310 C.M.R. 22.06
(j) apply to Community, Non-transient Non-community, and Transient Non-community Water Systems. The Maximum Contaminant Level for arsenic is 0.05 milligrams per liter for Community Water Systems and Non-transient Non-community Water Systems until January 23, 2006.
MAXIMUM CONTAMINANT LEVELS FOR INORGANIC CHEMICALS
Contaminant MCL (mg/l)
C = Community Water Systems; NTNC = Non-transient Non-community Water Systems; TNC = Transient Non-community W ater Systems
1 The Department will review and revise as necessary the perchlorate MCL within six years of its promulgation, taking into account new data on health effects, sources and occurrence, Treatment Techniques and associated issues, analytical feasibility and any other relevant information.
(4) Sampling Protocol. Monitoring shall be as follows:
(d) Composite Sampling. The total number of samples which must be analyzed may be reduced by compositing samples. Composite samples from a maximum of five Sampling Points are allowed provided that the detection limit of the method used for analysis is less than 1/5 of the MCL and none of the samples to be composited are representative of multiple sources. Compositing of samples must be approved by the Department and must be done in the laboratory. Compositing of source with previous detects is not allowed, unless otherwise authorized by the Department.
1. If the concentration in the composite sample is greater than or equal to 1/5 of the MCL of any inorganic chemical, then a follow-up sample must be analyzed within 14 days from each Sampling Point included in the composite. These samples must be analyzed for the contaminants that exceeded 1/5 of the MCL in the composite sample. Detection limits for each analytical method and MCL are the following:
DETECTION LIMITS FOR INORGANIC CONTAMINANTS
Contaminant MCL(mg/l) Methodology Detection Limit (mg/l) Antimony 0.006 Atomic Absorption; furnace 0.003
0.00085
ICP-Mass Spectrometry 0.0004 Hydride-Atomic absorption 0.001
6
Arsenic 0.010 Atomic Absorption; Furnace 0.001
Atomic Absorption; Platform-Stabilized Temperature 0.00057 Atomic Absorption; Gaseous Hydride 0.001 ICP- Mass Spectrometry 0.00148
1
Asbestos 7 MFL Transmission Electron Microscopy 0.2 MFL
Barium 2 Atomic Absorption; furnace technique 0.002
Atomic Absorption; direct aspiration 0.1 Inductively Coupled Plasma 0.002
(0.001)
Beryllium 0.004 Atomic Absorption; furnace 0.0002
Atomic Absorption; platform 0.000025
2
Inductively Coupled Plasma 0.0003 ICP-Mass Spectrometry
0.0003
Cadmium 0.005 Atomic Absorption; furnace technique 0.0001
Inductively Coupled Plasma 0.001
Chromium 0.1 Atomic Absorption; furnace technique 0.001
Inductively Coupled Plasma 0.007
(0.001)
3
Cyanide 0.2 Distillation, Spectrophotometric 0.02
3
Distillation, Automated, Spectrophotometric 0.005
3, 4
Distillation, Selective Electrode 0.05
4
Distillation, Amenable, Spectrophotometric 0.02
11
UV, Distillation, Spectrophotometric 0.0005 Micro Distillation, Flow Injection,
3
Spectrophotometric 0.0006
4
Ligand Exchange with Amperometry 0.0005
Mercury 0.002 Manual Cold Vapor Technique 0.0002
Automated Cold Vapor Technique 0.0002
Nickel Reserved Nitrate 10 (as N) Manual Cadmium Reduction 0.01
Automated Hydrazine Reduction 0.01 Automated Cadmium Reduction 0.05 Ion Selective Electrode 1 Ion Chromatography 0.01 Capillary Ion Electrophoresis 0.076
Nitrite 1 (as N) Spectrophotometric 0.01
Automated Cadmium Reduction 0.05 Manual Cadmium Reduction 0.01 Ion Chromatography 0.004 Capillary Ion Electrophoresis 0.103
9 10
Perchlorate 0.0020 Ion Chromatography 0.0010
LC/MS or LC/MS/MS
0.0010
IC/MS or IC/MS/MS 0.0010
Selenium 0.05 Atomic Absorption; furnace 0.002
Atomic Absorption: gaseous hydride 0.002
Sodium See 310 CMR 22.06A Thallium 0.002 Atomic Absorption; furnace 0.001
Atomic Absorption; platform 0.00075 ICP-Mass Spectrometry 0.0003
1 MFL = million fibers per liter >10 µm. 2 Using a 2X preconcentration step as noted in Method 200.7. Lower MDLs may be achieved when using a 4X preconcentration. 3 Screening methods for total cyanides. 4 Measures "free" cyanides when distillation, digestion, or ligand exchange is omitted. 5 Lower MDLs are reported using stabilized temperature graphite furnace atomic absorption. 6 The MCL for arsenic is effective January 23, 2006. Until then, the MCL is 0.05 mg/l. 7 The MDL reported for EPA method 200.9 (Atomic Absorption; Platform---Stabilized Temperature) was determined using a 2x concentration step during sample digestion. The MDL determined for samples analyzed using direct analyses (i.e., no sample digestion) will be higher. Using multiple deposition, EPA 200.9 is capable of obtaining MDL of 0.0001 mg/l. 8 Using selective ion monitoring, EPA Method 200.8 (ICP-MS) is capable of obtaining a MDL of 0.0001 mg/l. 9 Analysis must be conducted using EPA Method 314.0, revision 1.0, November 1999 as modified to achieve the stated detection limit or EPA Method 314.1. 10 Minimum Reporting Level (MRL). EPA Method 314.0 is capable of obtaining a MDL of less than 0.0010 mg/l. 11 Measures total cyanides when UV-digestor is used, and “free” cyanides when UV-digestor is bypassed.
(5) Asbestos Sampling Frequency. The frequency of monitoring conducted to determine compliance with the Maximum Contaminant Level for asbestos specified in 310 CMR 22.06(2) shall be conducted as follows:
(c) Basis of an Asbestos Waiver. The granting of a waiver will be based on a consideration of the following factors:
(6) Sampling Frequency for IOCs. The frequency of monitoring conducted to determine compliance with the Maximum Contaminant Levels in 310 CMR 22.06(2) for antimony, arsenic, beryllium, barium, cadmium, chromium, cyanide, fluoride, mercury, nickel, selenium and thallium shall be as follows:
(e) Basis of the IOC Sampling Frequency During a Waiver. The granting of a waiver by the Department will be based on the following:
(7) Sampling Frequency for Nitrate. All Public Water Systems (Community, Non-transient Non-community, and Transient Non-community Water Systems) shall monitor to determine compliance with the Maximum Contaminant Level for nitrate specified in 310 CMR 22.06(2).
(8) Sampling Frequency for Nitrite. All Public Water Systems (Community, Non-transient Non-community, and Transient Non-community Water Systems) shall monitor to determine compliance with the Maximum Contaminant Level for nitrite in 310 CMR 22.06(2).
(9) Sampling Frequency for Perchlorate.
(a) Initial Monitoring. Community and Non-transient Non-community systems shall complete initial monitoring for perchlorate as specified in 310 CMR 22.06(9)(a).
(10) Confirmation Sampling.
(c) Deadline for Perchlorate Confirmation Samples. Whenever the perchlorate sampling results indicate an exceedance of the Maximum Contaminant Level, the system shall take a confirmation sample using EPA Method 331.0 or EPA Method 332.0 in accordance with 310 CMR 22.06(10)(c)1. and 2. within 24 hours of the system's receipt of written notification of the analytical results. For the purposes of 310 CMR 22.06(10)(c), written notification of the analytical results means notification by email, fax, or letter. The system shall report the initial sample result that exceeded the MCL to the Department within seven days. Systems that are unable to take a confirmation sample within 24 hours of the system's receipt of written notification of the analytical results, shall immediately contact the Department for further direction. When taking a confirmation sample as required by 310 CMR 22.06(10)(c):
(13) Compliance Calculations. Compliance with the Maximum Contaminant Levels set out in 310 CMR 22.06(2) shall be determined based on the analytical results obtained at each Sampling Point. If one Sampling Point is in violation of an MCL, the system is in violation of the MCL.
(16) Analytical and Sampling Methods for Inorganics:
(a) Analytical Methods for IOCs: Analysis for the listed inorganic contaminants shall be conducted using the following methods:
INORGANIC CONTAMINANTS ANALYTICAL METHODS
Reference (Method Number)
11 3 4 23
Contaminant Methodology EPA ASTM SM SM Online Other Antimony Atomic Absorption: 3113B 3113 B-99
Furnace
2
Atomic Absorption: 200.9 platform
2
ICP-Mass Spectrometry 200.8 Hydride-Atomic Absorption
D-3697-92, 02
12
Arsenic Atomic Absorption: Furnace 3113B 3113 B-99
D2972-97C, 03C
Atomic Absorption; Hydride 3114B 3114 B-97
D-2972-97, 03B
13 2 5
Inductively Coupled Plasma 200.7 3120B 3120 B-99
2
ICP-Mass Spectrometry 200.8
2
Atomic Absorption; Platform 200.9 Differential Pulse Anodic Stripping Voltametry Method 100116
Asbestos Transmission Electron
9
Microscopy 100.1
10
Transmission Electron 100.2 Microscopy
Barium Atomic Absorption; Furnace 3113B 3113B-99
Atomic Absorption; Direct 3111D 3111D-99
2
Inductively Coupled Plasma 200.7 3120B 3120B-99
2
ICP-Mass Spectrometry 200.8
Beryllium Atomic Absorption; Furnace 3113B 3113B-99
D3645-97, 03B
2
Atomic Absorption; Platform 200.9
2
Inductively Coupled Plasma 200.7 3120B 3120B-99
2
ICP-Mass Spectrometry 200.8
11 3 4 23
Contaminant Methodology EPA ASTM SM SM Online Other Cadmium Atomic absorption; Furnace 3113B 3113B-99
2
Inductively-coupled Plasma 200.7
2
ICP-Mass Spectrometry 200.8
2
Atomic Absorption; Platform 200.9
Chromium Atomic absorption; Furnace 3113B 3113B-99
2
Inductively Coupled Plasma 200.7 3120B 3120B-99
2
ICP-Mass Spectrometry 200.8
2
Atomic Absorption; Platform 200.9
Cyanide Manual Distillation 4500-CN C-
D2036-98A
Manual Distillation followed by: Spectrophotometric,
- -
Amenable D2036-98B 4500-C NG 4500-CN G-99 Manual Distillation followed by Spectrophotometric,
- - 5
Manual D2036-98A 4500-CN E 4500-CN E-99 I-3300-85 Spectrophotometric, Semi-
6
automated 335.4
- -
Selective Electrode 4500-CN F 4500-CN F-99 UV, Distillation, Spectrophotmetric Micro Distillation, Flow Injection Kelada-0118 Spectrophotometric QuikChem10-204-00-
1-X 19
Ligand Exchange and
22 21
Amperometry D6888-04 OIA-1677-DW
2
Mercury Manual cold vapor 245.1 D3223-97,02 3112B 3112B-99
1
Automated cold vapor 245.2
2
ICP-Mass Spectrometry 200.8
Nickel Atomic Absorption: Furnace 3113B 3113B-99
2
Atomic Absorption: Platform 200.9 Atomic Absorption Direct 3111B 3113B-99
2
Inductively Coupled Plasma 200.7 3120B 3120-99
2
ICP-Mass Spectrometry 200.8
- -
Nitrate Manual cadmium reduction D3867-90B 4500-NO E 3 4500-NO E-00 3
6 - -
Automated cadmium reduction 353.2 D3867-90A 4500-NO F 3 4500-NO F-00 3
- - 7
Ion selective electrode 4500-NO D 3 4500-NO D-0 3 601
6 8
Ion chromatography 300.0 D4327-97,03 4110B 4110B-00 B-1011
20 300.1
Capillary Ion Electrophoresis D6508-00, Rev.224
- -
Nitrite Spectrophotometric 4500-NO B 2 4500- NO B-00 2
6 - -
Automated cadmium reduction 353.2 D3867-90A 4500-NO F 3 4500-NO F-00 3
- -
Manual cadmium reduction 4500-NO E 3 4500-NO E-00 3
D3867-90B
6 8
Ion chromatography 300.0 D4327-97,03 4110B 4110B-00 B-1011
20 300.1
Capillary Ion Electrophoresis D6508-00, Rev.224
14
Perchlorate Ion chromatography 314.0
15 314.1 16
LC/MS or LC/MS/MS 331
17
IC/MS or IC/MS/MS 332
Selenium Hydride-Atomic absorption; D3859-98,03A 3114B 3114B-97
Atomic Absorption: Furnace 3113B 3113B-99
D3859-98,03B
2
ICP-Mass Spectrometry 200.8
2
Atomic Absorption; Platform 200.9
2
Thallium Atomic absorption; Platform 200.9
2
ICP-Mass Spectrometry 200.8
S)))))))))))))))))))))))))))))))))))))))))))))))))Q
The procedures shall be done in accordance with the documents listed below. The incorporation by reference of the following documents listed in footnotes 1-11 and 15 was approved by the Director of the Federal Register in accordance with 5 U.S.C. 552(a) and 1 CFR Part 51. Copies of the documents may be obtained from the sources listed below. Information regarding obtaining these documents can be obtained from the Safe Drinking Water Hotline at 900-426-4791. Documents may be inspected at EPA’s Drinking Water Docket, 401 M Street, SW., Washington, DC 20460 (Telephone 202-260-3027); or at the Office of Federal Register, 800 North Capital Street, NW., Suite 700, Washington, DC.
1 Methods of Chemical Analysis of Water and Wastes, EPA-600/4-79-020, March 1983. Available at NTIS, PB84-128677. 2 Methods for the Determination of Metals in Environmental Samples - Supplement I, EPA-600/R-94/111 May 1994. Available at NTIS, PB 95-125472. 3 Annual Book of ASTM Standards, 1994 , 1996, or 1999 Vols. 11.01 and 11.02, American Society for Testing and Materials. The previous versions of D1688-95A, D1688-95C (copper), D3559-95D (lead), D1293-95 (pH), D1125-95A, (conductivity) and D859-94 (silica) are also approved. These previous versions D1688-90A, C; D3559-90D, D1293-84, D1125-91A and D859-88, respectively are located in the Annual Book of ASTM Standards, 1994, Vols. 11.01. Copies may be obtained from the American Society for Testing and Materials, 100 Barr Harbor Drive, West Conshohocken, PA 19428. 4 th th th th 18 , 19 , and 20 edition of Standard Methods for the Examination of Water and Wastewater, 18 (1982),
th th 19 (1995), and 20 (1998) editions, American Public Health Association; either edition may be used. Copies may be obtained from the American Public Health Association, 1015 Fifteenth Street NW, Washington, DC 20005. The cited methods published in any of these three editions may be used, except
th
that the versions of 3111B, 3111D, 3113B and 3114B in the 20 edition may not be used. 5 Method I-2601-90, Methods for Analysis by the U.S. Geological Survey National Water Quality Laboratory – Determination of Inorganic and Organic Constituents in Water and Fluvial Sediments, Open File Report 93-125, 1993; For Methods I-1030-85; I-1601-85; I-1700-85; I-2598-85, I-2700-85; and I-3300-85 See Techniques of Water Resources Investigation of the U.S. Geological Survey, Book 5,
rd
Chapter A-1, 3 edition, 1989; Available from Information Services, U.S. Geological Survey, Federal Center, Box 25286, Denver, CO 80225-0425.
6 Methods for the Determination of Inorganic Substances in Environmental Samples, EPA 600/R-93/100, August 1993. Available at NTIS, PB94-120821. 7 The procedure shall be done in accordance with Technical Bulletin 601 Standard Method of Test for Nitrate in Drinking Water, July 1994, PN 221890-001, Analytical Technology, Inc. Copies may be obtained from ATI Orion, 529 Main Street, Boston, MA 02129. 8 Method B-1011, Standard Method of Test for Nitrate in Drinking Water, July 1994, PN 221890-001, Analytical Technology, Inc. Copies may be obtained from ATI Orion, 529 Main Street, Boston, MA 02129. 9 Method 100.1, Analytical Methods for Determination of Asbestos Fibers in Water, EPA/600/4-83/043, September 1983, Available at NTIS, PB83-206471. 10 Method 100.2, Determination of Asbestos Structures Over 10 (cid:58)m in Length in Drinking Water, EPA/600/R-94/134, June 1994. Available at NTIS, PB94-201902. 11 Because MDLs reported in EPA Methods 200.7 and 200.9 were determined using a 2X preconcentration step during sample digestion, MDLs determined when samples are analyzed by direct analysis (i.e., no sample digestion) will be higher. For direct analysis of cadmium and arsenic by Method 200.7, and arsenic by Method 3120B sample preconcentration using pneumatic nebulization may be required to achieve lower detection limits. Preconcentration may also be required for direct analysis of antimony, lead, and thallium by Method 200.9; antimony and lead by Method 3113B; and lead by Method D3559-90D unless multiple infurnace depositions are made. 12 If ultrasonic nebulization is used in the determination of arsenic by Method 200.8 the arsenic must be in the pentavalent state to provide uniform signal response. For direct analysis of arsenic with the Method 200.8 using ultrasonic nebulization, samples and standards must contain 1 mg/L of sodium hypochlorite. 13 [Deleted]. 14 Revision 1.0, November, 1999, Determination of Perchlorate in Drinking Water Using Ion Chromatography as modified to achieve performance requirements in 310 CMR 22.06(4). 15 EPA Method 314.1: Determination of Perchlorate in Drinking Water Using Inline Column Concentration/Matrix Elimination Ion Chromatography with Suppressed Conductivity Detection. 16 EPA Method 331.0: Determination of Perchlorate in Drinking Water by Liquid Chromatography Electrospray Ionization Mass Spectrometry.
17 EPA Method 332.0: Determination of Perchlorate in Drinking Water Using Ion Chromatography with Suppressed Conductivity and Electrospray Ionization Mass Spectrometry. 18 The description for the Kelada-01 Method, Kelada Automated Test Methods for Total Cyanide, Acid Dissociable Cyanide, and Thiocyanate, Revision 1.2, August 2001, EPA #821-B-01-009 for cyanide is available from the National Technical Information Service (NTIS), PB 2001-108275, 5285 Port Royal Road, Springfield, VA 22161. The toll-free telephone number is 800-553-6847. 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. Similarity, modified flow cell configurations and flow conditions may be used in the method, provided that the QC acceptance criteria are met. 19 The description for the 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 2.1, November 30, 2000, for cyanide is available from Lachat Instruments, 6645 W. Mill Rd., Milwaukee, WI 53218. Telephone: 414-358-4200. 20 Methods for the Determination of Organic and Inorganic Compounds in Drinking Water, Vol.1, EPA 815- R-00-014, August 2000. Available at NTIS, PB2000-106981. 21 Method OIA -1677, DW Available Cyanide by Flow Injection, Ligand Exchange, and Amperometry, January 2004. EPA-821-R-04-001, Available from ALPKEM, A Division of OL Analytical, P.O. Box 9010, College Station, TX 77842-9010. 22 Sulfide levels below those detected using lead acetate paper may produce positive method interferences. Test samples using a more sensitive sulfide method to determine if a sulfide interference is present, and treat samples accordingly. 23 Standard Methods Online are available at http://www.standardmethods.org. The year in which each method was approved by the Standards Methods Committee is designated by the last two digits in the method number. The methods listed are the only online versions that may be used. 24 Method D6508, Rev.2, Test Method for Determination of Dissolved Inorganic Anions in Aqueous Matrices Using Capillary Ion Electrophoresis and Chromate Electrolyte.
(b) Analytical Methods for Fluoride: Analyses for fluoride shall be conducted using the following methods:
Reference (Method Number)
1 2 8
Methodology EPA ASTM SM SM Online Other
Ion Chromatography 300.05 D4327-97 4110B 4110B-00- Manual Distillation; Colorimetric 300.16 4500F-B,D 4500F-B,D-97 SPADNS Manual Electrode D1179-93,99B 4500F-C 4500F-C-97 Automated Alizarin fluorine blue - 4500F-E 129-71W 3 lanthanum with distillation (complexone) Automated ion selective electrode 380-75W E 4 Capillary Ion Electrophoresis D6508, Rev. 27
1 Annual Book of ASTM Standards, part 31 Water. American Society for Testing and Materials, 1916 Race Street, Philadelphia, Pennsylvania 19103. 2 th th th Standard Methods for the Examination of Water and Wastewater, 18 , 19 , and 20 edition, American Public Health Association, American Water Works Association, Water Pollution Control Federation, 1992, 1995, and 1998. 3 Fluoride in Water and Wastewater, Industrial Method # 129-71W. Technicon Industrial Systems. December 1972. Copies may be obtained from Bran & Luebbe, 1025 Busch Parkway, Buffalo Grove, IL 60089. 4 Fluoride in Water and Wastewater, Technicon Industrial Systems. February 1976. Copies may be obtained from Bran & Luebbe, 1025 Busch Parkway, Buffalo Grove, IL 60089. 5 Methods for the Determination of Inorganic Substances in Environmental Samples, EPA-600/R-93/100, August 1993. Available at NTIS, PB94-120821. 6 Methods for the Determination of Organic and Inorganic Compounds in Drinking Water, Vol.1, EPA 815- R-00-014, August 2000, Available at NTIS, PB2000-106981.
7 Method 6508, Rev.2, Test Method for Determination of Dissolved Inorganic Anions in Aqueous Matrices Using Capillary Ion Electrophoreses and Chromate Electrolyte, available from Waters Corp., 34 Maple St., Milford, MA 01757, Telephone: 508/482-2131, Fax: 508/482-3625. 8 Standard Methods Online are available at http://www.standardmethods.org. The year in which each method was approved by the Standard Methods Committee is designated by the last two digits in the method number. The methods listed are the only online versions that may be used.
(c) Sample Collection Methods for IOCs: Sample collection for antimony, arsenic, asbestos, barium, beryllium, cadmium, chromium, cyanide, fluoride, mercury, nickel, nitrate, nitrite, perchlorate, selenium and thallium under 310 CMR 22.06 shall be conducted using the sample preservation, container, and maximum holding time procedures specified in the table below:
1 2 3
Contaminant Preservative Container Time Antimony Con HNO to pH<2 3 P or G six months Arsenic Con HNO to pH<2 3 P or G six months Asbestos Cool, 4°C P or G 48 hours Barium Con HNO to pH<2 3 P or G six months Beryllium Con HNO to pH<2 3 P or G six months Cadmium Con HNO to pH<2 3 P or G six months Chromium Con HNO to pH<2 3 P or G six months
4
Cyanide Cool,4°C, NAOH to pH>12 P or G 14 days Fluoride None P or G one month Mercury Con HNO to pH<2 3 P or G 28 days Nickel Conc HNO 3 P or G six months Nitrate Chlorinated Cool, 4°C P or G 14 days Chlorinated Con H SO to pH<2 2 4 P or G 28 days Non-chlorinated Cool 4°C P or G 48 hours Non-chlorinated Con H SO to pH<2 2 4 P or G 28 days Nitrite Cool, 4°C P or G 48 hours Perchlorate None P or G 28 days Selenium Con HNO to pH<2 3 P or G six months Thallium Con HNO to pH<2 3 P or G six months
1 For cyanide determinations samples must be adjusted with sodium hydroxide to pH 12 at the time of collection. When chilling is indicated the sample must be shipped and stored at 4°C or less. Acidification of nitrate or metals samples may be with a concentrated acid or a dilute (50% by volume) solution of the applicable concentrated acid. Acidification of samples for metals analyses is encouraged and allowed at the laboratory rather than at the time of sampling provided the shipping time and other instruction in Section 8.3 of EPA methods 200.78 or 200.8 or 200.9 are followed. 2 P = plastic, hard or soft; G = glass, hard or soft. 3 In all cases, samples should be analyzed as soon after collection as possible. Follow additional (if any) information on preservation, containers, or holding times that is specified in the method. 4 See method(s) for the information for preservation.
BAT FOR INORGANIC CONTAMINANTS LISTED IN 310 CMR 22.06(2)
CHEMICAL NAME BAT(s) Antimony 2,7 Arsenic 1, 2, 5, 6, 7, 9, 125 Asbestos 2, 3, 8 Barium 5, 6, 7, 9 Beryllium 1, 2, 5, 6, 7 Cadmium 2, 5, 6, 7 Chromium 2, 5, 6 , 72 Cyanide 5, 7, 13
1 1 1
Mercury 2 , 4, 6 , 7 Nickel 5, 6, 7 Nitrate 5, 7, 9 Nitrite 5, 7 Perchlorate 5
3
Selenium 1, 2 , 6, 7, 9 Thallium 1, 5
Key to BATs in Table 1 = Activated Alumina 2 = Coagulation/Filtration (Not BAT for Systems <500 service connections) 3 = Direct and Diatomite Filtration 4 = Granular Activated Carbon 5 = Ion Exchange 6 = Lime Softening (not BAT for systems <500 service connections) 7 = Reverse Osmosis 8 = Corrosion Control 9 = Electrodialysis 10 = Chlorine 11 = Ultraviolet 12 = Oxidation/Filtration 13 = Alkaline Chlorination
1 2 BAT only if influent Hg concentrations <10 µg/l. BAT for Chromium III only 3 BAT for Selenium IV only 4 BAT for Arsenic V. Pre-oxidation may be required to convert Arsenic III to Arsenic V. 5 To obtain high removals; iron to arsenic ratio must be at least 20.1.
(18) The Administrator, pursuant to the Safe Drinking Water Act, Title 14, § 1412, hereby identifies in the following table the affordable technology, Treatment Technique, or other means available to systems serving 10,000 persons or fewer for achieving compliance with the Maximum Contaminant Level for arsenic:
1 2
SMALL SYSTEM COMPLIANCE TECHNOLOGIES (SSCTS) FOR ARSENIC
Small System Compliance Technology Affordable for Listed Small System Categories3 Activated Alumina (centralized) . . . . . . . . . . . . . . . . . . . . All size categories.
4
Activated Alumina (Point-of-Use) . . . . . . . . . . . . . . . . . . All size categories.
5
Coagulation/Filtration . . . . . . . . . . . . . . . . . . . . . . . 501–3,300, 3,301–10,000. Coagulation-assisted Microfiltration . . . . . . . . . . . . 501–3,300, 3,301–10,000.
6
Electrodialysis reversal . . . . . . . . . . . . . . . . . . . . . . 501–3,300, 3,301–10,000. Enhanced Coagulation/Filtration . . . . . . . . . . . . . . . . . . . . All size categories. Enhanced lime softening (pH> 10.5) . . . . . . . . . . . . . . . . . All size categories. Ion Exchange . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . All size categories.
5
Lime Softening . . . . . . . . . . . . . . . . . . . . . . . . . . . . 501–3,300, 3,301–10,000.
7
Oxidation/Filtration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . All size categories.
6
Reverse Osmosis (centralized) . . . . . . . . . . . . . . . . 501–3,300, 3,301–10,000.
4
Reverse Osmosis (Point-of-Use) . . . . . . . . . . . . . . . . . . . All size categories.
1 Section 1412(b)(4)(E)(ii) of SDWA specifies that SSCTs must be affordable and technically feasible for small systems. 2 SSCTs for Arsenic V. Pre-oxidation may be required to convert Arsenic III to Arsenic V. 3 The SDWA (ibid.) specifies three categories of small systems: (i) those serving 25 or more, but fewer than 501, (ii) those serving more than 500, but fewer than 3,301, and (iii) those serving more than 3,300, but fewer than 10,001. 4 When POU or POE devices are used for compliance, programs to ensure proper long-term operation, maintenance, and monitoring must be provided by the water system to ensure adequate performance. 5 Unlikely to be installed solely for arsenic removal. May require pH adjustment to optimal range if high removals are needed. 6 Technologies reject a large volume of water—may not be appropriate for areas where water quantity may be an issue. 7 To obtain high removals, iron to arsenic ratio must be at least 20:1.