proposes to add USGS
Method I–2540–90 titled ‘‘Nitrogen,
nitrite, colorimetry, diazotization,
automated-segmented flow’’ to Table IB
for nitrite. USGS Method I–2540–90
employs the same underlying chemistry
and determinative technique as other
methods approved at 40 CFR part 136
for measurement of nitrite. The method
is similar to other methods approved at
40 CFR part 136 for measurement of
nitrite, including USGS Method I–4540–
85, which uses an automated-segmented
flow analyzer (Technicon AA II).
Method I–2540–90, nitrite reacts with
sulfanilamide under acidic conditions
to form a diazo compound which is
coupled with N–1naphthylethylenediamine
dihydrochloride to form a red
compound, the absorbance of which is
measured using an automatedsegmented flow, spectrophotometry.
4. The EPA proposes to add USGS
Method I–2601–90 titled ‘‘Phosphorus,
orthophosphate, colorimetry,
phosphomolybdate, automatedsegmented flow’’ to Table IB for
orthophosphate. USGS Method I–2601–
90 employs the same underlying
chemistry and determinative technique
as other methods approved in 40 CFR
part 136 for measurement of
orthophosphate. Orthophosphate reacts
with ammonium molybdate in acidic
solution to form phosphomolybdic acid,
which upon reduction with ascorbic
acid produces an intensely blue
complex the absorbance of which is
measured using automated
spectrophotometry. Antimony
potassium tartrate is added to increase
the rate of reduction. The method is
similar to other approved methods, such
as USGS Method I–4601–85 which uses
an automated-segmented flow analyzer
(Technicon AA II). The submitted USGS
Method I–2601–90 also uses an
automated-segmented flow analyzer
(Alpkem rapid flow analyzer). It should
be noted that the approved USGS
Method I–4601–85 has two parameter
codes listed:
a. Phosphorus, orthophosphate,
dissolved, I–2601–85 (mg/L as P);
b. Phosphorus, orthophosphate, total,
I–4601–85 (mg/L as P).
Although USGS Method I–4601–85 is
listed in Table IB, samples to be used for
measurement of orthophosphate are to
be filtered upon collection per Table II.
Therefore, the correct parameter code
listed for the method should have been
I–2601–85. I–2601–90 is just an updated
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version of that method (parameter code).
In Section 3—Interferences, USGS
Method I–2601–85 states: ‘‘Because as
phosphorus is easily adsorbed on
sediment, the orthophosphate recovered
from the supernatant solution above a
water-suspended sediment after some
time has elapsed may be less than the
orthophosphate that would have been
determined in the filtrate from a sample
filtered at the time of collection. The
amount recovered may also depend on
the type of sediment (clay, sand, etc.).’’
5. The EPA proposes USGS Method I–
4472–97 titled ‘‘Metals, Acid Digestion,
Whole-Water Recoverable, inductively
coupled plasma-mass spectrometry’’ to
be added to Table IB for certain metals
by ICP/MS. USGS Method I–4472–97 is
an ICP/MS method that was previously
listed under the same method number
as the USGS ICP/AES Method I–4471–
97 and was split out and assigned a
unique method number by USGS in
2003. The EPA proposes to add this to
Table IB on the line for ICP/MS and
replace USGS Method I–4471–97 as an
approved method for measurement of
the following 16 elements: aluminum,
antimony, barium, beryllium, cadmium,
chromium, cobalt, copper, lead,
manganese, molybdenum, nickel,
selenium, silver, thallium and zinc.
USGS Method I–4472–97 relies on the
same underlying chemistry and
determinative technique as other ICP/
MS methods approved at 40 CFR part
136 for measurement of the same 16
elements (e.g., EPA Method 200.8 and
Standard Methods Method 3125 B)
where analytes in the sample are
solubilized by gentle refluxing with
acids and then measured using
inductively coupled plasma-mass
spectrometry.
H. Changes to 40 CFR 136.3 To Include
New United States Geological Survey
(USGS) Organic Methods Based on
Previously Approved Technologies
1. The EPA proposes to add USGS
Method O–4127–96 titled
‘‘Determination of 86 Volatile Organic
Compounds in Water by Gas
Chromatography/Mass Spectrometry,
Including Detections Less Than
Reporting Limits’’ to Table IC for certain
organic compounds. USGS Method O–
4127–96 relies on the same underlying
chemistry and determinative technique
as other methods approved at 40 CFR
part 136 for measurement of the
analytes for which the method is being
proposed. Volatile organic compounds
are extracted by purging with Helium,
collecting onto a sorbent trap, thermally
desorbed, separated by a gas
chromatographic capillary column, and
finally determined by a full-scan
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quadrupole mass spectrometer.
Compound identification is confirmed
by the gas chromatographic retention
time and by the resultant mass
spectrum, typically identified by three
unique ions.
2. The EPA Proposes to add USGS
Method O–4436–16 titled
‘‘Determination of Heat Purgeable and
Ambient Purgeable Volatile Organic
Compounds in Water by Gas
Chromatography/Mass Spectrometry’’ to
Table IC for certain organic compounds.
USGS Method O–4436–16 relies on the
same underlying chemistry and
determinative technique as other
methods approved at 40 CFR part 136
for measurement of the analytes for
which the method is being proposed.
Volatile organic compounds are
extracted from a water sample and
compounds are trapped in a tube
containing a suitable sorbent materials
and then thermally desorbed into a
capillary gas chromatographic column
interfaced to a mass spectrometer
system. Selected compounds are
identified by using strict qualification
criteria, which include analyzing
standard reference materials and
comparing retention times and relative
ratios of the mass spectra. Compounds
are quantitated using internal standard
procedures.
I. Changes to 40 CFR 136.3 To Include
Alternate Test Procedures (ATPs)
To promote method innovation, the
EPA maintains a program that allows
method developers to apply for EPA
review and potential approval of an
alternative method to an existing
approved method. This ATP program is
described for CWA applications at 40
CFR 136.4 and 136.5. The EPA is
proposing three ATPs for nationwide
use. Based on the EPA’s review, the
performance of these ATPs is equally
effective as other methods already
approved for measurement. The ATP
applicants supplied EPA with study
reports that contain the data from their
validation studies. These study reports
and the letters documenting EPA’s
review are contained as supporting
documents within the docket for this
proposed rule. These proposed new
methods include: FIAlab Method 100,
‘‘Determination of Inorganic Ammonia
by Continuous Flow Gas Diffusion and
Fluorescence Detector Analysis,’’
MACHEREY-NAGEL GmbH and Co.
Method 036/038 NANOCOLOR® COD
LR/HR, ‘‘Spectrophotometric
Measurement of Chemical Oxygen
Demand in Water and Wastewater,’’ and
Micrology Laboratories, LLC.
KwikCountTM EC Medium Escherichia
coli (E. coli) enzyme substrate test,
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‘‘Rapid Detection of E. coli in Beach
Water by KwikCountTM EC Membrane
Filtration.’’ Descriptions of these new
methods proposed for approval are as
follows:
1. FIAlab Instruments, Inc. Method
100, ‘‘Determination of Inorganic
Ammonia by Continuous Flow Gas
Diffusion and Fluorescence Detector
Analysis,’’ dated April 4, 2018 (FIAlab
Instruments, Inc. 2018a). FIAlab Method
100 uses automated flow injection
analysis with gas diffusion and
fluorescence detector analysis to
determine concentrations of ammonia in
wastewater, ambient water, and
Kjeldahl digestates. The method
involves the following steps:
• The sample is introduced to the
analyzer where it is made alkaline with
sodium hydroxide;
• Ammonia is separated from the
sample matrix by passage through a gas
diffusion cell;
• After separation in the gas diffusion
cell, ammonia is reacted with ophthalaldehyde to form a fluorescent
compound;
• The reaction product is detected by
a fluorimeter and the response is
directly proportional to the
concentration of ammonia in the
sample.
FIAlab Method 100 can be obtained
from FIAlab Instruments, Inc., 334 2151
N Northlake Way, Seattle, WA 98103.
Telephone: 425–376–0450.
2. MACHEREY-NAGEL GmbH and
Co. Method 036/038 NANOCOLOR®
COD LR/HR, ‘‘Spectrophotometric
Measurement of Chemical Oxygen
Demand in Water and Wastewater,’’
Revision 1.5, dated, May 2018
(MACHEREY-NAGEL GmbH and Co.
2018a). MACHEREY-NAGEL Method
036/038 NANOCOLOR® COD LR/HR is
a manual method that uses
spectrophotometry to measure chemical
oxygen demand in wastewater. The
method involves the following steps:
• Chemical Oxygen Demand (COD) is
defined as the mg of oxygen (O2)
consumed per liter of sample following
dichromate and sulfuric acid digestion;
• A sample is heated for two hours
with a strong oxidizing agent, potassium
dichromate. Oxidizable organic
compounds react, reducing the
dichromate ion (Cr2O72·) to the green
chromic ion (Cr3+);
• When the COD LR 150 test kit is
used, the amount of Cr6+ remaining after
digestion is determined;
• When the COD HR 1500 test kit is
used, the amount of Cr3+ produced is
determined.
MACHEREY-NAGEL GmbH and Co.
Method 036/038 NANOCOLOR® COD
LR/HR, can be obtained from
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MACHEREY-NAGEL GmbH and Co.,
2850 Emrick Blvd., Bethlehem, PA
18020. Telephone: 888–321–6224.
3. Micrology Laboratories LLC.
KwikCountTM EC Medium E. coli
enzyme substrate test, ‘‘Rapid Detection
of E. coli in Beach Water by
KwikCountTM EC Membrane Filtration’’
uses a membrane filtration procedure
for rapid detection and enumeration of
E. coli in ambient water. The method
involves the following steps:
• A water sample is filtered through
a 0.45-mm pore size, 47-mm diameter
membrane filter;
• The filter is then placed into a 50mm plate containing an absorbent pad
containing KwikCountTM EC broth;
• Plates are incubated at 41 ± 0.5 °C
for 8–10 hr. The plates are then viewed
in the dark using a long-wave UV light
and fluorescent colonies are counted as
E. coli.
The KwikCountTM EC Medium E. coli
enzyme substrate test can be obtained
from Micrology Laboratories, LLC, 1303
Eisenhower Drive, Goshen, IN 46526.
Telephone: 574–533–3351.
J. Changes to 40 CFR 136.3, Tables IA,
IB, and IH
The EPA is proposing the following
changes to 40 CFR 136.3, Tables IA and
IH:
1. Table IA: Moving Colilert-18 from
Parameter #1 Coliform (fecal), number
per 100 mL or number per gram dry
weight, to Parameter #2 Coliform (fecal),
(number per 100 mL), to eliminate
confusion as to whether it is approved
for sewage sludge in addition to
wastewater.
2. Table IA: Adding E. coli, number
per 100 mL—MF, two-step, Standard
Methods Method 9222 B/9222 I, to the
table along with footnote 31 ‘‘Subject
coliform positive samples determined
by 9222 B–2015 or other membrane
filter procedure to 9222 I–2015 using
NA–MUG media.’’ The method was
inadvertently omitted from Table IA
when Table IA was split into two tables
(IA and IH) in an earlier rulemaking; the
addition corrects that error.
3. Table IA: Revising Parameter #2
Coliform (fecal), deleting ‘‘in presence
of chlorine,’’ number per 100 mL. The
phrase ‘‘in the presence of chlorine’’
caused confusion because the methods
cited were the same for the analyte/
matrix combination that did not state
‘‘in the presence of chlorine.’’ The
approved methods did not change.
4. Table IA: Deleting Parameter #4
Coliform (total) in presence of chlorine,
number per 100 mL. Except for ‘‘MF
with enrichment,’’ all the methods were
duplicative (e.g., Parameters #3 and #4).
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No approved methods for coliform
(total) were removed from Table IA.
5. Table IH: Deleting Parameters #2
Coliform (fecal) in presence of chlorine,
number per 100 mL and #4 Coliform
(total) in presence of chlorine, number
per 100 mL. Except for ‘‘MF with
enrichment’’ for coliform (total), all the
methods were duplicative (e.g.,
Parameters #1 and #2). In addition to
the methods being duplicative, Table IH
is for ambient water which would not be
expected to contain chlorine. No
approved methods for coliform (fecal) or
coliform (total) were removed from
Table IH. The remaining parameters are
renumbered.
6. Tables IA and IH: Revising footnote
13 to Table IA and footnote 12 to Table
IH as follows ‘‘These tests are
collectively known as defined enzyme
substrate tests.’’ The remaining text,
‘‘where, for example, a substrate is used
to detect the enzyme b-glucuronidase
produced by E. coli’’ has been deleted
because the example has caused some
confusion to stakeholders.
7. Tables IA and IH: Adding QuantiTray®/2000 as an option to footnotes 13
(IH), 15 (IH), 16 (IA) and 18 (IA). The
addition of Quanti-Tray®/2000 is to
address matrices with high bacterial
concentrations and to ensure Tables IA
and IH are accurate and consistent.
8. Tables IA and IH: Adding footnote
30 to Table IA and footnote 27 to Table
IH to specify a verification procedure.
The footnotes contain the following
language: ‘‘On a monthly basis, at least
ten sheen colonies from positive
samples must be verified using Lauryl
Tryptose Broth and brilliant green
lactose bile broth, followed by count
adjustment based on these results; and
representative non-sheen colonies
should be verified using Lauryl
Tryptose Broth. Where possible,
verifications should be done from
randomized sample sources.’’ Adding
the footnotes address the change in
Standard Methods Method 9222 B–2015
that stated that five typical and five
atypical colonies should be verified per
membrane, which could be burdensome
to laboratories analyzing samples other
than drinking water. In most cases,
analysis of ambient waters and
wastewaters could result in multiple
plates per sample with typical and
atypical colonies, whereas drinking
water analyses would seldom result in
any typical or atypical colonies. In
addition, the language in footnotes 29
(IA) and 26 (IH), was revised as follows
‘‘the medium’’ was replaced with
‘‘positive samples’’ for clarity and
consistency.
9. Tables IA and IH: Adding footnote
32 to Table IA and footnote 30 to Table
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IH. The footnotes contain the following
language ‘‘Verification of colonies by
incubation of BHI agar at 10 ± 0.5 °C for
48 ± 3 h is optional.’’ As per the Errata
to the 23rd Edition of Standard Methods
for the Examination of Water &
Wastewater, ‘‘Growth on a BHI agar
plate incubated at 10 ± 0.5 °C for 48 ±
3 h is further verification that the colony
belongs to the genus Enterococcus.’’
10. Table IH: Deleting ‘‘or number per
gram dry weight’’ from Parameter #1.
Table IH is specifically for ambient
waters, which does not require reporting
results on a per gram dry weight basis.
11. Table IH: Adding the Alternate
Test Procedure KwikCountTM EC for E.
coli, number per 100 mL under ‘‘Other.’’
12. Table IH: Adding EPA Method
1623.1 for Parameters 6 and 7. EPA
Method 1623.1 includes updated
acceptance criteria for IPR, OPR, and
MS/MSD, and clarifications and
revisions based on the use of EPA
Method 1623 and technical support
questions over the past 19 years. Both
methods 1623 and 1623.1 will be listed
as approved in the MUR because use of
either method is acceptable.
13. Table IH: Deleting footnote 5,
‘‘Because the MF technique usually
yields low and variable recovery from
chlorinated wastewaters, the Most
Probable Number method will be
required to resolve any controversies.’’
Table IH is specifically for ambient
waters, so the footnote is not applicable.
The remaining footnotes are
renumbered accordingly.
14. Table IH: Revising footnote 20, to
reference only EPA Method 1604. The
literature reference was deleted from the
footnote because it resulted in confusion
as to whether EPA Method 1604
provided all the necessary information
required by stakeholders to conduct
analyses of ambient waters under the
CWA.
flexibility to collect a single sample
with no acidification to be used for
analysis of both purgeable halocarbons
and purgeable aromatic hydrocarbons
within seven days of collection, or to
collect a single sample with
acidification to be used for analysis of
both purgeable halocarbons (except 2–
CEVE) and purgeable aromatic
hydrocarbons within the 14-day
maximum holding time specified in
Table II for both classes of compounds.
The added flexibility is consistent with
historical requirements for preservation
in 40 CFR part 136 and holding time
requirements in other EPA program
methods, such as the SW–846 methods
in the Office of Land and Emergency
Management. This is part of the EPA’s
ongoing effort to harmonize methods
between EPA programs, as requested by
the Environmental Laboratory Advisory
Board (ELAB).
Footnote 9 to Table II states: ‘‘If the
sample is not adjusted to pH 2, then the
sample must be analyzed within seven
days of sampling.’’
K. Changes to Table II at 40 CFR
136.3(e) to Required Containers,
Preservation Techniques, and Holding
Times
The EPA is proposing to update
footnote 6 to the preservation and
holding time requirements for cyanide
to cite the latest version of ASTM
method D7365–09a that was reapproved
in 2015. The recommended sampling
and preservation procedures in the
ASTM method have not changed since
2009, but the change to footnote 6 will
simplify identification of the current
method that is available from ASTM
International.
The EPA is proposing to add footnote
9 to the preservation and holding time
requirements to the purgeable
halocarbons entry. This will allow the
A. Executive Order 12866: Regulatory
Planning and Review and Review and
Executive Order 13563: Improving
Regulation and Regulatory Review
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L. Changes to 40 CFR 136.6 Method
Modifications and Analytical
Requirements
In response to requests from ELAB
and the Independent Laboratories
Institute (ILI), the EPA is proposing to
add a new paragraph (b)(4)(xviii) to 40
CFR 136.6 that explicitly allows the use
of closed-vessel microwave digestion as
a modification to the approved metals
digestion procedure that does not
require prior approval. Microwave
digestion has the same fundamental
chemistry as a hot plate digestion, both
the microwave and hot plate serve the
same function as heat sources.
V. Statutory and Executive Order
Reviews
This rule is not a significant
regulatory action and was therefore not
submitted to the Office of Management
and Budget (OMB) for interagency
review under this E.O.
B. Paperwork Reduction Act
This action does not impose an
information collection burden under the
Paperwork Reduction Act. This rule
does not impose any information
collection, reporting, or recordkeeping
requirements. This proposal would
merely add or revise CWA test
procedures.
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C. Regulatory Flexibility Act
I certify that this action would not
have a significant economic impact on
a substantial number of small entities
under the Regulatory Flexibility Act.
This action will not impose any
requirements on small entities. This
action would approve new and revised
versions of CWA testing procedures.
Generally, these changes would have a
positive impact on small entities by
increasing method flexibility, thereby
allowing entities to reduce costs by
choosing more cost-effective methods.
In general, the EPA expects the
proposed revisions would lead to few, if
any, increased costs. As explained
previously, most of the proposed
changes clarify or improve the
instructions in the method, update the
technology used in the method, improve
the QC instructions, make editorial
corrections, or reflect the most recent
approval year of an already approved
method. In some cases, the proposal
would add alternatives to currently
approved methods for a particular
analyte (e.g., Method N07–0003 for
Nitrate Reductase Nitrate-Nitrogen
Analysis). Because these methods
would be alternatives rather than
requirements, there are no direct costs
associated with this proposal. The EPA
proposes methods that would be
incorporated by reference. If a permittee
elected to use these methods, they could
incur a small cost associated with
obtaining these methods from the listed
sources. See Section IV.B.
D. Unfunded Mandates Reform Act
This action does not contain any
unfunded mandate as described in the
Unfunded Mandates Reform Act, 2
U.S.C. 1531–1538, and does not
significantly or uniquely affect small
governments. The action imposes no
enforceable duty on any state, local or
tribal governments or the private sector.
E. Executive Order 13132: Federalism
This proposed rule does not have
federalism implications. It will not have
substantial direct effects on the states,
on the relationship between the national
government and the states, or on the
distribution of power and
responsibilities among the various
levels of government.
F. Executive Order 13175: Consultation
and Coordination With Indian Tribal
Governments
This proposed rule does not have
tribal implications as specified in
Executive Order 13175. This rule would
merely approve new and revised
versions of test procedures. The EPA
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does not expect the proposal would lead
to any costs to any tribal governments,
and if incurred, projects they would be
minimal. Thus, Executive Order 13175
does not apply to this action.
G. Executive Order 13045: Protection of
Children From Environmental Health
Risks and Safety Risks
The EPA interprets Executive Order
13045 as applying only to those
regulatory actions that concern
environmental health or safety risks that
the EPA has reason to believe may
disproportionately affect children, per
the definition of ‘‘covered regulatory
action’’ in section 2–202 of the
Executive Order. This action is not
subject to Executive Order 13045
because it does not concern an
environmental health risk or safety risk.
H. Executive Order 13211: Actions That
Significantly Affect Energy Supply,
Distribution, or Use
This action is not subject to Executive
Order 13211 because it is not a
significant regulatory action under
Executive Order 12866.
I. National Technology Transfer and
Advancement Act of 1995
This action involves technical
standards. The EPA proposes to approve
the use of technical standards
developed and recommended by the
Standard Methods Committee and
ASTM International for use in
compliance monitoring where the EPA
determined that those standards meet
the needs of CWA programs. As
described above, this proposal is
consistent with the NTTAA.
J. Executive Order 12898: Federal
Actions To Address Environmental
Justice in Minority Populations and
Low-Income Populations
The EPA believes the human health or
environmental risk addressed by this
action will not have potential
disproportionately high and adverse
human health or environmental effects
on minority, low-income or indigenous
populations.
List of Subjects in 40 CFR Part 136
Environmental protection,
Incorporation by reference, Reporting
and recordkeeping requirements, Test
procedures, Water pollution control.
Dated: June 11, 2019.
Andrew R. Wheeler,
Administrator.
For the reasons set out in the
preamble, title 40, chapter I of the Code
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of Federal Regulations is proposed to be
amended as follows:
PART 136—GUIDELINES
ESTABLISHING TEST PROCEDURES
FOR THE ANALYSIS OF POLLUTANTS
1. The authority citation for part 136
continues to read as follows:
■
Authority: Secs. 301, 304(h), 307 and
501(a), Pub. L. 95–217, 91 Stat. 1566, et seq.
(33 U.S.C. 1251, et seq.) (the Federal Water
Pollution Control Act Amendments of 1972
as amended by the Clean Water Act of 1977).
2. Amend § 136.3 by:
a. In paragraph (a), seventh sentence,
removing the word ‘‘year’’ and adding
in its place the word ‘‘date’’ in its place,
and removing from the last sentence the
text ‘‘(paragraph (c) of this section, in
§ 136.5(a) through (d) or 40 CFR
401.13)’’ and adding in its place the text
‘‘paragraph (c) of this section, § 136.5(a)
through (d) or 40 CFR 401.13,’’
respectively;
■ b. Revising tables IA, IB, IC, and IH;
■ c. Revising paragraph (b) by:
■ i. Revising the introductory text;
paragraph (b)(8) introductory text, and
paragraphs (b)(8)(ix) through (b)(xv);
■ ii. Adding paragraph (b)(8)(xvi);
■ iii. Revising paragraphs (b)(10)(xiv),
(b)(10)(xxxix), (b)(10)(xliv), (b)(10)(xlvi),
(b)(10)(lii), (b)(10)(liv), (b)(10)(lxvii),
(b)(10)(lxviii), (b)(10)(lxix), (b)(10)(lxx),
b)(15)(v), (b)(15)(vi), (b)(15)(viii) through
(xiii), (b)(15)(xv) through (xix),
(b)(15)(xxi) through (xxvi), (b)(15)(xxxi),
(b)(15)(xxxiv) and (xxxv),
(b)(15)(xxxvii), (b)(15)(xxxix) through
(xliii), (b)(15)(xlv) through (l),
(b)(15)(lii), (b)(15)(liv) and (b)(15)(lv),
(b)(15)(lviii), (b)(15)(lxi) through (lxvi),
and (b)(15)(lxviii) through (lxix); and
■ iv. Adding paragraph (b)(15)(lxx);
■ v. Redesignating paragraphs (b)(25)
through (b)(36) as paragraphs (b)(28)
through (b)(39);
■ vi. Redesignating paragraphs (b)(19)
through (24) as paragraphs (b)(20)
through (25);
■ vii. Adding new paragraphs (b)(19),
(26), and (27); and
■ viii. Revising the newly redesignated
paragraphs (b)(38)(ii) through (xxi);
■ ix. Adding paragraphs (b)(38)(xxii)
and (xxiii); and
■ c. Revising paragraph (e) Table II.
The revisions and additions read as
follows:
■
■
§ 136.3
*
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Identification of test procedures.
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TABLE IA—LIST OF APPROVED BIOLOGICAL METHODS FOR WASTEWATER AND SEWAGE SLUDGE
Method 1
Parameter and units
EPA
Standard methods
AOAC, ASTM,
USGS
Other
Bacteria
1. Coliform (fecal), number per 100 mL
or number per gram dry weight.
2. Coliform (fecal), number per 100 mL
3. Coliform (total), number per 100 mL
4. E. coli, number per 100 mL .............
5. Fecal streptococci, number per 100
mL.
6. Enterococci, number per 100 mL ....
7. Salmonella, number per gram dry
weight 11.
Most Probable Number (MPN), 5
tube, 3 dilution, or.
Membrane filter (MF) 2 5, single step
MPN, 5 tube, 3 dilution, or ................
p. 132,3 1680,11 15
1681,11 20.
p. 124 3 ................
p. 132 3 ................
Multiple tube/multiple well, or ...........
MF2 5, single step 5 ............................
MPN, 5 tube, 3 dilution, or ................
MF 2 5, single step or two step ..........
MF 2 5, with enrichment .....................
..............................
p. 124 3 ................
p. 114 3 ................
p. 108 3 ................
p. 111 3 ................
MPN 6 8 16 multiple tube, or ................
..............................
multiple tube/multiple well, or ...........
..............................
MF 2 5 6 7 8, two step, or ......................
..............................
Single step ........................................
MPN, 5 tube, 3 dilution, or ................
1603 21
MF 2, or .............................................
Plate count ........................................
MPN, 5 tube, 3 dilution, or ................
MPN 6 8, multiple tube/multiple well,
or.
MF 2 5 6 7 8 single step or ...................
Plate count ........................................
MPN multiple tube ............................
p. 136 3 ................
p. 143 3.
p. 139 3 ................
..............................
9230 C–2013 32 .........
B–0055–85 4.
9230 B–2013.
9230 D–2013 .............
D6503–99 9 ..........
1600 24 .................
p. 143 3.
1682 22.
9230 C–2013 32.
.................
p. 139 3 ................
9221 E–2014.
9222 D–2015 29 .........
9221 E–2014; 9221
F.2–2014 33.
....................................
9222 D–2015 29.
9221 B–2014.
9222 B–2015 30 .........
9222
(B+B.4e)¥2015 30.
9221 B.3–2014/9221
F–2014 12 14 33.
9223 B–2016 13 .........
9222 B–2015/9222 I–
2015 31.
....................................
9230 B–2013.
B–0050–85 4.
..............................
B–0025–85 4.
991.15 10 ..............
Colilert®.13 18
Colilert18®.13 17 18
..............................
m-ColiBlue24®.19
Aquatic Toxicity
8. Toxicity, acute, fresh water organisms, LC50, percent effluent.
9. Toxicity, acute, estuarine and marine organisms of the Atlantic Ocean
and Gulf of Mexico, LC50, percent
effluent.
10. Toxicity, chronic, fresh water organisms, NOEC or IC25, percent effluent.
11. Toxicity, chronic, estuarine and
marine organisms of the Atlantic
Ocean and Gulf of Mexico, NOEC or
IC25, percent effluent.
Ceriodaphnia dubia acute .................
2002.0 25.
Daphnia puplex and Daphnia magna
acute.
Fathead Minnow, Pimephales
promelas, and Bannerfin shiner,
Cyprinella leedsi, acute.
Rainbow Trout, Oncorhynchus
mykiss, and brook trout,
Salvelinus fontinalis, acute.
Mysid, Mysidopsis bahia, acute ........
2021.0 25.
2000.0 25.
2019.0 25.
2007.0 25.
Sheepshead Minnow, Cyprinodon
variegatus, acute.
Silverside, Menidia beryllina, Menidia
menidia, and Menidia peninsulae,
acute.
Fathead minnow, Pimephales
promelas, larval survival and
growth.
Fathead minnow, Pimephales
promelas, embryo-larval survival
and teratogenicity.
Daphnia, Ceriodaphnia dubia, survival and reproduction.
Green alga, Selenastrum
capricornutum, growth.
Sheepshead minnow, Cyprinodon
variegatus, larval survival and
growth.
2004.0 25.
Sheepshead minnow, Cyprinodon
variegatus, embryo-larval survival
and teratogenicity.
Inland silverside, Menidia beryllina,
larval survival and growth.
Mysid, Mysidopsis bahia, survival,
growth, and fecundity.
Sea urchin, Arbacia punctulata, fertilization.
1005.0 27.
2006.0 25.
1000.0 26.
1001.0 26.
1002.0
26.
1003.0
26.
1004.0 27.
1006.0 27.
1007.0 27.
1008.0 27.
Table IA notes:
1 The method must be specified when results are reported.
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2 A 0.45-μm membrane filter (MF) or other pore size certified by the manufacturer to fully retain organisms to be cultivated and to be free of extractables which
could interfere with their growth.
3 Microbiological Methods for Monitoring the Environment, Water and Wastes, EPA/600/8–78/017. 1978. US EPA.
4 U.S. Geological Survey Techniques of Water-Resource Investigations, Book 5, Laboratory Analysis, Chapter A4, Methods for Collection and Analysis of Aquatic
Biological and Microbiological Samples. 1989. USGS.
5 Because the MF technique usually yields low and variable recovery from chlorinated wastewaters, the Most Probable Number method will be required to resolve
any controversies.
6 Tests must be conducted to provide organism enumeration (density). Select the appropriate configuration of tubes/filtrations and dilutions/volumes to account for
the quality, character, consistency, and anticipated organism density of the water sample.
7 When the MF method has been used previously to test waters with high turbidity, large numbers of noncoliform bacteria, or samples that may contain organisms
stressed by chlorine, a parallel test should be conducted with a multiple-tube technique to demonstrate applicability and comparability of results.
8 To assess the comparability of results obtained with individual methods, it is suggested that side-by-side tests be conducted across seasons of the year with the
water samples routinely tested in accordance with the most current Standard Methods for the Examination of Water and Wastewater or EPA alternate test procedure
(ATP) guidelines.
9 Annual Book of ASTM Standards-Water and Environmental Technology, Section 11.02. 2000, 1999, 1996. ASTM International.
10 Official Methods of Analysis of AOAC International. 16th Edition, 4th Revision, 1998. AOAC International.
11 Recommended for enumeration of target organism in sewage sludge.
12 The multiple-tube fermentation test is used in 9221B.2–2014. Lactose broth may be used in lieu of lauryl tryptose broth (LTB), if at least 25 parallel tests are conducted between this broth and LTB using the water samples normally tested, and this comparison demonstrates that the false-positive rate and false-negative rate for
total coliform using lactose broth is less than 10 percent. No requirement exists to run the completed phase on 10 percent of all total coliform-positive tubes on a seasonal basis.
13 These tests are collectively known as defined enzyme substrate tests.
14 After prior enrichment in a presumptive medium for total coliform using 9221B.2–2014, all presumptive tubes or bottles showing any amount of gas, growth or
acidity within 48 h ± 3 h of incubation shall be submitted to 9221F–2014. Commercially available EC–MUG media or EC media supplemented in the laboratory with
50 μg/mL of MUG may be used.
15 Method 1680: Fecal Coliforms in Sewage Sludge (Biosolids) by Multiple-Tube Fermentation Using Lauryl-Tryptose Broth (LTB) and EC Medium, EPA–821–R–
14–009. September 2014. U.S. EPA.
16 Samples shall be enumerated by the multiple-tube or multiple-well procedure. Using multiple-tube procedures, employ an appropriate tube and dilution configuration of the sample as needed and report the Most Probable Number (MPN). Samples tested with Colilert® may be enumerated with the multiple-well procedures,
Quanti-Tray® or Quanti-Tray®/2000 and the MPN calculated from the table provided by the manufacturer.
17 Colilert-18® is an optimized formulation of the Colilert® for the determination of total coliforms and E. coli that provides results within 18 h of incubation at 35°C
rather than the 24 h required for the Colilert® test and is recommended for marine water samples.
18 Descriptions of the Colilert®, Colilert-18®, Quanti-Tray®, and Quanti-Tray®/2000 may be obtained from IDEXX Laboratories, Inc.
19 A description of the mColiBlue24® test is available from Hach Company.
20 Method 1681: Fecal Coliforms in Sewage Sludge (Biosolids) by Multiple-Tube Fermentation Using A–1 Medium, EPA–821–R–06–013. July 2006. U.S. EPA.
21 Method 1603: Escherichia coli (E. coli) in Water by Membrane Filtration Using Modified Membrane-Thermotolerant Escherichia coli Agar (modified mTEC), EPA–
821–R–14–010. September 2014. U.S. EPA.
22 Method 1682: Salmonella in Sewage Sludge (Biosolids) by Modified Semisolid Rappaport-Vassiliadis (MSRV) Medium, EPA–821–R–14–012. September 2014.
U.S. EPA.
23 A description of the Enterolert® test may be obtained from IDEXX Laboratories Inc.
24 Method 1600: Enterococci in Water by Membrane Filtration Using membrane-Enterococcus Indoxyl-b-D-Glucoside Agar (mEI), EPA–821–R–14–011. September
2014. U.S. EPA.
25 Methods for Measuring the Acute Toxicity of Effluents and Receiving Waters to Freshwater and Marine Organisms, EPA–821–R–02–012. Fifth Edition, October
2002. U.S. EPA.
26 Short-term Methods for Estimating the Chronic Toxicity of Effluents and Receiving Waters to Freshwater Organisms, EPA–821–R–02–013. Fourth Edition, October 2002. U.S. EPA.
27 Short-term Methods for Estimating the Chronic Toxicity of Effluents and Receiving Waters to Marine and Estuarine Organisms, EPA–821–R–02–014. Third Edition, October 2002. U.S. EPA.
28 To use Colilert-18® to assay for fecal coliforms, the incubation temperature is 44.5 ± 0.2 °C, and a water bath incubator is used.
29 On a monthly basis, at least ten blue colonies from positive samples must be verified using Lauryl Tryptose Broth and EC broth, followed by count adjustment
based on these results; and representative non-blue colonies should be verified using Lauryl Tryptose Broth. Where possible, verifications should be done from randomized sample sources.
30 On a monthly basis, at least ten sheen colonies from positive samples must be verified using lauryl tryptose broth and brilliant green lactose bile broth, followed
by count adjustment based on these results; and representative non-sheen colonies should be verified using lauryl tryptose broth. Where possible, verifications should
be done from randomized sample sources.
31 Subject coliform positive samples determined by 9222 B–2015 or other membrane filter procedure to 9222 I–2015 using NA–MUG media.
32 Verification of colonies by incubation of BHI agar at 10 ± 0.5 °C for 48 ± 3 h is optional. As per the Errata to the 23rd Edition of Standard Methods for the Examination of Water and Wastewater ‘‘Growth on a BHI agar plate incubated at 10 ± 0.5 °C for 48 ± 3 h is further verification that the colony belongs to the genus
Enterococcus.’’
33 9221 F. 2–2014 This procedure allows for simultaneous detection of E. coli and thermotolerant coliforms by adding inverted vials to EC–MUG; the inverted vials
collect gas produced by thermotolerant coliforms.
TABLE IB—LIST OF APPROVED INORGANIC TEST PROCEDURES
Parameter
Methodology 58
EPA 52
Standard methods 84
ASTM
1. Acidity, as CaCO3,
mg/L.
2. Alkalinity, as CaCO3,
mg/L.
Electrometric endpoint or phenolphthalein
endpoint.
Electrometric or Colorimetric titration to pH
4.5, Manual.
Automatic ....................................................
Digestion 4, followed by any of the following:
AA direct aspiration 36 .................................
...................................
2310 B–2011 ............
D1067–16 .................
I–1020–85.2
...................................
2320 B–2011 ............
D1067–16 .................
973.43 3, I–1030–85.2
310.2 (Rev. 1974) 1 ..
...................................
...................................
I–2030–85.2
...................................
3111 D–2011 or
3111 E–2011.
3113 B–2010.
...................................
I–3051–85.2
3120 B–2011 ............
D1976–12 .................
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
...................................
3500–Al B–2011.
4500–NH3 B–2011 ...
D4190–15 .................
993.14 3, I–4472–
97.81
See footnote.34
...................................
973.49.3
...................................
4500–NH3 C–2011.
4500–NH3 D–2011 or
E–2011.
D1426–15 (A) ...........
973.49 3, I–3520–85.2
3. Aluminum—Total,4
mg/L.
AA furnace ..................................................
STGFAA ......................................................
ICP/AES 36 ...................................................
ICP/MS ........................................................
4. Ammonia (as N),
mg/L.
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Direct Current Plasma (DCP) 36 ..................
Colorimetric (Eriochrome cyanine R) ..........
Manual distillation 6 or gas diffusion (pH
>11), followed by any of the following:
Nesslerization ..............................................
Titration .......................................................
Electrode .....................................................
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200.9, Rev. 2.2
(1994).
200.5, Rev 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
350.1, Rev. 2.0
(1993).
...................................
...................................
...................................
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TABLE IB—LIST OF APPROVED INORGANIC TEST PROCEDURES—Continued
Methodology 58
EPA 52
Standard methods 84
ASTM
Manual phenate, salicylate, or other substituted phenols in Berthelot reactionbased methods.
Automated phenate, salicylate, or other
substituted phenols in Berthelot reactionbased methods.
Automated electrode ...................................
Ion Chromatography ...................................
Automated gas diffusion, followed by conductivity cell analysis.
Automated gas diffusion followed by fluorescence detector analysis.
Digestion 4, followed by any of the following:
AA direct aspiration 36 .................................
AA furnace ..................................................
STGFAA ......................................................
...................................
4500–NH3 F–2011 ....
...................................
See footnote.60
350.1 30, Rev. 2.0
(1993).
4500–NH3 G–2011 ...
4500–NH3 H–2011 ...
...................................
I–4523–85 2, I–2522–
90.80
...................................
...................................
...................................
...................................
...................................
...................................
...................................
D6919–17.
...................................
See footnote.7
...................................
...................................
...................................
...................................
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
206.5 (Issued 1978) 1.
3111 B–2011.
3113 B–2010.
...................................
Parameter
5. Antimony—Total,4
mg/L.
ICP/AES 36 ...................................................
ICP/MS ........................................................
6. Arsenic-Total,4 mg/L
Digestion 4, followed by any of the following:.
AA gaseous hydride ....................................
AA furnace ..................................................
STGFAA ......................................................
ICP/AES 36 ...................................................
ICP/MS ........................................................
7. Barium-Total,4 mg/L
Colorimetric (SDDC) ...................................
Digestion 4, followed by any of the following:
AA direct aspiration 36 .................................
AA furnace ..................................................
ICP/AES 36 ...................................................
ICP/MS ........................................................
8. Beryllium—Total,4
mg/L.
DCP 36 .........................................................
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
STGFAA ......................................................
3120 B–2011 ............
D1976–12.
3125 B–2011 ............
D5673–16 .................
993.14 3, I–4472–
97.81
3114 B–2011 or 3114
C–2011.
3113 B–2010 ............
D2972–15 (B) ...........
I–3062–85.2
D2972–15 (C) ...........
I–4063–98.49
3120 B–2011 ............
D1976–12.
3125 B–2011 ............
D5673–16 .................
3500–As B–2011 ......
D2972–15 (A) ...........
...................................
...................................
200.5, Rev 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
3111 D–2011 ............
3113 B–2010 ............
3120 B–2011 ............
...................................
D4382–18.
...................................
I–3084–85.2
3125 B–2011 ............
D5673–16 .................
...................................
...................................
993.14 3, I–4472–
97.81
See footnote.34
...................................
3111 D–2011 or
3111 E–2011.
3113 B–2010 ............
D3645–15 (A) ...........
I–3095–85.2
D3645–15 (B).
3120 B–2011 ............
D1976–12 .................
I–4471–97.50
993.14 3, I–4472–
97.81
See footnote.34
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
993.14 3, I–4020–
05.70
I–3060–85.2
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
DCP .............................................................
Colorimetric (aluminon) ...............................
Dissolved Oxygen Depletion .......................
...................................
See footnote 61.
5210 B–2016 ............
D4190–15 .................
Colorimetric (curcumin) ...............................
...................................
4500–B B–2011 .......
...................................
973.44 3, p. 17 9, I–
1578–78 8, See
footnote.10, 63
I–3112–85.2
ICP/AES ......................................................
200.5, Rev 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
300.0, Rev 2.1
(1993) and 300.1,
Rev 1.0 (1997).
...................................
3120 B–2011 ............
D1976–12 .................
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
993.14.3
...................................
...................................
4110 B–2011, C–
2011, D–2011.
D4190–15 .................
D1246–16 .................
D4327–17 .................
See footnote.34
I–1125–85.2
993.30 3, I–2057–
85.79
4140 B–2011 ............
D6508–15 .................
D6508, Rev. 2.54
3111 B–2011 or 3111
C–2011.
D3557–17 (A or B) ...
974.27 3, p. 37 9, I–
3135–85 2 or I–
3136–85.2
ICP/MS ........................................................
ICP/MS ........................................................
11. Bromide, mg/L .......
DCP .............................................................
Electrode .....................................................
Ion Chromatography ...................................
12. Cadmium—Total,4
mg/L.
CIE/UV ........................................................
Digestion 4, followed by any of the following:
AA direct aspiration 36 .................................
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Timberline Ammonia–
001.74
FIAlab100.82
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
...................................
ICP/AES ......................................................
9. Biochemical oxygen
demand (BOD5), mg/
L.
10. Boron—Total,37
mg/L.
USGS/AOAC/other
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TABLE IB—LIST OF APPROVED INORGANIC TEST PROCEDURES—Continued
Methodology 58
EPA 52
Standard methods 84
ASTM
AA furnace ..................................................
STGFAA ......................................................
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
...................................
3113 B–2010 ............
D3557–17 (D) ...........
I–4138–89.51
3120 B–2011 ............
D1976–12 .................
I–1472–85 2 or I–
4471–97.50
3125 B–2011 ............
D5673–16 .................
...................................
...................................
3500–Cd–D–1990.
D4190–15 .................
D3557–17 (C).
993.14 3, I–4472–
97.81
See footnote.34
...................................
200.5, Rev 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
...................................
...................................
3111 B–2011 ............
3120 B–2011 ............
D511–14 (B) .............
...................................
I–3152–85.2
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
993.14.3
...................................
3500–Ca B–2011 .....
...................................
5210 B–2016 ............
...................................
D511–14 (A).
D6919–17.
...................................
See footnote.34
410.3 (Rev. 1978)1 ...
5220 B–2011 or C–
2011.
5220 D–2011 ............
D1252–06(12) (A) .....
4500–Cl¥ B–2011 ....
4500–Cl¥ C–2011 ....
...................................
4500–Cl¥ E–2011 ....
4500–Cl¥ D–2011.
...................................
4110 B–2011 or 4110
C–2011.
D512–12 (B) .............
D512–12 (A) .............
...................................
...................................
973.46 3, p. 17 9, I–
3560–85.2
See footnotes 13, 14, 83, I–
3561–85.2
I–1183–85.2
973.51 3, I–1184–85.2
I–1187–85.2
I–2187–85.2
Parameter
ICP/AES 36 ...................................................
ICP/MS ........................................................
13. Calcium—Total,4
mg/L.
DCP 36 .........................................................
Voltametry 11 ................................................
Colorimetric (Dithizone) ...............................
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
ICP/AES ......................................................
ICP/MS ........................................................
DCP .............................................................
Titrimetric (EDTA) .......................................
Ion Chromatography ...................................
Dissolved Oxygen Depletion with nitrification inhibitor.
14. Carbonaceous biochemical oxygen demand (CBOD5), mg/
L 12.
15. Chemical oxygen
Titrimetric .....................................................
demand (COD), mg/L.
Spectrophotometric, manual or automatic ..
16. Chloride, mg/L .......
17. Chlorine-Total residual, mg/L.
17A. Chlorine-Free
Available, mg/L.
18. Chromium VI dissolved, mg/L.
19. Chromium—Total,4
mg/L.
Titrimetric: (silver nitrate) ............................
(Mercuric nitrate) .........................................
Colorimetric: manual ...................................
Automated (ferricyanide) .............................
Potentiometric Titration ...............................
Ion Selective Electrode ...............................
Ion Chromatography ...................................
CIE/UV ........................................................
Amperometric direct ....................................
4140 B–2011 ............
4500–Cl D–2011 ......
D6508–15 .................
D1253–14.
D6508, Rev. 2.54
Amperometric direct (low level) ..................
Iodometric direct ..........................................
Back titration ether end-point 15 ..................
DPD–FAS ....................................................
Spectrophotometric, DPD ...........................
Electrode .....................................................
Amperometric direct ....................................
...................................
...................................
...................................
...................................
...................................
...................................
...................................
4500–Cl E–2011.
4500–Cl B–2011.
4500–Cl C–2011.
4500–Cl F–2011.
4500–Cl G–2011.
...................................
4500–Cl D–2011 ......
...................................
D1253–14.
See footnote.16
Amperometric direct (low level) ..................
DPD–FAS ....................................................
Spectrophotometric, DPD ...........................
0.45-micron filtration followed by any of the
following:
AA chelation-extraction ...............................
Ion Chromatography ...................................
...................................
...................................
...................................
4500–Cl E–2011.
4500–Cl F–2011.
4500–Cl G–2011.
...................................
218.6, Rev. 3.3
(1994).
...................................
3111 C–2011 ............
3500–Cr C–2011 ......
...................................
D5257–17 .................
I–1232–85.2
993.23.3
3500–Cr B–2011 ......
D1687–17 (A) ...........
I–1230–85.2
...................................
...................................
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev 4.2
(2003) 68, 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
3111 B–2011 ............
3111 C–2011.
3113 B–2010 ............
D1687–17 (B) ...........
974.27 3, I–3236–85.2
D1687–17 (C) ...........
I–3233–93.46
3120 B–2011 ............
D1976–12.
3125 B–2011 ............
D5673–16 .................
...................................
3500–Cr B–2011.
D4190–15 .................
993.14 3, I–4020–
05 70 I–4472–97.81
See footnote.34
...................................
3111 B–2011 or 3111
C–2011.
3113 B–2010 ............
D3558–15 (A or B) ...
p. 37 9, I–3239–85.2
D3558–15 (C) ...........
I–4243–89.51
Colorimetric (diphenyl-carbazide) ...............
Digestion 4, followed by any of the following:
AA direct aspiration 36 .................................
AA chelation-extraction ...............................
AA furnace ..................................................
STGFAA ......................................................
ICP/MS ........................................................
DCP 36 .........................................................
Colorimetric (diphenyl-carbazide) ...............
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
STGFAA ......................................................
VerDate Sep<11>2014
D1252–06(12) (B) .....
See footnote.35, 63
...................................
...................................
...................................
...................................
...................................
...................................
300.0, Rev 2.1
(1993) and 300.1,
Rev 1.0 (1997).
...................................
...................................
ICP/AES 36 ...................................................
20. Cobalt—Total,4 mg/
L.
410.4, Rev. 2.0
(1993).
USGS/AOAC/other
17:41 Oct 21, 2019
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...................................
200.9, Rev. 2.2
(1994).
Fmt 4701
Sfmt 4702
E:\FR\FM\22OCP3.SGM
D512–12 (C).
D4327–17 .................
22OCP3
993.30 3, I–2057–
90.51
56606
Federal Register / Vol. 84, No. 204 / Tuesday, October 22, 2019 / Proposed Rules
TABLE IB—LIST OF APPROVED INORGANIC TEST PROCEDURES—Continued
Methodology 58
EPA 52
Standard methods 84
ASTM
ICP/AES ......................................................
200.7, Rev. 4.4
(1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
3120 B–2011 ............
D1976–12 .................
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
...................................
2120 F–2011 78.
D4190–15 .................
993.14 3, I–4020–
05 70 I–4472–97.81
See footnote.34
...................................
...................................
2120 B–2011 ............
...................................
...................................
...................................
I–1250–85.2
See footnote.18
...................................
3111 B–2011 or 3111
C–2011.
D1688–17 (A or B) ...
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
...................................
...................................
3113 B–2010 ............
D1688–17 (C) ...........
974.27 3, p. 37 9, I–
3270–85 2 or I–
3271–85.2
I–4274–89.51
3120 B–2011 ............
D1976–12 .................
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
...................................
3500–Cu B–2011.
3500–Cu C–2011 .....
...................................
D4190–15 .................
993.14 3, I–4020–
05 70, I–4472–97.81
See footnote.34
...................................
...................................
See footnote.19
Kelada-01.55
...................................
...................................
D7511–12(17).
335.4, Rev. 1.0
(1993) 57.
...................................
4500–CN¥ B–2016
and C–2016.
...................................
...................................
...................................
335.4, Rev. 1.0
(1993) 57.
...................................
...................................
...................................
4500–CN¥ D–2016 ..
4500–CN¥ E–2016 ..
4500–CN¥ N–2016 ..
D2036–09(15)(A),
D7284–13(17).
D2036–09(15)(A)
D7284–13(17).
D2036–09(15)(A) ......
D2036–09(15)(A) ......
...................................
...................................
4500–CN¥ F–2016 ..
4500–CN¥ G–2016 ..
D2036–09(15)(A).
D2036–09(15)(A).
D2036–09(15)(B).
...................................
...................................
D6888–16 .................
OIA–1677–09.44
...................................
...................................
...................................
Kelada-01.55
...................................
...................................
D7237–15 (A) ...........
OIA–1677–09.44
...................................
...................................
...................................
4500–F¥ B–2011.
D4282–15.
...................................
...................................
...................................
...................................
300.0, Rev 2.1
(1993) and 300.1,
Rev 1.0 (1997).
...................................
4500–F¥ C–2011 .....
...................................
4500–F¥ D–2011 .....
4500–F¥ E–2011.
4110 B–2011 or C–
2011.
D1179–16 (B).
...................................
D1179–16 (A).
I–4327–85.2
D4327–17 .................
993.30.3
4140 B–2011 ............
D6508–15 .................
D6508, Rev. 2.54
D5673–16 .................
993.14.3
...................................
See footnote.34
D1126–17 .................
973.52B 3, I–1338–
85.2
D1293–99 (A or B) ...
973.41 3, I–1586–85.2
Parameter
ICP/MS ........................................................
DCP .............................................................
21. Color, platinum co- Colorimetric (ADMI) .....................................
balt units or dominant wavelength,
hue, luminance purity.
Platinum cobalt visual comparison .............
Spectrophotometric .....................................
22. Copper—Total,4
Digestion 4, followed by any of the folmg/L.
lowing:
AA direct aspiration 36 .................................
AA furnace ..................................................
STGFAA ......................................................
ICP/AES 36 ...................................................
ICP/MS ........................................................
23. Cyanide—Total,
mg/L.
DCP 36 .........................................................
Colorimetric (Neocuproine) .........................
Colorimetric (Bathocuproine) ......................
Automated UV digestion/distillation and
Colorimetry.
Segmented Flow Injection, In-Line Ultraviolet Digestion, followed by gas diffusion
amperometry.
Manual distillation with MgCl2, followed by
any of the following:
Flow Injection, gas diffusion amperometry
Titrimetric .....................................................
Spectrophotometric, manual .......................
Semi-Automated 20 ......................................
24. Cyanide-Available,
mg/L.
24.A Cyanide-Free,
mg/L.
25. Fluoride—Total,
mg/L.
26. Gold—Total,4 mg/L
27. Hardness—Total,
as CaCO3, mg/L.
28. Hydrogen ion (pH),
pH units.
VerDate Sep<11>2014
Ion Chromatography ...................................
Ion Selective Electrode ...............................
Cyanide Amenable to Chlorination (CATC);
Manual distillation with MgCl2, followed
by Titrimetric or Spectrophotometric.
Flow injection and ligand exchange, followed by gas diffusion amperometry.59
Automated Distillation and Colorimetry (no
UV digestion).
Flow Injection, followed by gas diffusion
amperometry.
Manual micro-diffusion and colorimetry ......
Manual distillation 6, followed by any of the
following:.
Electrode, manual .......................................
Electrode, automated ..................................
Colorimetric, (SPADNS) ..............................
Automated complexone ..............................
Ion Chromatography ...................................
CIE/UV ........................................................
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
ICP/MS ........................................................
DCP .............................................................
Automated colorimetric ...............................
................................... 3111 B–2011.
231.2 (Issued 1978) 1 3113 B–2010.
200.8, Rev. 5.4
3125 B–2011 ............
(1994).
................................... ...................................
130.1 (Issued 1971) 1.
Titrimetric (EDTA) .......................................
...................................
2340 C–2011 ............
Ca plus Mg as their carbonates, by any approved method for Ca and Mg (See Parameters 13 and 33), provided that the
sum of the lowest point of quantitation
for Ca and Mg is below the NPDES permit requirement for Hardness.
Electrometric measurement ........................
...................................
2340 B–2011.
...................................
4500–H+ B–2011 ......
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USGS/AOAC/other
10–204–00–1–X.56
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I–3300–85.2
10–204–00–1–X 56,
I–4302–85.2
56607
Federal Register / Vol. 84, No. 204 / Tuesday, October 22, 2019 / Proposed Rules
TABLE IB—LIST OF APPROVED INORGANIC TEST PROCEDURES—Continued
Methodology 58
Parameter
EPA 52
Automated electrode ...................................
29. Iridium—Total,4 mg/
L.
30. Iron—Total,4 mg/L
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
ICP/MS ........................................................
Digestion 4, followed by any of the following:
AA direct aspiration 36 .................................
AA furnace ..................................................
STGFAA ......................................................
ICP/AES 36 ...................................................
ICP/MS ........................................................
31. Kjeldahl Nitrogen 5—Total, (as N),
mg/L.
DCP 36 .........................................................
Colorimetric (Phenanthroline) .....................
Manual digestion 20 and distillation or gas
diffusion, followed by any of the following:
Titration .......................................................
Nesslerization ..............................................
Electrode .....................................................
Semi-automated phenate ............................
32.
Lead—Total,4
mg/L
Manual phenate, salicylate, or other substituted phenols in Berthelot reaction
based methods.
Automated gas diffusion, followed by conductivity cell analysis.
Automated gas diffusion followed by fluorescence detector analysis.
Automated Methods for TKN that do not
require manual distillation.
Automated phenate, salicylate, or other
substituted phenols in Berthelot reaction
based methods colorimetric (auto digestion and distillation).
Semi-automated block digestor colorimetric
(distillation not required).
Block digester, followed by Auto distillation
and Titration.
Block digester, followed by Auto distillation
and Nesslerization.
Block Digester, followed by Flow injection
gas diffusion (distillation not required).
Digestion with peroxdisulfate, followed by
Spectrophotometric (2,6-dimethyl phenol).
Digestion with persulfate, followed by Colorimetric.
Digestion 4, followed by any of the following:
AA direct aspiration 36 .................................
AA furnace ..................................................
STGFAA ......................................................
ICP/AES 36 ...................................................
ICP/MS ........................................................
33. Magnesium—
Total,4 mg/L.
DCP 36 .........................................................
Voltametry 11 ................................................
Colorimetric (Dithizone) ...............................
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
ICP/AES ......................................................
ICP/MS ........................................................
DCP .............................................................
Ion Chromatography ...................................
VerDate Sep<11>2014
17:41 Oct 21, 2019
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Frm 00019
150.2 (Dec.
1982) 1
..
Standard methods 84
ASTM
...................................
...................................
See footnote 21, I–
2587–85.2
D1068–15 (A) ...........
974.27 3, I–3381–85.2
USGS/AOAC/other
................................... 3111 B–2011.
235.2 (Issued 1978) 1.
................................... 3125 B–2011.
...................................
3111 B–2011 or 3111
C–2011.
3113 B–2010 ............
D1068–15 (B).
3120 B–2011 ............
D1976–12 .................
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
993.14.3
D4190–15 .................
D1068–15 (C) ...........
D3590–17 (A) ...........
See footnote.34
See footnote.22
I–4515–91.45
...................................
D1426–15 (A).
D1426–15 (B).
973.48.3
350.1, Rev. 2.0
(1993).
...................................
...................................
3500-Fe B–2011 .......
4500–Norg B–2011 or
C–2011 and 4500–
NH3 B–2011.
4500–NH3 C–2011 ...
...................................
4500–NH3 D–2011 or
E–2011.
4500–NH3 G–2011 ...
4500–NH3 H–2011.
4500–NH3 F–2011 ....
...................................
See footnote.60
...................................
...................................
...................................
...................................
...................................
...................................
Timberline Ammonia001.74
FIAlab 100.82
351.1 (Rev. 1978) 1 ..
...................................
...................................
I–4551–78.8
351.2, Rev. 2.0
(1993).
...................................
4500–Norg D–2011 ...
D3590–17 (B) ...........
I–4515–91.45
...................................
...................................
See footnote.39
...................................
...................................
...................................
See footnote.40
...................................
...................................
...................................
See footnote.41
...................................
...................................
...................................
Hach 10242.76
...................................
...................................
...................................
NCASI TNTP
W10900.77
...................................
3111 B–2011 or 3111
C–2011..
3113 B–2010 ............
D3559–15 (A or B) ...
974.27 3, I–3399–85.2
D3559–15 (D) ...........
I–4403–89.51
3120 B–2011 ............
D1976–12 .................
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
...................................
...................................
3500-Pb B–2011 ......
D4190–15 .................
D3559–15 (C).
...................................
993.14 3, I–4472–
97.81
See footnote.34
3111 B–2011 ............
3120 B–2011 ............
D511–14 (B) .............
D1976–12 .................
974.27 3, I–3447–85.2
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
993.14.3
...................................
...................................
...................................
D6919–17.
See footnote.34
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev. 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
...................................
...................................
...................................
...................................
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev. 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
...................................
...................................
200.5, Rev. 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
Fmt 4701
Sfmt 4702
E:\FR\FM\22OCP3.SGM
22OCP3
56608
Federal Register / Vol. 84, No. 204 / Tuesday, October 22, 2019 / Proposed Rules
TABLE IB—LIST OF APPROVED INORGANIC TEST PROCEDURES—Continued
Methodology 58
Parameter
34. Manganese—
Total,4 mg/L.
Digestion 4, followed by any of the following:
AA direct aspiration 36 .................................
AA furnace ..................................................
STGFAA ......................................................
ICP/AES 36 ...................................................
ICP/MS ........................................................
35. Mercury—Total,
mg/L.
36. Molybdenum—
Total,4 mg/L.
DCP 36 .........................................................
Colorimetric (Persulfate) .............................
Colorimetric (Periodate) ..............................
Cold vapor, Manual .....................................
Cold vapor, Automated ...............................
Cold vapor atomic fluorescence spectrometry (CVAFS).
Purge and Trap CVAFS ..............................
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
ICP/AES ......................................................
ICP/MS ........................................................
37. Nickel—Total,4 mg/
L.
DCP .............................................................
Digestion 4, followed by any of the following:
AA direct aspiration 36 .................................
AA furnace ..................................................
STGFAA ......................................................
ICP/AES 36 ...................................................
ICP/MS ........................................................
38. Nitrate (as N), mg/L
DCP 36 .........................................................
Ion Chromatography ...................................
CIE/UV ........................................................
Ion Selective Electrode ...............................
Colorimetric (Brucine sulfate) ......................
39. Nitrate-nitrite (as
N), mg/L.
ASTM
USGS/AOAC/other
...................................
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev. 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
...................................
245.1, Rev. 3.0
(1994).
245.2 (Issued 1974) 1.
245.7 Rev. 2.0
(2005) 17.
1631E 43.
3111 B–2011 ............
3113 B–2010 ............
D858–17 (A or B) .....
D858–17 (C).
974.27 3, I–3454–85.2
3120 B–2011 ............
D1976–12 .................
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
...................................
3500-Mn B–2011 ......
...................................
3112 B–2011 ............
D4190–15 .................
...................................
...................................
D3223–17 .................
993.14 3, I–4472–
97.81
See footnote.34
920.203.3
See footnote.23
977.22 3, I–3462–85.2
...................................
...................................
I–4464–01.71
...................................
...................................
200.7, Rev. 4.4
(1994).
200.8, Rev. 5.4
(1994).
...................................
3111 D–2011 ............
3113 B–2010 ............
3120 B–2011 ............
...................................
...................................
D1976–12 .................
I–3490–85.2
I–3492–96.47
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
...................................
...................................
993.14 3, I–4472–
97.81
See footnote.34
...................................
3111 B–2011 or .......
3111 C–2011 ............
3113 B–2010 ............
D1886–14 (A or B) ...
I–3499–85.2
D1886–14 (C) ...........
I–4503–89.51
3120 B–2011 ............
D1976–12 .................
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
...................................
4110 B–2011 or C–
2011.
D4190–15 .................
D4327–17 .................
993.14 3, I–4020–
05 70 I–4472–97.81
See footnote.34
993.30.3
4140 B–2011 ............
4500–NO3¥ D–2016.
...................................
D6508–15 .................
D6508, Rev. 2.54
...................................
973.50 3, 419D 1 7, p.
28.9
Hach 10206.75
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev. 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
300.0, Rev. 2.1
(1993) and 300.1,
Rev. 1.0 (1997).
...................................
...................................
352.1 (Issued 1971) 1
...................................
...................................
...................................
...................................
4500–NO3¥ E–2016
D3867–16 (B).
Cadmium reduction, Automated .................
353.2, Rev. 2.0
(1993).
...................................
...................................
300.0, Rev. 2.1
(1993) and 300.1,
Rev. 1.0 (1997).
...................................
...................................
4500–NO3¥ F–2016
4500–NO3¥ I–2016 ..
4500–NO3¥ H–2016.
...................................
4110 B–2011 or C–
2011.
D3867–16 (A) ...........
I–2545–90.51
...................................
D4327–17 .................
See footnote.62
993.30.3
4140 B–2011 ............
...................................
D6508–15 .................
D7781–14 .................
D6508, Rev. 2.54
I–2547–11 72
I–2548–11 72
N07–0003.73
...................................
4500–NO3¥ J–2018.
...................................
...................................
...................................
...................................
4500–NO2¥ B–2011
...................................
...................................
...................................
...................................
353.2, Rev. 2.0
(1993).
...................................
4500–NO3¥ F–2016
4500–NO3¥ I–2016 ..
4500–NO3¥ E–2016,
4500–NO3 J–
2018.
4110 B–2011 or C–
2011.
D3867–16 (A) ...........
Hach 10206.75
See footnote.25
I–4540–85 2, See
footnote 62
I–2540–90.80
I–4545–85.2
D4327–17 .................
993.30.3
4140 B–2011 ............
D6508–15 .................
D6508, Rev. 2.54
CIE/UV ........................................................
Enzymatic reduction, followed by automated colorimetric determination.
Enzymatic reduction, followed by manual
colorimetric determination.
Spectrophotometric (2,6-dimethylphenol) ...
Spectrophotometric: Manual .......................
Automated (Diazotization) ...........................
Automated (*bypass cadmium reduction) ...
Manual (*bypass cadmium or enzymatic reduction).
Ion Chromatography ...................................
CIE/UV ........................................................
VerDate Sep<11>2014
Standard methods 84
Spectrophotometric (2,6-dimethylphenol) ...
Nitrate-nitrite N minus Nitrite N (See parameters 39 and 40)
Cadmium reduction, Manual .......................
Automated hydrazine ..................................
Reduction/Colorimetric ................................
Ion Chromatography ...................................
40. Nitrite (as N), mg/L
EPA 52
17:41 Oct 21, 2019
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300.0, Rev. 2.1
(1993) and 300.1,
Rev. 1.0 (1997).
...................................
Fmt 4701
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E:\FR\FM\22OCP3.SGM
D3867–16 (B).
22OCP3
56609
Federal Register / Vol. 84, No. 204 / Tuesday, October 22, 2019 / Proposed Rules
TABLE IB—LIST OF APPROVED INORGANIC TEST PROCEDURES—Continued
Methodology 58
EPA 52
Standard methods 84
ASTM
Automated (* bypass Enzymatic reduction)
...................................
...................................
D7781–14 .................
I–2547–11 72
I–2548–11 72
N07–0003.73
Hexane extractable material (HEM): nHexane extraction and gravimetry.
1664 Rev. A; 1664
Rev. B 42.
5520 B–2011 38.
Silica gel treated HEM (SGT–HEM): Silica
gel treatment and gravimetry.
Combustion .................................................
1664 Rev. A; 1664
Rev. B 42.
...................................
5520 B–2011 38 and
5520 F–2011 38.
5310 B–2014 ............
D7573–09(17) ...........
973.47 3, p. 14.24
Heated persulfate or UV persulfate oxidation.
Total Kjeldahl N (Parameter 31) minus ammonia N (Parameter 4)
Ascorbic acid method:
...................................
5310 C–2014 ............
5310 D–2011 ............
D4839–03(17) ..........
973.47 3, p. 14.24
Automated ...................................................
365.1, Rev. 2.0
(1993).
...................................
365.3 (Issued 1978) 1.
300.0, Rev. 2.1
(1993) and 300.1,
Rev. 1.0 (1997).
...................................
4500–P F–2011 or
G–2011.
4500–P E–2011 .......
...................................
D515–88 (A) .............
973.56 3, I–4601–
85 2, I–2601–90.80
973.55.3
4110 B–2011 or C–
2011.
D4327–17 .................
993.30.3
4140 B–2011 ............
D6508–15 .................
D6508, Rev. 2.54
................................... 3111 D–2011.
252.2 (Issued 1978) 1.
................................... 4500–O (B–F)-2016
D888–12 (A) .............
Electrode .....................................................
Luminescence-Based Sensor .....................
...................................
...................................
4500–O G–2016 .......
4500–O H–2016 .......
D888–12 (B) .............
D888–12 (C) .............
973.45B 3, I–1575–
78.8
I–1576–78.8
See footnote.63
See footnote.64
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
ICP/MS ........................................................
DCP .............................................................
Manual distillation 26, followed by any of
the following:
Colorimetric (4AAP) manual .......................
................................... 3111 B–2011.
253.2 (Issued 1978) 1.
................................... 3125 B–2011.
................................... ...................................
420.1 (Rev. 1978) 1 .. 5530 B–2010 ............
...................................
D1783–01(12)
Parameter
41. Oil and grease—
Total recoverable,
mg/L.
42. Organic carbon—
Total (TOC), mg/L.
43. Organic nitrogen
(as N), mg/L.
44. Ortho-phosphate
(as P), mg/L.
Manual, single-reagent ................................
Manual, two-reagent ...................................
Ion Chromatography ...................................
45. Osmium—Total 4,
mg/L.
46. Oxygen, dissolved,
mg/L.
47. Palladium—Total,4
mg/L.
48. Phenols, mg/L .......
CIE/UV ........................................................
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
Winkler (Azide modification) .......................
Automated colorimetric (4AAP) ...................
49. Phosphorus (elemental), mg/L.
50. Phosphorus—Total,
mg/L.
Gas-liquid chromatography .........................
Digestion 20, followed by any of the following:
Manual .........................................................
Automated ascorbic acid reduction .............
ICP/AES 4 36
Platinum—Total,4
51.
mg/L.
52. Potassium—Total,4
mg/L.
.................................................
Semi-automated block digestor (TKP digestion).
Digestion with persulfate, followed by Colorimetric.
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
ICP/MS ........................................................
DCP .............................................................
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
ICP/AES ......................................................
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See footnote.34
420.1 (Rev. 1978) 1 ..
5530 D–2010 27 ........
D1783–01(12) (A or
B)
420.4 Rev. 1.0
(1993).
...................................
...................................
...................................
See footnote.28
...................................
4500–P B(5)–2011 ...
...................................
973.55.3
365.3 (Issued 1978) 1
365.1 Rev. 2.0
(1993).
200.7, Rev. 4.4
(1994).
365.4 (Issued 1974) 1
4500–P E–2011 .......
4500–P (F–H)–2011
D515–88 (A)
...................................
973.56 3, I–4600–85.2
3120 B–2011 ............
...................................
I–4471–97.50
...................................
D515–88 (B) .............
I–4610–91.48
...................................
...................................
...................................
NCASI TNTP
W10900.77
................................... 3111 B–2011.
255.2 (Issued 1978) 1.
................................... 3125 B–2011.
................................... ...................................
...................................
See footnote.34
3111 B–2011 ............
3120 B–2011.
...................................
973.53 3, I–3630–85.2
3125 B–2011 ............
D5673–16 .................
993.14.3
Flame photometric ......................................
Electrode .....................................................
Ion Chromatography ...................................
Gravimetric, 103–105° ................................
...................................
200.7, Rev. 4.4
(1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
...................................
...................................
3500–K B–2011.
3500–K C–2011.
...................................
2540 B–2015 ............
D6919–17.
...................................
I–3750–85.2
Gravimetric, 180° ........................................
...................................
2540 C–2015 ............
D5907–13 .................
I–1750–85.2
Gravimetric, 103–105° post-washing of residue.
Volumetric (Imhoff cone), or gravimetric .....
...................................
2540 D–2015 ............
D5907–13 .................
I–3765–85.2
...................................
2540 F–2015.
ICP/MS ........................................................
53. Residue—Total,
mg/L.
54. Residue—filterable,
mg/L.
55. Residue—non-filterable (TSS), mg/L.
56. Residue—settleable, ml/L.
USGS/AOAC/other
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TABLE IB—LIST OF APPROVED INORGANIC TEST PROCEDURES—Continued
Methodology 58
EPA 52
Standard methods 84
ASTM
Gravimetric, 550° ........................................
160.4 (Issued 1971) 1
2540 E–2015 ............
...................................
I–3753–85.2
I–4668–98.49
Parameter
57. Residue—Volatile,
mg/L.
58. Rhodium—Total,4
mg/L.
59. Ruthenium—Total,4
mg/L.
60. Selenium—Total,4
mg/L.
Digestion 4, followed by any of the following:
AA direct aspiration, or ...............................
AA furnace ..................................................
ICP/MS ........................................................
Digestion 4, followed by any of the following:
AA direct aspiration, or ...............................
AA furnace ..................................................
ICP/MS ........................................................
Digestion 4, followed by any of the following:
AA furnace ..................................................
STGFAA ......................................................
3111 B–2011.
3113 B–2010 ............
D3859–15 (B) ...........
3120 B–2011 ............
D1976–12
3125 B–2011 ............
D5673–16 .................
AA gaseous hydride ....................................
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
3114 B–2011, or
3114 C–2011.
D3859–15 (A) ...........
993.14 3, I–4020–
05 70 I–4472–97.81
I–3667–85.2
0.45-micron filtration followed by any of the
following:
Colorimetric, Manual ...................................
Automated (Molybdosilicate) .......................
...................................
...................................
4500-SiO2 C–2011 ...
4500-SiO2 E–2011 or
F–2011.
3120 B–2011 ............
D859–16 ...................
...................................
I–1700–85.2
I–2700–85.2
...................................
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
993.14.3
3111 B–2011 or 3111
C–2011.
3113 B–2010 ............
...................................
...................................
974.27 3, p. 37 9, I–
3720–85.2
I–4724–89.51
3120 B–2011 ............
D1976–12 .................
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
...................................
...................................
993.14 3, I–4472–
97.81
See footnote.34
...................................
200.5, Rev. 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
...................................
120.1 (Rev. 1982) 1 ..
3111 B–2011 ............
3120 B–2011 ............
...................................
...................................
973.54 3, I–3735–85.2
I–4471–97.50
3125 B–2011 ............
D5673–16 .................
993.14.3
...................................
3500-Na B–2011.
...................................
2510 B–2011 ............
...................................
See footnote.34
D6919–17.
D1125–95(99) (A) .....
973.40,3 I–2781–85.2
Gravimetric ..................................................
375.2, Rev. 2.0
(1993).
...................................
...................................
925.54.3
Turbidimetric ................................................
...................................
Ion Chromatography ...................................
CIE/UV ........................................................
Sample Pretreatment ..................................
300.0, Rev. 2.1
(1993) and 300.1,
Rev. 1.0 (1997).
...................................
...................................
4500–SO42 F–
2011 or G–2011.
4500–SO42 C–
2011 or D–2011.
4500–SO42 E–
2011.
4110 B–2011 or C–
2011.
Titrimetric (iodine) .......................................
Colorimetric (methylene blue) .....................
Ion Selective Electrode ...............................
Titrimetric (iodine-iodate) ............................
...................................
...................................
...................................
...................................
4140 B–2011 ............ D6508–15 .................
4500–S 2¥ B, C–
2011.
4500–S 2¥ F–2011 ... ...................................
4500–S 2¥ D–2011.
4500–S 2¥ G–2011 .. D4658–15.
4500–SO32¥ B–2011.
Colorimetric (methylene blue) .....................
Thermometric ..............................................
Digestion,4 followed by any of the following:
...................................
...................................
5540 C–2011 ............
2550 B–2010 ............
ICP/MS ........................................................
61.
mg/L.
ICP/AES ......................................................
ICP/MS ........................................................
62. Silver—Total,4, 31
mg/L.
Digestion 4 29, followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
STGFAA ......................................................
ICP/AES ......................................................
ICP/MS ........................................................
63. Sodium—Total,4
mg/L.
DCP .............................................................
Digestion 4, followed by any of the following:
AA direct aspiration .....................................
ICP/AES ......................................................
ICP/MS ........................................................
64. Specific conductance, micromhos/cm
at 25 °C.
65. Sulfate (as SO4),
mg/L.
66. Sulfide (as S), mg/L
67. Sulfite (as SO3),
mg/L.
68. Surfactants, mg/L ..
69. Temperature, °C ....
70. Thallium-Total,4
mg/L.
VerDate Sep<11>2014
................................... 3111 B–2011.
265.2 (Issued 1978) 1.
................................... 3125 B–2011.
...................................
267.2 1.
...................................
ICP/AES 36 ...................................................
Silica—Dissolved,37
USGS/AOAC/other
DCP .............................................................
Flame photometric ......................................
Ion Chromatography ...................................
Wheatstone bridge ......................................
Automated colorimetric ...............................
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(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev. 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
Fmt 4701
Sfmt 4702
3125 B–2011.
E:\FR\FM\22OCP3.SGM
D516–16.
D4327–17 .................
D2330–02.
...................................
22OCP3
993, I–4020–
05 70.303
D6508, Rev. 2.54
I–3840–85.2
See footnote.32
56611
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TABLE IB—LIST OF APPROVED INORGANIC TEST PROCEDURES—Continued
Methodology 58
EPA 52
AA direct aspiration .....................................
AA furnace ..................................................
...................................
279.2 (Issued
1978) 1.
200.9, Rev. 2.2
(1994).
200.7, Rev. 4.4
(1994).
200.8, Rev. 5.4
(1994).
3111 B–2011.
3113 B–2010.
...................................
...................................
200.9, Rev. 2.2
(1994).
200.5, Rev. 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
Parameter
STGFAA ......................................................
ICP/AES ......................................................
ICP/MS ........................................................
71. Tin-Total,4 mg/L .....
Digestion,4 followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
STGFAA ......................................................
ICP/AES ......................................................
ICP/MS ........................................................
72. Titanium-Total,4
mg/L.
Digestion,4 followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
ICP/AES ......................................................
ICP/MS ........................................................
73. Turbidity, NTU 53 ...
74. Vanadium-Total,4
mg/L.
DCP .............................................................
Nephelometric .............................................
Digestion,4 followed by any of the following:
AA direct aspiration .....................................
AA furnace ..................................................
ICP/AES ......................................................
ICP/MS ........................................................
75. Zinc-Total4, mg/L ...
DCP .............................................................
Colorimetric (Gallic Acid) ............................
Digestion,4 followed by any of the following:
AA direct aspiration 36 .................................
AA furnace ..................................................
ICP/AES 36 ...................................................
ICP/MS ........................................................
76. Acid Mine Drainage
DCP 36 .........................................................
Colorimetric (Zincon) ...................................
......................................................................
Standard methods 84
ASTM
USGS/AOAC/other
3120 B–2011 ............
D1976–12.
3125 B–2011 ............
D5673–16 .................
993.14,3 I–4471–
97 50 I–4472–97.81
3111 B–2011 ............
3113 B–2010.
...................................
I–3850–78.8
3125 B–2011 ............
D5673–16 .................
993.14.3
................................... 3111 D–2011.
283.2 (Issued 1978) 1.
200.7, Rev. 4.4
(1994).
200.8, Rev. 5.4
3125 B–2011 ............
(1994).
................................... ...................................
180.1, Rev. 2.0
2130 B–2011 ............
(1993).
D5673–16 .................
993.14.3
...................................
D1889–00 .................
See footnote.34
I–3860–85 2
See footnote 65
See footnote 66
See footnote.67
...................................
...................................
200.5, Rev. 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
(1994).
...................................
...................................
3111 D–2011.
3113 B–2010 ............
3120 B–2011 ............
D3373–17.
D1976–12 .................
3125 B–2011 ............
D5673–16 .................
...................................
3500–V B–2011.
D4190–15 .................
...................................
3111 B–2011 or 3111
C–2011.
D1691–17 (A or B) ...
974.27,3 p. 37,9 I–
3900–85.2
D1976–12 .................
I–4471–97.50
D5673–16 .................
993.14,3 I–4020–
05 70 I–4472–97.81
See footnote.34
See footnote.33
289.2 (Issued 1978) 1.
3120 B–2011 ............
200.5, Rev. 4.2
(2003) 68; 200.7,
Rev. 4.4 (1994).
200.8, Rev. 5.4
3125 B–2011 ............
(1994).
................................... ...................................
................................... 3500 Zn B–2011 .......
1627 69.
D4190–15 .................
...................................
I–4471–97.50
993.14,3 I–4020–
05.70
See footnote.34
Table IB Notes:
1 Methods for Chemical Analysis of Water and Wastes, EPA–600/4–79–020. Revised March 1983 and 1979, where applicable. U.S. EPA.
2 Methods for Analysis of Inorganic Substances in Water and Fluvial Sediments, Techniques of Water-Resource Investigations of the U.S. Geological Survey, Book
5, Chapter A1., unless otherwise stated. 1989. USGS.
3 Official Methods of Analysis of the Association of Official Analytical Chemists, Methods Manual, Sixteenth Edition, 4th Revision, 1998. AOAC International.
4 For the determination of total metals (which are equivalent to total recoverable metals) the sample is not filtered before processing. A digestion procedure is required to solubilize analytes in suspended material and to break down organic-metal complexes (to convert the analyte to a detectable form for colorimetric analysis).
For non-platform graphite furnace atomic absorption determinations, a digestion using nitric acid (as specified in Section 4.1.3 of Methods for Chemical Analysis of
Water and Wastes) is required prior to analysis. The procedure used should subject the sample to gentle acid refluxing, and at no time should the sample be taken to
dryness. For direct aspiration flame atomic absorption (FLAA) determinations, a combination acid (nitric and hydrochloric acids) digestion is preferred, prior to analysis. The approved total recoverable digestion is described as Method 200.2 in Supplement I of ‘‘Methods for the Determination of Metals in Environmental Samples’’
EPA/600R–94/111, May, 1994, and is reproduced in EPA Methods 200.7, 200.8, and 200.9 from the same Supplement. However, when using the gaseous hydride
technique or for the determination of certain elements such as antimony, arsenic, selenium, silver, and tin by non-EPA graphite furnace atomic absorption methods,
mercury by cold vapor atomic absorption, the noble metals and titanium by FLAA, a specific or modified sample digestion procedure may be required, and, in all
cases the referenced method write-up should be consulted for specific instruction and/or cautions. For analyses using inductively coupled plasma-atomic emission
spectrometry (ICP–AES), the direct current plasma (DCP) technique or EPA spectrochemical techniques (platform furnace AA, ICP–AES, and ICP–MS), use EPA
Method 200.2 or an approved alternate procedure (e.g., CEM microwave digestion, which may be used with certain analytes as indicated in Table IB); the total recoverable digestion procedures in EPA Methods 200.7, 200.8, and 200.9 may be used for those respective methods. Regardless of the digestion procedure, the results
of the analysis after digestion procedure are reported as ‘‘total’’ metals.
5 Copper sulfate or other catalysts that have been found suitable may be used in place of mercuric sulfate.
6 Manual distillation is not required if comparability data on representative effluent samples are on file to show that this preliminary distillation step is not necessary;
however, manual distillation will be required to resolve any controversies. In general, the analytical method should be consulted regarding the need for distillation. If
the method is not clear, the laboratory may compare a minimum of 9 different sample matrices to evaluate the need for distillation. For each matrix, a matrix spike
and matrix spike duplicate are analyzed both with and without the distillation step (for a total of 36 samples, assuming 9 matrices). If results are comparable, the laboratory may dispense with the distillation step for future analysis. Comparable is defined as <20% RPD for all tested matrices). Alternatively, the two populations of
spike recovery percentages may be compared using a recognized statistical test.
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7 Industrial Method Number 379–75 WE Ammonia, Automated Electrode Method, Technicon Auto Analyzer II. February 19, 1976. Bran & Luebbe Analyzing Technologies Inc.
8 The approved method is that cited in Methods for Determination of Inorganic Substances in Water and Fluvial Sediments, Techniques of Water-Resources Investigations of the U.S. Geological Survey, Book 5, Chapter A1. 1979. USGS.
9 American National Standard on Photographic Processing Effluents. April 2, 1975. American National Standards Institute.
10 In-Situ Method 1003–8–2009, Biochemical Oxygen Demand (BOD) Measurement by Optical Probe. 2009. In-Situ Incorporated.
11 The use of normal and differential pulse voltage ramps to increase sensitivity and resolution is acceptable.
12 Carbonaceous biochemical oxygen demand (CBOD ) must not be confused with the traditional BOD test method which measures ‘‘total 5-day BOD.’’ The addi5
5
tion of the nitrification inhibitor is not a procedural option but must be included to report the CBOD5 parameter. A discharger whose permit requires reporting the traditional BOD5 may not use a nitrification inhibitor in the procedure for reporting the results. Only when a discharger’s permit specifically states CBOD5 is required can
the permittee report data using a nitrification inhibitor.
13 OIC Chemical Oxygen Demand Method. 1978. Oceanography International Corporation.
14 Method 8000, Chemical Oxygen Demand, Hach Handbook of Water Analysis, 1979. Hach Company.
15 The back-titration method will be used to resolve controversy.
16 Orion Research Instruction Manual, Residual Chlorine Electrode Model 97–70. 1977. Orion Research Incorporated. The calibration graph for the Orion residual
chlorine method must be derived using a reagent blank and three standard solutions, containing 0.2, 1.0, and 5.0 mL 0.00281 N potassium iodate/100 mL solution,
respectively.
17 Method 245.7, Mercury in Water by Cold Vapor Atomic Fluorescence Spectrometry, EPA–821–R–05–001. Revision 2.0, February 2005. US EPA.
18 National Council of the Paper Industry for Air and Stream Improvement (NCASI) Technical Bulletin 253 (1971) and Technical Bulletin 803, May 2000.
19 Method 8506, Bicinchoninate Method for Copper, Hach Handbook of Water Analysis. 1979. Hach Company.
20 When using a method with block digestion, this treatment is not required.
21 Industrial Method Number 378–75WA, Hydrogen ion (pH) Automated Electrode Method, Bran & Luebbe (Technicon) Autoanalyzer II. October 1976. Bran &
Luebbe Analyzing Technologies.
22 Method 8008, 1,10-Phenanthroline Method using FerroVer Iron Reagent for Water. 1980. Hach Company.
23 Method 8034, Periodate Oxidation Method for Manganese, Hach Handbook of Wastewater Analysis. 1979. Hach Company.
24 Methods for Analysis of Organic Substances in Water and Fluvial Sediments, Techniques of Water-Resources Investigations of the U.S. Geological Survey, Book
5, Chapter A3, (1972 Revised 1987). 1987. USGS.
25 Method 8507, Nitrogen, Nitrite-Low Range, Diazotization Method for Water and Wastewater. 1979. Hach Company.
26 Just prior to distillation, adjust the sulfuric-acid-preserved sample to pH 4 with 1 + 9 NaOH.
27 The colorimetric reaction must be conducted at a pH of 10.0 ± 0.2.
28 Addison, R.F., and R.G. Ackman. 1970. Direct Determination of Elemental Phosphorus by Gas-Liquid Chromatography, Journal of Chromatography, 47(3):421–
426.
29 Approved methods for the analysis of silver in industrial wastewaters at concentrations of 1 mg/L and above are inadequate where silver exists as an inorganic
halide. Silver halides such as the bromide and chloride are relatively insoluble in reagents such as nitric acid but are readily soluble in an aqueous buffer of sodium
thiosulfate and sodium hydroxide to pH of 12. Therefore, for levels of silver above 1 mg/L, 20 mL of sample should be diluted to 100 mL by adding 40 mL each of 2
M Na2S2O3and NaOH. Standards should be prepared in the same manner. For levels of silver below 1 mg/L the approved method is satisfactory.
30 The use of EDTA decreases method sensitivity. Analysts may omit EDTA or replace with another suitable complexing reagent provided that all method-specified
quality control acceptance criteria are met.
31 For samples known or suspected to contain high levels of silver (e.g., in excess of 4 mg/L), cyanogen iodide should be used to keep the silver in solution for
analysis. Prepare a cyanogen iodide solution by adding 4.0 mL of concentrated NH4OH, 6.5 g of KCN, and 5.0 mL of a 1.0 N solution of I2 to 50 mL of reagent water
in a volumetric flask and dilute to 100.0 mL. After digestion of the sample, adjust the pH of the digestate to >7 to prevent the formation of HCN under acidic conditions. Add 1 mL of the cyanogen iodide solution to the sample digestate and adjust the volume to 100 mL with reagent water (NOT acid). If cyanogen iodide is added
to sample digestates, then silver standards must be prepared that contain cyanogen iodide as well. Prepare working standards by diluting a small volume of a silver
stock solution with water and adjusting the pH >7 with NH4OH. Add 1 mL of the cyanogen iodide solution and let stand 1 hour. Transfer to a 100-mL volumetric flask
and dilute to volume with water.
32 ‘‘Water Temperature-Influential Factors, Field Measurement and Data Presentation,’’ Techniques of Water-Resources Investigations of the U.S. Geological Survey, Book 1, Chapter D1. 1975. USGS.
33 Method 8009, Zincon Method for Zinc, Hach Handbook of Water Analysis, 1979. Hach Company.
34 Method AES0029, Direct Current Plasma (DCP) Optical Emission Spectrometric Method for Trace Elemental Analysis of Water and Wastes. 1986-Revised 1991.
Thermo Jarrell Ash Corporation.
35 In-Situ Method 1004–8–2009, Carbonaceous Biochemical Oxygen Demand (CBOD) Measurement by Optical Probe. 2009. In-Situ Incorporated.
36 Microwave-assisted digestion may be employed for this metal, when analyzed by this methodology. Closed Vessel Microwave Digestion of Wastewater Samples
for Determination of Metals. April 16, 1992. CEM Corporation
37 When determining boron and silica, only plastic, PTFE, or quartz laboratory ware may be used from start until completion of analysis.
38 Only use n-hexane (n-Hexane—85% minimum purity, 99.0% min. saturated C6 isomers, residue less than 1 mg/L) extraction solvent when determining Oil and
Grease parameters—Hexane Extractable Material (HEM), or Silica Gel Treated HEM (analogous to EPA Methods 1664 Rev. A and 1664 Rev. B). Use of other extraction solvents is prohibited.
39 Method PAI–DK01, Nitrogen, Total Kjeldahl, Block Digestion, Steam Distillation, Titrimetric Detection. Revised December 22, 1994. OI Analytical.
40 Method PAI–DK02, Nitrogen, Total Kjeldahl, Block Digestion, Steam Distillation, Colorimetric Detection. Revised December 22, 1994. OI Analytical.
41 Method PAI–DK03, Nitrogen, Total Kjeldahl, Block Digestion, Automated FIA Gas Diffusion. Revised December 22, 1994. OI Analytical.
42 Method 1664 Rev. B is the revised version of EPA Method 1664 Rev. A. U.S. EPA. February 1999, Revision A. Method 1664, n-Hexane Extractable Material
(HEM; Oil and Grease) and Silica Gel Treated n-Hexane Extractable Material (SGT–HEM; Non-polar Material) by Extraction and Gravimetry. EPA–821–R–98–002.
U.S. EPA. February 2010, Revision B. Method 1664, n-Hexane Extractable Material (HEM; Oil and Grease) and Silica Gel Treated n-Hexane Extractable Material
(SGT–HEM; Non-polar Material) by Extraction and Gravimetry. EPA–821–R–10–001.
43 Method 1631, Revision E, Mercury in Water by Oxidation, Purge and Trap, and Cold Vapor Atomic Fluorescence Spectrometry, EPA–821–R–02–019. Revision
E. August 2002, U.S. EPA. The application of clean techniques described in EPA’s Method 1669: Sampling Ambient Water for Trace Metals at EPA Water Quality
Criteria Levels, EPA–821–R–96–011, are recommended to preclude contamination at low-level, trace metal determinations.
44 Method OIA–1677–09, Available Cyanide by Ligand Exchange and Flow Injection Analysis (FIA). 2010. OI Analytical.
45 Open File Report 00–170, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory—Determination of Ammonium Plus Organic Nitrogen by a Kjeldahl Digestion Method and an Automated Photometric Finish that Includes Digest Cleanup by Gas Diffusion. 2000. USGS.
46 Open File Report 93–449, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory—Determination of Chromium in Water by
Graphite Furnace Atomic Absorption Spectrophotometry. 1993. USGS.
47 Open File Report 97–198, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory—Determination of Molybdenum by Graphite
Furnace Atomic Absorption Spectrophotometry. 1997. USGS.
48 Open File Report 92–146, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory—Determination of Total Phosphorus by Kjeldahl
Digestion Method and an Automated Colorimetric Finish That Includes Dialysis. 1992. USGS.
49 Open File Report 98–639, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory—Determination of Arsenic and Selenium in
Water and Sediment by Graphite Furnace-Atomic Absorption Spectrometry. 1999. USGS.
50 Open File Report 98–165, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory—Determination of Elements in Whole-water Digests Using Inductively Coupled Plasma-Optical Emission Spectrometry and Inductively Coupled Plasma-Mass Spectrometry. 1998. USGS.
51 Open File Report 93–125, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory—Determination of Inorganic and Organic Constituents in Water and Fluvial Sediments. 1993. USGS.
52 Unless otherwise indicated, all EPA methods, excluding EPA Method 300.1, are published in U.S. EPA. May 1994. Methods for the Determination of Metals in
Environmental Samples, Supplement I, EPA/600/R–94/111; or U.S. EPA. August 1993. Methods for the Determination of Inorganic Substances in Environmental
Samples, EPA/600/R–93/100. EPA Method 300.1 is U.S. EPA. Revision 1.0, 1997, including errata cover sheet April 27, 1999. Determination of Inorganic Ions in
Drinking Water by Ion Chromatography.
53 Styrene divinyl benzene beads (e.g., AMCO–AEPA–1 or equivalent) and stabilized formazin (e.g., Hach StablCalTM or equivalent) are acceptable substitutes for
formazin.
54 Method D6508–15, Test Method for Determination of Dissolved Inorganic Anions in Aqueous Matrices Using Capillary Ion Electrophoresis and Chromate Electrolyte. 2015. ASTM
55 Kelada-01, Kelada Automated Test Methods for Total Cyanide, Acid Dissociable Cyanide, and Thiocyanate, EPA 821–B–01–009, Revision 1.2, August 2001. US
EPA. Note: A 450–W UV lamp may be used in this method instead of the 550–W lamp specified if it provides performance within the quality control (QC) acceptance
criteria of the method in a given instrument. Similarly, modified flow cell configurations and flow conditions may be used in the method, provided that the QC acceptance criteria are met.
56 QuikChem Method 10–204–00–1–X, Digestion and Distillation of Total Cyanide in Drinking and Wastewaters using MICRO DIST and Determination of Cyanide
by Flow Injection Analysis. Revision 2.2, March 2005. Lachat Instruments.
57 When using sulfide removal test procedures described in EPA Method 335.4–1, reconstitute particulate that is filtered with the sample prior to distillation.
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58 Unless otherwise stated, if the language of this table specifies a sample digestion and/or distillation ‘‘followed by’’ analysis with a method, approved digestion
and/or distillation are required prior to analysis.
59 Samples analyzed for available cyanide using OI Analytical method OIA–1677–09 or ASTM method D6888–16 that contain particulate matter may be filtered only
after the ligand exchange reagents have been added to the samples, because the ligand exchange process converts complexes containing available cyanide to free
cyanide, which is not removed by filtration. Analysts are further cautioned to limit the time between the addition of the ligand exchange reagents and sample filtration
to no more than 30 minutes to preclude settling of materials in samples.
60 Analysts should be aware that pH optima and chromophore absorption maxima might differ when phenol is replaced by a substituted phenol as the color reagent
in Berthelot Reaction (‘‘phenol-hypochlorite reaction’’) colorimetric ammonium determination methods. For example, when phenol is used as the color reagent, pH optimum and wavelength of maximum absorbance are about 11.5 and 635 nm, respectively—see, Patton, C.J. and S.R. Crouch. March 1977. Anal. Chem. 49:464–469.
These reaction parameters increase to pH >12.6 and 665 nm when salicylate is used as the color reagent—see, Krom, M.D. April 1980. The Analyst 105:305–316.
61 If atomic absorption or ICP instrumentation is not available, the aluminon colorimetric method detailed in the 19th Edition of Standard Methods for the Examination of Water and Wastewater may be used. This method has poorer precision and bias than the methods of choice.
62 Easy (1-Reagent) Nitrate Method, Revision November 12, 2011. Craig Chinchilla.
63 Hach Method 10360, Luminescence Measurement of Dissolved Oxygen in Water and Wastewater and for Use in the Determination of BOD and CBOD . Revi5
5
sion 1.2, October 2011. Hach Company. This method may be used to measure dissolved oxygen when performing the methods approved in Table IB for measurement of biochemical oxygen demand (BOD) and carbonaceous biochemical oxygen demand (CBOD).
64 In-Situ Method 1002–8–2009, Dissolved Oxygen (DO) Measurement by Optical Probe. 2009. In-Situ Incorporated.
65 Mitchell Method M5331, Determination of Turbidity by Nephelometry. Revision 1.0, July 31, 2008. Leck Mitchell.
66 Mitchell Method M5271, Determination of Turbidity by Nephelometry. Revision 1.0, July 31, 2008. Leck Mitchell.
67 Orion Method AQ4500, Determination of Turbidity by Nephelometry. Revision 5, March 12, 2009. Thermo Scientific.
68 EPA Method 200.5, Determination of Trace Elements in Drinking Water by Axially Viewed Inductively Coupled Plasma-Atomic Emission Spectrometry, EPA/600/
R–06/115. Revision 4.2, October 2003. US EPA.
69 Method 1627, Kinetic Test Method for the Prediction of Mine Drainage Quality, EPA–821–R–09–002. December 2011. US EPA.
70 Techniques and Methods Book 5–B1, Determination of Elements in Natural-Water, Biota, Sediment and Soil Samples Using Collision/Reaction Cell Inductively
Coupled Plasma-Mass Spectrometry, Chapter 1, Section B, Methods of the National Water Quality Laboratory, Book 5, Laboratory Analysis, 2006. USGS.
71 Water-Resources Investigations Report 01–4132, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory—Determination of Organic Plus Inorganic Mercury in Filtered and Unfiltered Natural Water with Cold Vapor-Atomic Fluorescence Spectrometry, 2001. USGS.
72 USGS Techniques and Methods 5–B8, Chapter 8, Section B, Methods of the National Water Quality Laboratory Book 5, Laboratory Analysis, 2011 USGS
73 NECi Method N07–0003, ’’Nitrate Reductase Nitrate-Nitrogen Analysis,’’ Revision 9.0, March 2014, The Nitrate Elimination Co., Inc.
74 Timberline Instruments, LLC Method Ammonia-001, ‘‘Determination of Inorganic Ammonia by Continuous Flow Gas Diffusion and Conductivity Cell Analysis,’’
June 2011, Timberline Instruments, LLC.
75 Hach Company Method 10206, ‘‘Spectrophotometric Measurement of Nitrate in Water and Wastewater,’’ Revision 2.1, January 2013, Hach Company.
76 Hach Company Method 10242, ‘‘Simplified Spectrophotometric Measurement of Total Kjeldahl Nitrogen in Water and Wastewater,’’ Revision 1.1, January 2013,
Hach Company.
77 National Council for Air and Stream Improvement (NCASI) Method TNTP–W10900, ‘‘Total (Kjeldahl) Nitrogen and Total Phosphorus in Pulp and Paper Biologically Treated Effluent by Alkaline Persulfate Digestion,’’ June 2011, National Council for Air and Stream Improvement, Inc.
78 The pH adjusted sample is to be adjusted to 7.6 for NPDES reporting purposes.
79 I–2057–85 U.S. Geological Survey Techniques of Water-Resources Investigations, Book 5, Chap. A11989, Methods for Determination of Inorganic Substances in
Water and Fluvial Sediments, 1989.
80 Methods I–2522–90, I–2540–90, and I–2601–90 U.S. Geological Survey Open-File Report 93–125, Methods of Analysis by the U.S. Geological Survey National
Water Quality Laboratory–Determination of Inorganic and Organic Constituents in Water and Fluvial Sediments, 1993.
81 Method I–1472–97, U.S. Geological Survey Open-File Report 98–165, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory–Determination of Inorganic and Organic Constituents in Water and Fluvial Sediments, 1998.
82 FIAlab Instruments, Inc. Method FIAlab 100, ‘‘Determination of Inorganic Ammonia by Continuous Flow Gas Diffusion and Fluorescence Detector Analysis’’, April
4, 2018, FIAlab Instruments, Inc.
83 MACHEREY–NAGEL GmbH and Co. Method 036/038 NANOCOLOR® COD LR/HR, ‘‘Spectrophotometric Measurement of Chemical Oxygen Demand in Water
and Wastewater’’, Revision 1.5, May 2008, MACHEREY–NAGEL GmbH and Co. KG.
84 Please refer to the following applicable Quality Control Sections: Part 2000 Methods, Physical and Aggregate Properties 2020 (2017); Part 3000 Methods, Metals, 3020 (2017); Part 4000 Methods, Inorganic Nonmetallic Constituents, 4020 (2014); Part 5000 Methods, and Aggregate Organic Constituents, 5020 (2017). These
Quality Control Standards are available for download at www.standardmethods.org at no charge.
TABLE IC—LIST OF APPROVED TEST PROCEDURES FOR NON-PESTICIDE ORGANIC COMPOUNDS
Parameter 1
Method
EPA 2 7
1. Acenaphthene .................................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
Spectro-photometric.
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
610.
625.1, 1625B ........
610 .......................
610.
625.1, 1625B ........
610 .......................
603.
624.1 4, 1624B.
603.
624.1 4, 1624B ......
610.
625.1, 1625B ........
610 .......................
602 .......................
624.1, 1624B ........
...............................
2. Acenaphthylene ...............................
3. Acrolein ............................................
4. Acrylonitrile ......................................
5. Anthracene ......................................
6. Benzene ..........................................
7. Benzidine .........................................
8. Benzo(a)anthracene ........................
9. Benzo(a)pyrene ...............................
10. Benzo(b)fluoranthene ....................
11. Benzo(g,h,i)perylene .....................
12. Benzo(k)fluoranthene ....................
13. Benzyl chloride ..............................
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625.1 5, 1625B ......
605.
610.
625.1, 1625B ........
610 .......................
610.
625.1, 1625B ........
610 .......................
610.
625.1, 1625B ........
610 .......................
610.
625.1, 1625B ........
610 .......................
610.
625.1, 1625B ........
610 .......................
...............................
...............................
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6410 B–2000 ........
6440 B–2005 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
6410 B–2000 ........
6440 B–2005 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
...............................
...............................
O–4127–96.13
6410 B–2000 ........
6440B–2005 .........
6200 C–2011.
6200 B–2011 ........
...............................
...............................
D4657–92 (98).
See footnote 9, p. 27.
...............................
...............................
O–4127–96 13, O–4436–16.14
See footnote 3, p. 1.
6410 B–2000 ........
6440 B–2005 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
6410 B–2000 ........
6440 B–2005 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
6410 B–2000 ........
6440 B–2005 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
6410 B–2000 ........
6440 B–2005 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
6410 B–2000 ........
6440 B–2005 ........
...............................
...............................
...............................
D4657–92 (98).
...............................
...............................
See footnote 9, p. 27.
6410 B–2000.
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See footnote 3, p. 130.
See footnote 6, p. S102.
22OCP3
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TABLE IC—LIST OF APPROVED TEST PROCEDURES FOR NON-PESTICIDE ORGANIC COMPOUNDS—Continued
Parameter 1
Method
EPA 2 7
14. Butyl benzyl phthalate ...................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
606.
625.1, 1625B ........
611.
625.1, 1625B ........
611.
625.1, 1625B ........
606.
625.1, 1625B ........
601 .......................
624.1, 1624B ........
601 .......................
624.1, 1624B ........
601 .......................
624.1, 1624B ........
611.
625.1, 1625B ........
601 .......................
624.1, 1624B ........
604 .......................
625.1, 1625B ........
601, 602 ...............
624.1, 1624B ........
601 .......................
624.1, 1624B ........
601.
624.1, 1624B.
601 .......................
624.1, 1624B ........
601 .......................
624.1, 1624B ........
612.
625.1, 1625B ........
604 .......................
625.1, 1625B ........
611.
625.1, 1625B ........
610.
625.1, 1625B ........
610 .......................
610.
625.1, 1625B ........
610 .......................
601 .......................
624.1, 1624B ........
601, 602 ...............
624.1, 1625B ........
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
15. bis(2-Chloroethoxy) methane ........
16. bis(2-Chloroethyl) ether .................
17. bis(2-Ethylhexyl) phthalate ............
18. Bromodichloromethane .................
19. Bromoform .....................................
20. Bromomethane ..............................
21. 4-Bromophenyl phenyl ether .........
22. Carbon tetrachloride ......................
23. 4-Chloro-3-methyl phenol ..............
24. Chlorobenzene ..............................
25. Chloroethane .................................
26. 2-Chloroethylvinyl ether .................
27. Chloroform .....................................
28. Chloromethane ..............................
29. 2-Chloronaphthalene .....................
30. 2-Chlorophenol ..............................
31. 4-Chlorophenyl phenyl ether .........
32. Chrysene .......................................
33. Dibenzo(a,h)anthracene ................
34. Dibromochloromethane .................
35. 1,2-Dichlorobenzene .....................
36. 1,3-Dichlorobenzene .....................
37. 1,4-Dichlorobenzene .....................
38. 3,3′-Dichlorobenzidine ...................
39. Dichlorodifluoromethane ................
40. 1,1-Dichloroethane ........................
41. 1,2-Dichloroethane ........................
42. 1,1-Dichloroethene ........................
43. trans-1,2-Dichloroethene ...............
44. 2,4-Dichlorophenol ........................
45. 1,2-Dichloropropane ......................
46. cis-1,3-Dichloropropene ................
47. trans-1,3-Dichloropropene .............
48. Diethyl phthalate ............................
49. 2,4-Dimethylphenol ........................
50. Dimethyl phthalate .........................
51. Di-n-butyl phthalate .......................
52. Di-n-octyl phthalate .......................
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6410 B–2000 ........
...............................
See footnote 9, p. 27.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
6410
6200
6200
6200
6200
6200
6200
B–2000 ........
C–2011.
B–2011 ........
C–2011.
B–2011 ........
C–2011.
B–2011 ........
...............................
See footnote 9, p. 27.
...............................
O–4127–96 13, O–4436–16.14
...............................
O–4127–96 13, O–4436–16.14
...............................
O–4127–96 13, O–4436–16.14
6410
6200
6200
6420
6410
6200
6200
6200
6200
B–2000 ........
C–2011 ........
B–2011 ........
B–2000.
B–2000 ........
C–2011 ........
B–2011 ........
C–2011.
B–2011 ........
...............................
...............................
...............................
See footnote 9, p. 27.
See footnote 3, p. 130.
O–4127–96 13, O–4436–16.14
...............................
...............................
...............................
See footnote 9, p. 27.
See footnote 3, p. 130.
O–4127–96 13, O–4436–16.14
...............................
O–4127–96.13
6200
6200
6200
6200
C–2011 ........
B–2011 ........
C–2011.
B–2011 ........
...............................
...............................
See footnote 3, p. 130.
O–4127–96 13, O–4436–16.14
...............................
O–4127–96 13, O–4436–16.14
6410 B–2000 ........
6420 B–2000.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
...............................
See footnote 9, p. 27.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
6410 B–2000 ........
6440 B–2005 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
6410
6440
6200
6200
6200
6200
B–2000 ........
B–2005 ........
C–2011.
B–2011 ........
C–2011.
B–2011 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
...............................
O–4127–96 13, O–4436–16.14
...............................
See footnote 9, p. 27; O–4127–96 13,
O–4436–16.14
601, 602 ...............
624.1, 1625B ........
601, 602 ...............
624.1, 1625B ........
6200
6200
6200
6200
C–2011.
B–2011 ........
C–2011.
B–2011 ........
...............................
See footnote 9, p. 27; O–4127–96.13
...............................
See footnote 9, p. 27; O–4127–96 13,
O–4436–16.14
625.1, 1625B ........
605.
601.
...............................
601 .......................
624.1, 1624B ........
601 .......................
624.1, 1624B ........
601 .......................
624.1, 1624B ........
601 .......................
624.1, 1624B ........
604 .......................
625.1, 1625B ........
601 .......................
624.1, 1624B ........
601 .......................
624.1, 1624B ........
601 .......................
624.1, 1624B ........
606.
625.1, 1625B ........
604 .......................
625.1, 1625B ........
606.
625.1, 1625B ........
606.
625.1, 1625B ........
606.
6410 B–2000.
...............................
O–4127–96 13, O–4436–16.14
...............................
O–4127–96 13, O–4436–16.14
...............................
O–4127–96 13, O–4436–16.14
...............................
O–4127–96 13, O–4436–16.14
...............................
O–4127–96 13, O–4436–16.14
...............................
See footnote 9, p. 27.
...............................
O–4127–96 13, O–4436–16.14
...............................
O–4127–96 13, O–4436–16.14
...............................
O–4127–96 13, O–4436–16.14
6410 B–2000 ........
6420 B–2000.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
...............................
See footnote 9, p. 27.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
Frm 00026
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6200
6200
6200
6200
6200
6200
6200
6200
6420
6410
6200
6200
6200
6200
6200
6200
C–2011 ........
C–2011.
B–2011 ........
C–2011.
B–2011 ........
C–2011.
B–2011 ........
C–2011.
B–2011 ........
B–2000..
B–2000 ........
C–2011.
B–2011 ........
C–2011.
B–2011 ........
C–2011.
B–2011 ........
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TABLE IC—LIST OF APPROVED TEST PROCEDURES FOR NON-PESTICIDE ORGANIC COMPOUNDS—Continued
Parameter 1
53. 2,4-Dinitrophenol ...........................
54. 2,4-Dinitrotoluene ..........................
55. 2,6-Dinitrotoluene ..........................
56. Epichlorohydrin ..............................
57. Ethylbenzene .................................
58. Fluoranthene .................................
59. Fluorene ........................................
60. 1,2,3,4,6,7,8-Heptachlorodibenzofuran.
61. 1,2,3,4,7,8,9-Heptachlorodibenzofuran.
62. 1,2,3,4,6,7,8-Heptachloro-dibenzop-dioxin.
63. Hexachlorobenzene .......................
64. Hexachlorobutadiene .....................
65. Hexachlorocyclopentadiene ..........
66. 1,2,3,4,7,8-Hexachlorodibenzofuran.
67. 1,2,3,6,7,8-Hexachlorodibenzofuran.
68. 1,2,3,7,8,9-Hexachlorodibenzofuran.
69. 2,3,4,6,7,8-Hexachlorodibenzofuran.
70. 1,2,3,4,7,8-Hexachloro-dibenzo-pdioxin.
71. 1,2,3,6,7,8-Hexachloro-dibenzo-pdioxin.
72. 1,2,3,7,8,9-Hexachloro-dibenzo-pdioxin.
73. Hexachloroethane .........................
74. Indeno(1,2,3-c,d) pyrene ...............
75. Isophorone .....................................
76. Methylene chloride ........................
77. 2-Methyl-4,6-dinitrophenol .............
78. Naphthalene ..................................
79. Nitrobenzene .................................
80. 2-Nitrophenol .................................
81. 4-Nitrophenol .................................
82. N-Nitrosodimethylamine ................
83. N-Nitrosodi-n-propylamine .............
84. N-Nitrosodiphenylamine ................
85. Octachlorodibenzofuran ................
86. Octachlorodibenzo-p-dioxin ...........
87. 2,2′-oxybis(1-chloropropane) 12
[also known as bis(2-Chloro-1methylethyl) ether].
88. PCB–1016 .....................................
89. PCB–1221 .....................................
90. PCB–1232 .....................................
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Method
EPA 2 7
Standard methods
ASTM
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
HPLC ....................
GC/MS ..................
625.1, 1625B ........
604 .......................
625.1, 1625B ........
609.
625.1, 1625B ........
609.
625.1, 1625B ........
...............................
...............................
602 .......................
624.1, 1624B ........
610.
625.1, 1625B ........
610 .......................
610.
625.1, 1625B ........
610 .......................
1613B.
6410 B–2000 ........
6420 B–2000 ........
6410 B–2000.
...............................
...............................
See footnote 9, p. 27.
See footnote 9, p. 27.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
6410 B–2000 ........
...............................
...............................
6200 C–2011.
6200 B–2011 ........
...............................
...............................
...............................
See footnote 9, p. 27.
See footnote 3, p. 130.
See footnote 6, p. S102.
...............................
O–4127–96 13, O–4436–16.14
6410 B–2000 ........
6440 B–2005 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
6410 B–2000 ........
6440 B–2005 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
GC/MS ..................
1613B.
GC/MS ..................
1613B.
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC/MS ..................
612.
625.1, 1625B ........
612.
625.1, 1625B ........
612.
625.1 5, 1625B ......
1613B.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
6410 B–2000 ........
...............................
See footnote 9, p. 27; O–4127–96.13
6410 B–2000 ........
...............................
See footnote 9, p. 27; O–4127–96.13
GC/MS ..................
1613B.
GC/MS ..................
1613B.
GC/MS ..................
1613B.
GC/MS ..................
1613B.
GC/MS ..................
1613B.
GC/MS ..................
1613B.
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC/MS ..................
GC/MS ..................
GC ........................
612.
625.1, 1625B ........
610.
625.1, 1625B ........
610 .......................
609.
625.1, 1625B ........
601 .......................
624.1, 1624B ........
604 .......................
625.1, 1625B ........
610.
625.1, 1625B ........
610 .......................
609.
625.1, 1625B ........
...............................
604 .......................
625.1, 1625B ........
604 .......................
625.1, 1625B ........
607.
625.1 5, 1625B ......
607.
625.1 5, 1625B ......
607.
625.1 5, 1625B ......
1613B 10.
1613B 10.
611.
6410 B–2000 ........
...............................
See footnote 9, p. 27; O–4127–96.13
6410 B–2000 ........
6440 B–2005 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
6410
6200
6200
6420
6410
B–2000 ........
C–2011 ........
B–2011 ........
B–2000.
B–2000 ........
...............................
...............................
...............................
See footnote 9, p. 27.
See footnote 3, p. 130.
O–4127–96 13, O–4436–16.14
...............................
See footnote 9, p. 27.
6410 B–2000 ........
6440 B–2005.
...............................
See footnote 9, p. 27.
6410 B–2000 ........
...............................
6420 B–2000.
6410 B–2000 ........
6420 B–2000.
6410 B–2000 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
...............................
See footnote 9, p. 27.
...............................
See footnote 9, p. 27.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
6410 B–2000 ........
...............................
See footnote 9, p. 27.
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
625.1,
608.3
625.1
608.3
625.1
608.3
6410 B–2000 ........
...............................
6410 B–2000.
...............................
6410 B–2000.
...............................
...............................
...............................
See footnote 9, p. 27.
See footnote 3, p. 43; See footnote.8
...............................
See footnote 3, p. 43; See footnote.8
...............................
See footnote 3, p. 43; See footnote.8
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....................
....................
....................
....................
....................
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TABLE IC—LIST OF APPROVED TEST PROCEDURES FOR NON-PESTICIDE ORGANIC COMPOUNDS—Continued
Parameter 1
91. PCB–1242 .....................................
92. PCB–1248 .....................................
93. PCB–1254 .....................................
94. PCB–1260 .....................................
95. 1,2,3,7,8-Pentachlorodibenzofuran.
96. 2,3,4,7,8-Pentachlorodibenzofuran.
97. 1,2,3,7,8-Pentachloro-dibenzo-pdioxin.
98. Pentachlorophenol .........................
99. Phenanthrene ................................
100. Phenol .........................................
101. Pyrene .........................................
102. 2,3,7,8-Tetrachloro-dibenzofuran
103. 2,3,7,8-Tetrachloro-dibenzo-pdioxin.
104. 1,1,2,2-Tetrachloroethane ...........
105. Tetrachloroethene .......................
106. Toluene ........................................
107. 1,2,4-Trichlorobenzene ................
108. 1,1,1-Trichloroethane ..................
109. 1,1,2-Trichloroethane ..................
110. Trichloroethene ............................
111. Trichlorofluoromethane ................
112. 2,4,6-Trichlorophenol ...................
113. Vinyl chloride ...............................
114. Nonylphenol .................................
115. Bisphenol A (BPA) ......................
116. p-tert-Octylphenol (OP) ...............
117. Nonylphenol Monoethoxylate
(NP1EO).
118. Nonylphenol Diethoxylate
(NP2EO).
119. Adsorbable Organic Halides
(AOX).
120. Chlorinated Phenolics .................
Method
EPA 2 7
Standard methods
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC/MS ..................
625.1 ....................
608.3 ....................
625.1 ....................
608.3 ....................
625.1 ....................
608.3 ....................
625.1 ....................
608.3 ....................
625.1 ....................
1613B.
6410 B–2000.
...............................
6410 B–2000.
...............................
6410 B–2000.
...............................
6410 B–2000.
...............................
6410 B–2000.
GC/MS ..................
1613B.
GC/MS ..................
1613B.
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
HPLC ....................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
HPLC ....................
GC/MS ..................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
604 .......................
625.1, 1625B ........
610.
625.1, 1625B ........
610 .......................
604 .......................
625.1, 1625B ........
610.
625.1, 1625B ........
610 .......................
1613B 10.
613, 625.1 5a,
1613B.
601 .......................
624.1, 1624B ........
601 .......................
624.1, 1624B ........
602 .......................
624.1, 1624B ........
612 .......................
625.1, 1625B ........
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC ........................
GC/MS ..................
GC/MS ..................
GC/MS ..................
GC/MS ..................
GC/MS ..................
601 .......................
624.1, 1624B ........
601 .......................
624.1, 1624B ........
601 .......................
624.1, 1624B ........
601 .......................
624.1 ....................
604 .......................
625.1, 1625B ........
601 .......................
624.1, 1624B ........
...............................
...............................
...............................
...............................
6200 C–2011.
6200 B–2011 ........
6200 C–2011 ........
6200 B–2011 ........
6200 C–2011.
6200 B–2011 ........
6200 C–2011.
6200 B–2011 ........
6420 B–2000.
6410 B–2000 ........
6200 C–2011.
6200 B–2011 ........
...............................
...............................
...............................
...............................
GC/MS ..................
...............................
...............................
D7065–17.
Adsorption and
Coulometric Titration.
In Situ Acetylation
and GC/MS.
1650 11.
ASTM
Other
...............................
See footnote 3, p. 43; See footnote.8
...............................
See footnote 3, p. 43; See footnote.8
...............................
See footnote 3, p. 43; See footnote.8
...............................
See footnote 3, p. 43; See footnote.8
6420 B–2000 ........
6410 B–2000 ........
...............................
...............................
See footnote 3, p. 140.
See footnote 9, p. 27.
6410
6440
6420
6410
B–2000 ........
B–2005 ........
B–2000.
B–2000 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
...............................
See footnote 9, p. 27.
6410 B–2000 ........
6440 B–2005 ........
...............................
D4657–92 (98).
See footnote 9, p. 27.
6200 C–2011 ........
6200 B–2011 ........
6200 C–2011 ........
6200 B–2011 ........
6200 C–2011.
6200 B–2011 ........
...............................
6410 B–2000 ........
...............................
...............................
...............................
...............................
See footnote 3, p. 130.
O–4127–96.13
See footnote 3, p. 130.
O–4127–96 13, O–4436–16.14
...............................
...............................
...............................
O–4127–96 13, O–4436–16.14
See footnote 3, p. 130.
See footnote 9, p. 27; O–4127–96 13,
O–4436–16.14
...............................
...............................
...............................
O–4127–96 13, O–4436–16.14
See footnote 3, p. 130.
O–4127–96 13, O–4436–16.14
...............................
O–4127–96 13, O–4436–16.14
...............................
O–4127–96.13
...............................
See footnote 9, p. 27.
...............................
D7065–17.
D7065–17.
D7065–17.
D7065–17.
O–4127–96 13, O–4436–16.14
1653 11.
Table IC notes:
1 All parameters are expressed in micrograms per liter (μg/L) except for Method 1613B, in which the parameters are expressed in picograms per liter (pg/L).
2 The full text of Methods 601–613, 1613B, 1624B, and 1625B are provided at appendix A, Test Procedures for Analysis of Organic Pollutants. The standardized
test procedure to be used to determine the method detection limit (MDL) for these test procedures is given at appendix B of this part, Definition and Procedure for the
Determination of the Method Detection Limit. These methods are available at: https://www.epa.gov/cwa-methods as individual PDF files.
3 Methods for Benzidine: Chlorinated Organic Compounds, Pentachlorophenol and Pesticides in Water and Wastewater. September 1978. U.S. EPA.
4 Method 624.1 may be used for quantitative determination of acrolein and acrylonitrile, provided that the laboratory has documentation to substantiate the ability to
detect and quantify these analytes at levels necessary to comply with any associated regulations. In addition, the use of sample introduction techniques other than
simple purge-and-trap may be required. QC acceptance criteria from Method 603 should be used when analyzing samples for acrolein and acrylonitrile in the absence
of such criteria in Method 624.1.
5 Method 625.1 may be extended to include benzidine, hexachlorocyclopentadiene, N-nitrosodimethylamine, N-nitrosodi-n-propylamine, and N-nitrosodiphenylamine.
However, when they are known to be present, Methods 605, 607, and 612, or Method 1625B, are preferred methods for these compounds.
5a Method 625.1 screening only.
6 Selected Analytical Methods Approved and Cited by the United States Environmental Protection Agency, Supplement to the 15th Edition of Standard Methods for
the Examination of Water and Wastewater. 1981. American Public Health Association (APHA).
7 Each analyst must make an initial, one-time demonstration of their ability to generate acceptable precision and accuracy with Methods 601–603, 1624B, and
1625B in accordance with procedures in Section 8.2 of each of these methods. Additionally, each laboratory, on an on-going basis must spike and analyze 10% (5%
for Methods 624.1 and 625.1 and 100% for methods 1624B and 1625B) of all samples to monitor and evaluate laboratory data quality in accordance with Sections
8.3 and 8.4 of these methods. When the recovery of any parameter falls outside the quality control (QC) acceptance criteria in the pertinent method, analytical results
for that parameter in the unspiked sample are suspect. The results should be reported but cannot be used to demonstrate regulatory compliance. If the method does
not contain QC acceptance criteria, control limits of ± three standard deviations around the mean of a minimum of five replicate measurements must be used. These
quality control requirements also apply to the Standard Methods, ASTM Methods, and other methods cited.
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8 Organochlorine
Pesticides and PCBs in Wastewater Using EmporeTM Disk. Revised October 28, 1994. 3M Corporation.
O–3116–87 is in Open File Report 93–125, Methods of Analysis by U.S. Geological Survey National Water Quality Laboratory—Determination of Inorganic
and Organic Constituents in Water and Fluvial Sediments. 1993. USGS.
10 Analysts may use Fluid Management Systems, Inc. Power-Prep system in place of manual cleanup provided the analyst meets the requirements of Method
1613B (as specified in Section 9 of the method) and permitting authorities. Method 1613, Revision B, Tetra- through Octa-Chlorinated Dioxins and Furans by Isotope
Dilution HRGC/HRMS. Revision B, 1994. U.S. EPA. The full text of this method is provided in appendix A to this part and at https://www.epa.gov/cwa-methods/approved-cwa-test-methods-organic-compounds.
11 Method 1650, Adsorbable Organic Halides by Adsorption and Coulometric Titration. Revision C, 1997 U.S. EPA. Method 1653, Chlorinated Phenolics in Wastewater by In Situ Acetylation and GCMS. Revision A, 1997 U.S. EPA. The full text for both of these methods is provided at appendix A in part 430 of this chapter, The
Pulp, Paper, and Paperboard Point Source Category.
12 The compound was formerly inaccurately labeled as 2,2′-oxybis(2-chloropropane) and bis(2-chloroisopropyl) ether. Some versions of Methods 611, and 1625 inaccurately list the analyte as ‘‘bis(2-chloroisopropyl)ether,’’ but use the correct CAS number of 108–60–1.
13 Method O–4127–96, U.S. Geological Survey Open-File Report 97–829, Methods of analysis by the U.S. Geological Survey National Water Quality Laboratory—
Determination of 86 volatile organic compounds in water by gas chromatography/mass spectrometry, including detections less than reporting limits,1998, USGS.
14 Method O–4436–16 U.S. Geological Survey Techniques and Methods, book 5, chap. B12, Determination of heat purgeable and ambient purgeable volatile organic compounds in water by gas chromatography/mass spectrometry, 2016, USGS.
9 Method
*
*
*
*
*
TABLE IH—LIST OF APPROVED MICROBIOLOGICAL METHODS FOR AMBIENT WATER
Parameter and units
Method 1
EPA
Standard methods
AOAC, ASTM, USGS
Other
Bacteria
1. Coliform (fecal),
number per 100 mL.
2. Coliform (total), number per 100 mL.
3. E. coli, number per
100 mL.
4. Fecal streptococci,
number per 100 mL.
5. Enterococci, number
per 100 mL.
Most Probable Number (MPN), 5 tube,
3 dilution, or.
Membrane filter
(MF) 2, single step.
MPN, 5 tube, 3 dilution, or.
MF 2, single step or
two step.
MF 2 with enrichment
p.
132 3
.....................
p. 124 3 .....................
9222 D–2015 26 ........
p. 114 3 .....................
9221 B–2014.
Single step ................
MPN, 5 tube, 3 dilution, or.
MF 2, or .....................
Plate count ...............
MPN 5 7, multiple
tube/multiple well,
or.
MF 2 5 6 7 two step, or
Single step, or ..........
Plate count ...............
B–0050–85 4.
.....................
9222 B–2015 27 ........
B–0025–85 4.
p. 111 3 .....................
9222 (B + B.4e)—
2015 27.
9221 B.3–2014/9221
F–2014 10 12 32.
9223 B–2016 11 ........
991.15 9 ....................
p.
108 3
MPN 5 7 13,
multiple
tube, or.
Multiple tube/multiple
well, or.
MF 2 5 6 7, two step, or
9221 E–2014, 9221
F.2–2014 32.
1103.1 18 ...................
1603 19, 1604 20 ........
p. 139 3 .....................
p. 136 3 .....................
p. 143 3.
1106.1 22 ...................
1600 23 ......................
p. 143 3.
Colilert® 11 15, Colilert-18®.11 14 15
D5392–93 8.
9222 B–2015/9222 I–
2015 17, 9213 D–
2007.
m-ColiBlue24® 16, KwikCountTM EC.28 29
9230 B–2013.
9230 C–2013 30 ........
B–0055–85 4.
9230 D–2013 ............
D6503–99 8 ...............
9230 C–2013 30 ........
9230 C–2013 30.
D5259–92 8.
Enterolert®.11 21
Protozoa
6. Cryptosporidium ......
Filtration/IMS/FA .......
7. Giardia .....................
Filtration/IMS/FA .......
1622 24, 1623 25,
1623.1 25 31.
1623 25, 1623.1 25 31.
Table 1H notes:
1 The method must be specified when results are reported.
2 A 0.45-μm membrane filter (MF) or other pore size certified by the manufacturer to fully retain organisms to be cultivated and to be free of extractables which
could interfere with their growth.
3 Microbiological Methods for Monitoring the Environment, Water and Wastes. EPA/600/8–78/017. 1978. US EPA.
4 U.S. Geological Survey Techniques of Water-Resource Investigations, Book 5, Laboratory Analysis, Chapter A4, Methods for Collection and Analysis of Aquatic
Biological and Microbiological Samples. 1989. USGS.
5 Tests must be conducted to provide organism enumeration (density). Select the appropriate configuration of tubes/filtrations and dilutions/volumes to account for
the quality, character, consistency, and anticipated organism density of the water sample.
6 When the MF method has not been used previously to test waters with high turbidity, large numbers of noncoliform bacteria, or samples that may contain organisms stressed by chlorine, a parallel test should be conducted with a multiple-tube technique to demonstrate applicability and comparability of results.
7 To assess the comparability of results obtained with individual methods, it is suggested that side-by-side tests be conducted across seasons of the year with the
water samples routinely tested in accordance with the most current Standard Methods for the Examination of Water and Wastewater or EPA alternate test procedure
(ATP) guidelines.
8 Annual Book of ASTM Standards—Water and Environmental Technology. Section 11.02. 2000, 1999, 1996. ASTM International.
9 Official Methods of Analysis of AOAC International, 16th Edition, Volume I, Chapter 17. 1995. AOAC International.
10 The multiple-tube fermentation test is used in 9221B.3–2014. Lactose broth may be used in lieu of lauryl tryptose broth (LTB), if at least 25 parallel tests are conducted between this broth and LTB using the water samples normally tested, and this comparison demonstrates that the false-positive rate and false-negative rate for
total coliform using lactose broth is less than 10 percent. No requirement exists to run the completed phase on 10 percent of all total coliform-positive tubes on a seasonal basis.
11 These tests are collectively known as defined enzyme substrate tests.
12 After prior enrichment in a presumptive medium for total coliform using 9221B.3–2014, all presumptive tubes or bottles showing any amount of gas, growth or
acidity within 48 h ± 3 h of incubation shall be submitted to 9221F–2014. Commercially available EC–MUG media or EC media supplemented in the laboratory with
50 μg/mL of MUG may be used.
13 Samples shall be enumerated by the multiple-tube or multiple-well procedure. Using multiple-tube procedures, employ an appropriate tube and dilution configuration of the sample as needed and report the Most Probable Number (MPN). Samples tested with Colilert® may be enumerated with the multiple-well procedures,
Quanti-Tray® or Quanti-Tray®/2000, and the MPN calculated from the table provided by the manufacturer.
14 Colilert-18® is an optimized formulation of the Colilert® for the determination of total coliforms and E. coli that provides results within 18 h of incubation at 35 °C,
rather than the 24 h required for the Colilert® test, and is recommended for marine water samples.
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Federal Register / Vol. 84, No. 204 / Tuesday, October 22, 2019 / Proposed Rules
of the Colilert®, Colilert-18®, Quanti-Tray®, and Quanti-Tray®/2000 may be obtained from IDEXX Laboratories Inc.
description of the mColiBlue24® test may be obtained from Hach Company.
17 Subject coliform positive samples determined by 9222B–2015 or other membrane filter procedure to 9222I–2015 using NA–MUG media.
18 Method 1103.1: Escherichia coli (E. coli) in Water by Membrane Filtration Using membrane-Thermotolerant Escherichia coli Agar (mTEC), EPA–821–R–10–002.
March 2010. US EPA.
19 Method 1603: Escherichia coli (E. coli) in Water by Membrane Filtration Using Modified membrane-Thermotolerant Escherichia coli Agar (Modified mTEC), EPA–
821–R–14–010. September 2014. US EPA.
20 Method 1604: Total Coliforms and Escherichia coli (E. coli) in Water by Membrane Filtration by Using a Simultaneous Detection Technique (MI Medium), EPA
821–R–02–024. September 2002. US EPA.
21 A description of the Enterolert® test may be obtained from IDEXX Laboratories Inc.
22 Method 1106.1: Enterococci in Water by Membrane Filtration Using membrane-Enterococcus-Esculin Iron Agar (mE–EIA), EPA–821–R–09–015. December 2009.
US EPA.
23 Method 1600: Enterococci in Water by Membrane Filtration Using membrane-Enterococcus Indoxyl-b-D-Glucoside Agar (mEI), EPA–821–R–14–011. September
2014. US EPA.
24 Method 1622 uses a filtration, concentration, immunomagnetic separation of oocysts from captured material, immunofluorescence assay to determine concentrations, and confirmation through vital dye staining and differential interference contrast microscopy for the detection of Cryptosporidium. Method 1622: Cryptosporidium
in Water by Filtration/IMS/FA, EPA–821–R–05–001. December 2005. US EPA.
25 Methods 1623 and 1623.1 use a filtration, concentration, immunomagnetic separation of oocysts and cysts from captured material, immunofluorescence assay to
determine concentrations, and confirmation through vital dye staining and differential interference contrast microscopy for the simultaneous detection of
Cryptosporidium and Giardia oocysts and cysts. Method 1623: Cryptosporidium and Giardia in Water by Filtration/IMS/FA. EPA–821–R–05–002. December 2005. US
EPA. Method 1623.1: Cryptosporidium and Giardia in Water by Filtration/IMS/FA. EPA 816–R–12–001. January 2012. US EPA.
26 On a monthly basis, at least ten blue colonies from positive samples must be verified using Lauryl Tryptose Broth and EC broth, followed by count adjustment
based on these results; and representative non-blue colonies should be verified using Lauryl Tryptose Broth. Where possible, verifications should be done from randomized sample sources.
27 On a monthly basis, at least ten sheen colonies from positive samples must be verified using Lauryl Tryptose Broth and brilliant green lactose bile broth, followed
by count adjustment based on these results; and representative non-sheen colonies should be verified using Lauryl Tryptose Broth. Where possible, verifications
should be done from randomized sample sources.
28 A description of KwikCountTM EC may be obtained from Micrology Laboratories LLC.
29 Approved for the analyses of E. coli in freshwater only.
30 Verification of colonies by incubation of BHI agar at 10 ± 0.5 °C for 48 ± 3 h is optional. As per the Errata to the 23rd Edition of Standard Methods for the Examination of Water and Wastewater ‘‘Growth on a BHI agar plate incubated at 10 ± 0.5 °C for 48 ± 3 h is further verification that the colony belongs to the genus
Enterococcus.’’
31 Method 1623.1 includes updated acceptance criteria for IPR, OPR, and MS/MSD and clarifications and revisions based on the use of Method 1623 for years and
technical support questions.
32 9221 F.2–2014 This procedure allows for simultaneous detection of E. coli and thermotolerant coliforms by adding inverted vials to EC–MUG; the inverted vials
collect gas produced by thermotolerant coliforms.
15 Descriptions
16 A
*
*
*
*
*
(b) Certain material is incorporated by
reference into this section with the
approval of the Director of the Federal
Register under 5 U.S.C. 552(a) and 1
CFR part 51. All approved material may
be inspected at EPA’s Water Docket,
EPA West, 1301 Constitution Avenue
NW, Room 3334, Washington, DC
20004, (Telephone: 202–566–2426) and
is available from the sources listed
below. It is also available for inspection
at National Archives and Records
Administration (NARA). For
information on the availability of this
material at NARA, email fedreg.legal@
nara.gov, or go to: www.archives.gov/
federal-register/cfr/ibr-locations.html.
*
*
*
*
*
(8) Office of Water, U.S.
Environmental Protection Agency,
Washington, DC (US EPA). Available at
https://www.epa.gov/cwa-methods
*
*
*
*
*
(ix) 1623.1: Cryptosporidium and
Giardia in Water by Filtration/IMS/FA.
EPA 816–R–12–001. January 2012. US
EPA, Table IH, Note 25.
(x) Method 1627, Kinetic Test Method
for the Prediction of Mine Drainage
Quality. December 2011. EPA–821–R–
09–002. Table IB, Note 69.
(xi) Method 1664, n-Hexane
Extractable Material (HEM; Oil and
Grease) and Silica Gel Treated n-Hexane
Extractable Material (SGT–HEM;
Nonpolar Material) by Extraction and
Gravimetry.
Revision A, February 1999. EPA–821–
R–98–002. Table IB, Notes 38 and 42.
VerDate Sep<11>2014
17:41 Oct 21, 2019
Jkt 250001
(xii) Method 1664, n-Hexane
Extractable Material (HEM; Oil and
Grease) and Silica Gel Treated n-Hexane
Extractable Material (SGT–HEM;
Nonpolar Material) by Extraction and
Gravimetry, Revision B, February 2010.
EPA–821–R–10–001. Table IB, Notes 38
and 42.
(xiii) Method 1669, Sampling
Ambient Water for Trace Metals at EPA
Water Quality Criteria Levels. July 1996.
Table IB, Note 43.
(xiv) Method 1680: Fecal Coliforms in
Sewage Sludge (Biosolids) by MultipleTube Fermentation using Lauryl
Tryptose Broth (LTB) and EC Medium.
September 2014. EPA–821–R–14–
009.Table IA, Note 15.
(xv) Method 1681: Fecal Coliforms in
Sewage Sludge (Biosolids) by MultipleTube Fermentation using A–1 Medium.
July 2006. EPA 821–R–06–013. Table
IA, Note 20.
(xvi) Method 1682: Salmonella in
Sewage Sludge (Biosolids) by Modified
Semisolid Rappaport-Vassiliadis
(MSRV) Medium. September 2014. EPA
821–R–14–012. Table IA, Note 23.
*
*
*
*
*
(10) * * *
(xiv) 2540, solids. 2015. Table IB.
*
*
*
*
*
(xxxix) 4500-CN¥, Cyanide. 2016.
Table IB.
*
*
*
*
*
(xliv) 4500-NO3¥, Nitrogen (Nitrate).
2016. Table IB.
*
*
*
*
*
(xlvi) 4500-O, Oxygen (Dissolved).
2016. Table IB.
*
*
*
*
*
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(lii) 5210, Biochemical Oxygen
Demand (BOD). 2016. Table IB.
*
*
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*
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(liv) 5310, Total Organic Carbon
(TOC). 2014. Table IB.
*
*
*
*
*
(lxvii) 9221 Multiple-Tube
Fermentation Technique for Members of
the Coliform Group. 2014. Table IA,
Notes 12 and 14; Table IH, Notes 10 and
12.
(lxviii) 9222, Membrane Filter
Technique for Members of the Coliform
Group. 2015. Table IA; Table IH, Note
17.
(lxix) 9223 Enzyme Substrate
Coliform Test. 2016. Table IA; Table IH.
(lxx) 9230 Fecal Enterococcus/
Streptococcus Groups. 2013. Table IA;
Table IH.
*
*
*
*
*
(15) * * *
(v) ASTM D511–14, Standard Test
Methods for Calcium and Magnesium in
Water. November 2014. Table IB.
(vi) ASTM D512–12, Standard Test
Methods for Chloride Ion in Water. July
2012. Table IB.
*
*
*
*
*
(viii) ASTM D516–16, Standard Test
Method for Sulfate Ion in Water, June
2016. Table IB.
(ix) ASTM D858–17, Standard Test
Methods for Manganese in Water. June
2017. Table IB.
(x) ASTM D859–16, Standard Test
Method for Silica in Water. June 2016.
Table IB.
(xi) ASTM D888–12, Standard Test
Methods for Dissolved Oxygen in Water.
March 2012. Table IB.
E:\FR\FM\22OCP3.SGM
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Federal Register / Vol. 84, No. 204 / Tuesday, October 22, 2019 / Proposed Rules
(xii) ASTM D1067–16, Standard Test
Methods for Acidity or Alkalinity of
Water. June 2016. Table IB.
(xiii) ASTM D1068–15, Standard Test
Methods for Iron in Water. October
2015. Table IB.
*
*
*
*
*
(xv) ASTM D1126–17, Standard Test
Method for Hardness in Water.
December 2017. Table IB.
(xvi) ASTM D1179–16, Standard Test
Methods for Fluoride Ion in Water. June
2016. Table IB.
(xvii) ASTM D1246–16, Standard Test
Method for Bromide Ion in Water. June
2016. Table IB.
(xviii) ASTM D1252–06 (Reapproved
2012), Standard Test Methods for
Chemical Oxygen Demand (Dichromate
Oxygen Demand) of Water. June 2012.
Table IB.
(xix) ASTM D1253–14, Standard Test
Method for Residual Chlorine in Water.
February 2014. Table IB.
*
*
*
*
*
(xxi) ASTM D1426–15, Standard Test
Methods for Ammonia Nitrogen in
Water. April 2015. Table IB.
(xxii) ASTM D1687–17, Standard Test
Methods for Chromium in Water. July
2017. Table IB.
(xxiii) ASTM D1688–17, Standard
Test Methods for Copper in Water. July
2017. Table IB.
(xxiv) ASTM D1691–17, Standard
Test Methods for Zinc in Water. June
2017. Table IB.
(xxv) ASTM D1783–01 (Reapproved
2012), Standard Test Methods for
Phenolic Compounds in Water. August
2012. Table IB.
(xxvi) ASTM D1886–14, Standard
Test Methods for Nickel in Water.
November 2014. Table IB.
*
*
*
*
*
(xxxi) ASTM D2036–09 (Reapproved
2015), Standard Test Methods for
Cyanides in Water. July 2015. Table IB.
*
*
*
*
*
(xxxiv) ASTM D2972–15, Standard
Tests Method for Arsenic in Water.
March 2015. Table IB.
(xxxv) ASTM D3223–17, Standard
Test Method for Total Mercury in Water.
June 2017. Table IB.
*
*
*
*
*
(xxxvii) ASTM D3373–17, Standard
Test Method for Vanadium in Water.
June 2017. Table IB.
*
*
*
*
*
(xxxix) ASTM D3557–17, Standard
Test Method for Cadmium in Water.
June 2017. Table IB.
(xl) ASTM D3558–15, Standard Test
Method for Cobalt in Water. March
2015. Table IB.
(xli) ASTM D3559–15, Standard Test
Methods for Lead in Water. October
2015. Table IB.
VerDate Sep<11>2014
17:41 Oct 21, 2019
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(xlii) ASTM D3590–17, Standard Test
Methods for Total Kjeldahl Nitrogen in
Water. June 2017. Table IB.
(xliii) ASTM D3645–15, Standard Test
Methods for Beryllium in Water. March
2015. Table IB.
*
*
*
*
*
(xlv) ASTM D3859–15, Standard Test
Methods for Selenium in Water. April
2015. Table IB.
(xlvi) ASTM D3867–16, Standard Test
Method for Nitrite-Nitrate in Water.
June 2016. Table IB.
(xlvii) ASTM D4190–15, Standard
Test Method for Elements in Water by
Direct-Current Plasma Atomic Emission
Spectroscopy. March 2015. Table IB.
(xlviii) ASTM D4282–15, Standard
Test Method for Determination of Free
Cyanide in Water and Wastewater by
Microdiffusion. July 2015. Table IB.
(xlix) ASTM D4327–17, Standard Test
Method for Anions in Water by
Suppressed Ion Chromatography.
December 2017. Table IB.
(l) ASTM D4382–18, Standard Test
Method for Barium in Water, Atomic
Absorption Spectrophotometry,
Graphite Furnace. May 2018. Table IB.
*
*
*
*
*
(lii) ASTM D4658–15, Standard Test
Method for Sulfide Ion in Water. April
2015. Table IB.
*
*
*
*
*
(liv) ASTM D4839–03 (Reapproved
2017), Standard Test Method for Total
Carbon and Organic Carbon in Water by
Ultraviolet, or Persulfate Oxidation, or
Both, and Infrared Detection. December
2017. Table IB.
(lv) ASTM D5257–17, Standard Test
Method for Dissolved Hexavalent
Chromium in Water by Ion
Chromatography. December 2017. Table
IB.
*
*
*
*
*
(lviii) ASTM D5673–16, Standard Test
Method for Elements in Water by
Inductively Coupled Plasma—Mass
Spectrometry. February 2016. Table IB.
*
*
*
*
*
(lxi) ASTM. D6508–15, Standard Test
Method for Determination of Dissolved
Inorganic Anions in Aqueous Matrices
Using Capillary Ion Electrophoresis and
Chromate Electrolyte. October 2015.
Table IB, Note 54.
(lxii) ASTM. D6888–16, Standard Test
Method for Available Cyanide with
Ligand Displacement and Flow Injection
Analysis (FIA) Utilizing Gas Diffusion
Separation and Amperometric
Detection. June 2016. Table IB, Note 59.
(lxiii) ASTM. D6919–17, Standard
Test Method for Determination of
Dissolved Alkali and Alkaline Earth
Cations and Ammonium in Water and
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56619
Wastewater by Ion Chromatography.
June 2017. Table IB.
*
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*
*
(lxiv) ASTM. D7065–17, Standard
Test Method for Determination of
Nonylphenol, Bisphenol A, p-tertOctylphenol, Nonylphenol
Monoethoxylate and Nonylphenol
Diethoxylate in Environmental Waters
by Gas Chromatography Mass
Spectrometry. January 2018. Table IC.
(lxv) ASTM. D7237–15a, Standard
Test Method for Free Cyanide with Flow
Injection Analysis (FIA) Utilizing Gas
Diffusion Separation and Amperometric
Detection. June 2015. Table IB.
(lxvi) ASTM. D7284–13 (Reapproved
2017), Standard Test Method for Total
Cyanide in Water by Micro Distillation
followed by Flow Injection Analysis
with Gas Diffusion Separation and
Amperometric Detection. July 2017.
Table IB.
*
*
*
*
*
(lxviii) ASTM. D7511–12 (Reapproved
2017), Standard Test Method for Total
Cyanide by Segmented Flow Injection
Analysis, In-Line Ultraviolet Digestion
and Amperometric Detection. July 2017.
Table IB.
(lxix) ASTM. D7573–09 (Reapproved
2017), Standard Test Method for Total
Carbon and Organic Carbon in Water by
High Temperature Catalytic Combustion
and Infrared Detection, February 2017.
Table IB.
(lxx) ASTM D7781–14 Standard Test
Method for Nitrate-Nitrite in Water by
Nitrate Reductase, May 2014. Table IB.
*
*
*
*
*
(19) FIAlab Instruments, Inc., 334
2151 N Northlake Way, Seattle, WA
98103. Telephone: 425–376–0450
(i) Method 100, Determination of
Inorganic Ammonia by Continuous
Flow Gas Diffusion and Fluorescence
Detector Analysis, April 4, 2018. Table
IB, Note 82.
(ii) [Reserved]
*
*
*
*
*
(26) MACHEREY-NAGEL GmbH and
Co., 2850 Emrick Blvd., Bethlehem, PA
18020. Telephone: 888–321–6224.
(i) Method 036/038 NANOCOLOR®
COD LR/HR, Spectrophotometric
Measurement of Chemical Oxygen
Demand in Water and Wastewater,
Revision 1.5, May, 2018. Table IB, Note
83.
(ii) [Reserved]
(27) Micrology Laboratories, LLC,
1303 Eisenhower Drive, Goshen, IN
46526. Telephone: 574–533–3351.
(i) KwikCountTM EC Medium E. coli
enzyme substrate test, Rapid Detection
of E. coli in Beach Water By
KwikCountTM EC Membrane Filtration.
2014. Table IH, Notes 28 and 29.
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(ii) [Reserved]
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(38) * * *
(ii) Determination of Heat Purgeable
and Ambient Purgeable Volatile Organic
Compounds in Water by Gas
Chromatography/Mass Spectrometry.
Chapter 12 of Section B, Methods of the
National Water Quality Laboratory, of
Book 5, Laboratory Analysis. 2016.
(iii) Methods for Determination of
Inorganic Substances in Water and
Fluvial Sediments, editors, Techniques
of Water-Resources Investigations of the
U.S. Geological Survey, Book 5, Chapter
A1. 1979. Table IB, Note 8.
(iv) Methods for Determination of
Inorganic Substances in Water and
Fluvial Sediments, Techniques of
Water-Resources Investigations of the
U.S. Geological Survey, Book 5, Chapter
A1. 1989. Table IB, Notes 2 and 79.
(v) Methods for the Determination of
Organic Substances in Water and
Fluvial Sediments. Techniques of
Water-Resources Investigations of the
U.S. Geological Survey, Book 5, Chapter
A3. 1987. Table IB, Note 24; Table ID,
Note 4.
(vi) OFR 76–177, Selected Methods of
the U.S. Geological Survey of Analysis
of Wastewaters. 1976. Table IE, Note 2.
(vii) OFR 91–519, Methods of
Analysis by the U.S. Geological Survey
National Water Quality Laboratory—
Determination of Organonitrogen
Herbicides in Water by Solid-Phase
Extraction and Capillary-Column Gas
Chromatography/Mass Spectrometry
With Selected-Ion Monitoring. 1992.
Table ID, Note 14.
(viii) OFR 92–146, Methods of
Analysis by the U.S. Geological Survey
National Water Quality Laboratory—
Determination of Total Phosphorus by a
Kjeldahl Digestion Method and an
Automated Colorimetric Finish That
Includes Dialysis. 1992. Table IB, Note
48.
(ix) OFR 93–125, Methods of Analysis
by the U.S. Geological Survey National
Water Quality Laboratory—
Determination of Inorganic and Organic
Constituents in Water and Fluvial
Sediments. 1993. Table IB, Note 51 and
80; Table IC, Note 9.
(x) OFR 93–449, Methods of Analysis
by the U.S. Geological Survey National
*
Water Quality Laboratory—
Determination of Chromium in Water by
Graphite Furnace Atomic Absorption
Spectrophotometry. 1993. Table IB,
Note 46.
(xi) OFR 94–37, Methods of Analysis
by the U.S. Geological Survey National
Water Quality Laboratory—
Determination of Triazine and Other
Nitrogen-containing Compounds by Gas
Chromatography with Nitrogen
Phosphorus Detectors. 1994. Table ID,
Note 9.
(xii) OFR 95–181, Methods of
Analysis by the U.S. Geological Survey
National Water Quality Laboratory—
Determination of Pesticides in Water by
C–18 Solid-Phase Extraction and
Capillary-Column Gas Chromatography/
Mass Spectrometry With Selected-Ion
Monitoring. 1995. Table ID, Note 11.
(xiii) OFR 97–198, Methods of
Analysis by the U.S. Geological Survey
National Water Quality Laboratory—
Determination of Molybdenum in Water
by Graphite Furnace Atomic Absorption
Spectrophotometry. 1997. Table IB,
Note 47.
(xiv) OFR 97–829, Methods of
Analysis by the U.S. Geological Survey
National Water Quality Laboratory—
Determination of 86 Volatile Organic
Compounds in Water by Gas
Chromatography/Mass Spectrometry,
Including Detections Less Than
Reporting Limits. 1999. Table IC, Note
13.
(xv) OFR 98–165, Methods of
Analysis by the U.S. Geological Survey
National Water Quality Laboratory—
Determination of Elements in WholeWater Digests Using Inductively
Coupled Plasma-Optical Emission
Spectrometry and Inductively Coupled
Plasma-Mass Spectrometry. 1998. Table
IB, Notes 50 and 81.
(xvi) OFR 98–639, Methods of
Analysis by the U.S. Geological Survey
National Water Quality Laboratory—
Determination of Arsenic and Selenium
in Water and Sediment by Graphite
Furnace—Atomic Absorption
Spectrometry. 1999. Table IB, Note 49.
(xvii) OFR 00–170, Methods of
Analysis by the U.S. Geological Survey
National Water Quality Laboratory—
Determination of Ammonium Plus
Organic Nitrogen by a Kjeldahl
Digestion Method and an Automated
Photometric Finish that Includes Digest
Cleanup by Gas Diffusion. 2000. Table
IB, Note 45.
(xviii) Techniques and Methods Book
5–B1, Determination of Elements in
Natural-Water, Biota, Sediment and Soil
Samples Using Collision/Reaction Cell
Inductively Coupled Plasma-Mass
Spectrometry. Chapter 1, Section B,
Methods of the National Water Quality
Laboratory, Book 5, Laboratory
Analysis. 2006. Table IB, Note 70.
(xix) U.S. Geological Survey
Techniques of Water-Resources
Investigations, Book 5, Laboratory
Analysis, Chapter A4, Methods for
Collection and Analysis of Aquatic
Biological and Microbiological Samples.
1989. Table IA, Note 4; Table IH, Note
4.
(xx) Water-Resources Investigation
Report 01–4098, Methods of Analysis by
the U.S. Geological Survey National
Water Quality Laboratory—
Determination of Moderate-Use
Pesticides and Selected Degradates in
Water by C–18 Solid-Phase Extraction
and Gas Chromatography/Mass
Spectrometry. 2001. Table ID, Note 13.
(xxi) Water-Resources Investigations
Report 01–4132, Methods of Analysis by
the U.S. Geological Survey National
Water Quality Laboratory—
Determination of Organic Plus Inorganic
Mercury in Filtered and Unfiltered
Natural Water With Cold Vapor-Atomic
Fluorescence Spectrometry. 2001. Table
IB, Note 71.
(xxii) Water-Resources Investigation
Report 01–4134, Methods of Analysis by
the U.S. Geological Survey National
Water Quality Laboratory—
Determination of Pesticides in Water by
Graphitized Carbon-Based Solid-Phase
Extraction and High-Performance Liquid
Chromatography/Mass Spectrometry.
2001. Table ID, Note 12.
(xxiii) Water Temperature—
Influential Factors, Field Measurement
and Data Presentation, Techniques of
Water-Resources Investigations of the
U.S. Geological Survey, Book 1, Chapter
D1. 1975. Table IB, Note 32.
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(e) * * *
TABLE II—REQUIRED CONTAINERS, PRESERVATION TECHNIQUES, AND HOLDING TIMES
Container 1
Parameter No./name
Preservation 2 3
Maximum holding time 4
Table IA—Bacterial Tests
1–5. Coliform, total, fecal, and E.
coli.
6. Fecal streptococci ......................
7. Enterococci ................................
VerDate Sep<11>2014
17:41 Oct 21, 2019
PA, G ............................................
Cool, <10 °C, 0.008% Na2S2O3 5
8 hours.22 23
PA, G ............................................
PA, G ............................................
Cool, <10 °C, 0.008% Na2S2O3 5
Cool, <10 °C, 0.008% Na2S2O3 5
8 hours.22
8 hours.22
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TABLE II—REQUIRED CONTAINERS, PRESERVATION TECHNIQUES, AND HOLDING TIMES—Continued
Parameter No./name
Container 1
Preservation 2 3
8. Salmonella .................................
PA, G ............................................
Maximum holding time 4
Cool, <10 °C, 0.008% Na2S2O3 5
8 hours.22
Table IA—Aquatic Toxicity Tests
9–12. Toxicity, acute and chronic ..
P, FP, G ........................................
Cool, ≤6 °C 16 ...............................
36 hours.
Table IB—Inorganic Tests
1. Acidity ........................................
2. Alkalinity .....................................
4. Ammonia ....................................
9. Biochemical oxygen demand .....
10. Boron .......................................
11. Bromide ...................................
14. Biochemical oxygen demand,
carbonaceous.
15. Chemical oxygen demand .......
16. Chloride ...................................
17. Chlorine, total residual .............
21. Color ........................................
23–24. Cyanide, total or available
(or CATC) and free.
P,
P,
P,
P,
P,
P,
P,
FP, G ........................................
FP, G ........................................
FP, G ........................................
FP, G ........................................
FP, or Quartz ...........................
FP, G ........................................
FP G .........................................
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18, H2SO4 to pH <2 ...
Cool, ≤6 °C 18 ...............................
HNO3 to pH <2 .............................
None required ...............................
Cool, ≤6 °C 18 ...............................
14 days.
14 days.
28 days.
48 hours.
6 months.
28 days.
48 hours.
P,
P,
P,
P,
P,
FP, G ........................................
FP, G ........................................
G ..............................................
FP, G ........................................
FP, G ........................................
28 days.
28 days.
Analyze within 15 minutes.
48 hours.
14 days.
25.
27.
28.
31,
P
P,
P,
P,
...................................................
FP, G ........................................
FP, G ........................................
FP, G ........................................
Cool, ≤6 °C 18, H2SO4 to pH <2 ...
None required ...............................
None required ...............................
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18, NaOH to pH
>10 5 6, reducing agent if oxidizer present.
None required ...............................
HNO3 or H2SO4 to pH <2 ............
None required ...............................
Cool, ≤6 °C 18, H2SO4 to pH <2 ...
Fluoride ....................................
Hardness .................................
Hydrogen ion (pH) ...................
43. Kjeldahl and organic N ......
28 days.
6 months.
Analyze within 15 minutes.
28 days.
Table IB—Metals 7
18. Chromium VI ............................
35. Mercury (CVAA) .......................
35. Mercury (CVAFS) ....................
3, 5–8, 12, 13, 19, 20, 22, 26, 29,
30, 32–34, 36, 37, 45, 47, 51,
52, 58–60, 62, 63, 70–72, 74,
75. Metals, except boron, chromium VI, and mercury.
38. Nitrate ......................................
39. Nitrate-nitrite ............................
40. Nitrite .......................................
41. Oil and grease .........................
P, FP, G ........................................
P, FP, G ........................................
FP, G; and FP-lined cap 17 ...........
P, FP, G ........................................
Cool, ≤6 °C 18, pH = 9.3¥9.7 20 ...
HNO3 to pH <2 .............................
5 mL/L 12N HCl or 5 mL/L BrCl 17
HNO3 to pH <2, or at least 24
hours prior to analysis 19.
28 days.
28 days.
90 days.17
6 months.
P,
P,
P,
G
48
28
48
28
42. Organic Carbon .......................
P, FP, G ........................................
44. Orthophosphate .......................
P, FP, G ........................................
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18, H2SO4 to pH <2 ...
Cool, ≤6 °C 18 ...............................
Cool to ≤6 °C 18, HCl or H2SO4 to
pH <2.
Cool to ≤6 °C 18, HCl, H2SO4, or
H3PO4 to pH <2.
Cool, to ≤6 °C 18 24 .......................
46.
47.
48.
49.
50.
53.
54.
55.
56.
57.
61.
64.
65.
66.
Oxygen, Dissolved Probe ........
Winkler .....................................
Phenols ....................................
Phosphorus (elemental) ...........
Phosphorus, total .....................
Residue, total ...........................
Residue, Filterable (TDS) ........
Residue, Nonfilterable (TSS) ...
Residue, Settleable .................
Residue, Volatile ......................
Silica ........................................
Specific conductance ...............
Sulfate ......................................
Sulfide ......................................
G, Bottle and top ..........................
G, Bottle and top ..........................
G ...................................................
G ...................................................
P, FP, G ........................................
P, FP, G ........................................
P, FP, G ........................................
P, FP, G ........................................
P, FP, G ........................................
P, FP, G ........................................
P or Quartz ...................................
P, FP, G ........................................
P, FP, G ........................................
P, FP, G ........................................
67.
68.
69.
73.
Sulfite .......................................
Surfactants ...............................
Temperature ............................
Turbidity ...................................
P,
P,
P,
P,
FP, G ........................................
FP, G ........................................
FP, G ........................................
...................................................
FP,
FP,
FP,
FP,
G
G
G
G
........................................
........................................
........................................
........................................
None required ...............................
Fix on site and store in dark ........
Cool, ≤6 °C 18, H2SO4 to pH <2 ...
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18, H2SO4 to pH <2 ...
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18 ...............................
Cool, ≤6 °C 18, add zinc acetate
plus sodium hydroxide to pH >9.
None required ...............................
Cool, ≤6 °C 18 ...............................
None required ...............................
Cool, ≤6 °C 18 ...............................
hours.
days.
hours.
days.
28 days.
Filter within 15 minutes; Analyze
within 48 hours.
Analyze within 15 minutes.
8 hours.
28 days.
48 hours.
28 days.
7 days.
7 days.
7 days.
48 hours.
7 days.
28 days.
28 days.
28 days.
7 days.
Analyze within 15 minutes.
48 hours.
Analyze within 15 minutes.
48 hours.
Table IC—Organic Tests 8
13, 18–20, 22, 24, 25, 27, 28, 34–
37, 39–43, 45–47, 56, 76, 104,
105, 108–111, 113. Purgeable
Halocarbons.
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TABLE II—REQUIRED CONTAINERS, PRESERVATION TECHNIQUES, AND HOLDING TIMES—Continued
Parameter No./name
Container 1
Preservation 2 3
26. 2-Chloroethylvinyl ether ...........
6, 57, 106. Purgeable aromatic hydrocarbons.
3, 4. Acrolein and acrylonitrile .......
G, FP-lined septum ......................
G, FP-lined septum ......................
23, 30, 44, 49, 53, 77, 80, 81, 98,
100, 112. Phenols 11.
7, 38. Benzidines 11 12 ....................
14, 17, 48, 50–52. Phthalate
esters 11.
82–84. Nitrosamines 11 14 ..............
G, FP-lined cap ............................
Cool, ≤6 °C 18, 0.008% Na2S2O3 5
Cool, ≤6 °C 18, 0.008%
Na2S2O3 5, HCl to pH 2 9.
Cool, ≤6 °C 18, 0.008% Na2S2O3,
pH to 4–5 10.
Cool, ≤6 °C 18, 0.008% Na2S2O3
G, FP-lined cap ............................
G, FP-lined cap ............................
Cool, ≤6 °C 18, 0.008% Na2S2O3 5
Cool, ≤6 °C 18 ...............................
G, FP-lined cap ............................
88–94. PCBs 11 ..............................
G, FP-lined cap ............................
Cool, ≤6 °C 18, store in dark,
0.008% Na2S2O3 5.
Cool, ≤6 °C 18 ...............................
54, 55, 75, 79. Nitroaromatics and
isophorone 11.
1, 2, 5, 8–12, 32, 33, 58, 59, 74,
78, 99, 101. Polynuclear aromatic hydrocarbons 11.
15, 16, 21, 31, 87. Haloethers 11 ...
G, FP-lined cap ............................
G, FP-lined septum ......................
G, FP-lined cap ............................
Maximum holding time 4
Cool, ≤6 °C 18, store in dark,
0.008% Na2S2O3 5.
Cool, ≤6 °C 18, store in dark,
0.008% Na2S2O3 5.
14 days.
14 days.9
14 days 10
7 days until extraction, 40 days
after extraction.
7 days until extraction.13
7 days until extraction, 40 days
after extraction.
7 days until extraction, 40 days
after extraction.
1 year until extraction, 1 year
after extraction.
7 days until extraction, 40 days
after extraction.
7 days until extraction, 40 days
after extraction.
G, FP-lined cap ............................
Cool, ≤6 °C 18, 0.008% Na2S2O3 5
29, 35–37, 63–65, 107.
Chlorinated hydrocarbons 11.
60–62, 66–72, 85, 86, 95–97, 102,
103. CDDs/CDFs 11.
G, FP-lined cap ............................
Cool, ≤6 °C 18 ...............................
G ...................................................
See footnote 11 ............................
Aqueous Samples: Field and Lab
Preservation.
Solids and Mixed-Phase Samples:
Field Preservation.
Tissue Samples: Field Preservation.
Solids, Mixed-Phase, and Tissue
Samples: Lab Preservation.
114–118. Alkylated phenols ..........
G ...................................................
G ...................................................
Cool, ≤6 °C 18, 0.008%
Na2S2O3 5, pH <9.
Cool, ≤6 °C 18 ...............................
7 days.
G ...................................................
Cool, ≤6 °C 18 ...............................
24 hours.
G ...................................................
Freeze, ≤¥10 °C ..........................
1 year.
G ...................................................
Cool, <6 °C, H2SO4 to pH <2 ......
G ...................................................
Cool, <6 °C, 0.008% Na2S2O3,
HNO3 to pH <2.
Cool, <6 °C, 0.008% Na2S2O3,
H2SO4 to pH <2.
28 days until extraction, 40 days
after extraction.
Hold at least 3 days, but not more
than 6 months.
30 days until acetylation, 30 days
after acetylation.
119. Adsorbable Organic Halides
(AOX).
120. Chlorinated Phenolics ............
G, FP-lined cap ............................
7 days until extraction, 40 days
after extraction.
7 days until extraction, 40 days
after extraction.
See footnote 11.
1 year.
Table ID—Pesticides Tests
1–70. Pesticides 11 .........................
G, FP-lined cap ............................
Cool, ≤6 °C 18, pH 5–9 15 ..............
7 days until extraction, 40 days
after extraction.
Table IE—Radiological Tests
1–5. Alpha, beta, and radium ........
P, FP, G ........................................
HNO3 to pH <2 .............................
6 months.
Table IH—Bacterial Tests
1–4. Coliform, total, fecal ...............
5. E. coli .........................................
6. Fecal streptococci ......................
7. Enterococci ................................
PA,
PA,
PA,
PA,
G
G
G
G
............................................
............................................
............................................
............................................
Cool,
Cool,
Cool,
Cool,
<10
<10
<10
<10
°C,
°C,
°C,
°C,
0.008% Na2S2O3 5
0. 008% Na2S2O3 5
0.008% Na2S2O3 5
0. 008% Na2S2O3 5
8
8
8
8
hours.22 23
hours.22
hours.22
hours.22
Table IH—Protozoan Tests
8. Cryptosporidium .........................
9. Giardia .......................................
LDPE; field filtration ......................
LDPE; field filtration ......................
1–10 °C .........................................
1–10 °C .........................................
96 hours.21
96 hours.21
1 ‘‘P’’ is for polyethylene; ‘‘FP’’ is fluoropolymer (polytetrafluoroethylene [PTFE]; Teflon®), or other fluoropolymer, unless stated otherwise in this
Table II; ‘‘G’’ is glass; ‘‘PA’’ is any plastic that is made of a sterilizable material (polypropylene or other autoclavable plastic); ‘‘LDPE’’ is low density polyethylene.
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2 Except where noted in this Table II and the method for the parameter, preserve each grab sample within 15 minutes of collection. For a composite sample collected with an automated sample (e.g., using a 24-hour composite sample; see 40 CFR 122.21(g)(7)(i) or 40 CFR part 403, Appendix E), refrigerate the sample at ≤6 °C during collection unless specified otherwise in this Table II or in the method(s). For a composite sample to be split into separate aliquots for preservation and/or analysis, maintain the sample at ≤6 °C, unless specified otherwise in this Table II or
in the method(s), until collection, splitting, and preservation is completed. Add the preservative to the sample container prior to sample collection
when the preservative will not compromise the integrity of a grab sample, a composite sample, or aliquot split from a composite sample within 15
minutes of collection. If a composite measurement is required but a composite sample would compromise sample integrity, individual grab samples must be collected at prescribed time intervals (e.g., 4 samples over the course of a day, at 6-hour intervals). Grab samples must be analyzed separately and the concentrations averaged. Alternatively, grab samples may be collected in the field and composited in the laboratory if
the compositing procedure produces results equivalent to results produced by arithmetic averaging of results of analysis of individual grab samples. For examples of laboratory compositing procedures, see EPA Method 1664 Rev. A (oil and grease) and the procedures at 40 CFR
141.24(f)(14)(iv) and (v) (volatile organics).
3 When any sample is to be shipped by common carrier or sent via the U.S. Postal Service, it must comply with the Department of Transportation Hazardous Materials Regulations (49 CFR part 172). The person offering such material for transportation is responsible for ensuring such
compliance. For the preservation requirement of Table II, the Office of Hazardous Materials, Materials Transportation Bureau, Department of
Transportation has determined that the Hazardous Materials Regulations do not apply to the following materials: Hydrochloric acid (HCl) in water
solutions at concentrations of 0.04% by weight or less (pH about 1.96 or greater; Nitric acid (HNO3) in water solutions at concentrations of 0.15%
by weight or less (pH about 1.62 or greater); Sulfuric acid (H2SO4) in water solutions at concentrations of 0.35% by weight or less (pH about
1.15 or greater); and Sodium hydroxide (NaOH) in water solutions at concentrations of 0.080% by weight or less (pH about 12.30 or less).
4 Samples should be analyzed as soon as possible after collection. The times listed are the maximum times that samples may be held before
the start of analysis and still be considered valid. Samples may be held for longer periods only if the permittee or monitoring laboratory have data
on file to show that, for the specific types of samples under study, the analytes are stable for the longer time, and has received a variance from
the Regional ATP Coordinator under Sec. 136.3(e). For a grab sample, the holding time begins at the time of collection. For a composite sample
collected with an automated sampler (e.g., using a 24-hour composite sampler; see 40 CFR 122.21(g)(7)(i) or 40 CFR part 403, Appendix E), the
holding time begins at the time of the end of collection of the composite sample. For a set of grab samples composited in the field or laboratory,
the holding time begins at the time of collection of the last grab sample in the set. Some samples may not be stable for the maximum time period
given in the table. A permittee or monitoring laboratory is obligated to hold the sample for a shorter time if it knows that a shorter time is necessary to maintain sample stability. See 136.3(e) for details. The date and time of collection of an individual grab sample is the date and time at
which the sample is collected. For a set of grab samples to be composited, and that are all collected on the same calendar date, the date of collection is the date on which the samples are collected. For a set of grab samples to be composited, and that are collected across two calendar
dates, the date of collection is the dates of the two days; e.g., November 14–15. For a composite sample collected automatically on a given
date, the date of collection is the date on which the sample is collected. For a composite sample collected automatically, and that is collected
across two calendar dates, the date of collection is the dates of the two days; e.g., November 14–15. For static-renewal toxicity tests, each grab
or composite sample may also be used to prepare test solutions for renewal at 24 h, 48 h, and/or 72 h after first use, if stored at 0–6 °C, with
minimum head space.
5 ASTM D7365–09a specifies treatment options for samples containing oxidants (e.g., chlorine) for cyanide analyses. Also, Section 9060A of
Standard Methods for the Examination of Water and Wastewater (23rd edition) addresses dechlorination procedures for microbiological analyses.
6 Sampling, preservation and mitigating interferences in water samples for analysis of cyanide are described in ASTM D7365–09a(15). There
may be interferences that are not mitigated by the analytical test methods or D7365–09a(15). Any technique for removal or suppression of interference may be employed, provided the laboratory demonstrates that it more accurately measures cyanide through quality control measures described in the analytical test method. Any removal or suppression technique not described in D7365–09a(15) or the analytical test method must
be documented along with supporting data.
7 For dissolved metals, filter grab samples within 15 minutes of collection and before adding preservatives. For a composite sample collected
with an automated sampler (e.g., using a 24-hour composite sampler; see 40 CFR 122.21(g)(7)(i) or 40 CFR part 403, Appendix E), filter the
sample within 15 minutes after completion of collection and before adding preservatives. If it is known or suspected that dissolved sample integrity will be compromised during collection of a composite sample collected automatically over time (e.g., by interchange of a metal between dissolved and suspended forms), collect and filter grab samples to be composited (footnote 2) in place of a composite sample collected automatically.
8 Guidance applies to samples to be analyzed by GC, LC, or GC/MS for specific compounds.
9 If the sample is not adjusted to pH 2, then the sample must be analyzed within seven days of sampling.
10 The pH adjustment is not required if acrolein will not be measured. Samples for acrolein receiving no pH adjustment must be analyzed within 3 days of sampling.
11 When the extractable analytes of concern fall within a single chemical category, the specified preservative and maximum holding times
should be observed for optimum safeguard of sample integrity (i.e., use all necessary preservatives and hold for the shortest time listed). When
the analytes of concern fall within two or more chemical categories, the sample may be preserved by cooling to ≤6 °C, reducing residual chlorine
with 0.008% sodium thiosulfate, storing in the dark, and adjusting the pH to 6–9; samples preserved in this manner may be held for seven days
before extraction and for forty days after extraction. Exceptions to this optional preservation and holding time procedure are noted in footnote 5
(regarding the requirement for thiosulfate reduction), and footnotes 12, 13 (regarding the analysis of benzidine).
12 If 1,2-diphenylhydrazine is likely to be present, adjust the pH of the sample to 4.0 ± 0.2 to prevent rearrangement to benzidine.
13 Extracts may be stored up to 30 days at <0 °C.
14 For the analysis of diphenylnitrosamine, add 0.008% Na S O and adjust pH to 7–10 with NaOH within 24 hours of sampling.
2 2 3
15 The pH adjustment may be performed upon receipt at the laboratory and may be omitted if the samples are extracted within 72 hours of collection. For the analysis of aldrin, add 0.008% Na2S2O3.
16 Place sufficient ice with the samples in the shipping container to ensure that ice is still present when the samples arrive at the laboratory.
However, even if ice is present when the samples arrive, immediately measure the temperature of the samples and confirm that the preservation
temperature maximum has not been exceeded. In the isolated cases where it can be documented that this holding temperature cannot be met,
the permittee can be given the option of on-site testing or can request a variance. The request for a variance should include supportive data
which show that the toxicity of the effluent samples is not reduced because of the increased holding temperature. Aqueous samples must not be
frozen. Hand-delivered samples used on the day of collection do not need to be cooled to 0 to 6 °C prior to test initiation.
17 Samples collected for the determination of trace level mercury (<100 ng/L) using EPA Method 1631 must be collected in tightly-capped
fluoropolymer or glass bottles and preserved with BrCl or HCl solution within 48 hours of sample collection. The time to preservation may be extended to 28 days if a sample is oxidized in the sample bottle. A sample collected for dissolved trace level mercury should be filtered in the laboratory within 24 hours of the time of collection. However, if circumstances preclude overnight shipment, the sample should be filtered in a designated clean area in the field in accordance with procedures given in Method 1669. If sample integrity will not be maintained by shipment to and
filtration in the laboratory, the sample must be filtered in a designated clean area in the field within the time period necessary to maintain sample
integrity. A sample that has been collected for determination of total or dissolved trace level mercury must be analyzed within 90 days of sample
collection.
18 Aqueous samples must be preserved at ≤6 °C, and should not be frozen unless data demonstrating that sample freezing does not adversely
impact sample integrity is maintained on file and accepted as valid by the regulatory authority. Also, for purposes of NPDES monitoring, the
specification of ‘‘≤ °C’’ is used in place of the ‘‘4 °C’’ and ‘‘<4 °C’’ sample temperature requirements listed in some methods. It is not necessary
to measure the sample temperature to three significant figures (1/100th of 1 degree); rather, three significant figures are specified so that rounding down to 6 °C may not be used to meet the ≤6 °C requirement. The preservation temperature does not apply to samples that are analyzed
immediately (less than 15 minutes).
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19 An aqueous sample may be collected and shipped without acid preservation. However, acid must be added at least 24 hours before analysis to dissolve any metals that adsorb to the container walls. If the sample must be analyzed within 24 hours of collection, add the acid immediately (see footnote 2). Soil and sediment samples do not need to be preserved with acid. The allowances in this footnote supersede the preservation and holding time requirements in the approved metals methods.
20 To achieve the 28-day holding time, use the ammonium sulfate buffer solution specified in EPA Method 218.6. The allowance in this footnote supersedes preservation and holding time requirements in the approved hexavalent chromium methods, unless this supersession would
compromise the measurement, in which case requirements in the method must be followed.
21 Holding time is calculated from time of sample collection to elution for samples shipped to the laboratory in bulk and calculated from the time
of sample filtration to elution for samples filtered in the field.
22 Sample analysis should begin as soon as possible after receipt; sample incubation must be started no later than 8 hours from time of collection.
23 For fecal coliform samples for sewage sludge (biosolids) only, the holding time is extended to 24 hours for the following sample types using
either EPA Method 1680 (LTB–EC) or 1681 (A–1): Class A composted, Class B aerobically digested, and Class B anaerobically digested.
24 The immediate filtration requirement in orthophosphate measurement is to assess the dissolved or bio-available form of orthophosphorus
(i.e., that which passes through a 0.45-micron filter), hence the requirement to filter the sample immediately upon collection (i.e., within 15 minutes of collection).
3. Amend § 136.6 by adding paragraph
(b)(4)(xxiii) to read as follows:
■
§ 136.6 Method modifications and
analytical requirements.
*
*
*
*
*
(b) * * *
(4) * * *
(xxiii) When analyzing metals by
inductively coupled plasma-atomic
emission spectroscopy, inductively
coupled plasma-mass spectrometry, and
stabilized temperature graphite furnace
atomic absorption, closed-vessel
microwave digestion of wastewater
samples is allowed as alternative
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heating source for Method 200.2—
‘‘Sample Preparation Procedure for
Spectrochemical Determination of Total
Recoverable Elements’’ for the following
elements: Aluminum, antimony,
arsenic, barium, beryllium, boron,
cadmium, calcium, chromium, cobalt,
copper, iron, lead, magnesium,
manganese, molybdenum, nickel,
potassium, selenium, silver, sodium,
thallium, tin, titanium, vanadium, zinc,
provided the performance specifications
in the relevant determinative method
are met. (Note that this list does not
include Mercury.) Each laboratory
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determining total recoverable metals is
required to operate a formal quality
control (QC) program. The minimum
requirements include initial
demonstration of capability, method
detection limit (MDL), analysis of
reagent blanks, fortified blanks, matrix
spike samples, and blind proficiency
testing samples, as continuing quality
control checks on performance. The
laboratory is required to maintain
performance records on file that define
the quality of the data generated.
[FR Doc. 2019–22437 Filed 10–21–19; 8:45 am]
BILLING CODE 6560–50–P
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Agencies
[Federal Register Volume 84, Number 204 (Tuesday, October 22, 2019)]
[Proposed Rules]
[Pages 56590-56624]
From the Federal Register Online via the Government Publishing Office [www.gpo.gov]
[FR Doc No: 2019-22437]
[[Page 56589]]
Vol. 84
Tuesday,
No. 204
October 22, 2019
Part III
Environmental Protection Agency
-----------------------------------------------------------------------
40 CFR Part 136
Clean Water Act Methods Update Rule for the Analysis of Effluent;
Proposed Rule
Federal Register / Vol. 84 , No. 204 / Tuesday, October 22, 2019 /
Proposed Rules
[[Page 56590]]
-----------------------------------------------------------------------
ENVIRONMENTAL PROTECTION AGENCY
40 CFR Part 136
[EPA-HQ-OW-2018-0826; FRL-9995-22-OW]
RIN 2040-AF84
Clean Water Act Methods Update Rule for the Analysis of Effluent
AGENCY: Environmental Protection Agency (EPA).
ACTION: Proposed rule.
-----------------------------------------------------------------------
SUMMARY: The Environmental Protection Agency (EPA) is proposing changes
to its test procedures required to be used by industries and
municipalities when analyzing the chemical, physical, and biological
properties of wastewater and other environmental samples for reporting
under the EPA's National Pollutant Discharge Elimination System (NPDES)
permit program. The Clean Water Act requires the EPA to promulgate
these test procedures (analytical methods) for analysis of pollutants.
The EPA anticipates that these proposed changes will provide increased
flexibility for the regulated community in meeting monitoring
requirements while improving data quality. In addition, this proposed
update to the CWA methods would incorporate technological advances in
analytical technology. As such, the EPA expects that there will be no
negative economic impacts resulting from these proposed changes.
DATES: Comments on this proposed rule must be received on or before
December 23, 2019.
ADDRESSES: You may send comments, identified by Docket ID No. EPA-HQ-
OW-2018-0826, by any of the following means:
Federal eRulemaking Portal: https://www.regulations.gov/_
(preferred way of receiving comments): Follow the online instructions
for submitting comments.
Email: [email protected]. Include Docket ID No. EPA-HQ-OW-
2018-0826 in the subject line of the message.
Mail: U.S. Environmental Protection Agency, EPA Docket
Center, Office of Water Docket, Mail Code 28221T, 1200 Pennsylvania
Avenue NW, Washington, DC 20460.
Hand Delivery/Courier: EPA Docket Center, WJC West
Building, Room 3334, 1301 Constitution Avenue NW, Washington, DC 20004.
The Docket Center's hours of operations are 8:30 a.m.-4:30 p.m.,
Monday-Friday (except Federal Holidays).
Instructions: All submissions received must include the Docket ID
No. for this rulemaking. Comments received may be posted without change
to https://www.regulations.gov/, including any personal information
provided. For detailed instructions on sending comments and additional
information on the rulemaking process, see Section I.B ``What Should I
Consider as I Prepare My Comments for the EPA'' heading of the
SUPPLEMENTARY INFORMATION section of this document.
Docket: All documents in the docket are listed in the
www.regulations.gov index. Although listed in the index, some
information in the docket is not publicly available, e.g., Confidential
Business Information (CBI) or other information whose disclosure is
restricted by statute. Certain other material, such as copyrighted
material, will be publicly available only in hard copy. Publicly
available docket materials are available either electronically in
www.regulations.gov or in hard copy at the Water Docket in EPA Docket
Center, EPA/DC, EPA West William J. Clinton Building, Room 3334, 1301
Constitution Avenue NW, Washington, DC. The Public Reading Room is open
from 8:30 a.m. to 4:30 p.m., Monday through Friday, excluding legal
holidays. The telephone number for the Public Reading Room is 202-566-
1744, and the telephone number for the Water Docket is 202-566-2426.
FOR FURTHER INFORMATION CONTACT: Meghan Hessenauer, Engineering and
Analysis Division (4303T), Office of Water, Environmental Protection
Agency, 1200 Pennsylvania Avenue NW, Washington, DC 20460-0001;
telephone: 202-566-1040; email: [email protected].
SUPPLEMENTARY INFORMATION:
Table of Contents
I. General Information
II. Overview
III. Statutory Authority
IV. Purpose and Summary of Proposed Rule
V. Statutory and Executive Order Reviews
I. General Information
A. Does this action apply to me?
Entities potentially affected by the requirements of this proposed
action include:
------------------------------------------------------------------------
Category Examples of potentially affected entities
------------------------------------------------------------------------
State, Territorial, and States, territories, and tribes
Indian Tribal Governments. authorized to administer the National
Pollutant Discharge Elimination System
(NPDES) permitting program; states,
territories, and tribes providing
certification under CWA section 401;
state, territorial, and tribal-owned
facilities that must conduct monitoring
to comply with NPDES permits.
Industry..................... Facilities that must conduct monitoring
to comply with NPDES permits.
Municipalities............... Publicly Owned Treatment Works (POTWs) or
other municipality-owned facilities that
must conduct monitoring to comply with
NPDES permits.
------------------------------------------------------------------------
This table is not exhaustive, but rather provides a guide for
readers regarding entities likely to be affected by this action. This
table lists types of entities that the EPA is now aware of that could
potentially be affected by this action. Other types of entities not
listed in the table could also be affected. To determine whether your
facility is affected by this action, you should carefully examine the
applicability language at 40 CFR 122.1 (NPDES purpose and scope), 40
CFR 136.1 (NPDES permits and CWA) and 40 CFR 403.1 (pretreatment
standards purpose and applicability). If you have questions regarding
the applicability of this action to a particular entity, consult the
appropriate person listed in the preceding FOR FURTHER INFORMATION
CONTACT section.
B. What should I consider as I prepare my comments for the EPA?
Submit your comments, identified by Docket ID No. EPA-HQ-OW-2018-
0826, at https://www.regulations.gov (preferred way of receiving
comments), or the other means identified in the ADDRESSES section. Once
submitted, comments cannot be edited or removed from the docket. The
EPA may publish any comment received to its public docket. Do not
submit electronically any information you consider to be CBI or other
information whose disclosure is restricted by statute. Do not submit
CBI to the EPA through www.regulations.gov or email. Clearly mark the
part or all of the information that you claim to be CBI. For CBI
information in a disk that you mail to the EPA, mark the outside
[[Page 56591]]
of the disk as CBI and then identify electronically within the disk the
specific information that is claimed as CBI. In addition to one
complete version of the comment that includes information claimed as
CBI, a copy of the comment that does not contain the information
claimed as CBI must be submitted for inclusion in the public docket.
Information so marked will not be disclosed except in accordance with
procedures for handling and protection of CBI set forth in 40 CFR part
2.
Multimedia submissions (audio, video, etc.) must be accompanied by
a written comment. The written comment is considered the official
comment and should include discussion of all points you wish to make.
The EPA will generally not consider comments or comment contents
located outside of the primary submission (i.e., on the web, cloud, or
other file sharing system). For additional submission means or methods,
the full EPA public comment policy, information about CBI or multimedia
submissions, and general guidance on making effective comments, please
visit https://www.epa.gov/dockets/commenting-epa-dockets.
II. Overview
This preamble describes the reasons for the proposed rule; the
legal authority for the proposed rule; a summary of the proposed
changes and clarifications; and explanation of the abbreviations and
acronyms used in this document. In addition, this preamble solicits
comment and data from the public.
Abbreviations and Acronyms Used in the Preamble and Proposed Rule Text
2-CEVE: 2-Chloroethylvinyl ether
AA: Atomic Absorption
ADMI: American Dye Manufacturers Institute
ASTM: ASTM International \1\
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\1\ Formerly known as the American Society for Testing and
Materials (ASTM).
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ATP: Alternate Test Procedure
BHI: Brain heart infusion
BOD5: 5-day Biochemical Oxygen Demand
CAS: Chemical Abstract Services
CATC: Cyanide Amenable to Chlorination
CCB: Continuing calibration blank
CCV: Continuing calibration verification
CFR: Code of Federal Regulations
COD: Chemical Oxygen Demand
CWA: Clean Water Act
EC-MUG: EC broth with 4-methylumbelliferyl-[beta]-D-glucuronide
EDTA: Ethylenediaminetetraacetic acid
ELAB: Environmental Laboratory Advisory Board
EPA: Environmental Protection Agency
FLAA: Flame Atomic Absorption Spectroscopy
GC: Gas Chromatography
GFAA: Graphite Furnace Atomic Absorption Spectroscopy
ICP/AES: Inductively Coupled Plasma-Atomic Emission Spectroscopy
ICP/MS: Inductively Coupled Plasma-Mass Spectrometry
ILI: Independent Laboratories Institute
IPR: Initial Precision and Recovery
LCS: Laboratory Control Sample
MDL: Method Detection Limit
MF: Membrane Filtration
MgCl2: Magnesium Chloride
MPN: Most Probable Number
MS/MSD: Matrix Spike/Matrix Spike Duplicate
MS: Mass Spectrometry
NA-MUG: Nutrient Agar with 4-methylumbelliferyl-[beta]-D-glucuronide
NECi: A shortened name used by the Nitrate Elimination Company, Inc.
NPDES: National Pollutant Discharge Elimination System
NTTAA: National Technology Transfer and Advancement Act
OPR: Ongoing Precision and Recovery
QC: Quality Control
STGFAA: Stabilized Temperature Graphite Furnace Atomic Absorption
Spectroscopy
TKN: Total Kjeldahl Nitrogen
TOC: Total Organic Carbon
USGS: United States Geological Survey
VCSB: Voluntary Consensus Standards Body
III. Statutory Authority
The EPA is proposing this regulation under the authorities of
sections 301(a), 304(h), and 501(a) of the CWA; 33 U.S.C. 1311(a),
1314(h), and 1361(a). Section 301(a) of the CWA prohibits the discharge
of any pollutant into navigable waters unless the discharge complies
with, among other provisions, an NPDES permit issued under section 402
of the CWA. Section 304(h) of the CWA requires the Administrator of the
EPA to ``. . . promulgate guidelines establishing test procedures for
the analysis of pollutants that shall include the factors which must be
provided in any certification pursuant to [section 401 of the CWA] or
permit application pursuant to [section 402 of the CWA].'' Section
501(a) of the CWA authorizes the Administrator to ``. . . prescribe
such regulations as are necessary to carry out this function under [the
CWA].'' The EPA generally has codified its test procedure regulations
(including analysis and sampling requirements) for CWA programs at 40
CFR part 136, though some requirements are codified in other parts
(e.g., 40 CFR Chapter I, Subchapters N and O).
IV. Purpose and Summary of Proposed Rule
NPDES permits must include conditions designed to ensure compliance
with the technology-based and water quality-based requirements of the
CWA, including in many cases, restrictions on the quantity of specific
pollutants that can be discharged as well as pollutant measurement and
reporting requirements. Often, entities have a choice in deciding which
approved test procedure they will use for a specific pollutant because
the EPA has approved the use of more than one method.\2\
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\2\ NPDES permit regulations also specify that the approved
method needs to be sufficiently sensitive. See 40 CFR 122.21.e.3.
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The procedures for the analysis of pollutants required by CWA
section 304(h) are a central element of the NPDES permit program.
Examples of where these EPA-approved analytical methods must be used
include the following: (1) Applications for NPDES permits, (2) sampling
or other reports required under NPDES permits, (3) other requests for
quantitative or qualitative effluent data under the NPDES regulations,
(4) State CWA 401 certifications and (5) sampling and analysis required
under the EPA's General Pretreatment Regulations for Existing and New
Sources of Pollution, 40 CFR 136.1 and 40 CFR 403.12(b)(5)(v).
Periodically, the EPA proposes to update the approved methods in 40
CFR part 136. In general, the changes proposed in this action fall into
the following categories. The first is new or revised methods published
by the VCSBs or the USGS that are similar to methods previously adopted
as EPA-approved methods in 40 CFR part 136. The second category is
methods the EPA has reviewed under the Agency's national ATP program
and preliminarily concluded are appropriate for nationwide use.
Finally, the EPA is proposing certain corrections or amendments to the
text and tables of 40 CFR part 136. The EPA is proposing adoption of
these revisions to improve data quality, update methods to keep current
with technology advances, and provide the regulated community with
greater flexibility. The following paragraphs provide details on the
proposed revisions.
A. Changes to 40 CFR 136.3 To Include New Versions of Previously
Approved EPA Methods
The EPA proposes to add the latest version of EPA Method 1623 to
Table IH. The latest version of Method 1623 (labeled 1623.1) includes
updated acceptance criteria for IPR, OPR, and MS/MSD, and
clarifications and revisions based on user questions and feedback about
Method 1623 over the past 19 years.
[[Page 56592]]
B. Methods Incorporated by Reference
Currently, hundreds of methods and ATPs are incorporated by
reference within 40 CFR part 136. In most cases, 40 CFR part 136
contains multiple approved methods for a single pollutant, and
regulated entities often have a choice in selecting a method. The
proposed rule contains revisions to VCSB methods that are currently
incorporated by reference. Two VCSBs have made such revisions, Standard
Methods and ASTM. The proposed VCSB methods are consistent with the
requirements of the National Technology Transfer and Advancement Act
(NTTAA), under which federal agencies use technical standards developed
or adopted by the VCSBs if compliance would not be inconsistent with
applicable law or otherwise impracticable (see Section V.I below). The
proposed VCSB methods are available on their respective websites
(www.standardmethods.org/ and www.astm.org) to everyone at a cost
determined by the VCSB, generally from $40 to $80. Both organizations
also offer memberships or subscriptions that allow unlimited access to
their methods. The cost of obtaining these methods is not a significant
financial burden for a discharger or environmental laboratory, making
the methods reasonably available. Finally, this proposal also includes
USGS methods and vendor ATPs, all of which the EPA proposes to
incorporate by reference. The ATPs and USGS methods are available free
of charge on their respective websites (flowinjection.com, mn-net.com,
micrologylabs.com, and USGS.gov), enabling the EPA to conclude that the
USGS methods and ATPs incorporated by reference are reasonably
available.
C. Changes to 40 CFR 136.3 To Include New Versions of Approved Standard
Methods
The EPA is proposing to approve new versions of Standard Methods
methods previously approved in 40 CFR part 136. The newer versions
provide clarifications or make editorial corrections. As was the case
with the previous methods update rule (82 FR 40836-40941, August 28,
2017), the EPA generally proposes to approve and include in 40 CFR part
136 only the most recent version of a method published by the Standard
Methods Committee. The EPA is proposing to list only one version of the
method with the year of publication designated by the last four digits
in the method number (e.g., Standard Methods Method 3111 B-2011). The
date indicates the date of the specific revision to the method. This
allows use of a specific method in any edition of the hard copy
publication of Standard Methods for the Examination of Water &
Wastewater (Standard Methods) that includes a method with the same
method number and year of publication.
The proposed revisions to Standard Methods methods previously
approved in 40 CFR part 136 will not affect the performance of the
method. Below is a list of the Standard Methods methods the EPA is
proposing to include in 40 CFR part 136. Each entry contains the
proposed Standard Methods number and date, the parameter, and a brief
description of the analytical method. The methods listed below are
organized according to the table at 40 CFR part 136 in which they
appear.
The EPA proposes to make the following changes to Tables IA and IH
at 40 CFR part 136:
1. Standard Methods Method 9221 (B, E, F)-2014: Method 9221B-2014
Coliform (total); analyzes for total coliforms in non-potable waters
using lauryl tryptose broth (LTB), all presumptive growth LTB tubes are
confirmed in brilliant green lactose bile broth (BGLB). Method 9221E-
2014 Coliform (fecal); analyzes all presumptive growth LTB tubes for
fecal coliform using EC broth. Method 9221F-2014 E. coli; analyzes all
presumptive growth LTB tubes for E. coli using EC-MUG. The number of
positive tubes (BGLB, EC broth or EC-MUG) is used to determine the most
probable number (MPN).
2. Standard Methods Method 9222 (B, D, I)-2015: Method 9222B-2015
Coliform (total); analyzes for total coliforms in non-potable waters by
filtration through a 0.45-[micro]m membrane filter and plated on mEndo
or LES Endo agar. Method 9222D-2015 Coliform (fecal); analyzes for
fecal coliforms in non-potable waters by filtration through a 0.45-
[micro]m membrane filter plated on mFC medium. Method 9222 I-2015 E.
coli; membrane filtration (MF), analyzes presumptive positive filters
from Method 9222B and 9222D using nutrient agar plates with MUG (NA-
MUG) which are examined under a longwave UV lamp.
3. Standard Methods Method 9223B-2016, E. coli, multiple tube/
multiple well. This method analyzes non-potable waters for E. coli
using commercially available enzyme substrate media that is mixed with
the sample and placed in multiple tubes or multiple well trays,
incubated and examined under ambient light for Coliform (total) and
under a longwave UV lamp for E. coli.
4. Standard Methods Method 9230 (B, C)-2013: Method 9230B-2013
Fecal Streptococci; analyzes non-potable waters for streptococci using
azide dextrose broth (ADB), Presumptive positive ADB tubes are
confirmed by streaking onto bile esculin azide agar (BEA). Method
9230C-2013 Enterococci; analyzes non-potable waters by filtration
through a 0.45-[micro]m membrane filter and plated on mE agar.
The EPA proposes to make the following changes to Table IB at 40
CFR part 136:
1. Standard Methods Methods: Method 2540B-2015, total solids; a
sample aliquot is evaporated in a pre-weighed evaporating dish at 103-
105 [deg]C. Method 2540C-2015 filterable residue (total dissolved
solids); a sample aliquot is filtered through a glass fiber filter and
the filtrate is evaporated on a pre-weighed dish to constant weight at
180 [deg]C. Method 2540D-2015 non-filterable residue (total suspended
solids); a sample aliquot is filtered through a pre-weighed glass fiber
filter which is then dried to constant weight at 103-105 [deg]C. Method
2540E-2015 volatile residue (fixed and volatile solids); the residue
obtained from the determination of total (Method 2540B), filterable
(Method 2540C) or non-filterable residue (Method 2540D) is ignited at
550 [deg]C in a muffle furnace. Method 2540E-2015 settleable residue
(settleable solids); settleable matter is measured with an Imhoff cone
either volumetrically or gravimetrically.
2. Standard Methods Method 4500-CN- (B-G)-2016, cyanide:
Cyanides are measured after preliminary treatment of samples to remove
interferences (4500-CN- B) and manual distillation with
magnesium chloride (MgCl2) (4500-CN- C) followed
by: Titration with silver nitrate (4500-CN- D),
spectrophotometric measurement after cyanide in the alkaline distillate
is converted to CNCl (4500-CN- E), potentiometric
measurement using an ion selective electrode (4500-CN- F),
and cyanide amenable to chlorination (CATC) in which a portion of the
sample is chlorinated at high pH and cyanide levels in the chlorinated
sample are determined after manual distillation followed by titrimetric
or spectrophotometric measurement. Amenable cyanide is calculated by
the difference between the results for cyanide in the unchlorinated
sample and the results for the chlorinated sample (4500-CN-
G).
3. Standard Methods Method 4500-NO3- D-2016,
nitrate (as nitrogen), measured using an ion-selective electrode (ISE)
that develops a potential across a thin, inert membrane holding in
place a water-immiscible liquid ion exchanger.
[[Page 56593]]
4. Standard Methods Method 4500-NO3- (E, F,
and H)-2016, nitrate-nitrite (as nitrogen): Nitrate is reduced to
nitrite using a cadmium-copper column, followed by diazotization to
form a colored azo dye, which is measured by colorimetry either
manually (4500 NO3- E) or automated (4500
NO3- F); or by reduction of nitrate to nitrite
using hydrazine followed by automated colorimetric measurement of
nitrite after diazotization (4500 NO3- H).
5. Standard Methods Method 4500-NO3- (E and
F)-2016, nitrite (as nitrogen), colorimetric: Bypasses the cadmium
reduction step and measures nitrite after diazotization either by
manual or automated colorimetric analysis.
6. Standard Methods Method 4500-O (B-F, and G)-2016, measurement of
oxygen (dissolved), using the Winkler iodometric titration procedure
with modifications to eliminate or minimize certain interferences if
necessary based on sample type (4500-O B through F), or by use of
polarographic or galvanic membrane electrodes (4500-O G).
7. Standard Methods Method 5210 B-2016, biochemical oxygen demand
(BOD5), dissolved oxygen depletion. The BOD5 test
is an indirect measurement of organic matter; it measures the change in
DO concentration caused by microorganisms as they degrade organic
matter in a sample held in a stoppered bottle incubated for 5 days in
the dark at 20 [deg]C.
8. Standard Methods Method 5310 (B, C)-2014, total organic carbon
(TOC), combustion, heated persulfate or UV persulfate oxidation: Method
5310B-2014, high-temperature combustion; a sample aliquot is combusted,
transported in a carrier gas stream and measured via a nondispersive
infrared analyzer, or titrated coulometrically Method 5310C-2014,
persulfate-ultraviolet or heated-persulfate oxidation method;
persulfate oxidizes organic carbon, the produced CO2 is then
purged and measured by either nondispersive infrared (NDIR) analyzer,
be coulometrically titrated, or separated from the liquid stream by a
membrane that specifically allows CO2 to pass into high-
purity water where the change in the high-purity water's conductivity
corresponds to the amount of CO2 passing the membrane.
The EPA is also proposing one revision to a previously approved
Standard Methods method for which the Standard Methods Committee has
adopted updates. This modification includes minor procedural changes
that do not affect the performance of the method.
The EPA proposes to make the following change to Table IA and Table
IH at 40 CFR part 136:
1. The EPA proposes that the MPN method Standard Methods Method
9221 F.2-2014 be approved as an acceptable method for detecting
thermotolerant coliforms and E. coli simultaneously. This method
analyzes Coliform (fecal) and E. coli using EC broth with 4-
methylumbelliferyl-[beta]-D-glucuronide (EC-MUG) with inverted vials.
D. Changes to 40 CFR 136.3 To Include New Standard Methods Methods
Based on Previously Approved Technologies
The EPA is proposing these changes based on the National Technology
Transfer and Advancement Act of 1995 (NTTAA), Public Law 104-113, which
states that federal agencies and departments shall use technical
standards developed or adopted by the VCSBs if compliance would not be
inconsistent with applicable law or otherwise impracticable. These
methods submitted by the Standard Methods Committee are consistent with
other methods already approved at 40 CFR part 136.
1. The EPA proposes to add Standard Methods Method 4500-
CN- N-2016 to Table IB for Cyanide, total. Cyanide is
measured after preliminary treatment of samples and manual distillation
with magnesium chloride (MgCl2) followed by automated
spectrophotometric measurement after conversion to CNCl. This method is
similar to the currently approved EPA Method 335.4, USGS Method I-4302-
85, and Lachat Method 10-204-00-1-X, and uses semi-automated
spectrophotometric measurement of cyanide.
2. The EPA proposes to add Standard Methods Method 4500-
NO3- I-2016 to Table IB for combined nitrate-
nitrite, nitrite (bypass the reduction column) and nitrate by
subtraction. Nitrate is reduced to nitrite using a cadmium-copper
column followed by diazotization to form an azo dye which is measured
by colorimetry. The cadmium reduction column may be by-passed for
measurement of nitrite only. The value obtained for nitrite may be
subtracted from the value obtained for combined nitrate-nitrite to
calculate the concentration of nitrate. This method is similar to the
currently approved EPA Method 353.2, Standard Methods Method 4500-
NO3- F-2011, ASTM Method D3867-04 (A), and USGS
Method I-2545-90, and uses automated cadmium reduction and
spectrophotometric measurement of nitrite.
3. The EPA proposes to add Standard Methods Method 4500-
NO3- J-2018 to Table IB for measurement of
combined nitrate-nitrite, for measurement of nitrite when bypassing the
enzymatic reduction step, and for measurement of nitrate by
subtraction. Nitrate is reduced to nitrite by an enzymatic reaction.
The nitrite is diazotized to yield an azo dye which is measured
colorimetrically. The enzyme reduction step may be by-passed for
measurement of nitrite singly. The value obtained for nitrite may be
subtracted from the value obtained for combined nitrate-nitrite to
calculate the concentration of nitrate. This method is similar to the
currently approved NECi Method N07-0003, USGS Method I-2547-11, and
USGS Method I-2548-11.
4. The EPA proposes to add Standard Methods Method 4500-O H-2016 to
Table IB for dissolved oxygen. This method uses a luminescent-based
sensor for measurement of dissolved oxygen. The method is similar to
the currently approved Hach Method 10360, In-Situ Method 1002-8-2009,
and ASTM Method D888-09 (C).
E. Changes to 40 CFR 136.3 To Include New Versions of Approved ASTM
Methods
The EPA is proposing to approve new versions of ASTM methods
previously approved in 40 CFR part 136 for the same reasons outlined in
the first paragraph of Section IV.C above. These changes to currently
approved ASTM methods in 40 CFR part 136 include minor clarifications
and editorial changes, and in some instances, minor procedural changes.
None of these proposed changes will affect the performance of the
method. The following describes the changes to current ASTM methods
that the EPA proposes to include in 40 CFR part 136. Each entry
contains (in the following order): Proposed ASTM method number (the
last two digits in the method number represent the year ASTM
published), the parameter, a brief description of the analytical
technique, and a brief description of any procedural changes in this
revision from the last approved version of the method. The methods
listed below are organized according to the table at 40 CFR part 136 in
which they appear.
The EPA proposes the following changes to Table IB at 40 CFR part
136:
1. ASTM Method D511-14 (A, B), calcium and magnesium, titrimetric,
(EDTA), AA direct aspiration: Method D511-14 A, titrimetric; the pH of
the sample is adjusted to 10 (for calcium), then to 12-13 (for
magnesium) and titrated with ethylenediamine tetraacetic acid (EDTA) to
form complexes with calcium and
[[Page 56594]]
magnesium ions which react with an indicator to form a colored product.
The volume of titrant used to affect the color change is proportional
to the concentrations of calcium and magnesium in the sample. Method
D511-14 B, AA direct aspiration; the sample is acidified and analyzed
by atomic absorption. The concentrations of calcium and magnesium in
the samples are proportional to the amount of light absorbed during the
analysis, and are determined in comparison to a standard curve.
This version adds specifications for filter paper.
2. ASTM Method D512-12 chloride ion (A, B), titrimetric (mercuric
nitrate), titration (silver nitrate): Method D512-12A, titrimetric
mercuric nitrate; the sample is acidified and titrated with mercuric
nitrate in the presence of a diphenylcarbazonebromophenol blue
indicator. Method D512-12B, titrimetric silver nitrate; sample pH is
adjusted to phenolphthalein endpoint and titrated with silver nitrate
in the presence of potassium chromate. The volume of titrant used to
affect the color change in either method is proportional to the
concentration of chloride in the sample. This version corrects one term
in the calculation of the chloride calculation.
3. ASTM Method D516-16, sulfate ion, turbidimetric. In this method,
sulfate ions are converted to barium sulfate to form a suspension. The
turbidity of the suspension is measured with a nephelometer,
spectrophotometer, or photoelectric colorimeter, and compared to a
standard curve to determine the sulfate concentration in the sample.
This version adds specifications for filter paper.
4. ASTM Method D858-17 (A-C), manganese, atomic absorption (AA)
direct aspiration, AA furnace. The sample is acid digested and analyzed
by direct aspiration atomic absorption or graphite furnace atomic
absorption. The concentration of manganese in the sample is
proportional to the amount of light absorbed and is determined in
comparison to a standard curve. There are no procedural changes.
5. ASTM Method D859-16, silica, colorimetric, manual. In this
method, soluble silica in the sample is reacted with molybdate then
reduced to form a blue complex in solution. The intensity of the blue
complex is determined with a spectrophotometer or filter photometer and
the concentration of silica is determined by comparison with a standard
curve. There are no procedural changes.
6. ASTM Method D888-12 (A-C) dissolved oxygen, Winkler, electrode,
luminescent-based sensor: Method D888-12A measures dissolved oxygen
using the Winkler iodometric titration procedure. The volume of titrant
used is proportional to the concentration of dissolved oxygen in the
sample. Method D888-12B measures dissolved oxygen in the sample with an
electrochemical probe that produces an electrical potential which is
logarithmically proportional to the concentration of dissolved oxygen
in the sample. Method D888-12C measures dissolved oxygen with a
luminescence-based sensor probe that employs frequency domain lifetime-
based luminescence quenching and signal processing. This version adds
information on a two-point calibration and updated performance
information from an interlaboratory study to D888-12C.
7. ASTM Method D1067-16, acidity or alkalinity, electrometric
endpoint or phenolphthalein endpoint; electrometric or colorimetric
titration to pH 4.5, manual. The acidity or alkalinity of the sample is
determined by titration to a specific pH endpoint which is determined
by colorimetry or with a pH electrode. The acidity or alkalinity is
proportional to the volume of titrant required to affect the pH change.
There are no procedural changes.
8. ASTM Method D1068-15 (A-C), iron, AA direct aspiration; AA
furnace; colorimetric (Phenanthroline): The sample is acid digested and
analyzed by either direct aspiration atomic absorption, graphite
furnace atomic absorption, or colorimetry. The concentration of iron in
the sample is proportional to the amount of light absorbed and is
determined in comparison to a standard curve. This version adds
specifications for filter paper.
9. ASTM Method D1126-17, hardness, titrimetric (EDTA). The pH of
the sample is adjusted and an indicator is added forming a red color.
The mixture is titrated until the color changes from red to blue. The
volume of titrant used to affect the color change is proportional to
the hardness in the sample. There are no procedural changes.
10. ASTM Method D1179-16 (A, B); fluoride ion, manual distillation,
electrode, manual: Method D1179A, manual distillation; the sample is
distilled as hydrofluorosilic acid and determined by ion-selective
electrode. Method D1179B, electrode; the fluoride ion is determined
potentiometrically with an ion-selective electrode in conjunction
without sample distillation. There are no procedural changes.
11. ASTM Method D1246-16, bromide ion, electrode. The bromide in
the sample is determined potentiometrically with an ion-selective
electrode, either through comparison to a standard curve or through a
direct readout on the instrument. There are no procedural changes.
12. ASTM Method D1252-06 (A, B) (Reapproved 2012), chemical oxygen
demand, titrimetric, spectrophotometric. This is the 2012 reapproval of
the 2006 ASTM method: Method D1252-06A, titrimetric; measures the loss
of the hexavalent dichromate ion by reflux digestion followed by
titration. The chemical oxygen demand in the sample is determined by
comparison to a standard curve. Method D1252-06B, spectrophotometric;
uses a spectrophotometer to measure the loss of the hexavalent
dichromate ion at 420 nm or the increase in the trivalent chromium ion
at 600 nm, after closed digestion and determines the chemical oxygen
demand by comparison to a standard curve. There are no procedural
changes.
13. ASTM Method D1253-14, residual chlorine, amperometric direct.
The concentration of chlorine in the sample is determined by titration
with phenylarsine oxide, using an amperometric probe that responds to
chlorine to determine when the titration is complete. The chlorine
concentration in the sample is proportional to the volume of titrant
used. There are no procedural changes.
14. ASTM Method D1426-15 (A, B), ammonia nitrogen, Nesslerization,
electrode: Method D1426A, Nesslerization; an aliquot is Nesslerized and
the ammonia content determined colormetrically. Method D1426B,
electrode; ammonia is potentiometric determined using a gas-permeable
ion-selective electrode, either through comparison to a standard curve
or through a direct readout on the instrument using. A lengthy section
of QC requirements was added to the Nesslerization procedure (D1426A)
that parallels the QC discussion that was already in the B procedure.
Both procedures added information on use of commercially prepared
standards and filter paper.
15. ASTM Method D1687-17 (A-C), chromium (total) and dissolved
hexavalent chromium, colorimetric (diphenyl-carbazide); AA direct
aspiration; AA furnace: Method D1687-17A, chromium (dissolved);
measures dissolved hexavalent chromium by reacting it with diphenyl-
carbohydrazide to produce a reddish-purple color that is measured with
a
[[Page 56595]]
spectrophotometer or filter photometer. The concentration in the sample
is proportional to the intensity of the color. Method D1687-17B,
chromium (total); the sample is acid digested and analyzed by direct
aspiration atomic absorption. Method D1687-17C, chromium (total); the
sample is acid digested and analyzed by graphite furnace atomic
absorption. The concentration of total chromium in the sample is
proportional to the amount of light absorbed during the analysis and is
determined in comparison to a standard curve. The changes mirror those
for the other metals methods. The QC frequencies for method blank,
continuing calibration verification (CCV), continuing calibration blank
(CCB), matrix spike, and duplicate analyses are now based on a
laboratory-defined batch of up to 20 samples.
16. ASTM Method D1688-17 (A-C), copper, AA direct aspiration, AA
furnace. The sample is acid digested and analyzed by direct aspiration
atomic absorption (D1688-17A and B) or graphite furnace atomic
absorption (D1688-17B). The concentration of copper in the sample is
proportional to the amount of light absorbed and is determined in
comparison to a standard curve. The changes mirror those for the other
metals methods. The proposed changes also clarify the requirements for
a multi-point calibration by discussing it in the calibration section
as well as the QC section of all three procedures. The QC frequencies
for method blank, CCV, CCB, matrix spike, and duplicate analyses are
now based on a laboratory-defined batch of up to 20 samples.
17. ASTM Method D1691-17 (A, B), zinc, AA direct aspiration. Method
D1691-17A; the sample is acid digested and analyzed by direct
aspiration atomic absorption. Method D1691-17B; the sample is processed
by chelation-extraction and analyzed by atomic absorption. The
concentration of zinc in the sample is proportional to the amount of
light absorbed and is determined in comparison to a standard curve. The
changes mirror those for the other metals methods. The QC frequencies
for method blank, CCV, CCB, matrix spike, and duplicate analyses are
now based on a laboratory-defined batch of up to 20 samples.
18. ASTM Method D1783-01 (A, B) (Reapproved 2012), phenols, manual
distillation followed by manual colorimetric (4AAP). The sample is
distilled, the distillate pH is adjusted to 10.0, and reacted with 4-
aminoantipyrine to form a colored product. In Method D1783-01A, the
colored product is extracted from the sample with chloroform and
measured with a photometer at 460 nm. In Method D1783-01B, the colored
product is measured without extraction, using a photometer at 510 nm.
The concentration of phenolics is determined in comparison to a
standard curve. There are no procedural changes.
19. ASTM Method D1886-14 (A-C), nickel AA direct aspiration,
chelation extraction AA and AA furnace. Method D1886-14A, the sample is
acid digested and analyzed by direct aspiration atomic absorption.
Method D1886-14B, the sample is acid digested and the nickel chelated
and extracted. The extract is analyzed by direct aspiration atomic
absorption. Method D1886-14C, the sample is acid digested and analyzed
by graphite furnace atomic absorption. The concentration of nickel in
the sample is proportional to the amount of light absorbed during the
analysis and is determined in comparison to a standard curve. The
changes mirror those for the other metals methods. The QC frequencies
for method blank, CCV, CCB, matrix spike, and duplicate analyses are
now based on a laboratory-defined batch of up to 20 samples.
20. ASTM Method D2036-09 (A, B) (Reapproved 2015), A, total
cyanide, manual distillation followed by gas diffusion amperometry,
titrimetric, spectrophotometric, ion chromatography, ion selective
electrode, B, available (amenable) cyanide, manual distillation
followed by titrimetric or spectrophotometric. The cyanide in the
sample is distilled and trapped in a sodium hydroxide solution. Method
D2036-09A, the cyanide is treated with strong acid and a catalyst
during distillation and measured by titration, gas diffusion
amperometry, spectrophotometry, ion-selective electrode, ion
chromatography, or flow injection analysis. Method D2036-09B, cyanide
amenable to chlorination is determined by comparing the results for one
sample aliquot analyzed for total cyanide and a second aliquot that is
treated with calcium hypochlorite prior to analysis by Method D2036-
09A. There are no procedural changes.
21. ASTM Method D2972-15 (A-C), arsenic, colorimetric, AA gaseous
hydride, AA furnace. The sample is digested with nitric and sulfuric
acids. Method D2972-15A, arsenic is trapped in a solution of silver
diethyldithiocarbamate in pyridine which produces a red-colored product
that is analyzed photometrically by comparison to a standard curve.
Method D2972-15B, arsenic in the digested sample is determined by
hydride generation atomic absorption. Method D2972-15C, arsenic in the
digested sample is determined by graphite furnace atomic absorption.
The changes mirror those for the other metals methods. The QC
frequencies for method blank, CCV, CCB, matrix spike, and duplicate
analyses are now based on a laboratory-defined batch of up to 20
samples.
22. ASTM Method D3223-17, total mercury, cold vapor, manual.
Mercury in the sample is converted to the mercuric ion which is reduced
to elemental mercury, purged from the sample, and analyzed by cold
vapor atomic absorption. The changes mirror those for the other metals
methods, but this version changes the acceptance limit for the CCV from
10% to 15% and adds a requirement for a CCB. Given that the most
comparable EPA procedure, Method 245.1, does not include a CCV
requirement or an acceptance limit, the change of the acceptance limit
from 10% to 15% in the revised ASTM method represents a requirement
that is more stringent than that required in the EPA's procedure and
therefore, the change to the ASTM method is not an impediment to its
approval.
23. ASTM Method D3373-17, vanadium, AA furnace. The sample is
digested with nitric acid and analyzed by graphite furnace atomic
absorption. The concentration of vanadium in the sample is proportional
to the amount of light absorbed during the graphite furnace atomic
absorption analysis and is determined in comparison to a standard
curve. The changes mirror those for the other metals methods. The
proposed changes clarify the requirements for a multi-point calibration
by discussing it in the calibration section as well as the QC section
of all three procedures. The QC frequencies for method blank, CCV, CCB,
matrix spike, and duplicate analyses are now based on a laboratory-
defined batch of up to 20 samples.
24. ASTM Method D3557-17 (A-D), cadmium, AA direct aspiration,
voltammetry, AA furnace. Method D3557-17A, the sample is acid digested
and analyzed by direct aspiration atomic absorption. Method D3557-17B,
the sample is acid digested, the digestate is chelated and extracted.
The extract analyzed by direct aspiration atomic absorption. Method
D3557-17C, the sample is acid digested and analyzed by differential
pulse anodic stripping voltametry. Method D3557-17D, the sample is
digested with nitric acid and analyzed by graphite furnace atomic
absorption. The concentration of cadmium in the sample is determined in
comparison to a standard curve. The changes mirror those for the other
[[Page 56596]]
metals methods. The proposed changes also clarify requirements for a
multi-point calibration by discussing it in the calibration section as
well as the QC section of all three procedures. The QC frequencies for
method blank, CCV, CCB, matrix spike, and duplicate analyses are now
based on a laboratory-defined batch of up to 20 samples, as opposed to
10 samples previously.
25. ASTM Method D3558-15 (A-C), cobalt, AA direct aspiration,
chelation extraction AA, and AA furnace. Method D3558-15A, the sample
is acid digested and analyzed by direct aspiration atomic absorption.
Method D3558-15B, the sample is acid digested, chelated and extracted.
The extract is analyzed by direct aspiration atomic absorption. Method
D3558-15C, the sample is acid digested and analyzed by graphite furnace
atomic absorption. The concentration of cobalt in the sample is
proportional to the amount of light absorbed during the analysis and is
determined in comparison to a standard curve. The changes mirror those
for the other metals methods. The proposed changes also clarify the
requirements for a multi-point calibration by discussing it in the
calibration section as well as the QC section of all three procedures.
The QC frequencies for method blank, CCV, CCB, matrix spike, and
duplicate analyses are now based on a laboratory-defined batch of up to
20 samples, as opposed to 10 samples previously.
26. ASTM Method D3559-15 (A-D), lead, AA direct aspiration,
voltammetry, AA furnace. Method D3559-15A, the sample is acid digested
and analyzed by direct aspiration atomic absorption. Method D3559-15B,
the sample is acid digested, chelated and extracted. The extract is
analyzed by direct aspiration atomic absorption. Method D3559-15C, the
sample is acid digested and analyzed by differential pulse anodic
stripping voltametry. Method D3559-15D, the sample is digested with
nitric acid and analyzed by graphite furnace atomic absorption. The
changes mirror those for the other metals methods. The proposed changes
also clarify the requirements for a multi-point calibration by
discussing it in the calibration section as well as the QC section of
all three procedures. It also adds a new section with the QC
requirements to the direct AA procedure that was already present in the
AA furnace portion of this procedure (D3559-15 [D]).
27. ASTM Method D3590-17 (A, B), total Kjeldahl nitrogen, manual
digestion and distillation or gas diffusion; semi-automated block
digester colorimetric (distillation not required). Method D3590-17A,
the sample is chemically processed to covert nitrogenous compounds to
ammonia, then distilled or subjected to a gas diffusion system which
releases the ammonia for analysis by colorimetry, titrimetry, or
potentiometry. Method D3590-17B, the digestion and distillation are
accomplished by a semi-automated system and the resulting ammonia is
determined by colorimetry of the salicylate/nitroprusside Berthelot
reaction product. This version changes the acceptance limit for the CCV
from 10% to 15% and adds a requirement for a CCB. Given that neither
the approved Standard Methods method for measuring ammonia after the
TKN digestion, nor the comparable EPA Method 350.1, include a CCV
requirement or an acceptance limit, the change of the acceptance limit
from 10% to 15% in the revised ASTM method represents a requirement
that is more stringent than that required in other approved procedures
and therefore is not an impediment to its approval.
28. ASTM Method D3645-15, beryllium (A, B), AA direct aspiration AA
furnace. Method D3645-15A, the sample is acid digested and analyzed by
direct aspiration atomic absorption. Method D3645-15B, the sample is
digested with nitric acid and analyzed by graphite furnace atomic
absorption. This version adds specifications for filter paper. The
proposed changes also clarify the requirements for a three-point
calibration by discussing it in the calibration section as well as the
QC section of both procedures. It also adds a new section with the QC
requirements to the direct aspiration AA procedure that was already
present in the AA furnace portion of this procedure (D3645-15B).
29. ASTM Method D3859-15 (A, B), selenium, AA gaseous hydride, AA
furnace. In Method D3859-15A, the selenium in the sample is converted
to gaseous selenium hydride, which is then analyzed by flame atomic
absorption. Method D3859-15B, the selenium in the sample is converted
to gaseous selenium hydride and analyzed by graphite furnace atomic
absorption. The changes to the gaseous hydride portion of the method
clarify the requirement for a 6-point calibration curve by discussing
it in the calibration section as well as the QC section. The version
adds an updated discussion of block digesters. The QC frequencies for
method blank, CCV, CCB, matrix spike, and duplicate analyses are now
based on a laboratory-defined batch, as opposed to an otherwise
undefined ``batch.'' The GFAA portion contains similar editorial and
technical changes. Technical changes also include specifications for
filter paper. The calibration requirement for three standards has been
clarified by discussing it in the calibration section as well as the QC
section.
30. ASTM Method D3867-16 (A, B) nitrate-nitrite, nitrite and
nitrate; automated cadmium reduction, manual cadmium reduction, bypass
cadmium reduction and subtraction. The combination of nitrate and
nitrite in the sample is determined by reducing the nitrate to nitrite
using a cadmium-copper column, diazotizing and analyzing in either a
manual or automated spectrophotometric system. A second aliquot of the
sample can be analyzed without use of the cadmium reduction column to
determine the concentration of nitrate by difference. The changes add
more detailed QC requirements, including specifically calling out the
laboratory control sample (LCS), method blank, and matrix spike
analyses. The 2016 version adds specifications for filter paper. It
also changes the LCS frequency from 10% of samples to once per batch
(up to 20) and sets the CCB and CCV frequencies at 10%.
31. ASTM Method D4190-15, dissolved elements and total recoverable
elements, direct current plasma. The concentrations of various metal
elements are determined by acidifying an aliquot of the sample and
analyzing it by direct current plasma spectrometry, monitoring a
specific wavelength of light for each element. There is one change that
adds a requirement to run at least four calibration standards for all
metals, as opposed to running four standards for only lithium to
demonstrate linearity.
32. ASTM Method D4282-15, free cyanide, manual micro-diffusion and
colorimetry. The sample is treated and allow for free cyanide diffuse
into a sodium hydroxide solution. An aliquot of that solution is
treated to form a colored product that is measured with a
spectrophotometer at 580 nm. There are no procedural changes.
33. ASTM Method D4327-17, inorganic anions (fluoride, bromide,
chloride, nitrite, nitrate, orthophosphate, and sulfate), ion
chromatography. An aliquot of the sample in injected into an ion
chromatograph equipped with an anion exchange column and a conductivity
detector. The anions are identified based on their retention times and
concentrations are determined by comparison to a standard curve.
Changes include updating the equipment and reagent descriptions to
[[Page 56597]]
reflect more modern instrumentation, such as the use of hydroxide
eluents and eluent regeneration systems.
34. ASTM Method D4382-18, barium, AA furnace. The sample is
digested with nitric acid and analyzed by graphite furnace atomic
absorption. The only procedural change is to the description of the hot
block digester equipment. The new version specifies the capability to
heat samples between 65 and 95 degrees C, instead of ``approximately 95
degrees C.'' That change recognizes the operational characteristics of
hot block digesters that will experience a temperature drop below 95
degrees when samples are added. This should not adversely affect use of
this method for barium.
35. ASTM Method D4658-15, sulfide ion, ion selective electrode. The
sample is treated with a sulfide antioxidant buffer to create a highly
alkaline solution. Sulfide in the sample is measured potentiometrically
with an ion-selective electrode. There are no procedural changes.
36. ASTM Method D4839-03 (Reapproved 2017), total organic carbon;
heated persulfate or UV persulfate oxidation. The sample is sparged
with an inert gas to remove dissolved inorganic carbon and then treated
with persulfate and either heat or UV radiation to convert organic
carbon to carbon dioxide. The carbon dioxide is measured with an infra-
red detector. There are no procedural changes.
37. ASTM Method D5257-17, dissolved hexavalent chromium, ion
chromatography. The sample is filtered and buffered and an aliquot
injected into an ion chromatograph that separates hexavalent chromium
from other ions. The eluent from the chromatograph is treated with an
acidic solution of diphenylcarbohydrazide to form a violet-colored
product that is measured with a photometric detector at 530 nm. The
changes add a few additional warnings or recommendations.
38. ASTM Method D5673-16, dissolved elements and total-recoverable
elements, ICP/MS. The sample is acid digested and analyzed by
inductively coupled plasma/mass spectrometry. Gold was added to the
list of target analytes. Some of the changes address the analysis of
gold.
39. ASTM Method D6508-15, inorganic anions (fluoride, bromide,
chloride, nitrite, nitrate, orthophosphate, and sulfate), capillary ion
electrophoresis with indirect UV detection. An aliquot of the sample in
injected into a capillary ion electrophoresis instrument where the
anions are separated in an applied electric field through a fused
silica capillary. The analytes are detected by a UV detector and their
concentrations are determined by comparison to a standard curve. There
are no procedural changes.
40. ASTM Method D6888-16, available cyanide, flow injection and
ligand exchange, followed by gas diffusion amperometry. An aliquot of
the sample is introduced into a flow injection analysis instrument,
where available cyanide is acidified to form hydrogen cyanide which
diffuses through a hydrophobic gas diffusion membrane into an alkaline
solution and is detected amperometrically with a silver electrode. This
version adds a new mixed ligand exchange reagent, but also retains the
original two ligand reagents that had to be mixed together during the
testing.
41. ASTM Method D6919-17, inorganic alkali and alkaline earth
cations and ammonium (ammonium, calcium magnesium, potassium and
sodium), ion chromatography. An aliquot of the sample in injected into
an ion chromatograph equipped with a cation exchange column and a
conductivity detector. The cations are identified based on their
retention times and concentrations are determined by comparison to a
standard curve. There are no procedural changes.
42. ASTM Method D7237-15 (A), free cyanide, flow injection,
followed by gas diffusion amperometry. An aliquot of the sample is
introduced into a flow injection analysis instrument, where it mixes
with a phosphate buffer to release hydrogen cyanide which diffuses
through a hydrophobic gas diffusion membrane into an alkaline solution
and is detected amperometrically with a silver electrode. There are a
few additions and changes to the newer version of note. The statement
of the applicable range of the method in Section 1.4 has been changed
at the low end, from 2 to 500 [micro]g/L to 5 to 500 [micro]g/L. New
information about interferences from floatation reagents has been added
to Section 6.3. New materials in Section 8 discuss alternative reagents
or concentrations.
43. ASTM Method D7284-13 (Reapproved 2017), total cyanide, manual
distillation with MgCl2 followed by flow injection, gas
diffusion amperometry. The sample is distilled with acid and a
magnesium chloride catalyst to release cyanide to a sodium hydroxide
solution. An aliquot of the sodium hydroxide solution is introduced
into a flow injection analysis instrument, where it is acidified and
the hydrogen cyanide diffuses through a hydrophobic gas diffusion
membrane into an alkaline solution and is detected amperometrically
with a silver electrode. There are no procedural changes.
44. ASTM Method D7511-12 (Reapproved 2017), total cyanide,
segmented flow injection, in-line ultraviolet digestion, followed by
gas diffusion amperometry. The sample is introduced into a segmented
flow injection analysis instrument, where UV light releases cyanide
from cyanide complexes. The sample is then acidified in the instrument
and the produced cyanide gas is detected amperometrically with a silver
electrode. There are no procedural changes.
45. ASTM Method D7573-09 (Reapproved 2017), total organic carbon,
combustion. The sample is sparged with an inert gas to remove dissolved
inorganic carbon, acidified, and then combusted at high temperature
convert organic carbon to carbon dioxide. The carbon dioxide is
measured with an infra-red detector. There are no procedural changes.
The EPA proposes the following changes to Table IC at 40 CFR part
136:
1. ASTM Method D7065-17, nonylphenol, bisphenol A, p-tert-
octylphenol, nonylphenol monoethoxylate, nonylphenol diethoxylate, gas
chromatography/mass spectrometry (GC/MS). The sample is extracted with
methylene chloride and the extract is injected into a gas
chromatograph-mass spectrometer. The target analytes are identified by
retention time and mass spectra and quantified using internal standards
and a calibration curve. There are a large number of editorial and
structural changes in the document. A new QC section has been added.
F. Changes to 40 CFR 136.3 To Include a New ASTM Method Based on
Previously Approved Technologies
The EPA is proposing these changes based on the National Technology
Transfer and Advancement Act of 1995 (NTTAA), Public Law 104-113, which
states that federal agencies and departments shall use technical
standards developed or adopted by the VCSBs if compliance would not be
inconsistent with applicable law or otherwise impracticable. This
method submitted by ASTM is consistent with other already approved
methods.
1. The EPA proposes to add ASTM Method D7781-14 to Table IB for
nitrate-nitrite, nitrite (bypass the enzymatic reduction step) and
nitrate by subtraction. Nitrate is reduced to nitrite by an enzymatic
reaction. The nitrite is diazotized to yield an azo dye which is
[[Page 56598]]
measured colorimetrically. The enzyme reduction step may be by-passed
for measurement of nitrite singly. The value obtained for nitrite may
be subtracted from the value obtained for combined nitrate-nitrite to
calculate the concentration of nitrate. This method is similar to the
currently approved NECi Method N07-0003, USGS Method I-2547-11, and
USGS Method I-2548-11.
G. Changes to 40 CFR 136.3 To Include New United States Geological
Survey (USGS) Inorganic Methods Based on Previously Approved
Technologies
1. The EPA proposes to add USGS Method I-2057-85 titled ``Anions,
ion-exchange chromatographic, automated,'' to Table IB for bromide.
Method I-2057-85 is an ion chromatography method that lists several
target analytes: bromide, chloride, fluoride, nitrate, nitrite,
orthophosphate, and sulfate. These are the same target analytes found
in EPA Methods 300.0 (Part A) and 300.1 (Part A). Both EPA methods are
approved in 40 CFR part 136 for the target analytes listed in the
methods. USGS Method I-2057-85 is similar to EPA Method 300.0, in that
it uses ion chromatography with a sodium bicarbonate/sodium carbonate
eluent and has the same target analyte list. The two methods specify
different columns and eluent concentrations, but rely on essentially
the same underlying chemistry and determinative technique as other ion
chromatography methods approved at 40 CFR part 136 for measurement of
bromide. That is, the sample is introduced into an ion chromatograph.
The anions of interest are separated and measured, using a system
comprised of a guard column, analytical column, suppressor device, and
conductivity detector.
2. The EPA proposes to add USGS Method I-2522-90 titled ``Nitrogen,
ammonia, colorimetry, salicylate-hypochlorite, automated-segmented
flow'' to Table IB for ammonia. USGS Method I-2522-90 uses the same
underlying chemistry and determinative technique as other methods
approved at 40 CFR part 136 for measurement of ammonia. The method is
similar to other approved methods, such as EPA Method 350.1, Standard
Methods Method 4500-NH3 G, and USGS Method I-4523-85, which rely on the
Berthelot reaction. USGS Method I-2522-90 uses a modified version of
the Berthelot reaction in which salicylate and hypochlorite react with
ammonia in the presence of ferricyanide ions to form the salicylic
analog of indophenol blue dye. The resulting color is directly
proportional to the concentration of ammonia present and is measured
using automated spectrophotometry. This is a well-documented
modification to the Berthelot reaction used in EPA Method 351 and is
specifically allowed in Table IB.
3. The EPA proposes to add USGS Method I-2540-90 titled ``Nitrogen,
nitrite, colorimetry, diazotization, automated-segmented flow'' to
Table IB for nitrite. USGS Method I-2540-90 employs the same underlying
chemistry and determinative technique as other methods approved at 40
CFR part 136 for measurement of nitrite. The method is similar to other
methods approved at 40 CFR part 136 for measurement of nitrite,
including USGS Method I-4540-85, which uses an automated-segmented flow
analyzer (Technicon AA II). Method I-2540-90, nitrite reacts with
sulfanilamide under acidic conditions to form a diazo compound which is
coupled with N-1-naphthylethylenediamine dihydrochloride to form a red
compound, the absorbance of which is measured using an automated-
segmented flow, spectrophotometry.
4. The EPA proposes to add USGS Method I-2601-90 titled
``Phosphorus, orthophosphate, colorimetry, phosphomolybdate, automated-
segmented flow'' to Table IB for orthophosphate. USGS Method I-2601-90
employs the same underlying chemistry and determinative technique as
other methods approved in 40 CFR part 136 for measurement of
orthophosphate. Orthophosphate reacts with ammonium molybdate in acidic
solution to form phosphomolybdic acid, which upon reduction with
ascorbic acid produces an intensely blue complex the absorbance of
which is measured using automated spectrophotometry. Antimony potassium
tartrate is added to increase the rate of reduction. The method is
similar to other approved methods, such as USGS Method I-4601-85 which
uses an automated-segmented flow analyzer (Technicon AA II). The
submitted USGS Method I-2601-90 also uses an automated-segmented flow
analyzer (Alpkem rapid flow analyzer). It should be noted that the
approved USGS Method I-4601-85 has two parameter codes listed:
a. Phosphorus, orthophosphate, dissolved, I-2601-85 (mg/L as P);
b. Phosphorus, orthophosphate, total, I-4601-85 (mg/L as P).
Although USGS Method I-4601-85 is listed in Table IB, samples to be
used for measurement of orthophosphate are to be filtered upon
collection per Table II. Therefore, the correct parameter code listed
for the method should have been I-2601-85. I-2601-90 is just an updated
version of that method (parameter code). In Section 3--Interferences,
USGS Method I-2601-85 states: ``Because as phosphorus is easily
adsorbed on sediment, the orthophosphate recovered from the supernatant
solution above a water-suspended sediment after some time has elapsed
may be less than the orthophosphate that would have been determined in
the filtrate from a sample filtered at the time of collection. The
amount recovered may also depend on the type of sediment (clay, sand,
etc.).''
5. The EPA proposes USGS Method I-4472-97 titled ``Metals, Acid
Digestion, Whole-Water Recoverable, inductively coupled plasma-mass
spectrometry'' to be added to Table IB for certain metals by ICP/MS.
USGS Method I-4472-97 is an ICP/MS method that was previously listed
under the same method number as the USGS ICP/AES Method I-4471-97 and
was split out and assigned a unique method number by USGS in 2003. The
EPA proposes to add this to Table IB on the line for ICP/MS and replace
USGS Method I-4471-97 as an approved method for measurement of the
following 16 elements: aluminum, antimony, barium, beryllium, cadmium,
chromium, cobalt, copper, lead, manganese, molybdenum, nickel,
selenium, silver, thallium and zinc. USGS Method I-4472-97 relies on
the same underlying chemistry and determinative technique as other ICP/
MS methods approved at 40 CFR part 136 for measurement of the same 16
elements (e.g., EPA Method 200.8 and Standard Methods Method 3125 B)
where analytes in the sample are solubilized by gentle refluxing with
acids and then measured using inductively coupled plasma-mass
spectrometry.
H. Changes to 40 CFR 136.3 To Include New United States Geological
Survey (USGS) Organic Methods Based on Previously Approved Technologies
1. The EPA proposes to add USGS Method O-4127-96 titled
``Determination of 86 Volatile Organic Compounds in Water by Gas
Chromatography/Mass Spectrometry, Including Detections Less Than
Reporting Limits'' to Table IC for certain organic compounds. USGS
Method O-4127-96 relies on the same underlying chemistry and
determinative technique as other methods approved at 40 CFR part 136
for measurement of the analytes for which the method is being proposed.
Volatile organic compounds are extracted by purging with Helium,
collecting onto a sorbent trap, thermally desorbed, separated by a gas
chromatographic capillary column, and finally determined by a full-scan
[[Page 56599]]
quadrupole mass spectrometer. Compound identification is confirmed by
the gas chromatographic retention time and by the resultant mass
spectrum, typically identified by three unique ions.
2. The EPA Proposes to add USGS Method O-4436-16 titled
``Determination of Heat Purgeable and Ambient Purgeable Volatile
Organic Compounds in Water by Gas Chromatography/Mass Spectrometry'' to
Table IC for certain organic compounds. USGS Method O-4436-16 relies on
the same underlying chemistry and determinative technique as other
methods approved at 40 CFR part 136 for measurement of the analytes for
which the method is being proposed. Volatile organic compounds are
extracted from a water sample and compounds are trapped in a tube
containing a suitable sorbent materials and then thermally desorbed
into a capillary gas chromatographic column interfaced to a mass
spectrometer system. Selected compounds are identified by using strict
qualification criteria, which include analyzing standard reference
materials and comparing retention times and relative ratios of the mass
spectra. Compounds are quantitated using internal standard procedures.
I. Changes to 40 CFR 136.3 To Include Alternate Test Procedures (ATPs)
To promote method innovation, the EPA maintains a program that
allows method developers to apply for EPA review and potential approval
of an alternative method to an existing approved method. This ATP
program is described for CWA applications at 40 CFR 136.4 and 136.5.
The EPA is proposing three ATPs for nationwide use. Based on the EPA's
review, the performance of these ATPs is equally effective as other
methods already approved for measurement. The ATP applicants supplied
EPA with study reports that contain the data from their validation
studies. These study reports and the letters documenting EPA's review
are contained as supporting documents within the docket for this
proposed rule. These proposed new methods include: FIAlab Method 100,
``Determination of Inorganic Ammonia by Continuous Flow Gas Diffusion
and Fluorescence Detector Analysis,'' MACHEREY-NAGEL GmbH and Co.
Method 036/038 NANOCOLOR[supreg] COD LR/HR, ``Spectrophotometric
Measurement of Chemical Oxygen Demand in Water and Wastewater,'' and
Micrology Laboratories, LLC. KwikCountTM EC Medium
Escherichia coli (E. coli) enzyme substrate test, ``Rapid Detection of
E. coli in Beach Water by KwikCountTM EC Membrane
Filtration.'' Descriptions of these new methods proposed for approval
are as follows:
1. FIAlab Instruments, Inc. Method 100, ``Determination of
Inorganic Ammonia by Continuous Flow Gas Diffusion and Fluorescence
Detector Analysis,'' dated April 4, 2018 (FIAlab Instruments, Inc.
2018a). FIAlab Method 100 uses automated flow injection analysis with
gas diffusion and fluorescence detector analysis to determine
concentrations of ammonia in wastewater, ambient water, and Kjeldahl
digestates. The method involves the following steps:
The sample is introduced to the analyzer where it is made
alkaline with sodium hydroxide;
Ammonia is separated from the sample matrix by passage
through a gas diffusion cell;
After separation in the gas diffusion cell, ammonia is
reacted with o-phthalaldehyde to form a fluorescent compound;
The reaction product is detected by a fluorimeter and the
response is directly proportional to the concentration of ammonia in
the sample.
FIAlab Method 100 can be obtained from FIAlab Instruments, Inc.,
334 2151 N Northlake Way, Seattle, WA 98103. Telephone: 425-376-0450.
2. MACHEREY-NAGEL GmbH and Co. Method 036/038 NANOCOLOR[supreg] COD
LR/HR, ``Spectrophotometric Measurement of Chemical Oxygen Demand in
Water and Wastewater,'' Revision 1.5, dated, May 2018 (MACHEREY-NAGEL
GmbH and Co. 2018a). MACHEREY-NAGEL Method 036/038 NANOCOLOR[supreg]
COD LR/HR is a manual method that uses spectrophotometry to measure
chemical oxygen demand in wastewater. The method involves the following
steps:
Chemical Oxygen Demand (COD) is defined as the mg of
oxygen (O2) consumed per liter of sample following
dichromate and sulfuric acid digestion;
A sample is heated for two hours with a strong oxidizing
agent, potassium dichromate. Oxidizable organic compounds react,
reducing the dichromate ion
(Cr2O7\2\-) to the green chromic ion
(Cr\3+\);
When the COD LR 150 test kit is used, the amount of Cr\6+\
remaining after digestion is determined;
When the COD HR 1500 test kit is used, the amount of
Cr\3+\ produced is determined.
MACHEREY-NAGEL GmbH and Co. Method 036/038 NANOCOLOR[supreg] COD
LR/HR, can be obtained from MACHEREY-NAGEL GmbH and Co., 2850 Emrick
Blvd., Bethlehem, PA 18020. Telephone: 888-321-6224.
3. Micrology Laboratories LLC. KwikCountTM EC Medium E.
coli enzyme substrate test, ``Rapid Detection of E. coli in Beach Water
by KwikCountTM EC Membrane Filtration'' uses a membrane
filtration procedure for rapid detection and enumeration of E. coli in
ambient water. The method involves the following steps:
A water sample is filtered through a 0.45-[mu]m pore size,
47-mm diameter membrane filter;
The filter is then placed into a 50-mm plate containing an
absorbent pad containing KwikCountTM EC broth;
Plates are incubated at 41 0.5 [deg]C for 8-
10 hr. The plates are then viewed in the dark using a long-wave UV
light and fluorescent colonies are counted as E. coli.
The KwikCountTM EC Medium E. coli enzyme substrate test
can be obtained from Micrology Laboratories, LLC, 1303 Eisenhower
Drive, Goshen, IN 46526. Telephone: 574-533-3351.
J. Changes to 40 CFR 136.3, Tables IA, IB, and IH
The EPA is proposing the following changes to 40 CFR 136.3, Tables
IA and IH:
1. Table IA: Moving Colilert-18 from Parameter #1 Coliform (fecal),
number per 100 mL or number per gram dry weight, to Parameter #2
Coliform (fecal), (number per 100 mL), to eliminate confusion as to
whether it is approved for sewage sludge in addition to wastewater.
2. Table IA: Adding E. coli, number per 100 mL--MF, two-step,
Standard Methods Method 9222 B/9222 I, to the table along with footnote
31 ``Subject coliform positive samples determined by 9222 B-2015 or
other membrane filter procedure to 9222 I-2015 using NA-MUG media.''
The method was inadvertently omitted from Table IA when Table IA was
split into two tables (IA and IH) in an earlier rulemaking; the
addition corrects that error.
3. Table IA: Revising Parameter #2 Coliform (fecal), deleting ``in
presence of chlorine,'' number per 100 mL. The phrase ``in the presence
of chlorine'' caused confusion because the methods cited were the same
for the analyte/matrix combination that did not state ``in the presence
of chlorine.'' The approved methods did not change.
4. Table IA: Deleting Parameter #4 Coliform (total) in presence of
chlorine, number per 100 mL. Except for ``MF with enrichment,'' all the
methods were duplicative (e.g., Parameters #3 and #4).
[[Page 56600]]
No approved methods for coliform (total) were removed from Table IA.
5. Table IH: Deleting Parameters #2 Coliform (fecal) in presence of
chlorine, number per 100 mL and #4 Coliform (total) in presence of
chlorine, number per 100 mL. Except for ``MF with enrichment'' for
coliform (total), all the methods were duplicative (e.g., Parameters #1
and #2). In addition to the methods being duplicative, Table IH is for
ambient water which would not be expected to contain chlorine. No
approved methods for coliform (fecal) or coliform (total) were removed
from Table IH. The remaining parameters are renumbered.
6. Tables IA and IH: Revising footnote 13 to Table IA and footnote
12 to Table IH as follows ``These tests are collectively known as
defined enzyme substrate tests.'' The remaining text, ``where, for
example, a substrate is used to detect the enzyme [beta]-glucuronidase
produced by E. coli'' has been deleted because the example has caused
some confusion to stakeholders.
7. Tables IA and IH: Adding Quanti-Tray[supreg]/2000 as an option
to footnotes 13 (IH), 15 (IH), 16 (IA) and 18 (IA). The addition of
Quanti-Tray[supreg]/2000 is to address matrices with high bacterial
concentrations and to ensure Tables IA and IH are accurate and
consistent.
8. Tables IA and IH: Adding footnote 30 to Table IA and footnote 27
to Table IH to specify a verification procedure. The footnotes contain
the following language: ``On a monthly basis, at least ten sheen
colonies from positive samples must be verified using Lauryl Tryptose
Broth and brilliant green lactose bile broth, followed by count
adjustment based on these results; and representative non-sheen
colonies should be verified using Lauryl Tryptose Broth. Where
possible, verifications should be done from randomized sample
sources.'' Adding the footnotes address the change in Standard Methods
Method 9222 B-2015 that stated that five typical and five atypical
colonies should be verified per membrane, which could be burdensome to
laboratories analyzing samples other than drinking water. In most
cases, analysis of ambient waters and wastewaters could result in
multiple plates per sample with typical and atypical colonies, whereas
drinking water analyses would seldom result in any typical or atypical
colonies. In addition, the language in footnotes 29 (IA) and 26 (IH),
was revised as follows ``the medium'' was replaced with ``positive
samples'' for clarity and consistency.
9. Tables IA and IH: Adding footnote 32 to Table IA and footnote 30
to Table IH. The footnotes contain the following language
``Verification of colonies by incubation of BHI agar at 10
0.5 [deg]C for 48 3 h is optional.'' As per the Errata to
the 23rd Edition of Standard Methods for the Examination of Water &
Wastewater, ``Growth on a BHI agar plate incubated at 10
0.5 [deg]C for 48 3 h is further verification that the
colony belongs to the genus Enterococcus.''
10. Table IH: Deleting ``or number per gram dry weight'' from
Parameter #1. Table IH is specifically for ambient waters, which does
not require reporting results on a per gram dry weight basis.
11. Table IH: Adding the Alternate Test Procedure
KwikCountTM EC for E. coli, number per 100 mL under
``Other.''
12. Table IH: Adding EPA Method 1623.1 for Parameters 6 and 7. EPA
Method 1623.1 includes updated acceptance criteria for IPR, OPR, and
MS/MSD, and clarifications and revisions based on the use of EPA Method
1623 and technical support questions over the past 19 years. Both
methods 1623 and 1623.1 will be listed as approved in the MUR because
use of either method is acceptable.
13. Table IH: Deleting footnote 5, ``Because the MF technique
usually yields low and variable recovery from chlorinated wastewaters,
the Most Probable Number method will be required to resolve any
controversies.'' Table IH is specifically for ambient waters, so the
footnote is not applicable. The remaining footnotes are renumbered
accordingly.
14. Table IH: Revising footnote 20, to reference only EPA Method
1604. The literature reference was deleted from the footnote because it
resulted in confusion as to whether EPA Method 1604 provided all the
necessary information required by stakeholders to conduct analyses of
ambient waters under the CWA.
K. Changes to Table II at 40 CFR 136.3(e) to Required Containers,
Preservation Techniques, and Holding Times
The EPA is proposing to update footnote 6 to the preservation and
holding time requirements for cyanide to cite the latest version of
ASTM method D7365-09a that was reapproved in 2015. The recommended
sampling and preservation procedures in the ASTM method have not
changed since 2009, but the change to footnote 6 will simplify
identification of the current method that is available from ASTM
International.
The EPA is proposing to add footnote 9 to the preservation and
holding time requirements to the purgeable halocarbons entry. This will
allow the flexibility to collect a single sample with no acidification
to be used for analysis of both purgeable halocarbons and purgeable
aromatic hydrocarbons within seven days of collection, or to collect a
single sample with acidification to be used for analysis of both
purgeable halocarbons (except 2-CEVE) and purgeable aromatic
hydrocarbons within the 14-day maximum holding time specified in Table
II for both classes of compounds. The added flexibility is consistent
with historical requirements for preservation in 40 CFR part 136 and
holding time requirements in other EPA program methods, such as the SW-
846 methods in the Office of Land and Emergency Management. This is
part of the EPA's ongoing effort to harmonize methods between EPA
programs, as requested by the Environmental Laboratory Advisory Board
(ELAB).
Footnote 9 to Table II states: ``If the sample is not adjusted to
pH 2, then the sample must be analyzed within seven days of sampling.''
L. Changes to 40 CFR 136.6 Method Modifications and Analytical
Requirements
In response to requests from ELAB and the Independent Laboratories
Institute (ILI), the EPA is proposing to add a new paragraph
(b)(4)(xviii) to 40 CFR 136.6 that explicitly allows the use of closed-
vessel microwave digestion as a modification to the approved metals
digestion procedure that does not require prior approval. Microwave
digestion has the same fundamental chemistry as a hot plate digestion,
both the microwave and hot plate serve the same function as heat
sources.
V. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory Planning and Review and Review and
Executive Order 13563: Improving Regulation and Regulatory Review
This rule is not a significant regulatory action and was therefore
not submitted to the Office of Management and Budget (OMB) for
interagency review under this E.O.
B. Paperwork Reduction Act
This action does not impose an information collection burden under
the Paperwork Reduction Act. This rule does not impose any information
collection, reporting, or recordkeeping requirements. This proposal
would merely add or revise CWA test procedures.
[[Page 56601]]
C. Regulatory Flexibility Act
I certify that this action would not have a significant economic
impact on a substantial number of small entities under the Regulatory
Flexibility Act. This action will not impose any requirements on small
entities. This action would approve new and revised versions of CWA
testing procedures. Generally, these changes would have a positive
impact on small entities by increasing method flexibility, thereby
allowing entities to reduce costs by choosing more cost-effective
methods. In general, the EPA expects the proposed revisions would lead
to few, if any, increased costs. As explained previously, most of the
proposed changes clarify or improve the instructions in the method,
update the technology used in the method, improve the QC instructions,
make editorial corrections, or reflect the most recent approval year of
an already approved method. In some cases, the proposal would add
alternatives to currently approved methods for a particular analyte
(e.g., Method N07-0003 for Nitrate Reductase Nitrate-Nitrogen
Analysis). Because these methods would be alternatives rather than
requirements, there are no direct costs associated with this proposal.
The EPA proposes methods that would be incorporated by reference. If a
permittee elected to use these methods, they could incur a small cost
associated with obtaining these methods from the listed sources. See
Section IV.B.
D. Unfunded Mandates Reform Act
This action does not contain any unfunded mandate as described in
the Unfunded Mandates Reform Act, 2 U.S.C. 1531-1538, and does not
significantly or uniquely affect small governments. The action imposes
no enforceable duty on any state, local or tribal governments or the
private sector.
E. Executive Order 13132: Federalism
This proposed rule does not have federalism implications. It will
not have substantial direct effects on the states, on the relationship
between the national government and the states, or on the distribution
of power and responsibilities among the various levels of government.
F. Executive Order 13175: Consultation and Coordination With Indian
Tribal Governments
This proposed rule does not have tribal implications as specified
in Executive Order 13175. This rule would merely approve new and
revised versions of test procedures. The EPA does not expect the
proposal would lead to any costs to any tribal governments, and if
incurred, projects they would be minimal. Thus, Executive Order 13175
does not apply to this action.
G. Executive Order 13045: Protection of Children From Environmental
Health Risks and Safety Risks
The EPA interprets Executive Order 13045 as applying only to those
regulatory actions that concern environmental health or safety risks
that the EPA has reason to believe may disproportionately affect
children, per the definition of ``covered regulatory action'' in
section 2-202 of the Executive Order. This action is not subject to
Executive Order 13045 because it does not concern an environmental
health risk or safety risk.
H. Executive Order 13211: Actions That Significantly Affect Energy
Supply, Distribution, or Use
This action is not subject to Executive Order 13211 because it is
not a significant regulatory action under Executive Order 12866.
I. National Technology Transfer and Advancement Act of 1995
This action involves technical standards. The EPA proposes to
approve the use of technical standards developed and recommended by the
Standard Methods Committee and ASTM International for use in compliance
monitoring where the EPA determined that those standards meet the needs
of CWA programs. As described above, this proposal is consistent with
the NTTAA.
J. Executive Order 12898: Federal Actions To Address Environmental
Justice in Minority Populations and Low-Income Populations
The EPA believes the human health or environmental risk addressed
by this action will not have potential disproportionately high and
adverse human health or environmental effects on minority, low-income
or indigenous populations.
List of Subjects in 40 CFR Part 136
Environmental protection, Incorporation by reference, Reporting and
recordkeeping requirements, Test procedures, Water pollution control.
Dated: June 11, 2019.
Andrew R. Wheeler,
Administrator.
For the reasons set out in the preamble, title 40, chapter I of the
Code of Federal Regulations is proposed to be amended as follows:
PART 136--GUIDELINES ESTABLISHING TEST PROCEDURES FOR THE ANALYSIS
OF POLLUTANTS
0
1. The authority citation for part 136 continues to read as follows:
Authority: Secs. 301, 304(h), 307 and 501(a), Pub. L. 95-217,
91 Stat. 1566, et seq. (33 U.S.C. 1251, et seq.) (the Federal Water
Pollution Control Act Amendments of 1972 as amended by the Clean
Water Act of 1977).
0
2. Amend Sec. 136.3 by:
0
a. In paragraph (a), seventh sentence, removing the word ``year'' and
adding in its place the word ``date'' in its place, and removing from
the last sentence the text ``(paragraph (c) of this section, in Sec.
136.5(a) through (d) or 40 CFR 401.13)'' and adding in its place the
text ``paragraph (c) of this section, Sec. 136.5(a) through (d) or 40
CFR 401.13,'' respectively;
0
b. Revising tables IA, IB, IC, and IH;
0
c. Revising paragraph (b) by:
0
i. Revising the introductory text; paragraph (b)(8) introductory text,
and paragraphs (b)(8)(ix) through (b)(xv);
0
ii. Adding paragraph (b)(8)(xvi);
0
iii. Revising paragraphs (b)(10)(xiv), (b)(10)(xxxix), (b)(10)(xliv),
(b)(10)(xlvi), (b)(10)(lii), (b)(10)(liv), (b)(10)(lxvii),
(b)(10)(lxviii), (b)(10)(lxix), (b)(10)(lxx), b)(15)(v), (b)(15)(vi),
(b)(15)(viii) through (xiii), (b)(15)(xv) through (xix), (b)(15)(xxi)
through (xxvi), (b)(15)(xxxi), (b)(15)(xxxiv) and (xxxv),
(b)(15)(xxxvii), (b)(15)(xxxix) through (xliii), (b)(15)(xlv) through
(l), (b)(15)(lii), (b)(15)(liv) and (b)(15)(lv), (b)(15)(lviii),
(b)(15)(lxi) through (lxvi), and (b)(15)(lxviii) through (lxix); and
0
iv. Adding paragraph (b)(15)(lxx);
0
v. Redesignating paragraphs (b)(25) through (b)(36) as paragraphs
(b)(28) through (b)(39);
0
vi. Redesignating paragraphs (b)(19) through (24) as paragraphs (b)(20)
through (25);
0
vii. Adding new paragraphs (b)(19), (26), and (27); and
0
viii. Revising the newly redesignated paragraphs (b)(38)(ii) through
(xxi);
0
ix. Adding paragraphs (b)(38)(xxii) and (xxiii); and
0
c. Revising paragraph (e) Table II.
The revisions and additions read as follows:
Sec. 136.3 Identification of test procedures.
* * * * *
[[Page 56602]]
Table IA--List of Approved Biological Methods for Wastewater and Sewage Sludge
--------------------------------------------------------------------------------------------------------------------------------------------------------
Parameter and units Method \1\ EPA Standard methods AOAC, ASTM, USGS Other
--------------------------------------------------------------------------------------------------------------------------------------------------------
Bacteria
--------------------------------------------------------------------------------------------------------------------------------------------------------
1. Coliform (fecal), number per Most Probable Number p. 132,\3\ 1680,11 15 9221 E-2014..........
100 mL or number per gram dry (MPN), 5 tube, 3 1681,11 20.
weight. dilution, or.
Membrane filter (MF) 2 5, p. 124 \3\........... 9222 D-2015 \29\..... B-0050-85 \4\.......
single step.
2. Coliform (fecal), number per MPN, 5 tube, 3 dilution, p. 132 \3\........... 9221 E-2014; 9221 F.2-
100 mL. or. 2014 \33\.
Multiple tube/multiple ..................... ..................... .................... Colilert-
well, or. 18[supreg].13 18 28
MF2 5, single step \5\.... p. 124 \3\........... 9222 D-2015 \29\.....
3. Coliform (total), number per MPN, 5 tube, 3 dilution, p. 114 \3\........... 9221 B-2014..........
100 mL. or.
MF 2 5, single step or two p. 108 \3\........... 9222 B-2015 \30\..... B-0025-85 \4\.......
step.
MF 2 5, with enrichment... p. 111 \3\........... 9222 (B+B.4e)-2015
\30\.
4. E. coli, number per 100 mL..... MPN 6 8 16 multiple tube, ..................... 9221 B.3-2014/9221 F-
or. 2014 12 14 33.
multiple tube/multiple ..................... 9223 B-2016 \13\..... 991.15 \10\......... Colilert[supreg].13
well, or. 18 Colilert-
18[supreg].13 17 18
MF 2 5 6 7 8, two step, or ..................... 9222 B-2015/9222 I-
2015 \31\.
Single step............... 1603 \21\............ ..................... .................... m-
ColiBlue24[supreg].
\19\
5. Fecal streptococci, number per MPN, 5 tube, 3 dilution, p. 139 \3\........... 9230 B-2013..........
100 mL. or.
MF \2\, or................ p. 136 \3\........... 9230 C-2013 \32\..... B-0055-85 \4\.......
Plate count............... p. 143 \3\...........
6. Enterococci, number per 100 mL. MPN, 5 tube, 3 dilution, p. 139 \3\........... 9230 B-2013..........
or.
MPN 6 8, multiple tube/ ..................... 9230 D-2013.......... D6503-99 \9\........ Enterolert[supreg].
multiple well, or. 13 23
MF 2 5 6 7 8 single step 1600 \24\............ 9230 C-2013 \32\.....
or.
Plate count............... p. 143 \3\...........
7. Salmonella, number per gram dry MPN multiple tube......... 1682 \22\............
weight \11\.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Aquatic Toxicity
--------------------------------------------------------------------------------------------------------------------------------------------------------
8. Toxicity, acute, fresh water Ceriodaphnia dubia acute.. 2002.0 \25\..........
organisms, LC50, percent effluent.
Daphnia puplex and Daphnia 2021.0 \25\..........
magna acute.
Fathead Minnow, Pimephales 2000.0 \25\..........
promelas, and Bannerfin
shiner, Cyprinella
leedsi, acute.
Rainbow Trout, 2019.0 \25\..........
Oncorhynchus mykiss, and
brook trout, Salvelinus
fontinalis, acute.
9. Toxicity, acute, estuarine and Mysid, Mysidopsis bahia, 2007.0 \25\..........
marine organisms of the Atlantic acute.
Ocean and Gulf of Mexico, LC50,
percent effluent.
Sheepshead Minnow, 2004.0 \25\..........
Cyprinodon variegatus,
acute.
Silverside, Menidia 2006.0 \25\..........
beryllina, Menidia
menidia, and Menidia
peninsulae, acute.
10. Toxicity, chronic, fresh water Fathead minnow, Pimephales 1000.0 \26\..........
organisms, NOEC or IC25, percent promelas, larval survival
effluent. and growth.
Fathead minnow, Pimephales 1001.0 \26\..........
promelas, embryo-larval
survival and
teratogenicity.
Daphnia, Ceriodaphnia 1002.0 \26\..........
dubia, survival and
reproduction.
Green alga, Selenastrum 1003.0 \26\..........
capricornutum, growth.
11. Toxicity, chronic, estuarine Sheepshead minnow, 1004.0 \27\..........
and marine organisms of the Cyprinodon variegatus,
Atlantic Ocean and Gulf of larval survival and
Mexico, NOEC or IC25, percent growth.
effluent.
Sheepshead minnow, 1005.0 \27\..........
Cyprinodon variegatus,
embryo-larval survival
and teratogenicity.
Inland silverside, Menidia 1006.0 \27\..........
beryllina, larval
survival and growth.
Mysid, Mysidopsis bahia, 1007.0 \27\..........
survival, growth, and
fecundity.
Sea urchin, Arbacia 1008.0 \27\..........
punctulata, fertilization.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Table IA notes:
\1\ The method must be specified when results are reported.
[[Page 56603]]
\2\ A 0.45-[micro]m membrane filter (MF) or other pore size certified by the manufacturer to fully retain organisms to be cultivated and to be free of
extractables which could interfere with their growth.
\3\ Microbiological Methods for Monitoring the Environment, Water and Wastes, EPA/600/8-78/017. 1978. US EPA.
\4\ U.S. Geological Survey Techniques of Water-Resource Investigations, Book 5, Laboratory Analysis, Chapter A4, Methods for Collection and Analysis of
Aquatic Biological and Microbiological Samples. 1989. USGS.
\5\ Because the MF technique usually yields low and variable recovery from chlorinated wastewaters, the Most Probable Number method will be required to
resolve any controversies.
\6\ Tests must be conducted to provide organism enumeration (density). Select the appropriate configuration of tubes/filtrations and dilutions/volumes
to account for the quality, character, consistency, and anticipated organism density of the water sample.
\7\ When the MF method has been used previously to test waters with high turbidity, large numbers of noncoliform bacteria, or samples that may contain
organisms stressed by chlorine, a parallel test should be conducted with a multiple-tube technique to demonstrate applicability and comparability of
results.
\8\ To assess the comparability of results obtained with individual methods, it is suggested that side-by-side tests be conducted across seasons of the
year with the water samples routinely tested in accordance with the most current Standard Methods for the Examination of Water and Wastewater or EPA
alternate test procedure (ATP) guidelines.
\9\ Annual Book of ASTM Standards-Water and Environmental Technology, Section 11.02. 2000, 1999, 1996. ASTM International.
\10\ Official Methods of Analysis of AOAC International. 16th Edition, 4th Revision, 1998. AOAC International.
\11\ Recommended for enumeration of target organism in sewage sludge.
\12\ The multiple-tube fermentation test is used in 9221B.2-2014. Lactose broth may be used in lieu of lauryl tryptose broth (LTB), if at least 25
parallel tests are conducted between this broth and LTB using the water samples normally tested, and this comparison demonstrates that the false-
positive rate and false-negative rate for total coliform using lactose broth is less than 10 percent. No requirement exists to run the completed phase
on 10 percent of all total coliform-positive tubes on a seasonal basis.
\13\ These tests are collectively known as defined enzyme substrate tests.
\14\ After prior enrichment in a presumptive medium for total coliform using 9221B.2-2014, all presumptive tubes or bottles showing any amount of gas,
growth or acidity within 48 h 3 h of incubation shall be submitted to 9221F-2014. Commercially available EC-MUG media or EC media
supplemented in the laboratory with 50 [micro]g/mL of MUG may be used.
\15\ Method 1680: Fecal Coliforms in Sewage Sludge (Biosolids) by Multiple-Tube Fermentation Using Lauryl-Tryptose Broth (LTB) and EC Medium, EPA-821-R-
14-009. September 2014. U.S. EPA.
\16\ Samples shall be enumerated by the multiple-tube or multiple-well procedure. Using multiple-tube procedures, employ an appropriate tube and
dilution configuration of the sample as needed and report the Most Probable Number (MPN). Samples tested with Colilert[supreg] may be enumerated with
the multiple-well procedures, Quanti-Tray[supreg] or Quanti-Tray[supreg]/2000 and the MPN calculated from the table provided by the manufacturer.
\17\ Colilert-18[supreg] is an optimized formulation of the Colilert[supreg] for the determination of total coliforms and E. coli that provides results
within 18 h of incubation at 35[deg]C rather than the 24 h required for the Colilert[supreg] test and is recommended for marine water samples.
\18\ Descriptions of the Colilert[supreg], Colilert-18[supreg], Quanti-Tray[supreg], and Quanti-Tray[supreg]/2000 may be obtained from IDEXX
Laboratories, Inc.
\19\ A description of the mColiBlue24[supreg] test is available from Hach Company.
\20\ Method 1681: Fecal Coliforms in Sewage Sludge (Biosolids) by Multiple-Tube Fermentation Using A-1 Medium, EPA-821-R-06-013. July 2006. U.S. EPA.
\21\ Method 1603: Escherichia coli (E. coli) in Water by Membrane Filtration Using Modified Membrane-Thermotolerant Escherichia coli Agar (modified
mTEC), EPA-821-R-14-010. September 2014. U.S. EPA.
\22\ Method 1682: Salmonella in Sewage Sludge (Biosolids) by Modified Semisolid Rappaport-Vassiliadis (MSRV) Medium, EPA-821-R-14-012. September 2014.
U.S. EPA.
\23\ A description of the Enterolert[supreg] test may be obtained from IDEXX Laboratories Inc.
\24\ Method 1600: Enterococci in Water by Membrane Filtration Using membrane-Enterococcus Indoxyl-[beta]-D-Glucoside Agar (mEI), EPA-821-R-14-011.
September 2014. U.S. EPA.
\25\ Methods for Measuring the Acute Toxicity of Effluents and Receiving Waters to Freshwater and Marine Organisms, EPA-821-R-02-012. Fifth Edition,
October 2002. U.S. EPA.
\26\ Short-term Methods for Estimating the Chronic Toxicity of Effluents and Receiving Waters to Freshwater Organisms, EPA-821-R-02-013. Fourth Edition,
October 2002. U.S. EPA.
\27\ Short-term Methods for Estimating the Chronic Toxicity of Effluents and Receiving Waters to Marine and Estuarine Organisms, EPA-821-R-02-014. Third
Edition, October 2002. U.S. EPA.
\28\ To use Colilert-18[supreg] to assay for fecal coliforms, the incubation temperature is 44.5 0.2 [deg]C, and a water bath incubator is
used.
\29\ On a monthly basis, at least ten blue colonies from positive samples must be verified using Lauryl Tryptose Broth and EC broth, followed by count
adjustment based on these results; and representative non-blue colonies should be verified using Lauryl Tryptose Broth. Where possible, verifications
should be done from randomized sample sources.
\30\ On a monthly basis, at least ten sheen colonies from positive samples must be verified using lauryl tryptose broth and brilliant green lactose bile
broth, followed by count adjustment based on these results; and representative non-sheen colonies should be verified using lauryl tryptose broth.
Where possible, verifications should be done from randomized sample sources.
\31\ Subject coliform positive samples determined by 9222 B-2015 or other membrane filter procedure to 9222 I-2015 using NA-MUG media.
\32\ Verification of colonies by incubation of BHI agar at 10 0.5 [deg]C for 48 3 h is optional. As per the Errata to the 23rd
Edition of Standard Methods for the Examination of Water and Wastewater ``Growth on a BHI agar plate incubated at 10 0.5 [deg]C for 48
3 h is further verification that the colony belongs to the genus Enterococcus.''
\33\ 9221 F. 2-2014 This procedure allows for simultaneous detection of E. coli and thermotolerant coliforms by adding inverted vials to EC-MUG; the
inverted vials collect gas produced by thermotolerant coliforms.
Table IB--List of Approved Inorganic Test Procedures
--------------------------------------------------------------------------------------------------------------------------------------------------------
Parameter Methodology \58\ EPA \52\ Standard methods \84\ ASTM USGS/AOAC/other
--------------------------------------------------------------------------------------------------------------------------------------------------------
1. Acidity, as CaCO3, mg/L........ Electrometric endpoint or ..................... 2310 B-2011.......... D1067-16............ I-1020-85.\2\
phenolphthalein endpoint.
2. Alkalinity, as CaCO3, mg/L..... Electrometric or ..................... 2320 B-2011.......... D1067-16............ 973.43 \3\, I-1030-
Colorimetric titration to 85.\2\
pH 4.5, Manual.
Automatic................. 310.2 (Rev. 1974) \1\ ..................... .................... I-2030-85.\2\
3. Aluminum--Total,\4\ mg/L....... Digestion \4\, followed by
any of the following:
AA direct aspiration \36\. ..................... 3111 D-2011 or 3111 E- .................... I-3051-85.\2\
2011.
AA furnace................ ..................... 3113 B-2010..........
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES \36\.............. 200.5, Rev 4.2 (2003) 3120 B-2011.......... D1976-12............ I-4471-97.\50\
\68\; 200.7, Rev.
4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4472-
(1994). 97.\81\
Direct Current Plasma ..................... ..................... D4190-15............ See footnote.\34\
(DCP) \36\.
Colorimetric (Eriochrome ..................... 3500-Al B-2011.......
cyanine R).
4. Ammonia (as N), mg/L........... Manual distillation \6\ or 350.1, Rev. 2.0 4500-NH3 B-2011...... .................... 973.49.\3\
gas diffusion (pH >11), (1993).
followed by any of the
following:
Nesslerization............ ..................... ..................... D1426-15 (A)........ 973.49 \3\, I-3520-
85.\2\
Titration................. ..................... 4500-NH3 C-2011......
Electrode................. ..................... 4500-NH3 D-2011 or E- D1426-15 (B)........
2011.
[[Page 56604]]
Manual phenate, ..................... 4500-NH3 F-2011...... .................... See footnote.\60\
salicylate, or other
substituted phenols in
Berthelot reaction-based
methods.
Automated phenate, 350.1 \30\, Rev. 2.0 4500-NH3 G-2011...... .................... I-4523-85 \2\, I-
salicylate, or other (1993). 4500-NH3 H-2011...... 2522-90.\80\
substituted phenols in
Berthelot reaction-based
methods.
Automated electrode....... ..................... ..................... .................... See footnote.\7\
Ion Chromatography........ ..................... ..................... D6919-17............
Automated gas diffusion, ..................... ..................... .................... Timberline Ammonia-
followed by conductivity 001.\74\
cell analysis.
Automated gas diffusion ..................... ..................... .................... FIAlab100.\82\
followed by fluorescence
detector analysis.
5. Antimony--Total,\4\ mg/L....... Digestion \4\, followed by
any of the following:
AA direct aspiration \36\. ..................... 3111 B-2011..........
AA furnace................ ..................... 3113 B-2010..........
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES \36\.............. 200.5, Rev 4.2 (2003) 3120 B-2011.......... D1976-12............
\68\; 200.7, Rev.
4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4472-
(1994). 97.\81\
6. Arsenic-Total,\4\ mg/L......... Digestion \4\, followed by 206.5 (Issued 1978)
any of the following:. \1\.
AA gaseous hydride........ ..................... 3114 B-2011 or 3114 C- D2972-15 (B)........ I-3062-85.\2\
2011.
AA furnace................ ..................... 3113 B-2010.......... D2972-15 (C)........ I-4063-98.\49\
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES \36\.............. 200.5, Rev 4.2 (2003) 3120 B-2011.......... D1976-12............
\68\; 200.7, Rev.
4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4020-
(1994). 05.\70\
Colorimetric (SDDC)....... ..................... 3500-As B-2011....... D2972-15 (A)........ I-3060-85.\2\
7. Barium-Total,\4\ mg/L.......... Digestion \4\, followed by
any of the following:
AA direct aspiration \36\. ..................... 3111 D-2011.......... .................... I-3084-85.\2\
AA furnace................ ..................... 3113 B-2010.......... D4382-18............
ICP/AES \36\.............. 200.5, Rev 4.2 (2003) 3120 B-2011.......... .................... I-4471-97.\50\
\68\; 200.7, Rev.
4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4472-
(1994). 97.\81\
DCP \36\.................. ..................... ..................... .................... See footnote.\34\
8. Beryllium--Total,\4\ mg/L...... Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 D-2011 or 3111 E- D3645-15 (A)........ I-3095-85.\2\
2011.
AA furnace................ ..................... 3113 B-2010.......... D3645-15 (B)........
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES................... 200.5, Rev 4.2 (2003) 3120 B-2011.......... D1976-12............ I-4471-97.\50\
\68\; 200.7, Rev.
4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4472-
(1994). 97.\81\
DCP....................... ..................... ..................... D4190-15............ See footnote.\34\
Colorimetric (aluminon)... ..................... See footnote \61\....
9. Biochemical oxygen demand Dissolved Oxygen Depletion ..................... 5210 B-2016.......... .................... 973.44 \3\, p. 17
(BOD5), mg/L. \9\, I-1578-78 \8\,
See footnote.\10,
63\
10. Boron--Total,\37\ mg/L........ Colorimetric (curcumin)... ..................... 4500-B B-2011........ .................... I-3112-85.\2\
ICP/AES................... 200.5, Rev 4.2 (2003) 3120 B-2011.......... D1976-12............ I-4471-97.\50\
\68\; 200.7, Rev.
4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14.\3\
(1994).
DCP....................... ..................... ..................... D4190-15............ See footnote.\34\
11. Bromide, mg/L................. Electrode................. ..................... ..................... D1246-16............ I-1125-85.\2\
Ion Chromatography........ 300.0, Rev 2.1 (1993) 4110 B-2011, C-2011, D4327-17............ 993.30 \3\, I-2057-
and 300.1, Rev 1.0 D-2011. 85.\79\
(1997).
CIE/UV.................... ..................... 4140 B-2011.......... D6508-15............ D6508, Rev. 2.\54\
12. Cadmium--Total,\4\ mg/L....... Digestion \4\, followed by
any of the following:
AA direct aspiration \36\. ..................... 3111 B-2011 or 3111 C- D3557-17 (A or B)... 974.27 \3\, p. 37
2011. \9\, I-3135-85 \2\
or I-3136-85.\2\
[[Page 56605]]
AA furnace................ ..................... 3113 B-2010.......... D3557-17 (D)........ I-4138-89.\51\
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES \36\.............. 200.5, Rev 4.2 (2003) 3120 B-2011.......... D1976-12............ I-1472-85 \2\ or I-
\68\; 200.7, Rev. 4471-97.\50\
4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4472-
(1994). 97.\81\
DCP \36\.................. ..................... ..................... D4190-15............ See footnote.\34\
Voltametry \11\........... ..................... ..................... D3557-17 (C)........
Colorimetric (Dithizone).. ..................... 3500-Cd-D-1990.......
13. Calcium--Total,\4\ mg/L....... Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 B-2011.......... D511-14 (B)......... I-3152-85.\2\
ICP/AES................... 200.5, Rev 4.2 (2003) 3120 B-2011.......... .................... I-4471-97.\50\
\68\; 200.7, Rev.
4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14.\3\
(1994).
DCP....................... ..................... ..................... .................... See footnote.\34\
Titrimetric (EDTA)........ ..................... 3500-Ca B-2011....... D511-14 (A).........
Ion Chromatography........ ..................... ..................... D6919-17............
14. Carbonaceous biochemical Dissolved Oxygen Depletion ..................... 5210 B-2016.......... .................... See footnote.\35,
oxygen demand (CBOD5), mg/L \12\. with nitrification 63\
inhibitor.
15. Chemical oxygen demand (COD), Titrimetric............... 410.3 (Rev. 1978)\1\. 5220 B-2011 or C-2011 D1252-06(12) (A).... 973.46 \3\, p. 17
mg/L. \9\, I-3560-85.\2\
Spectrophotometric, manual 410.4, Rev. 2.0 5220 D-2011.......... D1252-06(12) (B).... See footnotes \13,
or automatic. (1993). 14, 83\, I-3561-
85.\2\
16. Chloride, mg/L................ Titrimetric: (silver ..................... 4500-Cl- B-2011...... D512-12 (B)......... I-1183-85.\2\
nitrate).
(Mercuric nitrate)........ ..................... 4500-Cl- C-2011...... D512-12 (A)......... 973.51 \3\, I-1184-
85.\2\
Colorimetric: manual...... ..................... ..................... .................... I-1187-85.\2\
Automated (ferricyanide).. ..................... 4500-Cl- E-2011...... .................... I-2187-85.\2\
Potentiometric Titration.. ..................... 4500-Cl- D-2011......
Ion Selective Electrode... ..................... ..................... D512-12 (C).........
Ion Chromatography........ 300.0, Rev 2.1 (1993) 4110 B-2011 or 4110 C- D4327-17............ 993.30 \3\, I-2057-
and 300.1, Rev 1.0 2011. 90.\51\
(1997).
CIE/UV.................... ..................... 4140 B-2011.......... D6508-15............ D6508, Rev. 2.\54\
17. Chlorine-Total residual, mg/L. Amperometric direct....... ..................... 4500-Cl D-2011....... D1253-14............
Amperometric direct (low ..................... 4500-Cl E-2011.......
level).
Iodometric direct......... ..................... 4500-Cl B-2011.......
Back titration ether end- ..................... 4500-Cl C-2011.......
point \15\.
DPD-FAS................... ..................... 4500-Cl F-2011.......
Spectrophotometric, DPD... ..................... 4500-Cl G-2011.......
Electrode................. ..................... ..................... .................... See footnote.\16\
17A. Chlorine-Free Available, mg/L Amperometric direct....... ..................... 4500-Cl D-2011....... D1253-14............
Amperometric direct (low ..................... 4500-Cl E-2011.......
level).
DPD-FAS................... ..................... 4500-Cl F-2011.......
Spectrophotometric, DPD... ..................... 4500-Cl G-2011.......
18. Chromium VI dissolved, mg/L... 0.45-micron filtration
followed by any of the
following:
AA chelation-extraction... ..................... 3111 C-2011.......... .................... I-1232-85.\2\
Ion Chromatography........ 218.6, Rev. 3.3 3500-Cr C-2011....... D5257-17............ 993.23.\3\
(1994).
Colorimetric (diphenyl- ..................... 3500-Cr B-2011....... D1687-17 (A)........ I-1230-85.\2\
carbazide).
19. Chromium--Total,\4\ mg/L...... Digestion \4\, followed by
any of the following:
AA direct aspiration \36\. ..................... 3111 B-2011.......... D1687-17 (B)........ 974.27 \3\, I-3236-
85.\2\
AA chelation-extraction... ..................... 3111 C-2011..........
AA furnace................ ..................... 3113 B-2010.......... D1687-17 (C)........ I-3233-93.\46\
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES \36\.............. 200.5, Rev 4.2 (2003) 3120 B-2011.......... D1976-12............
\68\, 200.7, Rev.
4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4020-
(1994). 05 \70\ I-4472-
97.\81\
DCP \36\.................. ..................... ..................... D4190-15............ See footnote.\34\
Colorimetric (diphenyl- ..................... 3500-Cr B-2011.......
carbazide).
20. Cobalt--Total,\4\ mg/L........ Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 B-2011 or 3111 C- D3558-15 (A or B)... p. 37 \9\, I-3239-
2011. 85.\2\
AA furnace................ ..................... 3113 B-2010.......... D3558-15 (C)........ I-4243-89.\51\
STGFAA.................... 200.9, Rev. 2.2
(1994).
[[Page 56606]]
ICP/AES................... 200.7, Rev. 4.4 3120 B-2011.......... D1976-12............ I-4471-97.\50\
(1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4020-
(1994). 05 \70\ I-4472-
97.\81\
DCP....................... ..................... ..................... D4190-15............ See footnote.\34\
21. Color, platinum cobalt units Colorimetric (ADMI)....... ..................... 2120 F-2011 \78\.....
or dominant wavelength, hue,
luminance purity.
Platinum cobalt visual ..................... 2120 B-2011.......... .................... I-1250-85.\2\
comparison.
Spectrophotometric........ ..................... ..................... .................... See footnote.\18\
22. Copper--Total,\4\ mg/L........ Digestion \4\, followed by
any of the following:
AA direct aspiration \36\. ..................... 3111 B-2011 or 3111 C- D1688-17 (A or B)... 974.27 \3\, p. 37
2011. \9\, I-3270-85 \2\
or I-3271-85.\2\
AA furnace................ ..................... 3113 B-2010.......... D1688-17 (C)........ I-4274-89.\51\
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES \36\.............. 200.5, Rev 4.2 (2003) 3120 B-2011.......... D1976-12............ I-4471-97.\50\
\68\; 200.7, Rev.
4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4020-
(1994). 05 \70\, I-4472-
97.\81\
DCP \36\.................. ..................... ..................... D4190-15............ See footnote.\34\
Colorimetric (Neocuproine) ..................... 3500-Cu B-2011.......
Colorimetric ..................... 3500-Cu C-2011....... .................... See footnote.\19\
(Bathocuproine).
23. Cyanide--Total, mg/L.......... Automated UV digestion/ ..................... ..................... .................... Kelada-01.\55\
distillation and
Colorimetry.
Segmented Flow Injection, ..................... ..................... D7511-12(17)........
In-Line Ultraviolet
Digestion, followed by
gas diffusion amperometry.
Manual distillation with 335.4, Rev. 1.0 4500-CN- B-2016 and C- D2036-09(15)(A), 10-204-00-1-X.\56\
MgCl2, followed by any of (1993) \57\. 2016. D7284-13(17).
the following:
Flow Injection, gas ..................... ..................... D2036-09(15)(A)
diffusion amperometry. D7284-13(17).
Titrimetric............... ..................... 4500-CN- D-2016...... D2036-09(15)(A)..... p. 22.\9\
Spectrophotometric, manual ..................... 4500-CN- E-2016...... D2036-09(15)(A)..... I-3300-85.\2\
Semi-Automated \20\....... 335.4, Rev. 1.0 4500-CN- N-2016...... .................... 10-204-00-1-X \56\,
(1993) \57\. I-4302-85.\2\
Ion Chromatography........ ..................... ..................... D2036-09(15)(A).....
Ion Selective Electrode... ..................... 4500-CN- F-2016...... D2036-09(15)(A).....
24. Cyanide-Available, mg/L....... Cyanide Amenable to ..................... 4500-CN- G-2016...... D2036-09(15)(B).....
Chlorination (CATC);
Manual distillation with
MgCl2, followed by
Titrimetric or
Spectrophotometric.
Flow injection and ligand ..................... ..................... D6888-16............ OIA-1677-09.\44\
exchange, followed by gas
diffusion
amperometry.\59\
Automated Distillation and ..................... ..................... .................... Kelada-01.\55\
Colorimetry (no UV
digestion).
24.A Cyanide-Free, mg/L........... Flow Injection, followed ..................... ..................... D7237-15 (A)........ OIA-1677-09.\44\
by gas diffusion
amperometry.
Manual micro-diffusion and ..................... ..................... D4282-15............
colorimetry.
25. Fluoride--Total, mg/L......... Manual distillation \6\, ..................... 4500-F- B-2011.......
followed by any of the
following:.
Electrode, manual......... ..................... 4500-F- C-2011....... D1179-16 (B)........
Electrode, automated...... ..................... ..................... .................... I-4327-85.\2\
Colorimetric, (SPADNS).... ..................... 4500-F- D-2011....... D1179-16 (A)........
Automated complexone...... ..................... 4500-F- E-2011.......
Ion Chromatography........ 300.0, Rev 2.1 (1993) 4110 B-2011 or C-2011 D4327-17............ 993.30.\3\
and 300.1, Rev 1.0
(1997).
CIE/UV.................... ..................... 4140 B-2011.......... D6508-15............ D6508, Rev. 2.\54\
26. Gold--Total,\4\ mg/L.......... Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 B-2011..........
AA furnace................ 231.2 (Issued 1978) 3113 B-2010..........
\1\.
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14.\3\
(1994).
DCP....................... ..................... ..................... .................... See footnote.\34\
27. Hardness--Total, as CaCO3, mg/ Automated colorimetric.... 130.1 (Issued 1971)
L. \1\.
Titrimetric (EDTA)........ ..................... 2340 C-2011.......... D1126-17............ 973.52B \3\, I-1338-
85.\2\
Ca plus Mg as their ..................... 2340 B-2011..........
carbonates, by any
approved method for Ca
and Mg (See Parameters 13
and 33), provided that
the sum of the lowest
point of quantitation for
Ca and Mg is below the
NPDES permit requirement
for Hardness.
28. Hydrogen ion (pH), pH units... Electrometric measurement. ..................... 4500-H\+\ B-2011..... D1293-99 (A or B)... 973.41 \3\, I-1586-
85.\2\
[[Page 56607]]
Automated electrode....... 150.2 (Dec. 1982) \1\ ..................... .................... See footnote \21\, I-
2587-85.\2\
29. Iridium--Total,\4\ mg/L....... Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 B-2011..........
AA furnace................ 235.2 (Issued 1978)
\1\.
ICP/MS.................... ..................... 3125 B-2011..........
30. Iron--Total,\4\ mg/L.......... Digestion \4\, followed by
any of the following:
AA direct aspiration \36\. ..................... 3111 B-2011 or 3111 C- D1068-15 (A)........ 974.27 \3\, I-3381-
2011. 85.\2\
AA furnace................ ..................... 3113 B-2010.......... D1068-15 (B)........
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES \36\.............. 200.5, Rev. 4.2 3120 B-2011.......... D1976-12............ I-4471-97.\50\
(2003) \68\; 200.7,
Rev. 4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14.\3\
(1994).
DCP \36\.................. ..................... ..................... D4190-15............ See footnote.\34\
Colorimetric ..................... 3500-Fe B-2011....... D1068-15 (C)........ See footnote.\22\
(Phenanthroline).
31. Kjeldahl Nitrogen \5\--Total, Manual digestion \20\ and ..................... 4500-Norg B-2011 or C- D3590-17 (A)........ I-4515-91.\45\
(as N), mg/L. distillation or gas 2011 and 4500-NH3 B-
diffusion, followed by 2011.
any of the following:
Titration................. ..................... 4500-NH3 C-2011...... .................... 973.48.\3\
Nesslerization............ ..................... ..................... D1426-15 (A)........
Electrode................. ..................... 4500-NH3 D-2011 or E- D1426-15 (B)........
2011.
Semi-automated phenate.... 350.1, Rev. 2.0 4500-NH3 G-2011......
(1993). 4500-NH3 H-2011......
Manual phenate, ..................... 4500-NH3 F-2011...... .................... See footnote.\60\
salicylate, or other
substituted phenols in
Berthelot reaction based
methods.
Automated gas diffusion, ..................... ..................... .................... Timberline Ammonia-
followed by conductivity 001.\74\
cell analysis.
Automated gas diffusion ..................... ..................... .................... FIAlab 100.\82\
followed by fluorescence
detector analysis.
Automated Methods for TKN
that do not require
manual distillation.
Automated phenate, 351.1 (Rev. 1978) \1\ ..................... .................... I-4551-78.\8\
salicylate, or other
substituted phenols in
Berthelot reaction based
methods colorimetric
(auto digestion and
distillation).
Semi-automated block 351.2, Rev. 2.0 4500-Norg D-2011..... D3590-17 (B)........ I-4515-91.\45\
digestor colorimetric (1993).
(distillation not
required).
Block digester, followed ..................... ..................... .................... See footnote.\39\
by Auto distillation and
Titration.
Block digester, followed ..................... ..................... .................... See footnote.\40\
by Auto distillation and
Nesslerization.
Block Digester, followed ..................... ..................... .................... See footnote.\41\
by Flow injection gas
diffusion (distillation
not required).
Digestion with ..................... ..................... .................... Hach 10242.\76\
peroxdisulfate, followed
by Spectrophotometric
(2,6-dimethyl phenol).
Digestion with persulfate, ..................... ..................... .................... NCASI TNTP
followed by Colorimetric. W10900.\77\
32. Lead--Total,\4\ mg/L.......... Digestion \4\, followed by
any of the following:
AA direct aspiration \36\. ..................... 3111 B-2011 or 3111 C- D3559-15 (A or B)... 974.27 \3\, I-3399-
2011.. 85.\2\
AA furnace................ ..................... 3113 B-2010.......... D3559-15 (D)........ I-4403-89.\51\
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES \36\.............. 200.5, Rev. 4.2 3120 B-2011.......... D1976-12............ I-4471-97.\50\
(2003) \68\; 200.7,
Rev. 4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4472-
(1994). 97.\81\
DCP \36\.................. ..................... ..................... D4190-15............ See footnote.\34\
Voltametry \11\........... ..................... ..................... D3559-15 (C)........
Colorimetric (Dithizone).. ..................... 3500-Pb B-2011....... .................... ....................
33. Magnesium--Total,\4\ mg/L..... Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 B-2011.......... D511-14 (B)......... 974.27 \3\, I-3447-
85.\2\
ICP/AES................... 200.5, Rev. 4.2 3120 B-2011.......... D1976-12............ I-4471-97.\50\
(2003) \68\; 200.7,
Rev. 4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14.\3\
(1994).
DCP....................... ..................... ..................... .................... See footnote.\34\
Ion Chromatography........ ..................... ..................... D6919-17............
[[Page 56608]]
34. Manganese--Total,\4\ mg/L..... Digestion \4\, followed by
any of the following:
AA direct aspiration \36\. ..................... 3111 B-2011.......... D858-17 (A or B).... 974.27 \3\, I-3454-
85.\2\
AA furnace................ ..................... 3113 B-2010.......... D858-17 (C).........
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES \36\.............. 200.5, Rev. 4.2 3120 B-2011.......... D1976-12............ I-4471-97.\50\
(2003) \68\; 200.7,
Rev. 4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4472-
(1994). 97.\81\
DCP \36\.................. ..................... ..................... D4190-15............ See footnote.\34\
Colorimetric (Persulfate). ..................... 3500-Mn B-2011....... .................... 920.203.\3\
Colorimetric (Periodate).. ..................... ..................... .................... See footnote.\23\
35. Mercury--Total, mg/L.......... Cold vapor, Manual........ 245.1, Rev. 3.0 3112 B-2011.......... D3223-17............ 977.22 \3\, I-3462-
(1994). 85.\2\
Cold vapor, Automated..... 245.2 (Issued 1974)
\1\.
Cold vapor atomic 245.7 Rev. 2.0 (2005) ..................... .................... I-4464-01.\71\
fluorescence spectrometry \17\.
(CVAFS).
Purge and Trap CVAFS...... 1631E \43\...........
36. Molybdenum--Total,\4\ mg/L.... Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 D-2011.......... .................... I-3490-85.\2\
AA furnace................ ..................... 3113 B-2010.......... .................... I-3492-96.\47\
ICP/AES................... 200.7, Rev. 4.4 3120 B-2011.......... D1976-12............ I-4471-97.\50\
(1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4472-
(1994). 97.\81\
DCP....................... ..................... ..................... .................... See footnote.\34\
37. Nickel--Total,\4\ mg/L........ Digestion \4\, followed by
any of the following:
AA direct aspiration \36\. ..................... 3111 B-2011 or....... D1886-14 (A or B)... I-3499-85.\2\
3111 C-2011..........
AA furnace................ ..................... 3113 B-2010.......... D1886-14 (C)........ I-4503-89.\51\
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES \36\.............. 200.5, Rev. 4.2 3120 B-2011.......... D1976-12............ I-4471-97.\50\
(2003) \68\; 200.7,
Rev. 4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4020-
(1994). 05 \70\ I-4472-
97.\81\
DCP \36\.................. ..................... ..................... D4190-15............ See footnote.\34\
38. Nitrate (as N), mg/L.......... Ion Chromatography........ 300.0, Rev. 2.1 4110 B-2011 or C-2011 D4327-17............ 993.30.\3\
(1993) and 300.1,
Rev. 1.0 (1997).
CIE/UV.................... ..................... 4140 B-2011.......... D6508-15............ D6508, Rev. 2.\54\
Ion Selective Electrode... ..................... 4500-NO3- D-2016.....
Colorimetric (Brucine 352.1 (Issued 1971) ..................... .................... 973.50 \3\, 419D 1
sulfate). \1\. 7, p. 28.\9\
Spectrophotometric (2,6- ..................... ..................... .................... Hach 10206.\75\
dimethylphenol).
Nitrate-nitrite N minus
Nitrite N (See parameters
39 and 40)
39. Nitrate-nitrite (as N), mg/L.. Cadmium reduction, Manual. ..................... 4500-NO3- E-2016..... D3867-16 (B)........
Cadmium reduction, 353.2, Rev. 2.0 4500-NO3- F-2016..... D3867-16 (A)........ I-2545-90.\51\
Automated. (1993). 4500-NO3- I-2016.....
Automated hydrazine....... ..................... 4500-NO3- H-2016.....
Reduction/Colorimetric.... ..................... ..................... .................... See footnote.\62\
Ion Chromatography........ 300.0, Rev. 2.1 4110 B-2011 or C-2011 D4327-17............ 993.30.\3\
(1993) and 300.1,
Rev. 1.0 (1997).
CIE/UV.................... ..................... 4140 B-2011.......... D6508-15............ D6508, Rev. 2.\54\
Enzymatic reduction, ..................... ..................... D7781-14............ I-2547-11 \72\
followed by automated I-2548-11 \72\
colorimetric N07-0003.\73\
determination.
Enzymatic reduction, ..................... 4500-NO3- J-2018.....
followed by manual
colorimetric
determination.
Spectrophotometric (2,6- ..................... ..................... .................... Hach 10206.\75\
dimethylphenol).
40. Nitrite (as N), mg/L.......... Spectrophotometric: Manual ..................... 4500-NO2- B-2011..... .................... See footnote.\25\
Automated (Diazotization). ..................... ..................... .................... I-4540-85 \2\, See
footnote \62\
I-2540-90.\80\
Automated (*bypass cadmium 353.2, Rev. 2.0 4500-NO3- F-2016..... D3867-16 (A)........ I-4545-85.\2\
reduction). (1993). 4500-NO3- I-2016.....
Manual (*bypass cadmium or ..................... 4500-NO3- E-2016, D3867-16 (B)........
enzymatic reduction). 4500-NO3\-\ J-2018.
Ion Chromatography........ 300.0, Rev. 2.1 4110 B-2011 or C-2011 D4327-17............ 993.30.\3\
(1993) and 300.1,
Rev. 1.0 (1997).
CIE/UV.................... ..................... 4140 B-2011.......... D6508-15............ D6508, Rev. 2.\54\
[[Page 56609]]
Automated (* bypass ..................... ..................... D7781-14............ I-2547-11 \72\
Enzymatic reduction). I-2548-11 \72\
N07-0003.\73\
41. Oil and grease--Total Hexane extractable 1664 Rev. A; 1664 5520 B-2011 \38\.....
recoverable, mg/L. material (HEM): n-Hexane Rev. B \42\.
extraction and gravimetry.
Silica gel treated HEM 1664 Rev. A; 1664 5520 B-2011 \38\ and
(SGT-HEM): Silica gel Rev. B \42\. 5520 F-2011 \38\.
treatment and gravimetry.
42. Organic carbon--Total (TOC), Combustion................ ..................... 5310 B-2014.......... D7573-09(17)........ 973.47 \3\, p.
mg/L. 14.\24\
Heated persulfate or UV ..................... 5310 C-2014.......... D4839-03(17)........ 973.47 \3\, p.
persulfate oxidation. 5310 D-2011.......... 14.\24\
43. Organic nitrogen (as N), mg/L. Total Kjeldahl N
(Parameter 31) minus
ammonia N (Parameter 4)
44. Ortho-phosphate (as P), mg/L.. Ascorbic acid method:
Automated................. 365.1, Rev. 2.0 4500-P F-2011 or G- .................... 973.56 \3\, I-4601-
(1993). 2011. 85 \2\, I-2601-
90.\80\
Manual, single-reagent.... ..................... 4500-P E-2011........ D515-88 (A)......... 973.55.\3\
Manual, two-reagent....... 365.3 (Issued 1978)
\1\.
Ion Chromatography........ 300.0, Rev. 2.1 4110 B-2011 or C-2011 D4327-17............ 993.30.\3\
(1993) and 300.1,
Rev. 1.0 (1997).
CIE/UV.................... ..................... 4140 B-2011.......... D6508-15............ D6508, Rev. 2.\54\
45. Osmium--Total \4\, mg/L....... Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 D-2011..........
AA furnace................ 252.2 (Issued 1978)
\1\.
46. Oxygen, dissolved, mg/L....... Winkler (Azide ..................... 4500-O (B-F)-2016.... D888-12 (A)......... 973.45B \3\, I-1575-
modification). 78.\8\
Electrode................. ..................... 4500-O G-2016........ D888-12 (B)......... I-1576-78.\8\
Luminescence-Based Sensor. ..................... 4500-O H-2016........ D888-12 (C)......... See footnote.\63\
See footnote.\64\
47. Palladium--Total,\4\ mg/L..... Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 B-2011..........
AA furnace................ 253.2 (Issued 1978)
\1\.
ICP/MS.................... ..................... 3125 B-2011..........
DCP....................... ..................... ..................... .................... See footnote.\34\
48. Phenols, mg/L................. Manual distillation \26\, 420.1 (Rev. 1978) \1\ 5530 B-2010.......... D1783-01(12)
followed by any of the
following:
Colorimetric (4AAP) manual 420.1 (Rev. 1978) \1\ 5530 D-2010 \27\..... D1783-01(12) (A or
B)
Automated colorimetric 420.4 Rev. 1.0 (1993)
(4AAP).
49. Phosphorus (elemental), mg/L.. Gas-liquid chromatography. ..................... ..................... .................... See footnote.\28\
50. Phosphorus--Total, mg/L....... Digestion \20\, followed ..................... 4500-P B(5)-2011..... .................... 973.55.\3\
by any of the following:
Manual.................... 365.3 (Issued 1978) 4500-P E-2011........ D515-88 (A)
\1\.
Automated ascorbic acid 365.1 Rev. 2.0 (1993) 4500-P (F-H)-2011.... .................... 973.56 \3\, I-4600-
reduction. 85.\2\
ICP/AES 4 36.............. 200.7, Rev. 4.4 3120 B-2011.......... .................... I-4471-97.\50\
(1994).
Semi-automated block 365.4 (Issued 1974) ..................... D515-88 (B)......... I-4610-91.\48\
digestor (TKP digestion). \1\.
Digestion with persulfate, ..................... ..................... .................... NCASI TNTP
followed by Colorimetric. W10900.\77\
51. Platinum--Total,\4\ mg/L...... Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 B-2011..........
AA furnace................ 255.2 (Issued 1978)
\1\.
ICP/MS.................... ..................... 3125 B-2011..........
DCP....................... ..................... ..................... .................... See footnote.\34\
52. Potassium--Total,\4\ mg/L..... Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 B-2011.......... .................... 973.53 \3\, I-3630-
85.\2\
ICP/AES................... 200.7, Rev. 4.4 3120 B-2011..........
(1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14.\3\
(1994).
Flame photometric......... ..................... 3500-K B-2011........
Electrode................. ..................... 3500-K C-2011........
Ion Chromatography........ ..................... ..................... D6919-17............
53. Residue--Total, mg/L.......... Gravimetric, 103-105[deg]. ..................... 2540 B-2015.......... .................... I-3750-85.\2\
54. Residue--filterable, mg/L..... Gravimetric, 180[deg]..... ..................... 2540 C-2015.......... D5907-13............ I-1750-85.\2\
55. Residue--non-filterable (TSS), Gravimetric, 103-105[deg] ..................... 2540 D-2015.......... D5907-13............ I-3765-85.\2\
mg/L. post-washing of residue.
56. Residue--settleable, ml/L..... Volumetric (Imhoff cone), ..................... 2540 F-2015..........
or gravimetric.
[[Page 56610]]
57. Residue--Volatile, mg/L....... Gravimetric, 550[deg]..... 160.4 (Issued 1971) 2540 E-2015.......... .................... I-3753-85.\2\
\1\.
58. Rhodium--Total,\4\ mg/L....... Digestion \4\, followed by
any of the following:
AA direct aspiration, or.. ..................... 3111 B-2011..........
AA furnace................ 265.2 (Issued 1978)
\1\.
ICP/MS.................... ..................... 3125 B-2011..........
59. Ruthenium--Total,\4\ mg/L..... Digestion \4\, followed by
any of the following:
AA direct aspiration, or.. ..................... 3111 B-2011..........
AA furnace................ 267.2 \1\............
ICP/MS.................... ..................... 3125 B-2011..........
60. Selenium--Total,\4\ mg/L...... Digestion \4\, followed by
any of the following:
AA furnace................ ..................... 3113 B-2010.......... D3859-15 (B)........ I-4668-98.\49\
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES \36\.............. 200.5, Rev 4.2 (2003) 3120 B-2011.......... D1976-12
\68\; 200.7, Rev.
4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4020-
(1994). 05 \70\ I-4472-
97.\81\
AA gaseous hydride........ ..................... 3114 B-2011, or 3114 D3859-15 (A)........ I-3667-85.\2\
C-2011.
61. Silica--Dissolved,\37\ mg/L... 0.45-micron filtration
followed by any of the
following:
Colorimetric, Manual...... ..................... 4500-SiO2 C-2011..... D859-16............. I-1700-85.\2\
Automated ..................... 4500-SiO2 E-2011 or F- .................... I-2700-85.\2\
(Molybdosilicate). 2011.
ICP/AES................... 200.5, Rev. 4.2 3120 B-2011.......... .................... I-4471-97.\50\
(2003) \68\; 200.7,
Rev. 4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14.\3\
(1994).
62. Silver--Total,\4, 31\ mg/L.... Digestion 4 29, followed
by any of the following:
AA direct aspiration...... ..................... 3111 B-2011 or 3111 C- .................... 974.27 \3\, p. 37
2011. \9\, I-3720-85.\2\
AA furnace................ ..................... 3113 B-2010.......... .................... I-4724-89.\51\
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES................... 200.5, Rev. 4.2 3120 B-2011.......... D1976-12............ I-4471-97.\50\
(2003) \68\; 200.7,
Rev. 4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14 \3\, I-4472-
(1994). 97.\81\
DCP....................... ..................... ..................... .................... See footnote.\34\
63. Sodium--Total,\4\ mg/L........ Digestion \4\, followed by
any of the following:
AA direct aspiration...... ..................... 3111 B-2011.......... .................... 973.54 \3\, I-3735-
85.\2\
ICP/AES................... 200.5, Rev. 4.2 3120 B-2011.......... .................... I-4471-97.\50\
(2003) \68\; 200.7,
Rev. 4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14.\3\
(1994).
DCP....................... ..................... ..................... .................... See footnote.\34\
Flame photometric......... ..................... 3500-Na B-2011.......
Ion Chromatography........ ..................... ..................... D6919-17............
64. Specific conductance, Wheatstone bridge......... 120.1 (Rev. 1982) \1\ 2510 B-2011.......... D1125-95(99) (A).... 973.40,\3\ I-2781-
micromhos/cm at 25 [deg]C. 85.\2\
65. Sulfate (as SO4), mg/L........ Automated colorimetric.... 375.2, Rev. 2.0 4500-SO4\2-\ F-2011
(1993). or G-2011.
Gravimetric............... ..................... 4500-SO4\2-\ C-2011 .................... 925.54.\3\
or D-2011.
Turbidimetric............. ..................... 4500-SO4\2-\ E-2011.. D516-16.............
Ion Chromatography........ 300.0, Rev. 2.1 4110 B-2011 or C-2011 D4327-17............ 993, I-4020-05
(1993) and 300.1, \70\.303
Rev. 1.0 (1997).
CIE/UV.................... ..................... 4140 B-2011.......... D6508-15............ D6508, Rev. 2.\54\
66. Sulfide (as S), mg/L.......... Sample Pretreatment....... ..................... 4500-S 2- B, C-2011..
Titrimetric (iodine)...... ..................... 4500-S 2- F-2011..... .................... I-3840-85.\2\
Colorimetric (methylene ..................... 4500-S 2- D-2011.....
blue).
Ion Selective Electrode... ..................... 4500-S 2- G-2011..... D4658-15............
67. Sulfite (as SO3), mg/L........ Titrimetric (iodine- ..................... 4500-SO32- B-2011....
iodate).
68. Surfactants, mg/L............. Colorimetric (methylene ..................... 5540 C-2011.......... D2330-02............
blue).
69. Temperature, [deg]C........... Thermometric.............. ..................... 2550 B-2010.......... .................... See footnote.\32\
70. Thallium-Total,\4\ mg/L....... Digestion,\4\ followed by
any of the following:
[[Page 56611]]
AA direct aspiration...... ..................... 3111 B-2011..........
AA furnace................ 279.2 (Issued 1978) \ 3113 B-2010..........
1\.
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES................... 200.7, Rev. 4.4 3120 B-2011.......... D1976-12............
(1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14,\3\ I-4471-97
(1994). \50\ I-4472-97.\81\
71. Tin-Total,\4\ mg/L............ Digestion,\4\ followed by
any of the following:
AA direct aspiration...... ..................... 3111 B-2011.......... .................... I-3850-78.\8\
AA furnace................ ..................... 3113 B-2010..........
STGFAA.................... 200.9, Rev. 2.2
(1994).
ICP/AES................... 200.5, Rev. 4.2
(2003) \68\; 200.7,
Rev. 4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14.\3\
(1994).
72. Titanium-Total,\4\ mg/L....... Digestion,\4\ followed by
any of the following:
AA direct aspiration...... ..................... 3111 D-2011..........
AA furnace................ 283.2 (Issued 1978)
\1\.
ICP/AES................... 200.7, Rev. 4.4
(1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14.\3\
(1994).
DCP....................... ..................... ..................... .................... See footnote.\34\
73. Turbidity, NTU \53\........... Nephelometric............. 180.1, Rev. 2.0 2130 B-2011.......... D1889-00............ I-3860-85 \2\
(1993). See footnote \65\
See footnote \66\
See footnote.\67\
74. Vanadium-Total,\4\ mg/L....... Digestion,\4\ followed by
any of the following:
AA direct aspiration...... ..................... 3111 D-2011..........
AA furnace................ ..................... 3113 B-2010.......... D3373-17............
ICP/AES................... 200.5, Rev. 4.2 3120 B-2011.......... D1976-12............ I-4471-97.\50\
(2003) \68\; 200.7,
Rev. 4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14,\3\ I-4020-
(1994). 05.\70\
DCP....................... ..................... ..................... D4190-15............ See footnote.\34\
Colorimetric (Gallic Acid) ..................... 3500-V B-2011........
75. Zinc-Total\4\, mg/L........... Digestion,\4\ followed by
any of the following:
AA direct aspiration \36\. ..................... 3111 B-2011 or 3111 C- D1691-17 (A or B)... 974.27,\3\ p. 37,\9\
2011. I-3900-85.\2\
AA furnace................ 289.2 (Issued 1978)
\1\.
ICP/AES \36\.............. 200.5, Rev. 4.2 3120 B-2011.......... D1976-12............ I-4471-97.\50\
(2003) \68\; 200.7,
Rev. 4.4 (1994).
ICP/MS.................... 200.8, Rev. 5.4 3125 B-2011.......... D5673-16............ 993.14,\3\ I-4020-05
(1994). \70\ I-4472-97.\81\
DCP \36\.................. ..................... ..................... D4190-15............ See footnote.\34\
Colorimetric (Zincon)..... ..................... 3500 Zn B-2011....... .................... See footnote.\33\
76. Acid Mine Drainage............ .......................... 1627 \69\............
--------------------------------------------------------------------------------------------------------------------------------------------------------
Table IB Notes:
\1\ Methods for Chemical Analysis of Water and Wastes, EPA-600/4-79-020. Revised March 1983 and 1979, where applicable. U.S. EPA.
\2\ Methods for Analysis of Inorganic Substances in Water and Fluvial Sediments, Techniques of Water-Resource Investigations of the U.S. Geological
Survey, Book 5, Chapter A1., unless otherwise stated. 1989. USGS.
\3\ Official Methods of Analysis of the Association of Official Analytical Chemists, Methods Manual, Sixteenth Edition, 4th Revision, 1998. AOAC
International.
\4\ For the determination of total metals (which are equivalent to total recoverable metals) the sample is not filtered before processing. A digestion
procedure is required to solubilize analytes in suspended material and to break down organic-metal complexes (to convert the analyte to a detectable
form for colorimetric analysis). For non-platform graphite furnace atomic absorption determinations, a digestion using nitric acid (as specified in
Section 4.1.3 of Methods for Chemical Analysis of Water and Wastes) is required prior to analysis. The procedure used should subject the sample to
gentle acid refluxing, and at no time should the sample be taken to dryness. For direct aspiration flame atomic absorption (FLAA) determinations, a
combination acid (nitric and hydrochloric acids) digestion is preferred, prior to analysis. The approved total recoverable digestion is described as
Method 200.2 in Supplement I of ``Methods for the Determination of Metals in Environmental Samples'' EPA/600R-94/111, May, 1994, and is reproduced in
EPA Methods 200.7, 200.8, and 200.9 from the same Supplement. However, when using the gaseous hydride technique or for the determination of certain
elements such as antimony, arsenic, selenium, silver, and tin by non-EPA graphite furnace atomic absorption methods, mercury by cold vapor atomic
absorption, the noble metals and titanium by FLAA, a specific or modified sample digestion procedure may be required, and, in all cases the referenced
method write-up should be consulted for specific instruction and/or cautions. For analyses using inductively coupled plasma-atomic emission
spectrometry (ICP-AES), the direct current plasma (DCP) technique or EPA spectrochemical techniques (platform furnace AA, ICP-AES, and ICP-MS), use
EPA Method 200.2 or an approved alternate procedure (e.g., CEM microwave digestion, which may be used with certain analytes as indicated in Table IB);
the total recoverable digestion procedures in EPA Methods 200.7, 200.8, and 200.9 may be used for those respective methods. Regardless of the
digestion procedure, the results of the analysis after digestion procedure are reported as ``total'' metals.
\5\ Copper sulfate or other catalysts that have been found suitable may be used in place of mercuric sulfate.
\6\ Manual distillation is not required if comparability data on representative effluent samples are on file to show that this preliminary distillation
step is not necessary; however, manual distillation will be required to resolve any controversies. In general, the analytical method should be
consulted regarding the need for distillation. If the method is not clear, the laboratory may compare a minimum of 9 different sample matrices to
evaluate the need for distillation. For each matrix, a matrix spike and matrix spike duplicate are analyzed both with and without the distillation
step (for a total of 36 samples, assuming 9 matrices). If results are comparable, the laboratory may dispense with the distillation step for future
analysis. Comparable is defined as <20% RPD for all tested matrices). Alternatively, the two populations of spike recovery percentages may be compared
using a recognized statistical test.
[[Page 56612]]
\7\ Industrial Method Number 379-75 WE Ammonia, Automated Electrode Method, Technicon Auto Analyzer II. February 19, 1976. Bran & Luebbe Analyzing
Technologies Inc.
\8\ The approved method is that cited in Methods for Determination of Inorganic Substances in Water and Fluvial Sediments, Techniques of Water-Resources
Investigations of the U.S. Geological Survey, Book 5, Chapter A1. 1979. USGS.
\9\ American National Standard on Photographic Processing Effluents. April 2, 1975. American National Standards Institute.
\10\ In-Situ Method 1003-8-2009, Biochemical Oxygen Demand (BOD) Measurement by Optical Probe. 2009. In-Situ Incorporated.
\11\ The use of normal and differential pulse voltage ramps to increase sensitivity and resolution is acceptable.
\12\ Carbonaceous biochemical oxygen demand (CBOD5) must not be confused with the traditional BOD5 test method which measures ``total 5-day BOD.'' The
addition of the nitrification inhibitor is not a procedural option but must be included to report the CBOD5 parameter. A discharger whose permit
requires reporting the traditional BOD5 may not use a nitrification inhibitor in the procedure for reporting the results. Only when a discharger's
permit specifically states CBOD5 is required can the permittee report data using a nitrification inhibitor.
\13\ OIC Chemical Oxygen Demand Method. 1978. Oceanography International Corporation.
\14\ Method 8000, Chemical Oxygen Demand, Hach Handbook of Water Analysis, 1979. Hach Company.
\15\ The back-titration method will be used to resolve controversy.
\16\ Orion Research Instruction Manual, Residual Chlorine Electrode Model 97-70. 1977. Orion Research Incorporated. The calibration graph for the Orion
residual chlorine method must be derived using a reagent blank and three standard solutions, containing 0.2, 1.0, and 5.0 mL 0.00281 N potassium
iodate/100 mL solution, respectively.
\17\ Method 245.7, Mercury in Water by Cold Vapor Atomic Fluorescence Spectrometry, EPA-821-R-05-001. Revision 2.0, February 2005. US EPA.
\18\ National Council of the Paper Industry for Air and Stream Improvement (NCASI) Technical Bulletin 253 (1971) and Technical Bulletin 803, May 2000.
\19\ Method 8506, Bicinchoninate Method for Copper, Hach Handbook of Water Analysis. 1979. Hach Company.
\20\ When using a method with block digestion, this treatment is not required.
\21\ Industrial Method Number 378-75WA, Hydrogen ion (pH) Automated Electrode Method, Bran & Luebbe (Technicon) Autoanalyzer II. October 1976. Bran &
Luebbe Analyzing Technologies.
\22\ Method 8008, 1,10-Phenanthroline Method using FerroVer Iron Reagent for Water. 1980. Hach Company.
\23\ Method 8034, Periodate Oxidation Method for Manganese, Hach Handbook of Wastewater Analysis. 1979. Hach Company.
\24\ Methods for Analysis of Organic Substances in Water and Fluvial Sediments, Techniques of Water-Resources Investigations of the U.S. Geological
Survey, Book 5, Chapter A3, (1972 Revised 1987). 1987. USGS.
\25\ Method 8507, Nitrogen, Nitrite-Low Range, Diazotization Method for Water and Wastewater. 1979. Hach Company.
\26\ Just prior to distillation, adjust the sulfuric-acid-preserved sample to pH 4 with 1 + 9 NaOH.
\27\ The colorimetric reaction must be conducted at a pH of 10.0 0.2.
\28\ Addison, R.F., and R.G. Ackman. 1970. Direct Determination of Elemental Phosphorus by Gas-Liquid Chromatography, Journal of Chromatography,
47(3):421-426.
\29\ Approved methods for the analysis of silver in industrial wastewaters at concentrations of 1 mg/L and above are inadequate where silver exists as
an inorganic halide. Silver halides such as the bromide and chloride are relatively insoluble in reagents such as nitric acid but are readily soluble
in an aqueous buffer of sodium thiosulfate and sodium hydroxide to pH of 12. Therefore, for levels of silver above 1 mg/L, 20 mL of sample should be
diluted to 100 mL by adding 40 mL each of 2 M Na2S2O3and NaOH. Standards should be prepared in the same manner. For levels of silver below 1 mg/L the
approved method is satisfactory.
\30\ The use of EDTA decreases method sensitivity. Analysts may omit EDTA or replace with another suitable complexing reagent provided that all method-
specified quality control acceptance criteria are met.
\31\ For samples known or suspected to contain high levels of silver (e.g., in excess of 4 mg/L), cyanogen iodide should be used to keep the silver in
solution for analysis. Prepare a cyanogen iodide solution by adding 4.0 mL of concentrated NH4OH, 6.5 g of KCN, and 5.0 mL of a 1.0 N solution of I2
to 50 mL of reagent water in a volumetric flask and dilute to 100.0 mL. After digestion of the sample, adjust the pH of the digestate to >7 to prevent
the formation of HCN under acidic conditions. Add 1 mL of the cyanogen iodide solution to the sample digestate and adjust the volume to 100 mL with
reagent water (NOT acid). If cyanogen iodide is added to sample digestates, then silver standards must be prepared that contain cyanogen iodide as
well. Prepare working standards by diluting a small volume of a silver stock solution with water and adjusting the pH >7 with NH4OH. Add 1 mL of the
cyanogen iodide solution and let stand 1 hour. Transfer to a 100-mL volumetric flask and dilute to volume with water.
\32\ ``Water Temperature-Influential Factors, Field Measurement and Data Presentation,'' Techniques of Water-Resources Investigations of the U.S.
Geological Survey, Book 1, Chapter D1. 1975. USGS.
\33\ Method 8009, Zincon Method for Zinc, Hach Handbook of Water Analysis, 1979. Hach Company.
\34\ Method AES0029, Direct Current Plasma (DCP) Optical Emission Spectrometric Method for Trace Elemental Analysis of Water and Wastes. 1986-Revised
1991. Thermo Jarrell Ash Corporation.
\35\ In-Situ Method 1004-8-2009, Carbonaceous Biochemical Oxygen Demand (CBOD) Measurement by Optical Probe. 2009. In-Situ Incorporated.
\36\ Microwave-assisted digestion may be employed for this metal, when analyzed by this methodology. Closed Vessel Microwave Digestion of Wastewater
Samples for Determination of Metals. April 16, 1992. CEM Corporation
\37\ When determining boron and silica, only plastic, PTFE, or quartz laboratory ware may be used from start until completion of analysis.
\38\ Only use n-hexane (n-Hexane--85% minimum purity, 99.0% min. saturated C6 isomers, residue less than 1 mg/L) extraction solvent when determining Oil
and Grease parameters--Hexane Extractable Material (HEM), or Silica Gel Treated HEM (analogous to EPA Methods 1664 Rev. A and 1664 Rev. B). Use of
other extraction solvents is prohibited.
\39\ Method PAI-DK01, Nitrogen, Total Kjeldahl, Block Digestion, Steam Distillation, Titrimetric Detection. Revised December 22, 1994. OI Analytical.
\40\ Method PAI-DK02, Nitrogen, Total Kjeldahl, Block Digestion, Steam Distillation, Colorimetric Detection. Revised December 22, 1994. OI Analytical.
\41\ Method PAI-DK03, Nitrogen, Total Kjeldahl, Block Digestion, Automated FIA Gas Diffusion. Revised December 22, 1994. OI Analytical.
\42\ Method 1664 Rev. B is the revised version of EPA Method 1664 Rev. A. U.S. EPA. February 1999, Revision A. Method 1664, n-Hexane Extractable
Material (HEM; Oil and Grease) and Silica Gel Treated n-Hexane Extractable Material (SGT-HEM; Non-polar Material) by Extraction and Gravimetry. EPA-
821-R-98-002. U.S. EPA. February 2010, Revision B. Method 1664, n-Hexane Extractable Material (HEM; Oil and Grease) and Silica Gel Treated n-Hexane
Extractable Material (SGT-HEM; Non-polar Material) by Extraction and Gravimetry. EPA-821-R-10-001.
\43\ Method 1631, Revision E, Mercury in Water by Oxidation, Purge and Trap, and Cold Vapor Atomic Fluorescence Spectrometry, EPA-821-R-02-019. Revision
E. August 2002, U.S. EPA. The application of clean techniques described in EPA's Method 1669: Sampling Ambient Water for Trace Metals at EPA Water
Quality Criteria Levels, EPA-821-R-96-011, are recommended to preclude contamination at low-level, trace metal determinations.
\44\ Method OIA-1677-09, Available Cyanide by Ligand Exchange and Flow Injection Analysis (FIA). 2010. OI Analytical.
\45\ Open File Report 00-170, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory--Determination of Ammonium Plus
Organic Nitrogen by a Kjeldahl Digestion Method and an Automated Photometric Finish that Includes Digest Cleanup by Gas Diffusion. 2000. USGS.
\46\ Open File Report 93-449, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory--Determination of Chromium in Water by
Graphite Furnace Atomic Absorption Spectrophotometry. 1993. USGS.
\47\ Open File Report 97-198, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory--Determination of Molybdenum by
Graphite Furnace Atomic Absorption Spectrophotometry. 1997. USGS.
\48\ Open File Report 92-146, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory--Determination of Total Phosphorus by
Kjeldahl Digestion Method and an Automated Colorimetric Finish That Includes Dialysis. 1992. USGS.
\49\ Open File Report 98-639, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory--Determination of Arsenic and Selenium
in Water and Sediment by Graphite Furnace-Atomic Absorption Spectrometry. 1999. USGS.
\50\ Open File Report 98-165, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory--Determination of Elements in Whole-
water Digests Using Inductively Coupled Plasma-Optical Emission Spectrometry and Inductively Coupled Plasma-Mass Spectrometry. 1998. USGS.
\51\ Open File Report 93-125, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory--Determination of Inorganic and
Organic Constituents in Water and Fluvial Sediments. 1993. USGS.
\52\ Unless otherwise indicated, all EPA methods, excluding EPA Method 300.1, are published in U.S. EPA. May 1994. Methods for the Determination of
Metals in Environmental Samples, Supplement I, EPA/600/R-94/111; or U.S. EPA. August 1993. Methods for the Determination of Inorganic Substances in
Environmental Samples, EPA/600/R-93/100. EPA Method 300.1 is U.S. EPA. Revision 1.0, 1997, including errata cover sheet April 27, 1999. Determination
of Inorganic Ions in Drinking Water by Ion Chromatography.
\53\ Styrene divinyl benzene beads (e.g., AMCO-AEPA-1 or equivalent) and stabilized formazin (e.g., Hach StablCal\TM\ or equivalent) are acceptable
substitutes for formazin.
\54\ Method D6508-15, Test Method for Determination of Dissolved Inorganic Anions in Aqueous Matrices Using Capillary Ion Electrophoresis and Chromate
Electrolyte. 2015. ASTM
\55\ Kelada-01, Kelada Automated Test Methods for Total Cyanide, Acid Dissociable Cyanide, and Thiocyanate, EPA 821-B-01-009, Revision 1.2, August 2001.
US EPA. Note: A 450-W UV lamp may be used in this method instead of the 550-W lamp specified if it provides performance within the quality control
(QC) acceptance criteria of the method in a given instrument. Similarly, modified flow cell configurations and flow conditions may be used in the
method, provided that the QC acceptance criteria are met.
\56\ QuikChem Method 10-204-00-1-X, Digestion and Distillation of Total Cyanide in Drinking and Wastewaters using MICRO DIST and Determination of
Cyanide by Flow Injection Analysis. Revision 2.2, March 2005. Lachat Instruments.
\57\ When using sulfide removal test procedures described in EPA Method 335.4-1, reconstitute particulate that is filtered with the sample prior to
distillation.
[[Page 56613]]
\58\ Unless otherwise stated, if the language of this table specifies a sample digestion and/or distillation ``followed by'' analysis with a method,
approved digestion and/or distillation are required prior to analysis.
\59\ Samples analyzed for available cyanide using OI Analytical method OIA-1677-09 or ASTM method D6888-16 that contain particulate matter may be
filtered only after the ligand exchange reagents have been added to the samples, because the ligand exchange process converts complexes containing
available cyanide to free cyanide, which is not removed by filtration. Analysts are further cautioned to limit the time between the addition of the
ligand exchange reagents and sample filtration to no more than 30 minutes to preclude settling of materials in samples.
\60\ Analysts should be aware that pH optima and chromophore absorption maxima might differ when phenol is replaced by a substituted phenol as the color
reagent in Berthelot Reaction (``phenol-hypochlorite reaction'') colorimetric ammonium determination methods. For example, when phenol is used as the
color reagent, pH optimum and wavelength of maximum absorbance are about 11.5 and 635 nm, respectively--see, Patton, C.J. and S.R. Crouch. March 1977.
Anal. Chem. 49:464-469. These reaction parameters increase to pH >12.6 and 665 nm when salicylate is used as the color reagent--see, Krom, M.D. April
1980. The Analyst 105:305-316.
\61\ If atomic absorption or ICP instrumentation is not available, the aluminon colorimetric method detailed in the 19th Edition of Standard Methods for
the Examination of Water and Wastewater may be used. This method has poorer precision and bias than the methods of choice.
\62\ Easy (1-Reagent) Nitrate Method, Revision November 12, 2011. Craig Chinchilla.
\63\ Hach Method 10360, Luminescence Measurement of Dissolved Oxygen in Water and Wastewater and for Use in the Determination of BOD5 and CBOD5.
Revision 1.2, October 2011. Hach Company. This method may be used to measure dissolved oxygen when performing the methods approved in Table IB for
measurement of biochemical oxygen demand (BOD) and carbonaceous biochemical oxygen demand (CBOD).
\64\ In-Situ Method 1002-8-2009, Dissolved Oxygen (DO) Measurement by Optical Probe. 2009. In-Situ Incorporated.
\65\ Mitchell Method M5331, Determination of Turbidity by Nephelometry. Revision 1.0, July 31, 2008. Leck Mitchell.
\66\ Mitchell Method M5271, Determination of Turbidity by Nephelometry. Revision 1.0, July 31, 2008. Leck Mitchell.
\67\ Orion Method AQ4500, Determination of Turbidity by Nephelometry. Revision 5, March 12, 2009. Thermo Scientific.
\68\ EPA Method 200.5, Determination of Trace Elements in Drinking Water by Axially Viewed Inductively Coupled Plasma-Atomic Emission Spectrometry, EPA/
600/R-06/115. Revision 4.2, October 2003. US EPA.
\69\ Method 1627, Kinetic Test Method for the Prediction of Mine Drainage Quality, EPA-821-R-09-002. December 2011. US EPA.
\70\ Techniques and Methods Book 5-B1, Determination of Elements in Natural-Water, Biota, Sediment and Soil Samples Using Collision/Reaction Cell
Inductively Coupled Plasma-Mass Spectrometry, Chapter 1, Section B, Methods of the National Water Quality Laboratory, Book 5, Laboratory Analysis,
2006. USGS.
\71\ Water-Resources Investigations Report 01-4132, Methods of Analysis by the U.S. Geological Survey National Water Quality Laboratory--Determination
of Organic Plus Inorganic Mercury in Filtered and Unfiltered Natural Water with Cold Vapor-Atomic Fluorescence Spectrometry, 2001. USGS.
\72\ USGS Techniques and Methods 5-B8, Chapter 8, Section B, Methods of the National Water Quality Laboratory Book 5, Laboratory Analysis, 2011 USGS
\73\ NECi Method N07-0003, ''Nitrate Reductase Nitrate-Nitrogen Analysis,'' Revision 9.0, March 2014, The Nitrate Elimination Co., Inc.
\74\ Timberline Instruments, LLC Method Ammonia-001, ``Determination of Inorganic Ammonia by Continuous Flow Gas Diffusion and Conductivity Cell
Analysis,'' June 2011, Timberline Instruments, LLC.
\75\ Hach Company Method 10206, ``Spectrophotometric Measurement of Nitrate in Water and Wastewater,'' Revision 2.1, January 2013, Hach Company.
\76\ Hach Company Method 10242, ``Simplified Spectrophotometric Measurement of Total Kjeldahl Nitrogen in Water and Wastewater,'' Revision 1.1, January
2013, Hach Company.
\77\ National Council for Air and Stream Improvement (NCASI) Method TNTP-W10900, ``Total (Kjeldahl) Nitrogen and Total Phosphorus in Pulp and Paper
Biologically Treated Effluent by Alkaline Persulfate Digestion,'' June 2011, National Council for Air and Stream Improvement, Inc.
\78\ The pH adjusted sample is to be adjusted to 7.6 for NPDES reporting purposes.
\79\ I-2057-85 U.S. Geological Survey Techniques of Water-Resources Investigations, Book 5, Chap. A11989, Methods for Determination of Inorganic
Substances in Water and Fluvial Sediments, 1989.
\80\ Methods I-2522-90, I-2540-90, and I-2601-90 U.S. Geological Survey Open-File Report 93-125, Methods of Analysis by the U.S. Geological Survey
National Water Quality Laboratory-Determination of Inorganic and Organic Constituents in Water and Fluvial Sediments, 1993.
\81\ Method I-1472-97, U.S. Geological Survey Open-File Report 98-165, Methods of Analysis by the U.S. Geological Survey National Water Quality
Laboratory-Determination of Inorganic and Organic Constituents in Water and Fluvial Sediments, 1998.
\82\ FIAlab Instruments, Inc. Method FIAlab 100, ``Determination of Inorganic Ammonia by Continuous Flow Gas Diffusion and Fluorescence Detector
Analysis'', April 4, 2018, FIAlab Instruments, Inc.
\83\ MACHEREY-NAGEL GmbH and Co. Method 036/038 NANOCOLOR[supreg] COD LR/HR, ``Spectrophotometric Measurement of Chemical Oxygen Demand in Water and
Wastewater'', Revision 1.5, May 2008, MACHEREY-NAGEL GmbH and Co. KG.
\84\ Please refer to the following applicable Quality Control Sections: Part 2000 Methods, Physical and Aggregate Properties 2020 (2017); Part 3000
Methods, Metals, 3020 (2017); Part 4000 Methods, Inorganic Nonmetallic Constituents, 4020 (2014); Part 5000 Methods, and Aggregate Organic
Constituents, 5020 (2017). These Quality Control Standards are available for download at www.standardmethods.org at no charge.
Table IC--List of Approved Test Procedures for Non-Pesticide Organic Compounds
--------------------------------------------------------------------------------------------------------------------------------------------------------
Parameter \1\ Method EPA 2 7 Standard methods ASTM Other
--------------------------------------------------------------------------------------------------------------------------------------------------------
1. Acenaphthene................. GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
2. Acenaphthylene............... GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
3. Acrolein..................... GC..................... 603....................
GC/MS.................. 624.1 \4\, 1624B.......
4. Acrylonitrile................ GC..................... 603....................
GC/MS.................. 624.1 \4\, 1624B....... ....................... ....................... O-4127-96.\13\
5. Anthracene................... GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440B-2005............. D4657-92 (98)..........
6. Benzene...................... GC..................... 602.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
7. Benzidine.................... Spectro-photometric.... ....................... ....................... ....................... See footnote \3\,
p. 1.
GC/MS.................. 625.1 \5\, 1625B....... 6410 B-2000............
HPLC................... 605....................
8. Benzo(a)anthracene........... GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
9. Benzo(a)pyrene............... GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
10. Benzo(b)fluoranthene........ GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
11. Benzo(g,h,i)perylene........ GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
12. Benzo(k)fluoranthene........ GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
13. Benzyl chloride............. GC..................... ....................... ....................... ....................... See footnote \3\,
p. 130.
GC/MS.................. ....................... ....................... ....................... See footnote \6\,
p. S102.
[[Page 56614]]
14. Butyl benzyl phthalate...... GC..................... 606....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
15. bis(2-Chloroethoxy) methane. GC..................... 611....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
16. bis(2-Chloroethyl) ether.... GC..................... 611....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
17. bis(2-Ethylhexyl) phthalate. GC..................... 606....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
18. Bromodichloromethane........ GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
19. Bromoform................... GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
20. Bromomethane................ GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
21. 4-Bromophenyl phenyl ether.. GC..................... 611....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
22. Carbon tetrachloride........ GC..................... 601.................... 6200 C-2011............ ....................... See footnote \3\,
p. 130.
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
23. 4-Chloro-3-methyl phenol.... GC..................... 604.................... 6420 B-2000............
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
24. Chlorobenzene............... GC..................... 601, 602............... 6200 C-2011............ ....................... See footnote \3\,
p. 130.
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
25. Chloroethane................ GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96.\13\
26. 2-Chloroethylvinyl ether.... GC..................... 601....................
GC/MS.................. 624.1, 1624B...........
27. Chloroform.................. GC..................... 601.................... 6200 C-2011............ ....................... See footnote \3\,
p. 130.
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
28. Chloromethane............... GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
29. 2-Chloronaphthalene......... GC..................... 612....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
30. 2-Chlorophenol.............. GC..................... 604.................... 6420 B-2000............
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
31. 4-Chlorophenyl phenyl ether. GC..................... 611....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
32. Chrysene.................... GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
33. Dibenzo(a,h)anthracene...... GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
34. Dibromochloromethane........ GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
35. 1,2-Dichlorobenzene......... GC..................... 601, 602............... 6200 C-2011............
GC/MS.................. 624.1, 1625B........... 6200 B-2011............ ....................... See footnote \9\,
p. 27; O-4127-96
\13\, O-4436-
16.\14\
36. 1,3-Dichlorobenzene......... GC..................... 601, 602............... 6200 C-2011............
GC/MS.................. 624.1, 1625B........... 6200 B-2011............ ....................... See footnote \9\,
p. 27; O-4127-
96.\13\
37. 1,4-Dichlorobenzene......... GC..................... 601, 602............... 6200 C-2011............
GC/MS.................. 624.1, 1625B........... 6200 B-2011............ ....................... See footnote \9\,
p. 27; O-4127-96
\13\, O-4436-
16.\14\
38. 3,3'-Dichlorobenzidine...... GC/MS.................. 625.1, 1625B........... 6410 B-2000............
HPLC................... 605....................
39. Dichlorodifluoromethane..... GC..................... 601....................
GC/MS.................. ....................... 6200 C-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
40. 1,1-Dichloroethane.......... GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
41. 1,2-Dichloroethane.......... GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
42. 1,1-Dichloroethene.......... GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
43. trans-1,2-Dichloroethene.... GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
44. 2,4-Dichlorophenol.......... GC..................... 604.................... 6420 B-2000............
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
45. 1,2-Dichloropropane......... GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
46. cis-1,3-Dichloropropene..... GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
47. trans-1,3-Dichloropropene... GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
48. Diethyl phthalate........... GC..................... 606....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
49. 2,4-Dimethylphenol.......... GC..................... 604.................... 6420 B-2000............
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
50. Dimethyl phthalate.......... GC..................... 606....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
51. Di-n-butyl phthalate........ GC..................... 606....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
52. Di-n-octyl phthalate........ GC..................... 606....................
[[Page 56615]]
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
53. 2,4-Dinitrophenol........... GC..................... 604.................... 6420 B-2000............ ....................... See footnote \9\,
p. 27.
GC/MS.................. 625.1, 1625B........... 6410 B-2000............
54. 2,4-Dinitrotoluene.......... GC..................... 609....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
55. 2,6-Dinitrotoluene.......... GC..................... 609....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
56. Epichlorohydrin............. GC..................... ....................... ....................... ....................... See footnote \3\,
p. 130.
GC/MS.................. ....................... ....................... ....................... See footnote \6\,
p. S102.
57. Ethylbenzene................ GC..................... 602.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
58. Fluoranthene................ GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
59. Fluorene.................... GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
60. 1,2,3,4,6,7,8-Heptachloro- GC/MS.................. 1613B..................
dibenzofuran.
61. 1,2,3,4,7,8,9-Heptachloro- GC/MS.................. 1613B..................
dibenzofuran.
62. 1,2,3,4,6,7,8-Heptachloro- GC/MS.................. 1613B..................
dibenzo-p-dioxin.
63. Hexachlorobenzene........... GC..................... 612....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
64. Hexachlorobutadiene......... GC..................... 612....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27; O-4127-
96.\13\
65. Hexachlorocyclopentadiene... GC..................... 612....................
GC/MS.................. 625.1 \5\, 1625B....... 6410 B-2000............ ....................... See footnote \9\,
p. 27; O-4127-
96.\13\
66. 1,2,3,4,7,8-Hexachloro- GC/MS.................. 1613B..................
dibenzofuran.
67. 1,2,3,6,7,8-Hexachloro- GC/MS.................. 1613B..................
dibenzofuran.
68. 1,2,3,7,8,9-Hexachloro- GC/MS.................. 1613B..................
dibenzofuran.
69. 2,3,4,6,7,8-Hexachloro- GC/MS.................. 1613B..................
dibenzofuran.
70. 1,2,3,4,7,8-Hexachloro- GC/MS.................. 1613B..................
dibenzo-p-dioxin.
71. 1,2,3,6,7,8-Hexachloro- GC/MS.................. 1613B..................
dibenzo-p-dioxin.
72. 1,2,3,7,8,9-Hexachloro- GC/MS.................. 1613B..................
dibenzo-p-dioxin.
73. Hexachloroethane............ GC..................... 612....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27; O-4127-
96.\13\
74. Indeno(1,2,3-c,d) pyrene.... GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
75. Isophorone.................. GC..................... 609....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
76. Methylene chloride.......... GC..................... 601.................... 6200 C-2011............ ....................... See footnote \3\,
p. 130.
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
77. 2-Methyl-4,6-dinitrophenol.. GC..................... 604.................... 6420 B-2000............
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
78. Naphthalene................. GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............
79. Nitrobenzene................ GC..................... 609....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... ....................... ....................... D4657-92 (98)..........
80. 2-Nitrophenol............... GC..................... 604.................... 6420 B-2000............
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
81. 4-Nitrophenol............... GC..................... 604.................... 6420 B-2000............
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
82. N-Nitrosodimethylamine...... GC..................... 607....................
GC/MS.................. 625.1 \5\, 1625B....... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
83. N-Nitrosodi-n-propylamine... GC..................... 607....................
GC/MS.................. 625.1 \5\, 1625B....... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
84. N-Nitrosodiphenylamine...... GC..................... 607....................
GC/MS.................. 625.1 \5\, 1625B....... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
85. Octachlorodibenzofuran...... GC/MS.................. 1613B \10\.............
86. Octachlorodibenzo-p-dioxin.. GC/MS.................. 1613B \10\.............
87. 2,2'-oxybis(1-chloropropane) GC..................... 611....................
\12\ [also known as bis(2-
Chloro-1-methylethyl) ether].
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
88. PCB-1016.................... GC..................... 608.3.................. ....................... ....................... See footnote \3\,
p. 43; See
footnote.\8\
GC/MS.................. 625.1.................. 6410 B-2000............
89. PCB-1221.................... GC..................... 608.3.................. ....................... ....................... See footnote \3\,
p. 43; See
footnote.\8\
GC/MS.................. 625.1.................. 6410 B-2000............
90. PCB-1232.................... GC..................... 608.3.................. ....................... ....................... See footnote \3\,
p. 43; See
footnote.\8\
[[Page 56616]]
GC/MS.................. 625.1.................. 6410 B-2000............
91. PCB-1242.................... GC..................... 608.3.................. ....................... ....................... See footnote \3\,
p. 43; See
footnote.\8\
GC/MS.................. 625.1.................. 6410 B-2000............
92. PCB-1248.................... GC..................... 608.3.................. ....................... ....................... See footnote \3\,
p. 43; See
footnote.\8\
GC/MS.................. 625.1.................. 6410 B-2000............
93. PCB-1254.................... GC..................... 608.3.................. ....................... ....................... See footnote \3\,
p. 43; See
footnote.\8\
GC/MS.................. 625.1.................. 6410 B-2000............
94. PCB-1260.................... GC..................... 608.3.................. ....................... ....................... See footnote \3\,
p. 43; See
footnote.\8\
GC/MS.................. 625.1.................. 6410 B-2000............
95. 1,2,3,7,8-Pentachloro- GC/MS.................. 1613B..................
dibenzofuran.
96. 2,3,4,7,8-Pentachloro- GC/MS.................. 1613B..................
dibenzofuran.
97. 1,2,3,7,8-Pentachloro- GC/MS.................. 1613B..................
dibenzo-p-dioxin.
98. Pentachlorophenol........... GC..................... 604.................... 6420 B-2000............ ....................... See footnote \3\,
p. 140.
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
99. Phenanthrene................ GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
100. Phenol..................... GC..................... 604.................... 6420 B-2000............
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
101. Pyrene..................... GC..................... 610....................
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
HPLC................... 610.................... 6440 B-2005............ D4657-92 (98)..........
102. 2,3,7,8-Tetrachloro- GC/MS.................. 1613B \10\.............
dibenzofuran.
103. 2,3,7,8-Tetrachloro-dibenzo- GC/MS.................. 613, 625.1 \5a\, 1613B.
p-dioxin.
104. 1,1,2,2-Tetrachloroethane.. GC..................... 601.................... 6200 C-2011............ ....................... See footnote \3\,
p. 130.
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96.\13\
105. Tetrachloroethene.......... GC..................... 601.................... 6200 C-2011............ ....................... See footnote \3\,
p. 130.
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
106. Toluene.................... GC..................... 602.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
107. 1,2,4-Trichlorobenzene..... GC..................... 612.................... ....................... ....................... See footnote \3\,
p. 130.
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27; O-4127-96
\13\, O-4436-
16.\14\
108. 1,1,1-Trichloroethane...... GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
109. 1,1,2-Trichloroethane...... GC..................... 601.................... 6200 C-2011............ ....................... See footnote \3\,
p. 130.
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
110. Trichloroethene............ GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
111. Trichlorofluoromethane..... GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1.................. 6200 B-2011............ ....................... O-4127-96.\13\
112. 2,4,6-Trichlorophenol...... GC..................... 604.................... 6420 B-2000............
GC/MS.................. 625.1, 1625B........... 6410 B-2000............ ....................... See footnote \9\,
p. 27.
113. Vinyl chloride............. GC..................... 601.................... 6200 C-2011............
GC/MS.................. 624.1, 1624B........... 6200 B-2011............ ....................... O-4127-96 \13\, O-
4436-16.\14\
114. Nonylphenol................ GC/MS.................. ....................... ....................... D7065-17...............
115. Bisphenol A (BPA).......... GC/MS.................. ....................... ....................... D7065-17...............
116. p-tert-Octylphenol (OP).... GC/MS.................. ....................... ....................... D7065-17...............
117. Nonylphenol Monoethoxylate GC/MS.................. ....................... ....................... D7065-17...............
(NP1EO).
118. Nonylphenol Diethoxylate GC/MS.................. ....................... ....................... D7065-17...............
(NP2EO).
119. Adsorbable Organic Halides Adsorption and 1650 \11\..............
(AOX). Coulometric Titration.
120. Chlorinated Phenolics...... In Situ Acetylation and 1653 \11\..............
GC/MS.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Table IC notes:
\1\ All parameters are expressed in micrograms per liter ([micro]g/L) except for Method 1613B, in which the parameters are expressed in picograms per
liter (pg/L).
\2\ The full text of Methods 601-613, 1613B, 1624B, and 1625B are provided at appendix A, Test Procedures for Analysis of Organic Pollutants. The
standardized test procedure to be used to determine the method detection limit (MDL) for these test procedures is given at appendix B of this part,
Definition and Procedure for the Determination of the Method Detection Limit. These methods are available at: https://www.epa.gov/cwa-methods as
individual PDF files.
\3\ Methods for Benzidine: Chlorinated Organic Compounds, Pentachlorophenol and Pesticides in Water and Wastewater. September 1978. U.S. EPA.
\4\ Method 624.1 may be used for quantitative determination of acrolein and acrylonitrile, provided that the laboratory has documentation to
substantiate the ability to detect and quantify these analytes at levels necessary to comply with any associated regulations. In addition, the use of
sample introduction techniques other than simple purge-and-trap may be required. QC acceptance criteria from Method 603 should be used when analyzing
samples for acrolein and acrylonitrile in the absence of such criteria in Method 624.1.
\5\ Method 625.1 may be extended to include benzidine, hexachlorocyclopentadiene, N-nitrosodimethylamine, N-nitrosodi-n-propylamine, and N-
nitrosodiphenylamine. However, when they are known to be present, Methods 605, 607, and 612, or Method 1625B, are preferred methods for these
compounds.
\5a\ Method 625.1 screening only.
\6\ Selected Analytical Methods Approved and Cited by the United States Environmental Protection Agency, Supplement to the 15th Edition of Standard
Methods for the Examination of Water and Wastewater. 1981. American Public Health Association (APHA).
\7\ Each analyst must make an initial, one-time demonstration of their ability to generate acceptable precision and accuracy with Methods 601-603,
1624B, and 1625B in accordance with procedures in Section 8.2 of each of these methods. Additionally, each laboratory, on an on-going basis must spike
and analyze 10% (5% for Methods 624.1 and 625.1 and 100% for methods 1624B and 1625B) of all samples to monitor and evaluate laboratory data quality
in accordance with Sections 8.3 and 8.4 of these methods. When the recovery of any parameter falls outside the quality control (QC) acceptance
criteria in the pertinent method, analytical results for that parameter in the unspiked sample are suspect. The results should be reported but cannot
be used to demonstrate regulatory compliance. If the method does not contain QC acceptance criteria, control limits of three standard
deviations around the mean of a minimum of five replicate measurements must be used. These quality control requirements also apply to the Standard
Methods, ASTM Methods, and other methods cited.
[[Page 56617]]
\8\ Organochlorine Pesticides and PCBs in Wastewater Using Empore\TM\ Disk. Revised October 28, 1994. 3M Corporation.
\9\ Method O-3116-87 is in Open File Report 93-125, Methods of Analysis by U.S. Geological Survey National Water Quality Laboratory--Determination of
Inorganic and Organic Constituents in Water and Fluvial Sediments. 1993. USGS.
\10\ Analysts may use Fluid Management Systems, Inc. Power-Prep system in place of manual cleanup provided the analyst meets the requirements of Method
1613B (as specified in Section 9 of the method) and permitting authorities. Method 1613, Revision B, Tetra- through Octa-Chlorinated Dioxins and
Furans by Isotope Dilution HRGC/HRMS. Revision B, 1994. U.S. EPA. The full text of this method is provided in appendix A to this part and at https://www.epa.gov/cwa-methods/approved-cwa-test-methods-organic-compounds.
\11\ Method 1650, Adsorbable Organic Halides by Adsorption and Coulometric Titration. Revision C, 1997 U.S. EPA. Method 1653, Chlorinated Phenolics in
Wastewater by In Situ Acetylation and GCMS. Revision A, 1997 U.S. EPA. The full text for both of these methods is provided at appendix A in part 430
of this chapter, The Pulp, Paper, and Paperboard Point Source Category.
\12\ The compound was formerly inaccurately labeled as 2,2'-oxybis(2-chloropropane) and bis(2-chloroisopropyl) ether. Some versions of Methods 611, and
1625 inaccurately list the analyte as ``bis(2-chloroisopropyl)ether,'' but use the correct CAS number of 108-60-1.
\13\ Method O-4127-96, U.S. Geological Survey Open-File Report 97-829, Methods of analysis by the U.S. Geological Survey National Water Quality
Laboratory--Determination of 86 volatile organic compounds in water by gas chromatography/mass spectrometry, including detections less than reporting
limits,1998, USGS.
\14\ Method O-4436-16 U.S. Geological Survey Techniques and Methods, book 5, chap. B12, Determination of heat purgeable and ambient purgeable volatile
organic compounds in water by gas chromatography/mass spectrometry, 2016, USGS.
* * * * *
Table IH--List of Approved Microbiological Methods for Ambient Water
--------------------------------------------------------------------------------------------------------------------------------------------------------
Parameter and units Method \1\ EPA Standard methods AOAC, ASTM, USGS Other
--------------------------------------------------------------------------------------------------------------------------------------------------------
Bacteria
--------------------------------------------------------------------------------------------------------------------------------------------------------
1. Coliform (fecal), number per Most Probable Number p. 132 \3\........... 9221 E-2014, 9221 F.2-
100 mL. (MPN), 5 tube, 3 2014 \32\.
dilution, or.
Membrane filter (MF) p. 124 \3\........... 9222 D-2015 \26\..... B-0050-85 \4\.......
\2\, single step.
2. Coliform (total), number per MPN, 5 tube, 3 p. 114 \3\........... 9221 B-2014..........
100 mL. dilution, or.
MF \2\, single step p. 108 \3\........... 9222 B-2015 \27\..... B-0025-85 \4\.......
or two step.
MF \2\ with p. 111 \3\........... 9222 (B + B.4e)--2015
enrichment. \27\.
3. E. coli, number per 100 mL..... MPN 5 7 13, multiple 9221 B.3-2014/9221 F-
tube, or. 2014 10 12 32.
Multiple tube/ 9223 B-2016 \11\..... 991.15 \9\.......... Colilert[supreg] 11 15,
multiple well, or. Colilert-18[supreg].11
14 15
MF 2 5 6 7, two step, 1103.1 \18\.......... 9222 B-2015/9222 I- D5392-93 \8\........
or. 2015 \17\, 9213 D-
2007.
Single step.......... 1603 \19\, 1604 \20\. m-ColiBlue24[supreg]
\16\, KwikCountTM EC.28
29
4. Fecal streptococci, number per MPN, 5 tube, 3 p. 139 \3\........... 9230 B-2013..........
100 mL. dilution, or.
MF \2\, or........... p. 136 \3\........... 9230 C-2013 \30\..... B-0055-85 \4\.......
Plate count.......... p. 143 \3\...........
5. Enterococci, number per 100 mL. MPN 5 7, multiple 9230 D-2013.......... D6503-99 \8\........ Enterolert[supreg].11 21
tube/multiple well,
or.
MF 2 5 6 7 two step, 1106.1 \22\.......... 9230 C-2013 \30\..... D5259-92 \8\........
or.
Single step, or...... 1600 \23\............ 9230 C-2013 \30\.....
Plate count.......... p. 143 \3\...........
--------------------------------------------------------------------------------------------------------------------------------------------------------
Protozoa
--------------------------------------------------------------------------------------------------------------------------------------------------------
6. Cryptosporidium................ Filtration/IMS/FA.... 1622 \24\, 1623 \25\,
1623.1 25 31.
7. Giardia........................ Filtration/IMS/FA.... 1623 \25\, 1623.1 25
31.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Table 1H notes:
\1\ The method must be specified when results are reported.
\2\ A 0.45-[micro]m membrane filter (MF) or other pore size certified by the manufacturer to fully retain organisms to be cultivated and to be free of
extractables which could interfere with their growth.
\3\ Microbiological Methods for Monitoring the Environment, Water and Wastes. EPA/600/8-78/017. 1978. US EPA.
\4\ U.S. Geological Survey Techniques of Water-Resource Investigations, Book 5, Laboratory Analysis, Chapter A4, Methods for Collection and Analysis of
Aquatic Biological and Microbiological Samples. 1989. USGS.
\5\ Tests must be conducted to provide organism enumeration (density). Select the appropriate configuration of tubes/filtrations and dilutions/volumes
to account for the quality, character, consistency, and anticipated organism density of the water sample.
\6\ When the MF method has not been used previously to test waters with high turbidity, large numbers of noncoliform bacteria, or samples that may
contain organisms stressed by chlorine, a parallel test should be conducted with a multiple-tube technique to demonstrate applicability and
comparability of results.
\7\ To assess the comparability of results obtained with individual methods, it is suggested that side-by-side tests be conducted across seasons of the
year with the water samples routinely tested in accordance with the most current Standard Methods for the Examination of Water and Wastewater or EPA
alternate test procedure (ATP) guidelines.
\8\ Annual Book of ASTM Standards--Water and Environmental Technology. Section 11.02. 2000, 1999, 1996. ASTM International.
\9\ Official Methods of Analysis of AOAC International, 16th Edition, Volume I, Chapter 17. 1995. AOAC International.
\10\ The multiple-tube fermentation test is used in 9221B.3-2014. Lactose broth may be used in lieu of lauryl tryptose broth (LTB), if at least 25
parallel tests are conducted between this broth and LTB using the water samples normally tested, and this comparison demonstrates that the false-
positive rate and false-negative rate for total coliform using lactose broth is less than 10 percent. No requirement exists to run the completed phase
on 10 percent of all total coliform-positive tubes on a seasonal basis.
\11\ These tests are collectively known as defined enzyme substrate tests.
\12\ After prior enrichment in a presumptive medium for total coliform using 9221B.3-2014, all presumptive tubes or bottles showing any amount of gas,
growth or acidity within 48 h 3 h of incubation shall be submitted to 9221F-2014. Commercially available EC-MUG media or EC media
supplemented in the laboratory with 50 [micro]g/mL of MUG may be used.
\13\ Samples shall be enumerated by the multiple-tube or multiple-well procedure. Using multiple-tube procedures, employ an appropriate tube and
dilution configuration of the sample as needed and report the Most Probable Number (MPN). Samples tested with Colilert[supreg] may be enumerated with
the multiple-well procedures, Quanti-Tray[supreg] or Quanti-Tray[supreg]/2000, and the MPN calculated from the table provided by the manufacturer.
\14\ Colilert-18[supreg] is an optimized formulation of the Colilert[supreg] for the determination of total coliforms and E. coli that provides results
within 18 h of incubation at 35 [deg]C, rather than the 24 h required for the Colilert[supreg] test, and is recommended for marine water samples.
[[Page 56618]]
\15\ Descriptions of the Colilert[supreg], Colilert-18[supreg], Quanti-Tray[supreg], and Quanti-Tray[supreg]/2000 may be obtained from IDEXX
Laboratories Inc.
\16\ A description of the mColiBlue24[supreg] test may be obtained from Hach Company.
\17\ Subject coliform positive samples determined by 9222B-2015 or other membrane filter procedure to 9222I-2015 using NA-MUG media.
\18\ Method 1103.1: Escherichia coli (E. coli) in Water by Membrane Filtration Using membrane-Thermotolerant Escherichia coli Agar (mTEC), EPA-821-R-10-
002. March 2010. US EPA.
\19\ Method 1603: Escherichia coli (E. coli) in Water by Membrane Filtration Using Modified membrane-Thermotolerant Escherichia coli Agar (Modified
mTEC), EPA-821-R-14-010. September 2014. US EPA.
\20\ Method 1604: Total Coliforms and Escherichia coli (E. coli) in Water by Membrane Filtration by Using a Simultaneous Detection Technique (MI
Medium), EPA 821-R-02-024. September 2002. US EPA.
\21\ A description of the Enterolert[supreg] test may be obtained from IDEXX Laboratories Inc.
\22\ Method 1106.1: Enterococci in Water by Membrane Filtration Using membrane-Enterococcus-Esculin Iron Agar (mE-EIA), EPA-821-R-09-015. December 2009.
US EPA.
\23\ Method 1600: Enterococci in Water by Membrane Filtration Using membrane-Enterococcus Indoxyl-[beta]-D-Glucoside Agar (mEI), EPA-821-R-14-011.
September 2014. US EPA.
\24\ Method 1622 uses a filtration, concentration, immunomagnetic separation of oocysts from captured material, immunofluorescence assay to determine
concentrations, and confirmation through vital dye staining and differential interference contrast microscopy for the detection of Cryptosporidium.
Method 1622: Cryptosporidium in Water by Filtration/IMS/FA, EPA-821-R-05-001. December 2005. US EPA.
\25\ Methods 1623 and 1623.1 use a filtration, concentration, immunomagnetic separation of oocysts and cysts from captured material, immunofluorescence
assay to determine concentrations, and confirmation through vital dye staining and differential interference contrast microscopy for the simultaneous
detection of Cryptosporidium and Giardia oocysts and cysts. Method 1623: Cryptosporidium and Giardia in Water by Filtration/IMS/FA. EPA-821-R-05-002.
December 2005. US EPA. Method 1623.1: Cryptosporidium and Giardia in Water by Filtration/IMS/FA. EPA 816-R-12-001. January 2012. US EPA.
\26\ On a monthly basis, at least ten blue colonies from positive samples must be verified using Lauryl Tryptose Broth and EC broth, followed by count
adjustment based on these results; and representative non-blue colonies should be verified using Lauryl Tryptose Broth. Where possible, verifications
should be done from randomized sample sources.
\27\ On a monthly basis, at least ten sheen colonies from positive samples must be verified using Lauryl Tryptose Broth and brilliant green lactose bile
broth, followed by count adjustment based on these results; and representative non-sheen colonies should be verified using Lauryl Tryptose Broth.
Where possible, verifications should be done from randomized sample sources.
\28\ A description of KwikCountTM EC may be obtained from Micrology Laboratories LLC.
\29\ Approved for the analyses of E. coli in freshwater only.
\30\ Verification of colonies by incubation of BHI agar at 10 0.5 [deg]C for 48 3 h is optional. As per the Errata to the 23rd
Edition of Standard Methods for the Examination of Water and Wastewater ``Growth on a BHI agar plate incubated at 10 0.5 [deg]C for 48
3 h is further verification that the colony belongs to the genus Enterococcus.''
\31\ Method 1623.1 includes updated acceptance criteria for IPR, OPR, and MS/MSD and clarifications and revisions based on the use of Method 1623 for
years and technical support questions.
\32\ 9221 F.2-2014 This procedure allows for simultaneous detection of E. coli and thermotolerant coliforms by adding inverted vials to EC-MUG; the
inverted vials collect gas produced by thermotolerant coliforms.
* * * * *
(b) Certain material is incorporated by reference into this section
with the approval of the Director of the Federal Register under 5
U.S.C. 552(a) and 1 CFR part 51. All approved material may be inspected
at EPA's Water Docket, EPA West, 1301 Constitution Avenue NW, Room
3334, Washington, DC 20004, (Telephone: 202-566-2426) and is available
from the sources listed below. It is also available for inspection at
National Archives and Records Administration (NARA). For information on
the availability of this material at NARA, email [email protected],
or go to: www.archives.gov/federal-register/cfr/ibr-locations.html.
* * * * *
(8) Office of Water, U.S. Environmental Protection Agency,
Washington, DC (US EPA). Available at https://www.epa.gov/cwa-methods
* * * * *
(ix) 1623.1: Cryptosporidium and Giardia in Water by Filtration/
IMS/FA. EPA 816-R-12-001. January 2012. US EPA, Table IH, Note 25.
(x) Method 1627, Kinetic Test Method for the Prediction of Mine
Drainage Quality. December 2011. EPA-821-R-09-002. Table IB, Note 69.
(xi) Method 1664, n-Hexane Extractable Material (HEM; Oil and
Grease) and Silica Gel Treated n-Hexane Extractable Material (SGT-HEM;
Nonpolar Material) by Extraction and Gravimetry.
Revision A, February 1999. EPA-821-R-98-002. Table IB, Notes 38 and
42.
(xii) Method 1664, n-Hexane Extractable Material (HEM; Oil and
Grease) and Silica Gel Treated n-Hexane Extractable Material (SGT-HEM;
Nonpolar Material) by Extraction and Gravimetry, Revision B, February
2010. EPA-821-R-10-001. Table IB, Notes 38 and 42.
(xiii) Method 1669, Sampling Ambient Water for Trace Metals at EPA
Water Quality Criteria Levels. July 1996. Table IB, Note 43.
(xiv) Method 1680: Fecal Coliforms in Sewage Sludge (Biosolids) by
Multiple-Tube Fermentation using Lauryl Tryptose Broth (LTB) and EC
Medium. September 2014. EPA-821-R-14-009.Table IA, Note 15.
(xv) Method 1681: Fecal Coliforms in Sewage Sludge (Biosolids) by
Multiple-Tube Fermentation using A-1 Medium. July 2006. EPA 821-R-06-
013. Table IA, Note 20.
(xvi) Method 1682: Salmonella in Sewage Sludge (Biosolids) by
Modified Semisolid Rappaport-Vassiliadis (MSRV) Medium. September 2014.
EPA 821-R-14-012. Table IA, Note 23.
* * * * *
(10) * * *
(xiv) 2540, solids. 2015. Table IB.
* * * * *
(xxxix) 4500-CN-, Cyanide. 2016. Table IB.
* * * * *
(xliv) 4500-NO3-, Nitrogen (Nitrate). 2016.
Table IB.
* * * * *
(xlvi) 4500-O, Oxygen (Dissolved). 2016. Table IB.
* * * * *
(lii) 5210, Biochemical Oxygen Demand (BOD). 2016. Table IB.
* * * * *
(liv) 5310, Total Organic Carbon (TOC). 2014. Table IB.
* * * * *
(lxvii) 9221 Multiple-Tube Fermentation Technique for Members of
the Coliform Group. 2014. Table IA, Notes 12 and 14; Table IH, Notes 10
and 12.
(lxviii) 9222, Membrane Filter Technique for Members of the
Coliform Group. 2015. Table IA; Table IH, Note 17.
(lxix) 9223 Enzyme Substrate Coliform Test. 2016. Table IA; Table
IH.
(lxx) 9230 Fecal Enterococcus/Streptococcus Groups. 2013. Table IA;
Table IH.
* * * * *
(15) * * *
(v) ASTM D511-14, Standard Test Methods for Calcium and Magnesium
in Water. November 2014. Table IB.
(vi) ASTM D512-12, Standard Test Methods for Chloride Ion in Water.
July 2012. Table IB.
* * * * *
(viii) ASTM D516-16, Standard Test Method for Sulfate Ion in Water,
June 2016. Table IB.
(ix) ASTM D858-17, Standard Test Methods for Manganese in Water.
June 2017. Table IB.
(x) ASTM D859-16, Standard Test Method for Silica in Water. June
2016. Table IB.
(xi) ASTM D888-12, Standard Test Methods for Dissolved Oxygen in
Water. March 2012. Table IB.
[[Page 56619]]
(xii) ASTM D1067-16, Standard Test Methods for Acidity or
Alkalinity of Water. June 2016. Table IB.
(xiii) ASTM D1068-15, Standard Test Methods for Iron in Water.
October 2015. Table IB.
* * * * *
(xv) ASTM D1126-17, Standard Test Method for Hardness in Water.
December 2017. Table IB.
(xvi) ASTM D1179-16, Standard Test Methods for Fluoride Ion in
Water. June 2016. Table IB.
(xvii) ASTM D1246-16, Standard Test Method for Bromide Ion in
Water. June 2016. Table IB.
(xviii) ASTM D1252-06 (Reapproved 2012), Standard Test Methods for
Chemical Oxygen Demand (Dichromate Oxygen Demand) of Water. June 2012.
Table IB.
(xix) ASTM D1253-14, Standard Test Method for Residual Chlorine in
Water. February 2014. Table IB.
* * * * *
(xxi) ASTM D1426-15, Standard Test Methods for Ammonia Nitrogen in
Water. April 2015. Table IB.
(xxii) ASTM D1687-17, Standard Test Methods for Chromium in Water.
July 2017. Table IB.
(xxiii) ASTM D1688-17, Standard Test Methods for Copper in Water.
July 2017. Table IB.
(xxiv) ASTM D1691-17, Standard Test Methods for Zinc in Water. June
2017. Table IB.
(xxv) ASTM D1783-01 (Reapproved 2012), Standard Test Methods for
Phenolic Compounds in Water. August 2012. Table IB.
(xxvi) ASTM D1886-14, Standard Test Methods for Nickel in Water.
November 2014. Table IB.
* * * * *
(xxxi) ASTM D2036-09 (Reapproved 2015), Standard Test Methods for
Cyanides in Water. July 2015. Table IB.
* * * * *
(xxxiv) ASTM D2972-15, Standard Tests Method for Arsenic in Water.
March 2015. Table IB.
(xxxv) ASTM D3223-17, Standard Test Method for Total Mercury in
Water. June 2017. Table IB.
* * * * *
(xxxvii) ASTM D3373-17, Standard Test Method for Vanadium in Water.
June 2017. Table IB.
* * * * *
(xxxix) ASTM D3557-17, Standard Test Method for Cadmium in Water.
June 2017. Table IB.
(xl) ASTM D3558-15, Standard Test Method for Cobalt in Water. March
2015. Table IB.
(xli) ASTM D3559-15, Standard Test Methods for Lead in Water.
October 2015. Table IB.
(xlii) ASTM D3590-17, Standard Test Methods for Total Kjeldahl
Nitrogen in Water. June 2017. Table IB.
(xliii) ASTM D3645-15, Standard Test Methods for Beryllium in
Water. March 2015. Table IB.
* * * * *
(xlv) ASTM D3859-15, Standard Test Methods for Selenium in Water.
April 2015. Table IB.
(xlvi) ASTM D3867-16, Standard Test Method for Nitrite-Nitrate in
Water. June 2016. Table IB.
(xlvii) ASTM D4190-15, Standard Test Method for Elements in Water
by Direct-Current Plasma Atomic Emission Spectroscopy. March 2015.
Table IB.
(xlviii) ASTM D4282-15, Standard Test Method for Determination of
Free Cyanide in Water and Wastewater by Microdiffusion. July 2015.
Table IB.
(xlix) ASTM D4327-17, Standard Test Method for Anions in Water by
Suppressed Ion Chromatography. December 2017. Table IB.
(l) ASTM D4382-18, Standard Test Method for Barium in Water, Atomic
Absorption Spectrophotometry, Graphite Furnace. May 2018. Table IB.
* * * * *
(lii) ASTM D4658-15, Standard Test Method for Sulfide Ion in Water.
April 2015. Table IB.
* * * * *
(liv) ASTM D4839-03 (Reapproved 2017), Standard Test Method for
Total Carbon and Organic Carbon in Water by Ultraviolet, or Persulfate
Oxidation, or Both, and Infrared Detection. December 2017. Table IB.
(lv) ASTM D5257-17, Standard Test Method for Dissolved Hexavalent
Chromium in Water by Ion Chromatography. December 2017. Table IB.
* * * * *
(lviii) ASTM D5673-16, Standard Test Method for Elements in Water
by Inductively Coupled Plasma--Mass Spectrometry. February 2016. Table
IB.
* * * * *
(lxi) ASTM. D6508-15, Standard Test Method for Determination of
Dissolved Inorganic Anions in Aqueous Matrices Using Capillary Ion
Electrophoresis and Chromate Electrolyte. October 2015. Table IB, Note
54.
(lxii) ASTM. D6888-16, Standard Test Method for Available Cyanide
with Ligand Displacement and Flow Injection Analysis (FIA) Utilizing
Gas Diffusion Separation and Amperometric Detection. June 2016. Table
IB, Note 59.
(lxiii) ASTM. D6919-17, Standard Test Method for Determination of
Dissolved Alkali and Alkaline Earth Cations and Ammonium in Water and
Wastewater by Ion Chromatography. June 2017. Table IB.
* * * * *
(lxiv) ASTM. D7065-17, Standard Test Method for Determination of
Nonylphenol, Bisphenol A, p-tert-Octylphenol, Nonylphenol
Monoethoxylate and Nonylphenol Diethoxylate in Environmental Waters by
Gas Chromatography Mass Spectrometry. January 2018. Table IC.
(lxv) ASTM. D7237-15a, Standard Test Method for Free Cyanide with
Flow Injection Analysis (FIA) Utilizing Gas Diffusion Separation and
Amperometric Detection. June 2015. Table IB.
(lxvi) ASTM. D7284-13 (Reapproved 2017), Standard Test Method for
Total Cyanide in Water by Micro Distillation followed by Flow Injection
Analysis with Gas Diffusion Separation and Amperometric Detection. July
2017. Table IB.
* * * * *
(lxviii) ASTM. D7511-12 (Reapproved 2017), Standard Test Method for
Total Cyanide by Segmented Flow Injection Analysis, In-Line Ultraviolet
Digestion and Amperometric Detection. July 2017. Table IB.
(lxix) ASTM. D7573-09 (Reapproved 2017), Standard Test Method for
Total Carbon and Organic Carbon in Water by High Temperature Catalytic
Combustion and Infrared Detection, February 2017. Table IB.
(lxx) ASTM D7781-14 Standard Test Method for Nitrate-Nitrite in
Water by Nitrate Reductase, May 2014. Table IB.
* * * * *
(19) FIAlab Instruments, Inc., 334 2151 N Northlake Way, Seattle,
WA 98103. Telephone: 425-376-0450
(i) Method 100, Determination of Inorganic Ammonia by Continuous
Flow Gas Diffusion and Fluorescence Detector Analysis, April 4, 2018.
Table IB, Note 82.
(ii) [Reserved]
* * * * *
(26) MACHEREY-NAGEL GmbH and Co., 2850 Emrick Blvd., Bethlehem, PA
18020. Telephone: 888-321-6224.
(i) Method 036/038 NANOCOLOR[supreg] COD LR/HR, Spectrophotometric
Measurement of Chemical Oxygen Demand in Water and Wastewater, Revision
1.5, May, 2018. Table IB, Note 83.
(ii) [Reserved]
(27) Micrology Laboratories, LLC, 1303 Eisenhower Drive, Goshen, IN
46526. Telephone: 574-533-3351.
(i) KwikCountTM EC Medium E. coli enzyme substrate test,
Rapid Detection of E. coli in Beach Water By KwikCountTM EC
Membrane Filtration. 2014. Table IH, Notes 28 and 29.
[[Page 56620]]
(ii) [Reserved]
* * * * *
(38) * * *
(ii) Determination of Heat Purgeable and Ambient Purgeable Volatile
Organic Compounds in Water by Gas Chromatography/Mass Spectrometry.
Chapter 12 of Section B, Methods of the National Water Quality
Laboratory, of Book 5, Laboratory Analysis. 2016.
(iii) Methods for Determination of Inorganic Substances in Water
and Fluvial Sediments, editors, Techniques of Water-Resources
Investigations of the U.S. Geological Survey, Book 5, Chapter A1. 1979.
Table IB, Note 8.
(iv) Methods for Determination of Inorganic Substances in Water and
Fluvial Sediments, Techniques of Water-Resources Investigations of the
U.S. Geological Survey, Book 5, Chapter A1. 1989. Table IB, Notes 2 and
79.
(v) Methods for the Determination of Organic Substances in Water
and Fluvial Sediments. Techniques of Water-Resources Investigations of
the U.S. Geological Survey, Book 5, Chapter A3. 1987. Table IB, Note
24; Table ID, Note 4.
(vi) OFR 76-177, Selected Methods of the U.S. Geological Survey of
Analysis of Wastewaters. 1976. Table IE, Note 2.
(vii) OFR 91-519, Methods of Analysis by the U.S. Geological Survey
National Water Quality Laboratory--Determination of Organonitrogen
Herbicides in Water by Solid-Phase Extraction and Capillary-Column Gas
Chromatography/Mass Spectrometry With Selected-Ion Monitoring. 1992.
Table ID, Note 14.
(viii) OFR 92-146, Methods of Analysis by the U.S. Geological
Survey National Water Quality Laboratory--Determination of Total
Phosphorus by a Kjeldahl Digestion Method and an Automated Colorimetric
Finish That Includes Dialysis. 1992. Table IB, Note 48.
(ix) OFR 93-125, Methods of Analysis by the U.S. Geological Survey
National Water Quality Laboratory--Determination of Inorganic and
Organic Constituents in Water and Fluvial Sediments. 1993. Table IB,
Note 51 and 80; Table IC, Note 9.
(x) OFR 93-449, Methods of Analysis by the U.S. Geological Survey
National Water Quality Laboratory--Determination of Chromium in Water
by Graphite Furnace Atomic Absorption Spectrophotometry. 1993. Table
IB, Note 46.
(xi) OFR 94-37, Methods of Analysis by the U.S. Geological Survey
National Water Quality Laboratory--Determination of Triazine and Other
Nitrogen-containing Compounds by Gas Chromatography with Nitrogen
Phosphorus Detectors. 1994. Table ID, Note 9.
(xii) OFR 95-181, Methods of Analysis by the U.S. Geological Survey
National Water Quality Laboratory--Determination of Pesticides in Water
by C-18 Solid-Phase Extraction and Capillary-Column Gas Chromatography/
Mass Spectrometry With Selected-Ion Monitoring. 1995. Table ID, Note
11.
(xiii) OFR 97-198, Methods of Analysis by the U.S. Geological
Survey National Water Quality Laboratory--Determination of Molybdenum
in Water by Graphite Furnace Atomic Absorption Spectrophotometry. 1997.
Table IB, Note 47.
(xiv) OFR 97-829, Methods of Analysis by the U.S. Geological Survey
National Water Quality Laboratory--Determination of 86 Volatile Organic
Compounds in Water by Gas Chromatography/Mass Spectrometry, Including
Detections Less Than Reporting Limits. 1999. Table IC, Note 13.
(xv) OFR 98-165, Methods of Analysis by the U.S. Geological Survey
National Water Quality Laboratory--Determination of Elements in Whole-
Water Digests Using Inductively Coupled Plasma-Optical Emission
Spectrometry and Inductively Coupled Plasma-Mass Spectrometry. 1998.
Table IB, Notes 50 and 81.
(xvi) OFR 98-639, Methods of Analysis by the U.S. Geological Survey
National Water Quality Laboratory--Determination of Arsenic and
Selenium in Water and Sediment by Graphite Furnace--Atomic Absorption
Spectrometry. 1999. Table IB, Note 49.
(xvii) OFR 00-170, Methods of Analysis by the U.S. Geological
Survey National Water Quality Laboratory--Determination of Ammonium
Plus Organic Nitrogen by a Kjeldahl Digestion Method and an Automated
Photometric Finish that Includes Digest Cleanup by Gas Diffusion. 2000.
Table IB, Note 45.
(xviii) Techniques and Methods Book 5-B1, Determination of Elements
in Natural-Water, Biota, Sediment and Soil Samples Using Collision/
Reaction Cell Inductively Coupled Plasma-Mass Spectrometry. Chapter 1,
Section B, Methods of the National Water Quality Laboratory, Book 5,
Laboratory Analysis. 2006. Table IB, Note 70.
(xix) U.S. Geological Survey Techniques of Water-Resources
Investigations, Book 5, Laboratory Analysis, Chapter A4, Methods for
Collection and Analysis of Aquatic Biological and Microbiological
Samples. 1989. Table IA, Note 4; Table IH, Note 4.
(xx) Water-Resources Investigation Report 01-4098, Methods of
Analysis by the U.S. Geological Survey National Water Quality
Laboratory--Determination of Moderate-Use Pesticides and Selected
Degradates in Water by C-18 Solid-Phase Extraction and Gas
Chromatography/Mass Spectrometry. 2001. Table ID, Note 13.
(xxi) Water-Resources Investigations Report 01-4132, Methods of
Analysis by the U.S. Geological Survey National Water Quality
Laboratory--Determination of Organic Plus Inorganic Mercury in Filtered
and Unfiltered Natural Water With Cold Vapor-Atomic Fluorescence
Spectrometry. 2001. Table IB, Note 71.
(xxii) Water-Resources Investigation Report 01-4134, Methods of
Analysis by the U.S. Geological Survey National Water Quality
Laboratory--Determination of Pesticides in Water by Graphitized Carbon-
Based Solid-Phase Extraction and High-Performance Liquid
Chromatography/Mass Spectrometry. 2001. Table ID, Note 12.
(xxiii) Water Temperature--Influential Factors, Field Measurement
and Data Presentation, Techniques of Water-Resources Investigations of
the U.S. Geological Survey, Book 1, Chapter D1. 1975. Table IB, Note
32.
* * * * *
(e) * * *
Table II--Required Containers, Preservation Techniques, and Holding Times
----------------------------------------------------------------------------------------------------------------
Maximum holding time 4
Parameter No./name Container 1 Preservation 2 3
----------------------------------------------------------------------------------------------------------------
Table IA--Bacterial Tests
----------------------------------------------------------------------------------------------------------------
1-5. Coliform, total, fecal, and E. PA, G.................. Cool, <10 [deg]C, 8 hours.22 23
coli. 0.008% Na2S2O3 \5\.
6. Fecal streptococci................ PA, G.................. Cool, <10 [deg]C, 8 hours.\22\
0.008% Na2S2O3 \5\.
7. Enterococci....................... PA, G.................. Cool, <10 [deg]C, 8 hours.\22\
0.008% Na2S2O3 \5\.
[[Page 56621]]
8. Salmonella........................ PA, G.................. Cool, <10 [deg]C, 8 hours.\22\
0.008% Na2S2O3 \5\.
----------------------------------------------------------------------------------------------------------------
Table IA--Aquatic Toxicity Tests
----------------------------------------------------------------------------------------------------------------
9-12. Toxicity, acute and chronic.... P, FP, G............... Cool, <=6 [deg]C \16\.. 36 hours.
----------------------------------------------------------------------------------------------------------------
Table IB--Inorganic Tests
----------------------------------------------------------------------------------------------------------------
1. Acidity........................... P, FP, G............... Cool, <=6 [deg]C \18\.. 14 days.
2. Alkalinity........................ P, FP, G............... Cool, <=6 [deg]C \18\.. 14 days.
4. Ammonia........................... P, FP, G............... Cool, <=6 [deg]C \18\, 28 days.
H2SO4 to pH <2.
9. Biochemical oxygen demand......... P, FP, G............... Cool, <=6 [deg]C \18\.. 48 hours.
10. Boron............................ P, FP, or Quartz....... HNO3 to pH <2.......... 6 months.
11. Bromide.......................... P, FP, G............... None required.......... 28 days.
14. Biochemical oxygen demand, P, FP G................ Cool, <=6 [deg]C \18\.. 48 hours.
carbonaceous.
15. Chemical oxygen demand........... P, FP, G............... Cool, <=6 [deg]C \18\, 28 days.
H2SO4 to pH <2.
16. Chloride......................... P, FP, G............... None required.......... 28 days.
17. Chlorine, total residual......... P, G................... None required.......... Analyze within 15
minutes.
21. Color............................ P, FP, G............... Cool, <=6 [deg]C \18\.. 48 hours.
23-24. Cyanide, total or available P, FP, G............... Cool, <=6 [deg]C \18\, 14 days.
(or CATC) and free. NaOH to pH >10 5 6,
reducing agent if
oxidizer present.
25. Fluoride......................... P...................... None required.......... 28 days.
27. Hardness......................... P, FP, G............... HNO3 or H2SO4 to pH <2. 6 months.
28. Hydrogen ion (pH)................ P, FP, G............... None required.......... Analyze within 15
minutes.
31, 43. Kjeldahl and organic N....... P, FP, G............... Cool, <=6 [deg]C \18\, 28 days.
H2SO4 to pH <2.
----------------------------------------------------------------------------------------------------------------
Table IB--Metals \7\
----------------------------------------------------------------------------------------------------------------
18. Chromium VI...................... P, FP, G............... Cool, <=6 [deg]C \18\, 28 days.
pH = 9.3-9.7 \20\.
35. Mercury (CVAA)................... P, FP, G............... HNO3 to pH <2.......... 28 days.
35. Mercury (CVAFS).................. FP, G; and FP-lined cap 5 mL/L 12N HCl or 5 mL/ 90 days.\17\
\17\. L BrCl \17\.
3, 5-8, 12, 13, 19, 20, 22, 26, 29, P, FP, G............... HNO3 to pH <2, or at 6 months.
30, 32-34, 36, 37, 45, 47, 51, 52, least 24 hours prior
58-60, 62, 63, 70-72, 74, 75. to analysis \19\.
Metals, except boron, chromium VI,
and mercury.
38. Nitrate.......................... P, FP, G............... Cool, <=6 [deg]C \18\.. 48 hours.
39. Nitrate-nitrite.................. P, FP, G............... Cool, <=6 [deg]C \18\, 28 days.
H2SO4 to pH <2.
40. Nitrite.......................... P, FP, G............... Cool, <=6 [deg]C \18\.. 48 hours.
41. Oil and grease................... G...................... Cool to <=6 [deg]C 28 days.
\18\, HCl or H2SO4 to
pH <2.
42. Organic Carbon................... P, FP, G............... Cool to <=6 [deg]C 28 days.
\18\, HCl, H2SO4, or
H3PO4 to pH <2.
44. Orthophosphate................... P, FP, G............... Cool, to <=6 [deg]C 18 Filter within 15
24. minutes; Analyze
within 48 hours.
46. Oxygen, Dissolved Probe.......... G, Bottle and top...... None required.......... Analyze within 15
minutes.
47. Winkler.......................... G, Bottle and top...... Fix on site and store 8 hours.
in dark.
48. Phenols.......................... G...................... Cool, <=6 [deg]C \18\, 28 days.
H2SO4 to pH <2.
49. Phosphorus (elemental)........... G...................... Cool, <=6 [deg]C \18\.. 48 hours.
50. Phosphorus, total................ P, FP, G............... Cool, <=6 [deg]C \18\, 28 days.
H2SO4 to pH <2.
53. Residue, total................... P, FP, G............... Cool, <=6 [deg]C \18\.. 7 days.
54. Residue, Filterable (TDS)........ P, FP, G............... Cool, <=6 [deg]C \18\.. 7 days.
55. Residue, Nonfilterable (TSS)..... P, FP, G............... Cool, <=6 [deg]C \18\.. 7 days.
56. Residue, Settleable.............. P, FP, G............... Cool, <=6 [deg]C \18\.. 48 hours.
57. Residue, Volatile................ P, FP, G............... Cool, <=6 [deg]C \18\.. 7 days.
61. Silica........................... P or Quartz............ Cool, <=6 [deg]C \18\.. 28 days.
64. Specific conductance............. P, FP, G............... Cool, <=6 [deg]C \18\.. 28 days.
65. Sulfate.......................... P, FP, G............... Cool, <=6 [deg]C \18\.. 28 days.
66. Sulfide.......................... P, FP, G............... Cool, <=6 [deg]C \18\, 7 days.
add zinc acetate plus
sodium hydroxide to pH
>9.
67. Sulfite.......................... P, FP, G............... None required.......... Analyze within 15
minutes.
68. Surfactants...................... P, FP, G............... Cool, <=6 [deg]C \18\.. 48 hours.
69. Temperature...................... P, FP, G............... None required.......... Analyze within 15
minutes.
73. Turbidity........................ P, FP, G............... Cool, <=6 [deg]C \18\.. 48 hours.
----------------------------------------------------------------------------------------------------------------
Table IC--Organic Tests \8\
----------------------------------------------------------------------------------------------------------------
13, 18-20, 22, 24, 25, 27, 28, 34-37, G, FP-lined septum..... Cool, <=6 [deg]C \18\, 14 days.\9\
39-43, 45-47, 56, 76, 104, 105, 108- 0.008% Na2S2O3 \5\,
111, 113. Purgeable Halocarbons. HCl to pH 2 \9\.
[[Page 56622]]
26. 2-Chloroethylvinyl ether......... G, FP-lined septum..... Cool, <=6 [deg]C \18\, 14 days.
0.008% Na2S2O3 \5\.
6, 57, 106. Purgeable aromatic G, FP-lined septum..... Cool, <=6 [deg]C \18\, 14 days.\9\
hydrocarbons. 0.008% Na2S2O3 \5\,
HCl to pH 2 \9\.
3, 4. Acrolein and acrylonitrile..... G, FP-lined septum..... Cool, <=6 [deg]C \18\, 14 days \10\
0.008% Na2S2O3, pH to
4-5 \10\.
23, 30, 44, 49, 53, 77, 80, 81, 98, G, FP-lined cap........ Cool, <=6 [deg]C \18\, 7 days until
100, 112. Phenols \11\. 0.008% Na2S2O3. extraction, 40 days
after extraction.
7, 38. Benzidines 11 12.............. G, FP-lined cap........ Cool, <=6 [deg]C \18\, 7 days until
0.008% Na2S2O3 \5\. extraction.\13\
14, 17, 48, 50-52. Phthalate esters G, FP-lined cap........ Cool, <=6 [deg]C \18\.. 7 days until
\11\. extraction, 40 days
after extraction.
82-84. Nitrosamines 11 14............ G, FP-lined cap........ Cool, <=6 [deg]C \18\, 7 days until
store in dark, 0.008% extraction, 40 days
Na2S2O3 \5\. after extraction.
88-94. PCBs \11\..................... G, FP-lined cap........ Cool, <=6 [deg]C \18\.. 1 year until
extraction, 1 year
after extraction.
54, 55, 75, 79. Nitroaromatics and G, FP-lined cap........ Cool, <=6 [deg]C \18\, 7 days until
isophorone \11\. store in dark, 0.008% extraction, 40 days
Na2S2O3 \5\. after extraction.
1, 2, 5, 8-12, 32, 33, 58, 59, 74, G, FP-lined cap........ Cool, <=6 [deg]C \18\, 7 days until
78, 99, 101. Polynuclear aromatic store in dark, 0.008% extraction, 40 days
hydrocarbons \11\. Na2S2O3 \5\. after extraction.
15, 16, 21, 31, 87. Haloethers \11\.. G, FP-lined cap........ Cool, <=6 [deg]C \18\, 7 days until
0.008% Na2S2O3 \5\. extraction, 40 days
after extraction.
29, 35-37, 63-65, 107. Chlorinated G, FP-lined cap........ Cool, <=6 [deg]C \18\.. 7 days until
hydrocarbons \11\. extraction, 40 days
after extraction.
60-62, 66-72, 85, 86, 95-97, 102, G...................... See footnote 11........ See footnote 11.
103. CDDs/CDFs \11\.
----------------------------------------------------------------------------------------------------------------
Aqueous Samples: Field and Lab G...................... Cool, <=6 [deg]C \18\, 1 year.
Preservation. 0.008% Na2S2O3 \5\, pH
<9.
Solids and Mixed-Phase Samples: Field G...................... Cool, <=6 [deg]C \18\.. 7 days.
Preservation.
Tissue Samples: Field Preservation... G...................... Cool, <=6 [deg]C \18\.. 24 hours.
Solids, Mixed-Phase, and Tissue G...................... Freeze, <=-10 [deg]C... 1 year.
Samples: Lab Preservation.
114-118. Alkylated phenols........... G...................... Cool, <6 [deg]C, H2SO4 28 days until
to pH <2. extraction, 40 days
after extraction.
119. Adsorbable Organic Halides (AOX) G...................... Cool, <6 [deg]C, 0.008% Hold at least 3 days,
Na2S2O3, HNO3 to pH <2. but not more than 6
months.
120. Chlorinated Phenolics........... G, FP-lined cap........ Cool, <6 [deg]C, 0.008% 30 days until
Na2S2O3, H2SO4 to pH acetylation, 30 days
<2. after acetylation.
----------------------------------------------------------------------------------------------------------------
Table ID--Pesticides Tests
----------------------------------------------------------------------------------------------------------------
1-70. Pesticides \11\................ G, FP-lined cap........ Cool, <=6 [deg]C \18\, 7 days until
pH 5-9 \15\. extraction, 40 days
after extraction.
----------------------------------------------------------------------------------------------------------------
Table IE--Radiological Tests
----------------------------------------------------------------------------------------------------------------
1-5. Alpha, beta, and radium......... P, FP, G............... HNO3 to pH <2.......... 6 months.
----------------------------------------------------------------------------------------------------------------
Table IH--Bacterial Tests
----------------------------------------------------------------------------------------------------------------
1-4. Coliform, total, fecal.......... PA, G.................. Cool, <10 [deg]C, 8 hours.22 23
0.008% Na2S2O3 \5\.
5. E. coli........................... PA, G.................. Cool, <10 [deg]C, 0. 8 hours.\22\
008% Na2S2O3 \5\.
6. Fecal streptococci................ PA, G.................. Cool, <10 [deg]C, 8 hours.\22\
0.008% Na2S2O3 \5\.
7. Enterococci....................... PA, G.................. Cool, <10 [deg]C, 0. 8 hours.\22\
008% Na2S2O3 \5\.
----------------------------------------------------------------------------------------------------------------
Table IH--Protozoan Tests
----------------------------------------------------------------------------------------------------------------
8. Cryptosporidium................... LDPE; field filtration. 1-10 [deg]C............ 96 hours.\21\
9. Giardia........................... LDPE; field filtration. 1-10 [deg]C............ 96 hours.\21\
----------------------------------------------------------------------------------------------------------------
\1\ ``P'' is for polyethylene; ``FP'' is fluoropolymer (polytetrafluoroethylene [PTFE]; Teflon[supreg]), or
other fluoropolymer, unless stated otherwise in this Table II; ``G'' is glass; ``PA'' is any plastic that is
made of a sterilizable material (polypropylene or other autoclavable plastic); ``LDPE'' is low density
polyethylene.
[[Page 56623]]
\2\ Except where noted in this Table II and the method for the parameter, preserve each grab sample within 15
minutes of collection. For a composite sample collected with an automated sample (e.g., using a 24-hour
composite sample; see 40 CFR 122.21(g)(7)(i) or 40 CFR part 403, Appendix E), refrigerate the sample at <=6
[deg]C during collection unless specified otherwise in this Table II or in the method(s). For a composite
sample to be split into separate aliquots for preservation and/or analysis, maintain the sample at <=6 [deg]C,
unless specified otherwise in this Table II or in the method(s), until collection, splitting, and preservation
is completed. Add the preservative to the sample container prior to sample collection when the preservative
will not compromise the integrity of a grab sample, a composite sample, or aliquot split from a composite
sample within 15 minutes of collection. If a composite measurement is required but a composite sample would
compromise sample integrity, individual grab samples must be collected at prescribed time intervals (e.g., 4
samples over the course of a day, at 6-hour intervals). Grab samples must be analyzed separately and the
concentrations averaged. Alternatively, grab samples may be collected in the field and composited in the
laboratory if the compositing procedure produces results equivalent to results produced by arithmetic
averaging of results of analysis of individual grab samples. For examples of laboratory compositing
procedures, see EPA Method 1664 Rev. A (oil and grease) and the procedures at 40 CFR 141.24(f)(14)(iv) and (v)
(volatile organics).
\3\ When any sample is to be shipped by common carrier or sent via the U.S. Postal Service, it must comply with
the Department of Transportation Hazardous Materials Regulations (49 CFR part 172). The person offering such
material for transportation is responsible for ensuring such compliance. For the preservation requirement of
Table II, the Office of Hazardous Materials, Materials Transportation Bureau, Department of Transportation has
determined that the Hazardous Materials Regulations do not apply to the following materials: Hydrochloric acid
(HCl) in water solutions at concentrations of 0.04% by weight or less (pH about 1.96 or greater; Nitric acid
(HNO3) in water solutions at concentrations of 0.15% by weight or less (pH about 1.62 or greater); Sulfuric
acid (H2SO4) in water solutions at concentrations of 0.35% by weight or less (pH about 1.15 or greater); and
Sodium hydroxide (NaOH) in water solutions at concentrations of 0.080% by weight or less (pH about 12.30 or
less).
\4\ Samples should be analyzed as soon as possible after collection. The times listed are the maximum times that
samples may be held before the start of analysis and still be considered valid. Samples may be held for longer
periods only if the permittee or monitoring laboratory have data on file to show that, for the specific types
of samples under study, the analytes are stable for the longer time, and has received a variance from the
Regional ATP Coordinator under Sec. 136.3(e). For a grab sample, the holding time begins at the time of
collection. For a composite sample collected with an automated sampler (e.g., using a 24-hour composite
sampler; see 40 CFR 122.21(g)(7)(i) or 40 CFR part 403, Appendix E), the holding time begins at the time of
the end of collection of the composite sample. For a set of grab samples composited in the field or
laboratory, the holding time begins at the time of collection of the last grab sample in the set. Some samples
may not be stable for the maximum time period given in the table. A permittee or monitoring laboratory is
obligated to hold the sample for a shorter time if it knows that a shorter time is necessary to maintain
sample stability. See 136.3(e) for details. The date and time of collection of an individual grab sample is
the date and time at which the sample is collected. For a set of grab samples to be composited, and that are
all collected on the same calendar date, the date of collection is the date on which the samples are
collected. For a set of grab samples to be composited, and that are collected across two calendar dates, the
date of collection is the dates of the two days; e.g., November 14-15. For a composite sample collected
automatically on a given date, the date of collection is the date on which the sample is collected. For a
composite sample collected automatically, and that is collected across two calendar dates, the date of
collection is the dates of the two days; e.g., November 14-15. For static-renewal toxicity tests, each grab or
composite sample may also be used to prepare test solutions for renewal at 24 h, 48 h, and/or 72 h after first
use, if stored at 0-6 [deg]C, with minimum head space.
\5\ ASTM D7365-09a specifies treatment options for samples containing oxidants (e.g., chlorine) for cyanide
analyses. Also, Section 9060A of Standard Methods for the Examination of Water and Wastewater (23rd edition)
addresses dechlorination procedures for microbiological analyses.
\6\ Sampling, preservation and mitigating interferences in water samples for analysis of cyanide are described
in ASTM D7365-09a(15). There may be interferences that are not mitigated by the analytical test methods or
D7365-09a(15). Any technique for removal or suppression of interference may be employed, provided the
laboratory demonstrates that it more accurately measures cyanide through quality control measures described in
the analytical test method. Any removal or suppression technique not described in D7365-09a(15) or the
analytical test method must be documented along with supporting data.
\7\ For dissolved metals, filter grab samples within 15 minutes of collection and before adding preservatives.
For a composite sample collected with an automated sampler (e.g., using a 24-hour composite sampler; see 40
CFR 122.21(g)(7)(i) or 40 CFR part 403, Appendix E), filter the sample within 15 minutes after completion of
collection and before adding preservatives. If it is known or suspected that dissolved sample integrity will
be compromised during collection of a composite sample collected automatically over time (e.g., by interchange
of a metal between dissolved and suspended forms), collect and filter grab samples to be composited (footnote
2) in place of a composite sample collected automatically.
\8\ Guidance applies to samples to be analyzed by GC, LC, or GC/MS for specific compounds.
\9\ If the sample is not adjusted to pH 2, then the sample must be analyzed within seven days of sampling.
\10\ The pH adjustment is not required if acrolein will not be measured. Samples for acrolein receiving no pH
adjustment must be analyzed within 3 days of sampling.
\11\ When the extractable analytes of concern fall within a single chemical category, the specified preservative
and maximum holding times should be observed for optimum safeguard of sample integrity (i.e., use all
necessary preservatives and hold for the shortest time listed). When the analytes of concern fall within two
or more chemical categories, the sample may be preserved by cooling to <=6 [deg]C, reducing residual chlorine
with 0.008% sodium thiosulfate, storing in the dark, and adjusting the pH to 6-9; samples preserved in this
manner may be held for seven days before extraction and for forty days after extraction. Exceptions to this
optional preservation and holding time procedure are noted in footnote 5 (regarding the requirement for
thiosulfate reduction), and footnotes 12, 13 (regarding the analysis of benzidine).
\12\ If 1,2-diphenylhydrazine is likely to be present, adjust the pH of the sample to 4.0 0.2 to
prevent rearrangement to benzidine.
\13\ Extracts may be stored up to 30 days at <0 [deg]C.
\14\ For the analysis of diphenylnitrosamine, add 0.008% Na2S2O3 and adjust pH to 7-10 with NaOH within 24 hours
of sampling.
\15\ The pH adjustment may be performed upon receipt at the laboratory and may be omitted if the samples are
extracted within 72 hours of collection. For the analysis of aldrin, add 0.008% Na2S2O3.
\16\ Place sufficient ice with the samples in the shipping container to ensure that ice is still present when
the samples arrive at the laboratory. However, even if ice is present when the samples arrive, immediately
measure the temperature of the samples and confirm that the preservation temperature maximum has not been
exceeded. In the isolated cases where it can be documented that this holding temperature cannot be met, the
permittee can be given the option of on-site testing or can request a variance. The request for a variance
should include supportive data which show that the toxicity of the effluent samples is not reduced because of
the increased holding temperature. Aqueous samples must not be frozen. Hand-delivered samples used on the day
of collection do not need to be cooled to 0 to 6 [deg]C prior to test initiation.
\17\ Samples collected for the determination of trace level mercury (<100 ng/L) using EPA Method 1631 must be
collected in tightly-capped fluoropolymer or glass bottles and preserved with BrCl or HCl solution within 48
hours of sample collection. The time to preservation may be extended to 28 days if a sample is oxidized in the
sample bottle. A sample collected for dissolved trace level mercury should be filtered in the laboratory
within 24 hours of the time of collection. However, if circumstances preclude overnight shipment, the sample
should be filtered in a designated clean area in the field in accordance with procedures given in Method 1669.
If sample integrity will not be maintained by shipment to and filtration in the laboratory, the sample must be
filtered in a designated clean area in the field within the time period necessary to maintain sample
integrity. A sample that has been collected for determination of total or dissolved trace level mercury must
be analyzed within 90 days of sample collection.
\18\ Aqueous samples must be preserved at <=6 [deg]C, and should not be frozen unless data demonstrating that
sample freezing does not adversely impact sample integrity is maintained on file and accepted as valid by the
regulatory authority. Also, for purposes of NPDES monitoring, the specification of ``<= [deg]C'' is used in
place of the ``4 [deg]C'' and ``<4 [deg]C'' sample temperature requirements listed in some methods. It is not
necessary to measure the sample temperature to three significant figures (1/100th of 1 degree); rather, three
significant figures are specified so that rounding down to 6 [deg]C may not be used to meet the <=6 [deg]C
requirement. The preservation temperature does not apply to samples that are analyzed immediately (less than
15 minutes).
[[Page 56624]]
\19\ An aqueous sample may be collected and shipped without acid preservation. However, acid must be added at
least 24 hours before analysis to dissolve any metals that adsorb to the container walls. If the sample must
be analyzed within 24 hours of collection, add the acid immediately (see footnote 2). Soil and sediment
samples do not need to be preserved with acid. The allowances in this footnote supersede the preservation and
holding time requirements in the approved metals methods.
\20\ To achieve the 28-day holding time, use the ammonium sulfate buffer solution specified in EPA Method 218.6.
The allowance in this footnote supersedes preservation and holding time requirements in the approved
hexavalent chromium methods, unless this supersession would compromise the measurement, in which case
requirements in the method must be followed.
\21\ Holding time is calculated from time of sample collection to elution for samples shipped to the laboratory
in bulk and calculated from the time of sample filtration to elution for samples filtered in the field.
\22\ Sample analysis should begin as soon as possible after receipt; sample incubation must be started no later
than 8 hours from time of collection.
\23\ For fecal coliform samples for sewage sludge (biosolids) only, the holding time is extended to 24 hours for
the following sample types using either EPA Method 1680 (LTB-EC) or 1681 (A-1): Class A composted, Class B
aerobically digested, and Class B anaerobically digested.
\24\ The immediate filtration requirement in orthophosphate measurement is to assess the dissolved or bio-
available form of orthophosphorus (i.e., that which passes through a 0.45-micron filter), hence the
requirement to filter the sample immediately upon collection (i.e., within 15 minutes of collection).
0
3. Amend Sec. 136.6 by adding paragraph (b)(4)(xxiii) to read as
follows:
Sec. 136.6 Method modifications and analytical requirements.
* * * * *
(b) * * *
(4) * * *
(xxiii) When analyzing metals by inductively coupled plasma-atomic
emission spectroscopy, inductively coupled plasma-mass spectrometry,
and stabilized temperature graphite furnace atomic absorption, closed-
vessel microwave digestion of wastewater samples is allowed as
alternative heating source for Method 200.2--``Sample Preparation
Procedure for Spectrochemical Determination of Total Recoverable
Elements'' for the following elements: Aluminum, antimony, arsenic,
barium, beryllium, boron, cadmium, calcium, chromium, cobalt, copper,
iron, lead, magnesium, manganese, molybdenum, nickel, potassium,
selenium, silver, sodium, thallium, tin, titanium, vanadium, zinc,
provided the performance specifications in the relevant determinative
method are met. (Note that this list does not include Mercury.) Each
laboratory determining total recoverable metals is required to operate
a formal quality control (QC) program. The minimum requirements include
initial demonstration of capability, method detection limit (MDL),
analysis of reagent blanks, fortified blanks, matrix spike samples, and
blind proficiency testing samples, as continuing quality control checks
on performance. The laboratory is required to maintain performance
records on file that define the quality of the data generated.
[FR Doc. 2019-22437 Filed 10-21-19; 8:45 am]
BILLING CODE 6560-50-P