Post on 06-Mar-2018
METHODS LIST
Methods List forAutomated Ion AnalyzersFlow Injection Analysis • Ion Chromatography
SEPTEMBER 2013
QuikChem® Methods List Use this list to:
• Identify and select analytical methods for your analyte, range, and matrix requirements. • Locate all current Lachat methods for ion chromatography and flow injection analysis. • Find methods accepted for USEPA compliance monitoring. These methods have symbols after
the method number depending on whether the method is Accepted or Equivalent for NPDES and/or NPDWR reporting. Additional regulatory information can be found in the Regulatory Quick Reference section.
• Find methods with ERA or other external QC included in the support data. These methods have a * after the method number.
Performance Data Specifications • Range: The range quoted in the Lachat methods list is based on the actual, calibrated range. The
calibrated range is the lowest calibration standard to the highest calibration standard. (A blank is typically included in the calibration, but is not included in the method range.)
. • MDL: The MDL (method detection limit) is calculated by the following protocols:
The Student’s T number for the number of replicates is multiplied by the standard deviation calculated from those replications.
If 7 replicates are used: The Student’s T value is 3.14.
If 21 replicates are used: The Student’s T value is 2.528.
Example for 21 replicates: 2.528 X 0.123 = 0.39 for an MDL
• Quantitation Limit: Quantitation limit is typically 3 to 5 times the calculated MDL or 10X the standard deviation of the MDL standard used. Typically, this is the lowest calibration standard in a given method.
• Precision: Stated in the methods as %RSD. %RSD is calculated as follows: %RSD = (SD /Mean) x 100
Part Numbers Versus Method Numbers To convert Method Numbers to part numbers, place an E in front of the Method Number.
Table of Contents Method Number Key: 1 – 3 What’s New: 4 Regulatory Quick Reference: 5 – 10 Ion Chromatography Methods: 11– 16 Flow Injection Analysis Methods: 17 – 63 Sample Matrix / Method Parameter Table: 64 Chart of selected parts: 65-66 •This is a list of the reaction modules presently available for use with QuikChem® instruments. The analytical capabilities of these instruments are not
limited to these methods. The Lachat Applications group regularly adds new methods to this list. Requests for custom and proprietary methods development or consulting can be sent to Lachat Sales at 800-247-7613 ext 3580 or sales@lachatinstruments.com. •Methods, other than those listed as EPA-Accepted, were developed to meet individual customer requirements. In order to ensure that Lachat
methods exactly meet the requirements of your application, please contact your local Sales Representative or Distributor •When you have purchased a manifold, a copy of the method will be sent with a manifold diagram. Copies of methods without manifold diagrams are
available to Lachat customers upon request.
LachatQuikChem®MethodNumberKey
XX ‐ XXX ‐ XX ‐ X ‐ Xmatrix analyte form chemistry concentration
Matrix:10 Waters,wastewaters 11 Seawater12 Soilextracts 13 Plantorsoildigests14 Fertilizerdigests 15 Feeds&forages16 Bloodserum,plasma 17 Pharmaceuticals18 Aqueousformulations 19 Platingbaths/mineralprocessing20 Foodstuffs 21 Beverages22 Detergents 23 Bioreactorsolutions24 Extractsofairsamplingfilters 25 Chlor‐Alkali(Caustic,brine)26 Tobaccoextracts 27 Urine29 Produced/FlowbackWater 30 Brackishwaters31 Brackishorseawater 40 Non‐aqueous50 Diluteseawater 60 Biologicalfluids70 Highpuritywater 80 UltraLowFlowMethod90 Multi‐matrixmethod
Analyte:Thefirstthreenumbersindicatethepredominantchemicalmoiety.
Class(IonChromatography)510 Anions 511 RapidICAnions512 RapidSulfate 520 Cations530 Metals 540 Oxyhalides550 OrganicAcids
Element105 Boron 107 Nitrogen109 Fluorine 111 Sodium112 Magnesium 113 Aluminum114 Silicate 115 Phosphorus116 Sulfur 117 Chlorine119 Potassium 120 Calcium123 Molybdenum 124 Chromium(Hexavalent)125 Uranium 126 Iron127 Beryllium 128 Nickel129 Copper 130 Zinc131 Manganese 135 Bromine136 Iodine 138 Mercury140 Carbon 141 Chromium(Total)
Page 1 of 68
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage2of68
Enzymes401 Protease 402 Amylase403 Lactatedehydrogenase(LDH) 404 Catalase
Molecules
201 Reducingsugars(Total) 202 Nicotine203 Glucose 204 Cyanide206 Urea 207 Lacticacid,D(‐)208 Lowryprotein(albumin) 209 Hydrogenperoxide210 Phenol 212 Glucan(beta‐Glucan)213 Citricacid 214 Ethanol215 Penicillin 216 Carbondioxide217 Hydrazine 218 Totalaminoacids219 Ascorbicacid 220 Riboflavin221 Formaldehyde 223 Humicacid224 Chlorate 225 Hydroxide226 Hypochlorite 227 Creatinine228 Sorbicacid 229 Thiocyanate230 Pyruvate 231 Polyvinylalcohol(PVA)232 Glutamate 233 Glutamine234 CMC 235 Glycerol236 Erythromycin 237 Freeaminonitrogen238 Methanol 239 Glycolate240 Sebacate 241 Sulfurdioxide243 Hydroxy‐Proline 244 Amylose245 Monochloramine 246 ReducingSubstances
Parameters301 Hardness(Total) 302 Conductivity303 Alkalinity 304 pH305 Acidity 306 Surfactants307 Oxygen 308 Color
Form:Themethodeitherdeterminesthisformoftheanalyteorconvertstheanalytetothisformfordetermination.00 Formgivenbypreviousthreenumbers 01 Phosphate(PO4
3‐)02 Calcium(Ca2+) 03 Potassium(K+)04 Nitrate(NO3
‐) 05 Nitrite(NO2‐)
06 Ammonium(NH4+),Ammonia(NH3) 07 Chloride(Cl‐)
08 BoricAcid(H3BO3) 09 Iodide(I‐)10 Sulfate(SO4
2‐) 11 Sulfite(SO32‐)
12 Fluoride(F‐) 13 Chromium(VI)(Cr)14 Chromium(Cr3+) 15 Cobalt(II)(Co2+)16 Nickel(II)(Ni2+) 17 Copper(III)(Cu2+)18 TotalIron(Fe2++Fe3+) 19 Iron(II)(Fe2+)20 Iron(III),(Fe3+) 21 Bromide(Br‐)22 Silver(I) 23 Molybdenum(VI)(Mo)24 Hydronium(H3O
+,H+) 25 Hydroxide(OH‐)26 Magnesium(Mg2+) 27 Silicate(SiO2)29 Sulfide(S2‐) 30 Acidity(volatile)
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage3of68
31 Calciumcarbonate(CaCO3) 32 Sodiumcation(Na+)33 Aluminum(inorganic)(Al) 34 Aluminum(organic)(Al)35 Chlorate(ClO3
‐) 36 Hypochlorite(OCl‐)37 Mercury(atomic)(Hg) 38 Sorbate39 Carbondioxide(CO2) 40 Perchlorate41 Iodate(IO3
‐) 42 Sulfurdioxide
Chemistry:Someanalyteshavemorethanonechemistry.
Example:Ammonia 10‐107‐06‐1 phenolate,phenate 10‐107‐06‐2 salicylate
10‐107‐06‐5 gasdiffusion
Concentration:Eachrangeofconcentrationsforananalyteisgivenbyasingleletter.Seethemethodslistfortheranges.Somemethodscovermorethanonerange.
Heaters:Standardheater:Has175cmof0.032”i.d.(0.8mm)and650cmofof0.032”i.d.tubingNon‐standardheater:Hasadifferenttypeandorlengthoftubingthanthatlistedabove.(Controllerandheaterblockarethesame;onlythetubingisdifferent).
NewMethods:ThemajorityofnewmethodsdevelopedbyLachatInstrumentsaretheresultofacustomerrequest.Ifyoudonotseethemethodyouneed,pleasecontactusatwww.lachatinstruments.com.
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage4of68
What’sNewAugust2012throughAugust2013 These14LachatmethodswereintroducedsincethelastLachatmethod’slist,fromAugust2012throughAugust2013.Formoreinformationonanyofthesemethods,pleasecontactLachatTechnicalSupport.
MethodNumberAnalyteRange(s)Comments
Water/Wastewater10‐107‐06‐5‐J Ammonia
TKN(coppercatalyst)
0.01‐1.0 mgN/L0.1‐20mgN/L0.1‐5.0mgN/L0.25‐20mgN/L
Gasdiffusion.660nm.Salicylate/DCICmethod.Standardheaterrequired.Canbeusedwithbrackish/salinesamples.
10‐126‐18‐2‐A TotalFerrousandTotalDissolvediron
2‐100ugFe/L0.01‐0.500mgFe/L
Dissolvedferricironbysubtraction.2manifoldmethod.Ferrozine.560nm.Requiresaninertprobe.
10‐210‐00‐3‐D TotalPhenolics 1‐100mgphenol/L Inlinemethod,dedicatedchannel.Amino‐antipyrene,500nm
10‐204‐00‐4‐C WADCN 2‐100ugCN/L In‐linedistillation.Pyridinefree.600nm.Lowflowmethod.Requiresin‐linemoduleorheateronadjacentchannelfordistillation
10‐107‐04‐4‐C TotalNitrogen 0.025‐5.0mgN/L Singledigestion(autoclave);TNandTPmeasuredfromasingledigest.Imidazolebuffer.Cadmiumreduction.520nm.
10‐115‐01‐4‐C TotalPhosphorus 0.01‐1.0mgP/L Singledigestion(autoclave);NandPmeasuredfromthesamedigest.Molybdatemethod.880nm.Requiresastandardheater.
10‐109‐12‐3‐A Fluoride 0.1‐5.0mgF/L SPADNS‐2Method.580nm.(SPADNS‐2ispurchasedfromHachCompany).
SoilExtracts12‐107‐06‐2‐H Ammonia 1‐100mgN/L Glycerol/phosphoricacidairmonitoringextracts.
Salicylate.660nm.Requiresastandardheater.12‐206‐00‐1‐A Urea 0.1‐20mgN/L 2MKCl/5mgphenylmercuricacetate.Diacetyl
monoxime/thiosemicarbazidechemistry.530nm.Requiresanon‐standardheater.
12‐115‐01‐1‐Q Phosphorus 0.1‐10mgP/L 0.5Msodiumbicarbonateextracts.Molybdenumchemistry.880nm.Standardheaterrequired.Improvedthroughput,nodiffusionblock.
Industrial18‐107‐06‐5‐B Ammonia‐N 0.25‐20mg/Kg Aciddilutedto4.8%.Gasdiffusionmethod.590nm18‐209‐00‐1‐B HydrogenPeroxide 20‐40% 0.15%RSDmidrange
Chlor‐Alkali25‐226‐36‐1‐G NaOCl 1.6‐75mg/L Iodidemethod.410nm.3‐20%NaOHmatrix.
HighPurityWaters70‐520‐00‐1‐B NaandNH4 0.5‐25ug/L Non‐suppressedconductivity,IonChromatographic
method.NaandNH4onlyOmnion3.0only.
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage5of68
RegulatoryQuickReference TheseQuikChem®methodsareconsideredpermittedreportingoptionsfortheNationalPollutantDischargeElimination(NPDES)and/ortheNationalPrimaryDrinkingWaterRegulations(NPDWR)programsoftheUSEnvironmentalProtectionAgency(USEPA).AlsolistedarethoseQuikChem®methodsthatfollowISOstandards.ThemostrecentMUR(MethodUpdateRule)wassignedbytheAdministratoronApril17,2012andpublishedattheCFRonMay18,2012.TherearesomechangesincludedthathavethepotentialtopositivelyaffectLachatCustomers.
StandardMethods(WhichareLachatMethods)thatwereaddedtoTable1B:Analyte Lachat#* SM#Ammonia 10‐107‐06‐1‐J 4500‐NH3‐H
OrganicNitrogen(KjeldahlNitrogen)
10‐107‐06‐2‐D10‐107‐06‐2‐E
4500NORGD‐1997
Orthophosphorus 10‐115‐01‐1‐A 4500PG1999Totalphosphorus(manualdigest)
10‐115‐01‐1‐E 4500PH1999
Silica 10‐114‐27‐1‐A 4500SiO2F‐1997Sulfate 10‐116‐10‐2‐A 4500SO4G‐1997
(Pleasenotethatallofthesemethods,exceptforMTBsulfate,alreadyhadlettersofacceptance).AlthoughinformationregardingapprovedandacceptedmethodsispublishedintheCFR,statesstillhaveprimacy.Asaresult,itisabsolutelyvitalthatlabsdiscusstheirplanstouseanymethod(includingpromulgated,accepted,equivalent/modifiedmethods)withtheirauditorpriortothemethod’simplementation,tobesuretheproposedchangeormodifiedmethodwillbeaccepted.Bydoingso,thelabwillalsoknowinadvancewhatvalidationwillberequiredintheirspecificcaseforimplementationMethodNumber USEPA
NPDESUSEPANPDWR
USEPAMethod
ISO
Alkalinity10‐303‐31‐1‐A Accepted 10‐303‐31‐1‐D Equivalent 310.2
Chloride10‐117‐07‐1‐A Accepted Accepted 1568210‐117‐07‐1‐B Accepted Accepted 1568210‐117‐07‐1‐C Equivalent USGSI2187‐85 10‐117‐07‐1‐E Equivalent USGSI2187‐85 10‐117‐07‐1‐H Accepted 10‐117‐07‐1‐I Accepted 10‐117‐07‐1‐K Equivalent USGSI2187‐85 80‐117‐07‐1‐A Equivalent USGSI2187‐85
Chromium10‐124‐13‐1‐A Accepted 10‐124‐13‐1‐B
Equivalent SM(20th)3500Cr‐B
USGSI‐2030‐85ASTMD1687‐92,02
10‐141‐13‐2‐A 23913
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage6of68
MethodNumber USEPANPDES
USEPANPDWR
USEPAMethod
ISO
Conductivity10‐302‐00‐1‐A Accepted 10‐302‐00‐1‐B Accepted
Cyanide10‐204‐00‐1‐A Accepted Accepted 10‐204‐00‐1‐B Equivalent 335.4 10‐204‐00‐1‐F Equivalent 335.4 10‐204‐00‐1‐X Approved Approved Promulgated
method
10‐204‐00‐1‐X2 Equivalent Accepted 10‐204‐00‐1‐X 10‐204‐00‐2‐C1 Equivalent Kelada‐01 10‐204‐00‐2‐D1 Equivalent Kelada‐01 10‐204‐00‐2‐E1 Equivalent Kelada‐01 10‐204‐00‐5‐A Equivalent Accepted ASTMMethod
D6888‐04.
10‐204‐00‐2‐H 14403‐110‐204‐00‐5‐C Equivalent ASTMMethod
D7237‐10
10‐204‐00‐5‐D Equivalent ASTMMethodD7511‐09
80‐204‐00‐1‐A Equivalent 335.4 80‐204‐00‐1‐X Equivalent 10‐204‐00‐1‐X
Fluoride10‐109‐12‐2‐A Accepted Accepted 10‐109‐12‐2‐B Equivalent SM(20th)4500F‐B
USGSI‐4327‐85ASTMD1179‐93,99
10‐109‐12‐2‐C Equivalent SM(20th)4500F‐BUSGSI‐4327‐85
ASTMD1179‐93,99
10‐109‐12‐2‐D Equivalent SM(20th)4500F‐BUSGSI‐4327‐85
ASTMD1179‐93,99
Hardness10‐301‐31‐1‐A Accepted 10‐301‐31‐1‐B Accepted 10‐301‐31‐1‐C Equivalent 130.1
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage7of68
MethodNumber USEPANPDES
USEPANPDWR
USEPAMethod
ISO
Nitrogen–Ammonia10‐107‐06‐1‐B Accepted 10‐107‐06‐1‐C Accepted 10‐107‐06‐1‐F Equivalent 350.1 10‐107‐06‐1‐G Equivalent 350.1 10‐107‐06‐1‐I Accepted Accepted 10‐107‐06‐1‐J Accepted Accepted 10‐107‐06‐1‐K Accepted 10‐107‐06‐1‐M Equivalent 350.1 10‐107‐06‐1‐O Equivalent 350.1 10‐107‐06‐1‐X1 Equivalent 350.1 10‐107‐06‐2‐A2 Equivalent 350.1 10‐107‐06‐2‐L2 Equivalent 350.1 10‐107‐06‐2‐O2 Equivalent 350.1 10‐107‐06‐3‐F Equivalent 350.1 10‐107‐06‐5‐B 1173210‐107‐06‐5‐E 1173210‐107‐06‐5‐G 1173210‐107‐06‐5‐H 1173210‐107‐06‐5‐J1,2 Equivalent 350.1 10‐107‐06‐6‐A1,2 Equivalent 350.1 10‐107‐06‐6‐B1 Equivalent 350.1 30‐107‐06‐1‐A Accepted 31‐107‐06‐1‐B Equivalent 350.1 31‐107‐06‐1‐F Equivalent 350.1 31‐107‐06‐1‐G Equivalent 350.1 31‐107‐06‐1‐H Equivalent 350.1 80‐107‐06‐1‐A Equivalent 350.1 80‐107‐06‐1‐B Equivalent 350.1 80‐107‐06‐1‐C Equivalent 350.1
Nitrogen–Kjeldahl
(TKN)
10‐107‐06‐2‐D Accepted 10‐107‐06‐2‐E Accepted 10‐107‐06‐2‐H Equivalent 351.2 10‐107‐06‐2‐I Equivalent 351.2 10‐107‐06‐2‐K Equivalent 351.2 10‐107‐06‐2‐M Equivalent 351.2 10‐107‐06‐2‐N Equivalent 351.2 10‐107‐06‐2‐P Equivalent 351.2 10‐107‐06‐2‐Q Equivalent 351.2 10‐107‐06‐5‐F Equivalent PAIDK03 1173210‐107‐06‐6‐C1 Equivalent 351.2 10‐107‐06‐6‐D1 Equivalent 351.2
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage8of68
MethodNumber USEPANPDES
USEPANPDWR
USEPAMethod
ISO
Nitrogen–Nitrate+Nitrite10‐107‐04‐1‐A Accepted Accepted 10‐107‐04‐1‐B Accepted Accepted 10‐107‐04‐1‐C Accepted Accepted 10‐107‐04‐1‐F Equivalent 353.2 10‐107‐04‐1‐H Equivalent 353.2 10‐107‐04‐1‐J Accepted Accepted 10‐107‐04‐1‐K Accepted Accepted 10‐107‐04‐1‐L Accepted Accepted 10‐107‐04‐1‐O Accepted Accepted 10‐107‐04‐1‐Q Equivalent 353.2 10‐107‐04‐1‐R Equivalent Accepted 353.2 10‐107‐04‐2‐A2 Accepted Accepted 10‐107‐04‐2‐B2 Accepted Accepted 10‐107‐04‐2‐D2 Accepted Accepted 30‐107‐04‐1‐A Accepted 30‐107‐04‐1‐C Equivalent 353.2 31‐107‐04‐1‐A Equivalent 353.4 31‐107‐04‐1‐C Equivalent 353.4 31‐107‐04‐1‐D Equivalent 353.4 31‐107‐04‐1‐E Equivalent 353.4 31‐107‐04‐1‐F Equivalent 353.4 31‐107‐04‐1‐G Equivalent 353.4 31‐107‐04‐1‐H Equivalent 353.4 80‐107‐04‐1‐A Equivalent Accepted 353.2 Nitrogen–Nitrite10‐107‐05‐1‐A Equivalent Accepted 353.2 10‐107‐05‐1‐B Equivalent 353.2 10‐107‐05‐1‐C Equivalent 353.2 10‐107‐05‐1‐O Equivalent 353.2 31‐107‐05‐1‐A Equivalent 353.4 31‐107‐05‐1‐B Equivalent 353.4 80‐107‐05‐1‐A Equivalent Accepted 353.2
Phenol10‐210‐00‐1‐A Accepted 10‐210‐00‐1‐B Accepted 10‐210‐00‐1‐X1 Equivalent 420.1 10‐210‐00‐1‐Y1 Equivalent 420.1 10‐210‐00‐3‐C1 Equivalent 420.4
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage9of68
MethodNumber USEPANPDES
USEPANPDWR
USEPAMethod
ISO
Phosphate,Ortho10‐115‐01‐1‐A Accepted Accepted 10‐115‐01‐1‐B Accepted Accepted 10‐115‐01‐1‐M Accepted Accepted 10‐115‐01‐1‐O Equivalent 365.1 10‐115‐01‐1‐P Accepted Accepted 10‐115‐01‐1‐Q Accepted Accepted 10‐115‐01‐1‐T Accepted Accepted 10‐115‐01‐1‐V Equivalent Accepted 365.1 10‐115‐01‐1‐W Equivalent 365.1 10‐115‐01‐1‐Y Equivalent 365.1 31‐115‐01‐1‐G Equivalent 365.5 31‐115‐01‐1‐H Equivalent 365.5 31‐115‐01‐1‐I Equivalent 365.5 31‐115‐01‐1‐J Equivalent 365.5 31‐115‐01‐1‐W Equivalent 365.5 31‐115‐01‐1‐Y Equivalent 365.5 80‐115‐01‐1‐A Equivalent Accepted 365.1
Phosphate,Total
10‐115‐01‐1‐E Accepted 10‐115‐01‐1‐F Accepted 10‐115‐01‐2‐B Equivalent 365.4 10‐115‐01‐3‐A Equivalent 365.3 10‐115‐01‐3‐B Equivalent 365.3 10‐115‐01‐3‐C Equivalent 365.3 10‐115‐01‐3‐E Equivalent 365.3 10‐115‐01‐3‐F Equivalent 365.3 10‐115‐01‐4‐I Equivalent 365.3 10‐115‐01‐4‐S Equivalent 365.3 10‐115‐01‐4‐U Equivalent 365.3 31‐115‐01‐4‐A Equivalent 365.3
Phosphate,TotalKjeldahl
(TKP)
10‐115‐01‐1‐C Accepted 10‐115‐01‐1‐D Accepted 10‐115‐01‐1‐I Equivalent 365.4 10‐115‐01‐2‐B Equivalent 365.4 10‐115‐01‐2‐C Equivalent 365.4
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage10of68
MethodNumber USEPANPDES
USEPANPDWR
USEPAMethod
ISO
Silicate10‐114‐27‐1‐A Accepted 10‐114‐27‐1‐B Equivalent SM(20th)4500‐SiO2C
USGSI‐2700‐85ASTMD859‐94,00
10‐114‐27‐1‐C Equivalent SM(20th)4500‐SiO2CUSGSI‐2700‐85
ASTMD859‐94,00
31‐114‐27‐1‐A Equivalent 366.0 31‐114‐27‐1‐B Equivalent 366.0 31‐114‐27‐1‐D Equivalent 366.0 31‐114‐27‐1‐E Equivalent 366.0 31‐114‐27‐1‐F Equivalent 366.0
Sodium10‐111‐32‐1‐A Equivalent SM(20th)3500‐Na‐B
Sulfate10‐116‐01‐3‐A Equivalent ASTMD516‐02 10‐116‐10‐2‐A Equivalent 375.2 10‐116‐10‐2‐B Equivalent 375.2 10‐116‐10‐2‐E Equivalent 375.2
Sulfide10‐116‐29‐1‐A Equivalent SM(20th)4500‐S‐D 10‐116‐29‐1‐B Equivalent SM(20th)4500‐S‐D
Surfactants10‐306‐00‐1‐D Equivalent SM(20th)5540‐C
Anions(IonChromatography)10‐510‐00‐1‐A Equivalent Accepted 300.0 10‐510‐00‐1‐E Equivalent Accepted 300.0 10‐511‐00‐1‐A Equivalent Accepted 300.0 10‐540‐00‐1‐C Accepted 1EPAhasrevisedthelanguageat(b)(4)(T)bemorespecificwithrespecttotheuseofgasdiffusionacrossahydrophobicsemi‐permeablemembrane,toseparatetheanalyteofinterestfromthesamplematrixinplaceofmanualorautomateddistillationfortheanalysisofcertainanalytes.Thisisanacceptablechangetoanapprovedmethodforthefollowinganalytes:ammonia,cyanide,TKN,andTotalPhenolics.2Betholot‐basedmethod,usessalicylate.SeeTable1Bat40CFR136
In the list of methods that follows: # designation in the methods list means the method is EPA accepted for NPDWR, NPDES, or both (Check the table above) ^ designation in the methods list means the method is equivalent for NPDES reporting under the MUR.
Ion Chromatography Methods MethodNo Range MDL Matrix,
UnitsComments Rev
DateAnions
10‐136‐09‐1‐B Waters 11‐Aug‐09
Iodide 0.05–5.0 mgI‐/L 10‐510‐00‐1‐A# Watersand
extractsofsoilUSEPAmethod300.0(A);multi‐rangemethod(multiplerangespossiblewithdifferentsampleloops)
29‐Nov‐01
10‐510‐00‐1‐A1Bromide 0.05–5.0 0.018 mgBr‐/L Chloride 0.5–50.0 0.004 mgCl‐/L Fluoride 0.05–5.0 0.004 mgF‐/L Nitrate 0.05–5.0 0.004 mgNO3
‐‐N/L Nitrite 0.05–5.0 0.008 mgNO2
‐‐N/L Phosphorus 0.05–5.0 0.012 mgHPO4
2‐‐P/L Orthophosphate Sulfate 1.0–100 0.012 mgSO4
2‐/L 10‐510‐00‐1‐A2Bromide 0.1–5 mgBr‐/L Chloride 2–100 mgCl‐/L Fluoride 0.2–10 mgF‐/L Nitrate 0.2–10 mgNO3
‐‐N/L Nitrite 0.1–5 mgNO2
‐‐N/L Phosphorus 0.2–10 mgHPO4
2‐‐P/L Orthophosphate Sulfate 4–200 mgSO4
2‐/L 10‐510‐00‐1‐A3Bromide 0.025–2.5 0.005 mgBr‐/L Chloride 0.25–25 0.012 mgCl‐/L Fluoride 0.025–2.5 0.004 mgF‐/L Nitrate 0.025–2.5 0.002 mgNO3
‐‐N/L Nitrite 0.025–2.5 0.005 mgNO2
‐‐N/L Phosphorus 0.025–2.5 0.003 mgHPO4
2‐‐P/L Orthophosphate Sulfate 0.5–50 0.003 mgSO4
2‐/L
10‐510‐00‐1‐A4
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage12of68
Bromide 0.16–3.0 0.02 mgBr‐/L Chloride 32–600 mgCl‐/L Fluoride 0.04–0.75 0.008 mgF‐/L Nitrate 0.04–0.75 0.005 mgNO3
‐‐N/L Nitrite 0.04–0.75 0.02 mgNO2
‐‐N/L Phosphorus 0.10–
1.8750.02 mgHPO4
2‐‐P/L Orthophosphate
Sulfate 32–600 mgSO42‐/L
10‐510‐00‐1‐C Waters CommonInorganicAnions 8‐Sep‐03
Bromide 0.06–6.0 0.02 mgBr‐/L Chloride 0.6–60 0.005 mgCl‐/L Fluoride 0.04–4.0 0.006 mgF‐/L Nitrate 0.06–6.0 0.007 mgNO3
‐‐N/L Nitrite 0.016–1.6 0.002 mgNO2
‐‐N/L Phosphorus 0.06–6.0 0.015 mgHPO4
2‐‐P/L Orthophosphate Sulfate 2.0–200 0.03 mgSO4
2‐/L 10‐510‐00‐1‐D Waters 9‐Sep‐03
Bromide 40–400 µgBr‐/L Nitrate 20–200 µgNO3
‐‐N/L Nitrite 20–200 µgNO2
‐‐N/L 10‐510‐00‐1‐E^# Waters Rapidanionsmethod;
Omnion3.0only;multi‐rangemethod(multiplerangespossiblewithdifferentsampleloops)
29‐Oct‐08
10‐510‐00‐1‐E1Bromide 0.05–5.0 0.016 mgBr‐/L Chloride 0.5–50 0.029 mgCl‐/L Fluoride 0.05–5.0 0.004 mgF‐/L Nitrate 0.05–5.0 0.008 mgNO3
‐‐N/L Nitrite 0.05–5.0 0.033 mgNO2
‐‐N/L Phosphorus 0.05–5.0 0.015 mgHPO4
2‐‐P/L Orthophosphate Sulfate 1.0–100 0.02 mgSO4
2‐/L 10‐510‐00‐1‐E2Bromide 0.025–2.5 0.015 mgBr‐/L Chloride 0.015–2.5 0.006 mgCl‐/L Fluoride 0.025–2.5 0.003 mgF‐/L Nitrate 0.025–2.5 0.0048 mgNO3
‐‐N/L Nitrite 0.025–2.5 0.0048 mgNO2
‐‐N/L Phosphorus 0.025–2.5 0.0098 mgHPO4
2‐‐P/L Orthophosphate Sulfate 0.5–50 0.02 mgSO4
2‐/L
10‐510‐00‐1‐E3
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage13of68
Bromide 0.1–5 0.038 mgBr‐/L Chloride 2–100 0.016 mgCl‐/L Fluoride 0.2–10 0.016 mgF‐/L Nitrate 0.2–10 0.029 mgNO3
‐‐N/L Nitrite 0.1–5.0 0.01 mgNO2
‐‐N/L Phosphorus 0.2–10 0.034 mgHPO4
2‐‐P/L Orthophosphate Sulfate 4–200 0.144 mgSO4
2‐/L 10‐510‐00‐1‐F Waters Anionsmethod;High
Conductancesamples(3µS/cm)Omnion3.0
23‐Aug‐10
Bromide 0.2to4.0 0.021 mgBr‐/L Chloride 50‐1000 0.0102 mgCl‐/L Fluoride 0.1to2.0 0.0075 mgF‐/L Nitrate 0.2to5.0 0.0115 mgNO3
‐‐N/L Nitrite 0.1‐2.0 0.0075 mgNO2
‐‐N/L Phosphorus 0.2to4.0 0.025 mgHPO4
2‐‐P/L OrthophosphateSulfate 50to1000 0.144 mgSO4
2‐/L 10‐511‐00‐1‐A# Waters Rapidanionsmethod;multi‐
rangemethod(multiplerangespossiblewithdifferentsampleloops)
16‐Sep‐03
10‐511‐00‐1‐A1Chloride 1.0–100 0.004 mgCl‐/L Nitrate 0.2–20.0 0.003 mgNO3
‐‐N/L Phosphorus 0.05–5.0 0.006 mgHPO4
2‐‐P/L Orthophosphate Sulfate 1.0–100 0.014 mgSO4
2‐/L 10‐511‐00‐1‐A2Chloride 1.5–150 0.01 mgCl‐/L Nitrate 0.25–25 0.005 mgNO3
‐‐N/L Phosphorus 0.1–10 0.016 mgHPO4
2‐‐P/L Orthophosphate Sulfate 2.5–250 0.04 mgSO4
2‐/L
10‐510‐13‐1‐B Waters USEPAmethod218.6;(modified)Omnion3.0only
24‐Nov‐08
Cr(VI) 0.05‐10 0.02 µg CrO4‐ ICwithPostcolumn
derivatization;2cmflowcell;QC8500ONLY.
10‐540‐00‐1‐C# Waters USEPAmethod300.1;
determinationofdisinfectionbyproducts;Omnion3.0only
24‐Nov‐08
Bromate 5–50 1.15 µg BrO3‐/L
Bromide 10–100 2.01 µg Br‐/L Chlorate 20–200 5.00 µg ClO3
‐/L Chlorite 5–50 2.61 µg ClO2
‐/L 21‐510‐00‐1‐A Beverages Omnion3.0only 11‐Nov‐08
Chloride 1–50 0.045 mgCl‐/L
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage14of68
Fluoride 0.2–10 0.037 mgF‐/L Nitrate 0.2–10 0.021 mgNO3
‐‐N/L Phosphorus 4–200 0.062 mgHPO4
2‐‐P/L Orthophosphate Sulfate 4–200 0.102 mgSO4
2‐/L 70‐510‐00‐1‐A Highpuritywaters 9‐Sep‐03
Chloride 0.5–10 µgCl‐/L Nitrate 0.5–10 µgNO3
‐‐N/L Phosphorus 1.0–20 µgHPO4
2‐‐P/L Orthophosphate Sulfate 1.0–20 µgSO4
2‐/L 70‐510‐00‐1‐B Highpuritywaters 9‐Sep‐03
Bromide 2.0–20.0 µg Br‐/L Chloride 1.0–10.0 µg Cl‐/L Fluoride 1.0–10.0 µg F‐/L Nitrate 1.0–10.0 µg NO3
‐‐N/L Nitrite 1.0–10.0 µg NO2
‐‐N/L Phosphorus 3.0–30.0 µg HPO4
2‐‐P/L Orthophosphate Sulfate 1.5–15.0 µg SO4
2‐/L 70‐510‐00‐1‐C HighPurity
Waters 17‐Dec‐08
Bromide 2.0–40.0 0.67 µg Br‐/L Chloride 1.0–20.0 0.22 µg Cl‐/L Fluoride 1.0–20.0 0.39 µg F‐/L Nitrate 1.0–20.0 0.20 µg NO3
‐‐N/L Nitrite 1.0–20.0 0.40 µg NO2
‐‐N/L Phosphorus 3.0–60.0 0.60 µg HPO4
2‐‐P/L Orthophosphate Sulfate 1.5–30.0 0.45 µg SO4
2‐/L
Cations10‐520‐00‐1‐D Waters Omnion3.0only;multi‐
rangemethod(multiple17‐Feb‐09
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage15of68
rangespossiblewithdifferentsampleloops)
10‐520‐00‐1‐D1Ammonium 0.8–32 0.16 mgNH4
+/L Calcium 1.6–64 0.60 mgCa2+/L Lithium 0.25–10 0.05 mgLi+/L Magnesium 0.8–32 0.16 mgMg2+/L Potassium 1.6–64 0.32 mgK+/L Sodium 1.8–72 0.36 mgNa+/L 10‐520‐00‐1‐D2Ammonium 0.20–4.0 0.04 mgNH4
+/L Calcium 0.25–5.0 0.053 mgCa2+/L Lithium 0.05–1.0 0.58 mgLi+/L Magnesium 0.25–5.0 0.05 mgMg2+/L Potassium 0.20–4.0 0.04 mgK+/L Sodium 0.20–4.0 0.04 mgNa+/L 10‐520‐00‐1‐D3Ammonium 0.005–
0.2500.00349 mgNH4
+/L
Calcium 0.025–1.250
0.00744 mgCa2+/L
Lithium 0.008–0.4 0.00058 mgLi+/L Magnesium 0.012–0.6 0.0026 mgMg2+/L Potassium 0.020–1.0 0.00574 mgK+/L Sodium 0.010–0.5 0.00144 mgNa+/L 10‐520‐00‐1‐E Waters Omnion3.0only;High
Conductancesamples(3µS/cm)
1‐Sep‐10
Ammonium 1.0to20 0.14 mgNH4
+/L Calcium 5.0to100 1.14 mgCa2+/L Lithium 0.5to10 0.06 mgLi+/L Magnesium 5.0to100 1.47 mgMg2+/L Potassium 5.0to100 1.08 mgK+/L Sodium 5.0to100 0.10 mgNa+/L 70‐520‐00‐1‐B Waters Omnion3.0only;High
PurityWaters20‐Feb‐13
AmmoniumSodium
0.5‐250.5‐25
0.090.11
µgNa+/LµgNH4
+/L
Runtime9minutes,forsodiumandammoniumONLY.RuntimerequiresextensionforanalysisofadditionalCations.
OrganicAcids21‐550‐00‐1‐B Beverages Omnion3.0only 31‐Jan‐09
AceticAcid 3–300 1.16 mg/L
NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage16of68
AdipicAcid 4.5–450 3.34 mg/L CitricAcid 3–300 0.45 mg/L FormicAcid 3–300 0.50 mg/L FumaricAcid 3–300 0.45 mg/L LacticAcid 3–300 0.90 mg/L MalicAcid 3–300 0.60 mg/L MalonicAcid 3–300 1.07 mg/L OxalicAcid 3–300 0.71 mg/L SuccinicAcid 3–300 0.77 mg/L TartaricAcid 3–300 0.92 mg/L
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage17of68
FlowInjectionAnalysisAcidity10‐305‐31‐1‐A 30–500 4.0 mgCaCO3/L Waters Thymolbluemethod.600nm 3‐Sep‐0310‐305‐31‐1‐B 1.0–30.0 0.19 mgCaCO3/L Waters Thymolbluemethod.600nm 3‐Sep‐03
Alkalinity10‐303‐31‐1‐A# 10–500 2.3 mgCaCO3/L Waters Methylorangemethod;TotalAlkalinity.550
nm,NPDESAccepted.23‐Jan‐01
10‐303‐31‐1‐D^ 1–50 0.27 mgCaCO3/L Waters Methylorangemethod;TotalAlkalinity,550nm.NPDESEquivalent(310.2).
3‐Sep‐03
10‐303‐31‐2‐B 10–200 3.0 mgCaCO3/L Waters Phenolphthaleinmethod.p‐alkalinity,520nm 3‐Sep‐0310‐303‐31‐3‐A* 50–400 2.7 mgCaCO3/L Waters Bromocresolgreenmethod.TotalAlkalinity,640
nm3‐Sep‐03
10‐303‐31‐4‐A 50–500 1.1 mgCaCO3/L Waters Bromocresolgreen/methylredmethod;TotalAlkalinity,low‐flowmethod.640nm
3‐Sep‐03
Aluminum10‐113‐33‐1‐B 0.1 –5.0 0.02 mgAl/L Waters Totalreactive(monomeric)Al;pyrocatechol
violet;determinationin0.15%HNO3matrix.580nm.InertProberequired
27‐Aug‐03
10‐113‐33‐1‐C 10–300 1.0 µg Al/L Waters TotalReactive(monomeric)Al;pyrocatecholviolet;DiluteHNO3preservationrequired.580nm.InertProberequired.
14‐Apr‐08
10‐113‐34‐1‐B 0.01 –0.3 0.0015 mgAl/L Waters Non‐exchangeable(organicallycomplexed)Al.pyrocatecholviolet;DiluteHNO3preservationrequired.580nm.InertProberequired
27‐Aug‐03
12‐113‐33‐1‐B 1.0–30 0.1 mgAl/L Soilextracts Totalreactive(monomeric)Al;pyrocatecholviolet;Determinationin1MKClextracts.580nm.InertProberequired
3‐Sep‐03
13‐113‐33‐1‐B 0.8–4.0 0.05 mgAl/L Plantextracts Totalreactive(monomeric)Al.Low‐flowmethod.1MHClfinalmatrix.580nmInertProberequired
3‐Sep‐03
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage18of68
AminoAcids18‐218‐00‐1‐A 1.25–40 0.22 mMLeucine Aqueous
formulationsNinhydrin.Determinationinrumenfluid.580nm.Requiresanon‐standardheater.
3‐Sep‐03
Ammonia SeealsoICsection10‐107‐06‐1‐B#* 0.05–5.0 0.007 mgN/LasNH3 Waters Alkalinephenol‐basedmethod;determinationin
0.2%H2SO4preservedsamples;630nm.Requiresastandardheater.NPDESAccepted
27‐Aug‐01
10‐107‐06‐1‐C# 0.01–4.0 0.004 mgN/LasNH3 Waters Alkalinephenol‐basedmethod;630nm.determinationinnon‐preservedsamples;RequiresastandardheaterNPDESAccepted
2‐Nov‐01
10‐107‐06‐1‐F^ 10to100 1.0 µg N/L as NH3 Waters Alkalinephenol‐basedmethod;630nm.low‐flowmethod,preservedsamples;RequiresastandardheaterNPDESEquivalent(350.1)
25‐Aug‐03
10‐107‐06‐1‐G^ 10–500 0.00153 µg N/L as NH3 Waters Alkalinephenol‐basedmethod;630nm.Preservedsamples.UltraHighThroughputmethod(>100samples/hr);Requiresastandardheater.NPDESEquivalent(350.1)
14‐Dec‐07
10‐107‐06‐1‐I# 0.1 –30.0 0.01 mgN/LasNH3 Waters Alkalinephenol‐basedmethod;630nm.Non‐preservedsamples.RequiresastandardheaterNPDES/NPDWRAccepted
15‐Mar‐01
10‐107‐06‐1‐J# 0.01–2.0 0.002 mgN/LasNH3 Waters Alkalinephenol‐basedmethod;630nm.Low‐flowmethod;determinationinpreservedandnon‐preservedsamples;RequiresastandardheaterNPDES/NPDWRAccepted
29‐Nov‐07
10‐107‐06‐1‐K# 0.2–20.0 0.01 mgN/LasNH3 Waters Alkalinephenol‐basedmethod;630nm.Requiresastandardheater.Low‐flowmethod;NPDESAccepted
15‐Mar‐01
10‐107‐06‐1‐L 0.01 –2.0 0.0028 mgN/LasNH3 Waters Alkalinephenol‐basedmethod;630nm.Usew/10‐245‐00‐1‐AformonochloramineNon‐preservedsamples.Requiresastandardheater
6‐Nov‐07
10‐107‐06‐1‐M^ 0.01–2.0 0.002 mgN/LasNH3 Waters Alkalinephenol‐basedmethod; 9‐Nov‐07 0.2–20.0 0.011 determinationinacidpreservedornon‐acid
preservedsamples;multi‐rangemethod;630nm.RequiresastandardheaterNPDESEquivalent(350.1)
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage19of68
10‐107‐06‐1‐O^ 0.002–0.500 0.56 µg N/L as NH3 Waters Alkalinephenol‐basedmethod;multi‐range 22‐Feb‐08 0.25–10 mgN/LasNH3 method;630nm.Preservedsamples.Requiresa
standardheaterNPDESEquivalent(350.1)
10‐107‐06‐1‐Q^ 0.005‐2.00.25‐20.0
0.00220.0038
mgN/LasNH3 Waters Alkalinephenol‐basedmethod,citratebuffer;multi‐rangemethod;630nm.Non‐preservedsamples.RequiresastandardheaterNPDESEquivalent(349.0)
17‐Aug‐10
10‐107‐06‐1‐X^ 0.05–20.0 0.007 mgN/LasNH3 Waters MicroDistmethod;requiresMicroDistblockandtubes.Preservedorun‐preservedsamples.Alkalinephenoldetermination.630nm.RequiresastandardheaterNPDESEquivalent(350.1)
17‐Sep‐09
10‐107‐06‐2‐A*^ 0.10–5.0 0.005 mgN/LasNH3 Waters Sodiumsalicylate‐basedmethod;660nm.RequiresastandardheaterNPDESEquivalent(350.1)
25‐Mar‐08
10‐107‐06‐2‐L*^ 0.05–20 0.01 mgN/LasNH3 Waters Sodiumsalicylate‐basedmethod;660nmUltraHighThroughputmethod(>120samples/hr);RequiresastandardheaterNPDESEquivalent(350.1)
16‐Aug‐07
10‐107‐06‐2‐O^ 10–500 1.1 µg N/L as NH3 Waters Sodiumsalicylate‐basedmethod;660nm.Requiresastandardheatermulti‐range
7‐Dec‐07
0.25–30 0.011 mgNasNH3 method;NPDESEquivalent(350.1) 10‐107‐06‐2‐R 0.02–5.00 0.004 mgN/LasNH3 Waters Sodiumsalicylate‐basedmethod;Determinationin
10mMH3PO4matrix660nm.Requiresastandardheater.
18‐Dec‐09
10‐107‐06‐3‐B 0.05–1.0 0.008 mgN/LasNH3 Waters Sodiumsalicylate‐basedmethod;UsesDClCinsteadofNaOCl660nm.Requiresastandardheater.
26‐Aug‐03
10‐107‐06‐3‐D 0.005–0.25 0.001 mgN/LasNH3 Waters Sodiumsalicylate‐basedmethod;usesDClCinsteadofNaOCl660nm.Requiresastandardheater
26‐Aug‐03
10‐107‐06‐3‐F^ 1.25–100 0.41 µg N/L as NH3 Waters Alkalinephenol‐basedmethod;630nm.Requiresanon‐standardheaterusesDClC;2‐cmdetectormethod;forQC8500only;NPDESEquivalent(350.1)
17‐Feb‐09
10‐107‐06‐4‐D 0.5–80.0 0.10 mgN/LasNH3 Waters Sodiumsalicylate‐basedmethod;660nm.Requiresastandardheater.Dialysismethod
13‐Nov‐08
10‐107‐06‐5‐B 0.10–1.0 0.01 mgN/LasNH3 Waters Gasdiffusionmethod;low‐flowmethod;ISO(11732)590nm
19‐Mar‐04
10‐107‐06‐5‐E 0.1–10.0 0.02 mgN/LasNH3 Waters Gasdiffusionmethod;ISO(11732)590nm 18‐Mar‐04
10‐107‐06‐5‐G 0.1–0.9 0.005 mgN/LasNH3 Waters Gasdiffusionmethod;ISO(11732)590nm 08‐Sep‐0310‐107‐06‐5‐H 10–90 1.5 µg N/L as NH3 Waters Gasdiffusionmethod;low‐flowmethod;ISO(11732)
590nm23‐Mar‐04
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage20of68
10‐107‐06‐5‐I 0.1‐4.0 0.004 mgN/LasNH3 Waters Gasdiffusionmethod;low‐flowmethod;ISO(11732)590nm
15‐Oct‐10
10‐107‐06‐5‐J
0.01‐1.00.1‐20
0.0020.02
MgN/LasNH3 Waters GasDiffusionmethod.Salicylate/DCIC.MaybeusedforTKN.aswellasbrackish/salinesamples660nm.Requiresastandardheater.
26‐Sept‐12
10‐107‐06‐6‐A^ 0.25–20 0.13 mgN/LasNH3 Waters Sodiumsalicylate‐basedmethod;660nm.inlinedistillationmethod;Requiresastandardheaterandin‐linemodulefordistillationstep.Samplesw/particulatesnotsuitable.NPDESEquivalent(350.1);
24‐Jul‐08
10‐107‐06‐6‐B^ 0.25–10 0.066 mgN/LasNH3 Waters Alkalinephenol‐basedmethod;630nm.inlinedistillationmethod;low‐flowmethod;Requiresastandardheaterandanin‐linemoduleforthedistillation.Samplesw/particulatesnotsuitable.NPDESEquivalent(350.1);
29‐Jul‐08
10‐107‐06‐6‐E^ 10‐250 5(pres.)1(un‐pres.)
µg N/L as NH3 Waters Alkalinephenol‐basedmethod;630nminlinedistillationmethod;Requiresastandardheaterandanin‐linemoduleforthedistillation.Low‐flowmethod;samplesw/particulatesnotsuitableNPDESEquivalent(350.1);
15‐Apr‐11
12‐107‐06‐1‐A 0.01–1.0 0.002 mgN/LasNH3 Soilextracts Alkalinephenol‐basedmethod;Determinationin2MKClsoilextracts630nm.Requiresastandardheater.
17‐Sep‐08
12‐107‐06‐1‐B 1.0–20.0 0.035 mgN/LasNH3 Soilextracts Alkalinephenol‐basedmethod;Determinationin2MKClsoilextracts630nm.Requiresastandardheater.
15‐Sep‐08
12‐107‐06‐2‐A 0.10–20.0 0.035 mgN/LasNH3 Soilextracts Sodiumsalicylate‐basedmethod;Determinationin2MKClsoilextracts660nm.Requiresastandardheater.
3‐Sep‐03
12‐107‐06‐2‐E 0.05–10.0 0.016 mgN/LasNH3 Soilextracts Sodiumsalicylate‐basedmethod;Determinationin0.5MK2SO4soilextracts660nm.Requiresastandardheater.
3‐Sep‐03
12‐107‐06‐2‐F 0.1–20 0.026 mgN/LasNH3 Soilextracts Sodiumsalicylate‐basedmethod;Determinationin2MKClsoilextracts;UltraHighThroughputmethod(>120samples/hr)660nm.Requiresastandardheater.
15‐Aug‐07
NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage21of68
12‐107‐06‐2‐G 25‐500 4.32 µg N/L as NH3 Soilextracts Sodiumsalicylate‐basedmethod;660nm.Requiresastandardheater.Determinationin2MKClsoilextracts
12‐May‐10
12‐107‐06‐2‐H 1‐100 0.06 mgN/LasNH3 Airmonitoring(abovesoil)extracts
Sodiumalicylate.0.029Mglycerol/0.18MH3PO4matrix.660nm.Requiresastandardheater.
18‐Mar‐13
12‐107‐06‐3‐A 2.0–40.0 0.11 mgN/LasNH3 Soilextracts Sodiumsalicylate‐basedmethod;Determinationin0.0125MCaCl2soilextracts660nm.Requiresastandardheater.
3‐Sep‐03
12‐107‐06‐3‐B 0.2–4.0 0.01 mgN/LasNH3 Soilextracts Sodiumsalicylate‐basedmethod;2MKClsoilextracts.660nm.Requiresastandardheater.
3‐Sep‐03
12‐107‐06‐3‐C 0.2–4.0 0.03 mgN/LasNH3 Soilextracts Sodiumsalicylate‐basedmethod;Determinationin0.0125MCaCl2soilextracts660nm.Requiresastandardheater.
3‐Sep‐03
12‐107‐06‐5‐A 0.1–20.0 0.02 mgN/LasNH3 Soilextracts Gasdiffusionmethod;2MKClsoilextracts590nm. 23‐Feb‐1014‐107‐06‐1‐A 1.75–7.0 %N/LasNH3 Fertilizers Alkalinephenol‐basedmethod.Liquidfertilizers.
630nm.Requiresastandardheater3‐Sep‐03
14‐107‐06‐1‐B 5.0–180 0.5 mgN/LasNH3 Fertilizers Alkalinephenol‐basedmethod.HCldigestofsolidfertilizers.630nm.Requiresastandardheaterandinertprobe.
3‐Sep‐03
14‐107‐06‐1‐C 60–600 1.33 mgN/LasNH4 Fertilizers Salicylate/DCICbasedmethod.660nm.Requiresastandardheater.
21‐Aug‐03
14‐107‐06‐1‐D 1.5–150 0.05 mgN/LasNH4 Fertilizers Salicylate/DCICbasedmethod.660nm.Requiresastandardheater.
14‐Nov‐01
14‐107‐06‐2‐B 400–800 mgN/LasNH4 Fertilizers Sodiumsalicylate‐basedmethod.660nm.RequiresastandardheaterandInternalSampleLoopValve.
3‐Sep‐03
14‐107‐06‐2‐C 75–600 1.0 mgN/LasNH4 Fertilizers Sodiumsalicylate‐basedmethod.660nm.Intendedforusewithmethodnumber14‐206‐00‐4‐A,ureainfertilizers, but may be used alone. Requires astandardheaterand1mmpathlengthflowcell.
3‐Sep‐09
18‐107‐06‐1‐A 1.75–140 0.08 mgN/LasNH3 Aqueousformulations
Alkalinephenol‐basedmethod;0.10MHClandRumenfluid.630nm.Requiresastandardheater.
10‐Aug‐09
18‐107‐06‐5‐A 0.1–10 0.025 mgN/LasNH3 Aqueousformulations
Gasdiffusionmethod;Determinationofammoniainnitricacid(dilutedto1.59M)590nm.
10‐Sep‐09
18‐107‐06‐5‐B 0.25‐20 0.07 mg/kgH2SO4 Sulfuricacid Gasdiffusionmethod;Determinationofammoniainsulfuricacid,dilutedto4.8%590nm.
16‐May‐2013
NEW
NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage22of68
23‐107‐06‐3‐A 10–1000 mgN/LasNH3 Bioreactorsolutions
Sodiumsalicylate/DCICmethod;Determinationinfermentationbeers660nm.RequiresastandardheaterandInternalSampleLoopValve.
3‐Sep‐03
24‐107‐06‐5‐A 2.0–500.05–1.0
0.020.003
mgN/LasNH3 Airsamplefilterextracts
Gasdiffusionmethod;determinationin0.02Mcitricacidextracts;multi‐rangemethod.590nm
15‐Dec‐09
26‐107‐06‐4‐A 10–50.0 0.151 mgN/LasNH3 Tobaccoextracts
Sodiumsalicylate/DCICmethod;0.005MH2SO4matrix.660nm;dialysismethod;Requiresastandardheater.
3‐Sep‐03
30‐107‐06‐1‐A# 0.1 –20.00.007‐1.43
mgN/LasNH3
mMN/LasNH3
Brackish/Seawaters
Alkalinephenol‐basedmethod;Macrodistillationmethod;630nm.Requiresastandardheater.NPDESAccepted(350.1)
14‐Nov‐01
31‐107‐06‐1‐B^ 5–6000.36‐42.86
0.7 µg N/L as NH3
µM N/L as NH3
Brackish/Seawaters
Alkalinephenol‐basedmethod;Canbeusedfordeterminationofsamplesw/0to35pptsalinity;630nm.Requiresastandardheater.NPDESEquivalent(350.1)
18‐Sep‐08
31‐107‐06‐1‐F^ 0.005–2.00.36‐142.86
0.002 mgN/LasNH3
µM N/L as NH3
Brackish/Seawaters
Alkalinephenol‐basedmethod;630nm.Canbeusedfordeterminationofsamplesw/0to35pptsalinity;Requiresastandardheater.NPDESEquivalent(350.1)
12‐Nov‐07
31‐107‐06‐1‐G^ 1.25–1000.089‐7.143
0.41 µg N/L as NH3
µM N/L as NH3
Brackish/Seawaters
Alkalinephenol‐basedmethod;DCIC.630nm2‐cmdetectormethod;QC8500only;Canusedfordeterminationofsamplesw/0to35pptsalinity;Requiresanon‐standardheater.NPDESEquivalent(350.1)
26‐Jan‐10
31‐107‐06‐1‐H^ 0.25–30.00.018‐2.143
0.025 mgN/LasNH3
mMN/LasNH3
Brackish/Seawaters
Alkalinephenol‐basedmethod;630nm.highrangemethod;Canusedfordeterminationofsamplesw/0to35pptsalinity;Ultra‐HighThroughputmethod(>120samples/hr)Requiresastandardheater.
31‐Oct‐08
31‐107‐06‐1‐I 5‐5000.3571‐35.71
0.47 µg N/L as NH3
µM N/L as NH3
Brackish/Seawaters
Alkalinephenol‐basedmethod,citrate/tartratebuffer.630nm,Requiresastandardheater.
21‐Feb‐12
31‐107‐06‐1‐Q^ 0.005‐2.00.36‐142.86
0.0022 mgN/LasNH3
µM N/L as NH3
Brackish/Seawaters
Alkalinephenol‐basedmethod,citratebuffer.630nm,Requiresastandardheater.NPDESEquivalentto349.0
17‐Aug‐10
31‐107‐06‐4‐A5 1.0–30.00.071‐2.143
0.1 µg N/L as NH3µM N/L as NH3
Brackish/Seawaters
Fluorescencemethod;OPA.QC8500onlyFluorescencedetectormustbepurchasedseparatelyAlsorequiresastandardheater,Direct
22‐May‐07
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage23of68
VoltageModule,andcable.31‐107‐06‐5‐A 35–140
2.5‐10.08.54 µg N/L as NH3
µM N/L as NH3
Brackish/Seawaters
Gasdiffusionmethod;contactSales(specialcarerequired).PhenolRed,570nm.
12‐Apr‐01
80‐107‐06‐1‐A^ 0.25–200.1 –5.0
0.01‐1.0
0.050.0150.0027
mgN/LasNH3 Waters Alkalinephenol‐basedmethod;UltraLowFlowmethod(mustberunaloneorwithotherULFmethods,);630nm.NPDESEquivalent(350.1);multi‐rangemethod;non‐preservedsamples.Requiresastandardheater.
31‐Jul‐09
80‐107‐06‐1‐B^ 0.1–5.0 0.005 mgN/LasNH3 Waters Alkalinephenol‐basedmethod;630nm.Requiresastandardheater.
11‐Aug‐09
0.25–20 0.05 Preservedsamples;NPDESEquivalent(350.1);multi‐rangemethod
80‐107‐06‐1‐C^ 0.01–1.0 0.05 mgN/LasNH3 Waters Alkalinephenol‐basedmethod;UltraLowFlowmethod(mustberunaloneorwithotherULFmethods);preservedsamples,630nm.Requiresastandardheater.NPDESEquivalent(350.1)
11‐Aug‐09
90‐107‐06‐3‐A 0.1‐6.0 0.02‐0.06
mgN/LasNH3 Water/Soils MultiplematrixMethod.Water,2MKCl,0.5MK2SO4,0.01CaCl2.Salicylate/DCIC.UltraHighThroughputmethod.120samplesperhour.660nm.Requiresastandardheater
08‐Feb‐11
Amylose20‐244‐00‐1‐A 1–500 0.044 mgAmylose/L Foodstuffs Iodine/aceticacid. 600nm.Determinationin0.1
NNaOH/ETOHdigestsofrice;low‐flowmethod.20‐Jul‐07
Boron10‐105‐08‐1‐B 0.5–10.0 0.02 mgB/L Waters Azomethine‐Hmethod.430nm 22‐Aug‐0313‐105‐08‐1‐D 2.0–10.0 0.04 mgB/L Plant
extractsAzomethine‐Hmethod.430nmDeterminationin4%HClmatrix(followingashingofsamples).
3‐Sep‐03
13‐105‐08‐1‐E 1.0–4.0 0.10 mgB/L Plantextracts
Azomethine‐Hmethod.430nmDeterminationin1MHClmatrix;low‐flowmethod.
3‐Sep‐03
31‐105‐08‐1‐A 0.1 –5.09.25‐462.53
0.047 mgB/LµMB/L
Brackish/Seawaters
Azomethine‐Hmethod.430nmDeterminationin0to35pptsalinitysamples.Requiresanon‐standardheater.
3‐Apr‐08
70‐105‐08‐2‐A 0.25–10.0 0.035 µg BL Highpuritywaters
Fluorescencemethod,chromotropicacid.Detectormustbepurchasedseparately.Also
3‐Sep‐03
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage24of68
requiresastandardheater,directvoltagemodule,andcable.
Bromide SeealsoICsection10‐135‐21‐2‐B 0.5–10 0.075 mgBr‐/L Waters Phenolredmethod.590nm. 3‐Sep‐0318‐135‐21‐2‐B 0.5–10 0.05 mgBr‐/L Aqueous
formulationsPhenolRedmethod.590nm.Determinationin0to30%w/vNaClsolutions
3‐Sep‐03
30‐135‐21‐1‐A 0.5–10.00.0063‐0.1252
0.005
mgBr‐/LmMBr‐/L
Brackish/Seawaters
PhenolRedmethod.590nm.Low‐flowmethod;followsStandardMethods(4500‐Br‐D)
3‐Sep‐03
30‐135‐21‐1‐B 5.0–60.00.0625‐0.751
0.22 mgBr‐/LmMBr‐/L
Brackish/Seawaters
PhenolRedmethod.590nm.FollowsStandardMethods(4500‐Br‐D)590nm.
3‐Sep‐03
Calcium SeealsoICsectionandHardness10‐120‐02‐1‐B 0.5–50.0 0.07 mgCa/L Waters o‐cresolphthaleincomplexone600nm. 24‐Jul‐0810‐120‐02‐1‐C 20–500 1.1 mgCa/L Waters o‐cresolphthaleincomplexone600nm 6‐Jul‐09 5–125 0.2 Multi‐rangemethod 12‐120‐02‐2‐B 0.25‐50
10‐10000.050.7
mgCa/L Soilextracts 1Mammoniumacetateextracts.600nm.o‐cresolphthaleincomplexoneMulti‐rangemethod.
16‐May‐2012
14‐120‐02‐1‐B 5–120 0.5 mgCa/L Fertilizers DeterminationinHCldigests(0.48Mindigestate)o‐cresolphthaleincomplexone.600nm.
4‐Sep‐03
14‐120‐02‐1‐C 750–2000 mgCa/L Fertilizers 6%v/vHClindigestate.o‐cresolphthaleincomplexone600nm.Requiresaninternalsampleloopvalve.
4‐Sep‐03
Carbon(TotalDissolved) 12‐140‐39‐5‐A 5‐400 0.7 mgC/L SoilExtracts 0.5MK2SO4.Phenolredmethod;440nm.
CanmeasureTNfromthesamedigestusingmethod12‐107‐04‐3‐C.Requiresanin‐linedigestionmodule(Onlyonemoduleisneededforoneorbothmethods).
19‐Dec‐11
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage25of68
Chlorate SeealsoICsection25‐224‐35‐1‐D 0.1‐2.0 0.005 mgNaClO3/L Chlor‐Alkali Ferrozine.Determinationin50‐200g
NaOH/L.500nm.Requiresastandardheater.
4‐Sep‐03
25‐224‐35‐1‐E 0.5–10 mgNaClO3/L Chlor‐Alkali Determinationinmembranecellliquors;29to34%NaOHmatrix;ferrozinemethod500nm.Requiresastandardheater.
4‐Sep‐03
25‐224‐35‐1‐F 1.0–20 mgNaClO3/kg Chlor‐Alkali Determinationinmembranecellliquors;6to36%NaOHand1to6%NaClmatrix;ferrozinemethod500nm.Requiresastandardheater.
4‐Sep‐03
25‐224‐35‐1‐G 0.1–2.0 0.005 gNaClO3/L Chlor‐Alkali Determinationindiaphragmcellliquors;50to200gNaOH/Lmatrix;ferrozinemethod.500nm.Requiresastandardheater.
4‐Sep‐03
25‐224‐35‐1‐H 0.25–3.0 0.005 mgNaClO3/L Chlor‐Alkali 135to275gNaCl/Lsamplematrix(noNaOHinmatrix);ferrozinemethod;500nm.selectiveagainsthypochlorite.Requiresastandardheater.
4‐Sep‐03
25‐224‐35‐1‐I 10–50 0.597 gNaClO3/L Chlor‐Alkali 100to300gNaCl/Lsamplematrix(noNaOHinmatrix)ferrozinemethod.500nm.Requiresastandardheater.
11‐Sep‐08
25‐224‐35‐1‐J 5–60 0.4 mgNaClO3/L Chlor‐Alkali 250to500gNaOH/L(25‐50%)samplematrix.500nm.Requiresastandardheater.
17‐Sep‐08
25‐224‐35‐1‐K 0.25‐3.0 0.012 gNaClO3/L Chlor‐Alkali 135to275gNaCl/LMatrix,NoNaOH.500nm.Requiresastandardheater.
10‐Jun‐10
Chloride SeealsoICsection10‐117‐07‐1‐A#* 6–300 0.15 mgCl‐/L Waters Mercuricthiocyanate,480nm.Low‐flow
method;NPDES/NPDWRAccepted;alsofollowsISO(15682)
29‐Nov‐07
10‐117‐07‐1‐B# 2.5–100 0.5 mgCl‐/L Waters Mercuricthiocyanate,480nm.Low‐flowmethod;NPDES/NPDWRAccepted;alsofollowsISO(15682)
29‐Nov‐07
10‐117‐07‐1‐C^ 0.1–10.0 0.017 mgCl‐/L Waters Mercuricthiocyanate,480nm.Low‐flow 28‐Aug‐03
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage26of68
method;NPDESEquivalent.followsStandardMethods(4500‐Cl‐G);USGSI2187‐85);
10‐117‐07‐1‐E^ 5.0–2000 0.6 mgCl‐/L Waters Mercuricthiocyanate,480nm.NPDESEquivalent.alsofollowsISO(15682)
19‐Sep‐08
10‐117‐07‐1‐H# 2.5–100 0.2 mgCl‐/L Waters Mercuricthiocyanate,480followsStandardMethods(4500‐Cl‐G);USGSI2187‐85);nm.alsofollowsISO(15682)Low‐flowmethod;NPDESAccepted
5‐Apr‐01
10‐117‐07‐1‐I# 50–1000 1.0 mgCl‐/L Waters Mercuricthiocyanate,480nm.Low‐flowmethod;NPDESAcceptedalsofollowsISO(15682)
15‐Aug‐01
10‐117‐07‐1‐K^ 1.0–150 0.277 mgCl‐/L Waters Mercuricthiocyanate,480nm.UltraHighThroughputmethod(120samples/hr);NPDESEquivalent;followsStandardMethods(4500‐Cl‐G);USGSI2187‐85);alsofollowsISO(15682)
27‐May‐09
12‐117‐07‐1‐B 0.25‐30 0.05 mgCl‐/L SoilExtracts 0.01MCa(NO3)2.4H2O.Mercuricthiocyanate,480nm.
26‐Aug‐2011
12‐117‐07‐1‐C 5‐800 1 mgCl‐/L SoilExtracts 2MHNO3Mercuricthiocyanate,480nm. 05‐Jun‐1212‐117‐07‐1‐D 0.1‐30 0.05 mgCl‐/L SoilExtracts 0.014MCa(SO4)2Mercuricthiocyanate,480
nm.11‐Jun‐12
19‐117‐07‐1‐B 5–40 0.1 mgCl‐/L Platingbaths Determinationin34%zincsulfatematrix.Mercuricthiocyanate.480nm.
4‐Sep‐03
25‐117‐07‐1‐B 5–100 mgCl‐/L Chlor‐Alkali Determinationinmembranecellliquors;29to34%NaOHmatrix.Mercuricthiocyanate,480nm.
4‐Sep‐03
25‐117‐07‐1‐C 175–200 3.0 gCl‐/L Chlor‐Alkali NoNaOHinmatrix.Mercuricthiocyanate,480nm.
4‐Sep‐03
25‐117‐07‐1‐D 120‐200 3.3 gCl‐/L Chlor‐Alkali NoNaOHinmatrixMercuricthiocyanate,480nm.Requires1mmflowcellandInternalSampleLoopValve.
25‐May‐10
25‐117‐07‐1‐E 5‐100 1.0 mgCl‐/L Chlor‐Alkali Mercuricthiocyanate,480nm.29‐34%w/wNaOHMatrix
21‐Jun‐10
25‐117‐07‐1‐F 10‐250 N/A gCl‐/L Chlor‐Alkali Mercuricthiocyanate,480nm.70‐200gnaOHMatrix.Requires1mmflowcell
08‐Nov‐10
26‐117‐07‐1‐A 6‐300 1.5 mgCl‐/L TobaccoExtracts
5%Aceticacidextractsoftobacco.Mercuricthiocyanate,480nm
30‐Nov‐10
26‐117‐07‐2‐A 10‐225 3.0 mgCl‐/L Tobacco 5%Aceticacidextractsoftobacco.Mercuric 08‐Dec‐10
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage27of68
Extracts thiocyanate,480nmPre‐valvedialysistoexcludecolorinterference.
80‐117‐07‐1‐A^ 0.25–20 0.13 mgCl‐/L Waters UltraLowFlowmethod(mustberunalone 8‐Jul‐09 2.5–100 0.2 orwithotherULFmethods,pumpspeedis
6–300 1.0 10);Mercuricthiocyanate,480nmNPDESEquivalent;followsStandardMethods(4500‐Cl‐E);USGSI2187‐85.;multi‐rangemethod
Chromium SeealsoICsection10‐124‐13‐1‐A# 5–400 0.35 µgCr/LasCr(VI) Waters Hexavalentchromium;Diphenylcarbazide;
540nm.HasOmnion3.0supportadded.NPDESAccepted.
9‐Oct‐00
10‐124‐13‐1‐B^ 2–200 0.27 µgCr/LasCr(VI) Waters Hexavalentchromium;Diphenylcarbazide;540nmNPDESEquivalent;followsStandardMethods(3500Cr‐B)Diphenylcarbazide;
4‐Apr‐04
10‐141‐13‐2‐A 0.1 –1.01.0‐10
0.028 mgCr/L Waters TotalorhexavalentchromiumDiphenylcarbazide;540nm.(trivalentchromiumcanbemeasuredbysubtraction).;ISO(23913)Requiresanon‐standardheater.
18‐May‐04
31‐124‐13‐1‐A 2–2000.038‐3.85
0.660.0127
µgCr/LasCr(VI)µM Cr/L as Cr(VI)
Brackish/Seawaters
Hexavalentchromiuminseawater/brackishwaters.Diphenylcarbazide;540nm.
24‐Aug‐09
Color10‐308‐00‐1‐B 25–250 0.49 Pt‐CoColorUnits Waters 450nm 2‐Dec‐0810‐308‐00‐1‐C 2.5‐100 0.6 Pt‐CoColorUnits Waters 450nm 4‐Nov‐1021‐308‐00‐1‐A 0.250–0.700 Absunits Beverages Low‐flowmethod Cobaltouschloride,570nm. 18‐Sep‐03
Conductivity10‐302‐00‐1‐A5# 5.94–575 0.5 µS/cm Waters QC8500method;NPDESAccepted
Dedicatedchannelrequired29‐Nov‐07
10‐302‐00‐1‐AS2# QC8500Series2method;NPDESAccepted;Dedicatedchannelrequired
10‐302‐00‐1‐B5# 146.9–6667 µS/cm Waters QC8500method;NPDESAcceptedDedicatedchannelrequired
29‐Nov‐07
10‐302‐00‐1‐BS2# QC8500Series2method;NPDESAccepted;Dedicatedchannelrequired
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage28of68
10‐302‐00‐1‐E 1–5.0 0.01 µS/cm Waters QC8500method;Dedicatedchannelrequired 26‐Sep‐0710‐302‐00‐1‐ES2 QC8500Series2method;Dedicatedchannel
required.
Copper 10‐129‐17‐1‐A 0.02 –3.0 mgCu/L Waters Bathocuprinemethod;480nm. 26‐Sep‐08
Cyanide10‐204‐00‐1‐A# 0.005–0.5 0.0005 mgCN‐/L Waters TotalCyanideMacrodistillationmethod;0.25M
NaOHmatrixfollowingdistillation;Pyridine/barbituricacid,570nm.NPDES/NPDWRAccepted;followsStandardMethods(4500‐CN)..Requiresastandardheater.
29‐Nov‐07
10‐204‐00‐1‐B^ 0.50–50.0 mgCN‐/L Waters TotalCyanide0.25MNaOHmatrixfollowingdistillation;Pyridine/barbituricacid,570nm.UltraHighThroughputmethod(120samplesperhour)NPDESEquivalent(335.4)Requiresastandardheater.
19‐Sep‐08
10‐204‐00‐1‐D 0.20–10.0 0.003 mgCN‐/L Waters TotalCyanideAcetatebuffer;0.25MNaOHmatrixfollowingdistillation.Pyridine/barbituricacid,570nm.Requiresastandardheater.
18‐Sep‐03
10‐204‐00‐1‐E 0.002–0.03 0.00045 mgCN‐/L Waters TotalCyanideAcetatebuffer;0.25MNaOHmatrixfollowingdistillationPyridine/barbituricacid,570nm.Requiresastandardheater.
16‐Sep‐03
10‐204‐00‐1‐F^ 50–500 mgCN‐/L Waters FreeCyanide;low‐flowmethod;0.25MNaOHmatrixfollowingdistillation;Pyridine/barbituricacid,570nm.NPDESEquivalent(335.4).Standardheaterandinternalsampleloopvalverequired.
16‐Sep‐03
10‐204‐00‐1‐G 2.0–500 0.5 µg CN‐/L Waters Macrodistillationmethod;0.25MNaOHmatrixfollowingdistillation;pyridine‐freereagents(isonicotinic/barbituricacid).600nm.Standardheaterrequired.
16‐Sep‐03
10‐204‐00‐1‐H 0.002–0.01 0.00047 mgCN‐/L Waters FreeCyanide;isonicotinic/barbituricacid.600nm.pyridine‐freereagents;canbe
7‐Jun‐06
0.1–5.0 0.0138 usedw/10‐204‐00‐2‐GforinlinetotalCN;multi‐rangemethod;Requiresastandardheater.
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage29of68
10‐204‐00‐1‐V 0.005–0.50 0.0008 mgCN‐/L Waters TotalCyanide;mididistillationmethod;0.25MNaOHmatrixfollowingdistillationPyridine/barbituricacid,570nm.Requiresastandardheater.
16‐Sep‐03
10‐204‐00‐1‐WX 5–500 1.48 µg CN‐/L Waters WADCyanide;MicroDIST®method0.25MNaOHmatrixfollowingdistillation;Pyridine/barbituricacid,570nm.Requiresastandardheater.
1‐Apr‐09
10‐204‐00‐1‐X# 0.005–0.50 0.001 mgCN‐/L Waters TotalCyanide;MicroDIST®method;0.25MNaOHmatrixfollowingdistillation;Pyridine/barbituricacid,570nm.NPDES/NPDWRapprovedmethodRequiresastandardheater.
29‐Nov‐07
10‐204‐00‐1‐X2#^ 0.002–0.5 0.00038
mgCN‐/L Waters TotalCyanide;MicroDIST®method;0.25MNaOHmatrixfollowingdistillation;Pyridine/barbituricacid,570nm.Ultra‐HighThroughputmethod(>125samples/hr);NPDESEquivalent/NPDWRAcceptedRequiresastandardheater.
16‐Apr‐08
10‐204‐00‐2‐C^ 2–100 0.21 µg CN‐/L Waters TotalCyanide;inlinemethod;low‐flowmethod;NPDESEquivalent;Pyridine/barbituricacid,570nm.Samplesw/particulatesnotsuitableInlinemoduleandStandardheaterrequired.
14‐Sep‐07
10‐204‐00‐2‐D^ 5–500 0.51 µg CN‐/L Waters TotalCyanide;inlinemethod;low‐flowmethod;Pyridine/barbituricacid,570nm.NPDESEquivalent;Samplesw/particulatesnotsuitableInlinemoduleandStandardheaterrequired.
19‐Sep‐07
10‐204‐00‐2‐E^ 2–100 0.5 µg CN‐/L Waters TotalCyanide;inlinemethod;low‐flowmethod;lowerrecoveryofferricyanide;Pyridine/barbituricacid,570nm.NPDESEquivalent;.Samplesw/particulatesnotsuitableInlinemodule,Standardheaterrequired
3‐Dec‐08
10‐204‐00‐2‐G 0.002–0.01 0.00016 mgCN‐/L Waters TotalCyanide;inlinemethod;pyridine‐free 22‐Jun‐07 0.1–5.0 0.015 reagents;canbeusedw/10‐204‐00‐2‐Hforfree
cyanide;600nmmulti‐rangemethod;Samplesw/particulatesnotsuitable.In‐linemoduleandstandardheaterrequired.
10‐204‐00‐2‐H 2–200 µg CN‐/L Waters FreeorTotalCN.FreeCNismeasuredbyreducingtheheatertemperatureinthein‐line
28‐Jun‐2010
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage30of68
moduleandturningofftheUVlamp.1,3dimethylbarbituric/Isonicotinicacid.600nm.ISO14403‐1.Samplesw/particulatesnotsuitableIn‐linemodule,standardheaterrequired.
10‐204‐00‐2‐I 2–100 0.34 µg CN‐/L Waters TotalCyanide;inlinemethod;1,3‐dimethylbarbituricacid;Isonicotinicacid600nm.pyridine‐freereagents;Samplesw/particulatesnotsuitable.In‐linemoduleandstandardheaterrequired.
13‐Aug‐09
10‐204‐00‐3‐A 10–500 1.0 µg CN‐/L Waters WADCyanide;inlinemethod;Pyridine/barbituricacid;570nm.samplesw/particulatesnotsuitable.In‐linemoduleandstandardheaterrequired.
28‐May‐04
10‐204‐00‐4‐B 2.0–100 0.16 µg CN‐/L Waters WADCyanide;inlinemethod;pyridine‐freereagents;Isonicotinic/barbituricacid600nm.samplesw/particulatesnotsuitable;MANIFOLDONLY
27‐Jul‐07
10‐204‐00‐4B51 DEDICATED115VCHANNELFORQC8500.Pyridinefree,Isonicotinic/barbituricacid600nm.samplesw/particulatesnotsuitableRequires2channels,twoheaters,onedetectorandonevalve)
10‐204‐00‐4B52 DEDICATED220VCHANNELFORQC8500Isonicotinic/barbituricacid600nm.samplesw/particulatesnotsuitableRequires2channels,twoheaters,onedetectorandonevalve)
10‐204‐00‐4‐C
2.0–100
0.17 µg CN‐/L Waters WADCyanide;LowFlowMethod.Inlinedistillationmethod;pyridine‐freereagents;Isonicotinic/barbituricacid600nm.Samplesw/particulatesnotsuitable;Requiresaninlinemoduleandastandardheater.
11‐Mar‐13
12‐204‐00‐2‐A 2–200 0.16 µg CN‐/L Soilextracts Inlinemethod;determinationin1MNaOHsoilextracts;pyridine‐freereagents;600nm.Extractsmustbefilteredpriortoanalysis.Requiresanin‐linesamplepreparationmoduleandstandardheater.
25‐Aug‐08
26‐204‐00‐1‐A 1.0–15 0.024 mgCN‐/L Tobacco Determinationinmainstreamtobaccosmoke. 4‐May‐10
NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage31of68
extracts Pyridine‐pyrazolone;600nm.Requiresastandardheater.
80‐204‐00‐1‐A^ 0.005–0.5 0.001 mgCN‐/L Waters TotalCyanide;Pyridine/barbituricacid;570nm.UltraLowFlowmethod(mustberunaloneorwithotherULFmethods;macro‐distillationmethod;NPDESEquivalent(335.4).Requiresastandardheater.
25‐Jun‐09
80‐204‐00‐1‐X^ 0.005–0.5 0.001 mgCN‐/L Waters TotalCyanide;Pyridine/barbituricacid;570nm.UltraLowFlowmethod(mustberunaloneorwithotherULFmethods);MicroDIST®method;NPDESEquivalent(MicroDist®method).Requiresastandardheater.
24‐Jun‐09
Cyanide,AmperometricDetection10‐204‐00‐5‐A#^ 2.0–400 0.65 µg CN‐/L Waters AvailableCyanide;Amperometricdetectionw/
LigandExchange;NPDESEquivalent(335.4/ASTM6888‐09).Samplesw/particulatesnotsuitable.SoldinNorthAmerica.Requiresanamperometricdetector,directvoltagemodule,cable,andstandardheater
02‐May‐08
10‐204‐00‐5‐B^ 2.0–500
0.914 µg CN‐/L Waters TotalCyanide;inlinemethod;Amperometricdetection;Samplesw/particulatesnotsuitable.SoldinNorthAmerica;Requiresanin‐linedigestionmodule,amperometricdetector,directvoltagemodule,cable,andstandardheater.
29‐May‐08
10‐204‐00‐5‐C^ 2.0–400 0.08 µg CN‐/L Waters FreeCyanide;Amperometricdetection;Samplesw/particulatesnotsuitable.NPDESequivalent(ASTMD7237‐10).SoldinNorthAmerica.Requiresanamperometricdetector,directvoltagemodule,cable,andstandardheater.
12‐Feb‐10
10‐204‐00‐5‐D^
1.0–500
0.13 µg CN‐/L Waters TotalCyanide.Amperometricdetection;.Samplesw/particulatesnotsuitable.NPDESequivalenttoASTMD7511‐09.SoldinNorthAmerica.Requiresanamperometricdetector,
04‐Feb‐13
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage32of68
directvoltagemodule,cable,In‐linemoduleandstandardheater
10‐204‐00‐5‐WX 5.0–400 0.56 µg CN‐/L Waters WADCyanide;Amperometricdetection;MicroDIST®method;SoldinNorthAmerica.RequiresMicroDistblockandtubes,anamperometricdetector,directvoltagemodule,cable,andstandardheater.
5‐May‐09
10‐204‐00‐5‐X^ 5.0–400 0.975 µg CN‐/L Waters TotalCyanide;Amperometricdetection;MicroDIST®method;RequiresMicroDistblockandtubes,anamperometricdetector,directvoltagemodule,cable,andstandardheater.NPDESEquivalent(ASTMD7284‐08)SoldinNorthAmerica
30‐May‐08
Fluoride SeealsoICsection10‐109‐12‐2‐A5# 0.10–5.0 0.05 mgF‐/L Waters IonSelectiveElectrodemethods;QC8500
specific.NPDES/NPDWRAccepted;followsStandardMethods(4500‐F‐B);Requiresafluoridedetectormodule.
23‐Dec‐09
10‐109‐12‐2‐AS2# QC8500Series2specific.Requiresafluoridedetectormodule
23‐Dec‐09
10‐109‐12‐2‐B5^ 1–1000 0.14 mgF‐/L Waters IonSelectiveElectrodemethods;QC8500specific.NPDESEquivalent;Requiresafluoridedetectormodule
23‐Dec‐09
10‐109‐12‐2‐BS2^ QC8500Series2specific.Requiresafluoridedetectormodule
23‐Dec‐09
10‐109‐12‐2‐C5^ 0.10–2.0 0.02 mgF‐/L Waters IonSelectiveElectrodemethods;NPDESEquivalent;QC8500specificRequiresafluoridedetectormodule
23‐Dec‐09
10‐109‐12‐2‐CS2^ QC8500Series2specificRequiresafluoridedetectormodule
23‐Dec‐09
10‐109‐12‐2‐D5^ 0.10–10.0 0.03 mgF‐/L Waters IonSelectiveElectrodemethods;NPDESEquivalent.QC8500specificRequiresafluoridedetectormodule
23‐Dec‐09
10‐109‐12‐2‐DS2^ IonSelectiveElectrodemethods;NPDESEquivalent.QC8500Series2specificRequiresa
23‐Dec‐09
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage33of68
fluoridedetectormodule
10‐109‐12‐3‐A 0.1‐5.0 0.02 mgF‐/L Waters SPADNS‐2ColorimetricMethod.SPADNS‐2mustbepurchasedfromHachCompany.580nm.BellackDistillationrequiredforNPDES
1‐Jul‐2013
14‐109‐12‐2‐A5 0.5–20 0.1 mgF‐/L Fertilizers IonSelectiveElectrodemethods;QC8500specific.HCLdigestsoffertilizerRequiresafluoridedetectormodule
4‐Sep‐03
14‐109‐12‐2‐AS2 QC8500Series2specificHCLdigestsoffertilizer.Requiresafluoridedetectormodule
4‐Sep‐03
19‐109‐12‐2‐A5 1.6–80 0.4 mgF‐/L Platingbaths
IonSelectiveElectrodemethods;determinationin34%zincsulfate;QC8500specificRequiresafluoridedetectormodule
4‐Sep‐03
19‐109‐12‐2‐AS2 H2SO4 QC8500Series2specificRequiresafluoridedetectormodule
4‐Sep‐03
19‐109‐12‐2‐B5 0.1–10 0.02 mgF‐/L Platingbaths
IonSelectiveElectrodemethods;determinationin34%zincsulfate;QC8500specificRequiresafluoridedetectormodule
4‐Sep‐03
19‐109‐12‐2‐BS2 QC8500Series2specificRequiresafluoridedetectormodule
4‐Sep‐03
Formaldehyde10‐221‐00‐1‐B 0.05‐5.0 0.01 mgHCHO/L Waters MBTHmethod.630nm.Requiresastandard
heater.13‐Apr‐11
24‐221‐00‐1‐A 0.1‐10.0 0.033 mgHCHO/L AirMonitoringExtracts
Chromotropicacidmethod.580nm.Bisulfiteextracts.Requiresastandardheater.
09‐Sep‐03
FreeAminoNitrogen(FAN)21‐237‐00‐1‐A 10–120 mgN/L Beer FreeAminoNitrogen;determinationinbeer.
Ninhydrinmethod;570nm.Requiresanon‐standardheater.
5‐Sep‐03
Glucose(ReducingSugars)26‐201‐00‐1‐B 10–500 NA mgglucose/L Tobacco
extractsFerricyanidemethod;420nm.5%Aceticacid.Requiresastandardheater.
18‐Nov‐08
NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage34of68
Hardness10‐301‐31‐1‐A*# 5–300 0.331 mgCaCO3/L Waters Totalhardness;calmagitemethod630nm;
NPDESAccepted(130.1);2‐Jul‐09
10‐301‐31‐1‐B*# 30–800 5.4 mgCaCO3/L Waters Totalhardness;calmagitemethod630nm;NPDESAccepted(130.1);
18‐Dec‐00
10‐301‐31‐1‐C^ 125–1500 17.0 mgCaCO3/L Waters Totalhardness;calmagitemethod;630nmNPDESEquivalent(130.1);
5‐Sep‐03
Hydrazine10‐217‐00‐1‐B 0.005–1.0 0.002 mgN2H4/L Waters 4‐dimethylaminobenzaldehyde;460nm.
Requiresastandardheater.3‐Mar‐10
HydrogenPeroxide18‐209‐00‐1‐B 20‐40 %H2O2 Peroxide
solutionsIodinemethod.500nm,0.15%RSDmid‐range.Requiresanon‐standardheater,InternalSampleLoopValve,and1mmpathlengthflowcell.
19June2013
Hydroxide25‐225‐25‐1‐A 70–200 10 gNaOH/L Chlor‐Alkali Determinationindiaphragmormercurycell
liquors;EDA/coppersulfatemethod.630nm.InternalSampleLoopValverequired.
5‐Sep‐03
25‐225‐25‐1‐B 29–34 %w/wNaOH Chlor‐Alkali Determinationinmembranecellliquors;EDA/coppersulfatemethod.630nm.InternalSampleLoopValverequired.
5‐Sep‐03
25‐225‐25‐1‐E 29–34 %w/wNaOH Chlor‐Alkali Determinationinmembranecellliquors;EDA/coppersulfatemethod.500nm.1mmpathlengthflowcell,NOinternalsampleloopvalve
10‐Jul‐10
25‐225‐25‐1‐F 29–34 %w/wNaOH Chlor‐Alkali Determinationinmembranecellliquors;EDA/coppersulfatemethod.500nm.InternalSampleLoopValverequired.
07‐Jul‐10
25‐225‐25‐1‐G 70–200 gNaOH/L Chlor‐Alkali Determinationindiaphragmormercurycellliquors;EDA/coppersulfatemethod.630
03‐Nov‐10
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage35of68
nm.1mmpathlengthflowcell,NOinternalsampleloopvalve
Hydroxyproline20‐243‐00‐1‐A 0.1 –5.0
1–400.007
mg/L
Foodstuffs Determinationinaciddigestsofmeat; Paradimethylaminobenzaldehyde;550nm.0.0138MH2SO4finalmatrix.QC8500andQC8500Series2only;multi‐rangemethod.Requiresnon‐standardheater.
5‐Feb‐07
Hypochlorite18‐226‐36‐1‐A 0.05–2.0 0.0033 gNaOCl/L Aqueous
formulationsMethylorange;550nm.Gasdiffusionmethod;determinationincommercialproducts.
16‐Jan‐09
25‐226‐36‐1‐B 1.25–10 0.20 mgNaOCl/L Chlor‐Alkali Methyl‐orangemethod;550nm.dialysismethod
19‐Oct‐05
25‐226‐36‐1‐C 18.75–150 0.77 mgNaOCl/L Chlor‐Alkali Methyl‐orangemethod;550nm.dialysismethod
8‐Sep‐03
25‐226‐36‐1‐G 3‐75 0.6 mgNaOCl/L Chlor‐Alkali Determinationindiaphragmcellliquors;potassiumiodidemethod410nm.
25‐Apr‐13
Iodate18‐136‐41‐1‐A 0.25–8.0 0.014 mgIO3
‐/L Aqueousformulations
DPDmethod.550nm.DeterminationinNaCl/H2SO4solutions
12‐Sep‐03
Iodide SeealsoICsection
10‐136‐09‐1‐A 0.50–10.0 0.3 µgI‐/L waters 0.2MKOH420nm;.Requiresastandardheater
12‐Sep‐03
18‐136‐09‐1‐A 0.1–3.0 0.02 mgI‐/L Aqueousformulations
420nm.DeterminationinNaCl/H2SO4solutions
12‐Sep‐03
Iron10‐126‐18‐1‐A 0.1–5.0 0.01 mgFe/L Waters TotalsolubleironasFe(IIandIII);TPTZ
indicator;590nm.Inertsampleproberequired.
12‐Sep‐03
NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage36of68
10‐126‐18‐1‐B 0.05–0.5 0.002 mgFe/L Waters TotalsolubleironasFe(IIandIII);TPTZindicator590nm.Inertsampleproberequired.
12‐Sep‐03
10‐126‐18‐1‐C 1.0–5.0 0.01 mgFe/L Waters HCl/persulfatedigestsThiocyanatemethod460nm.TotalironasFe(IIandIII);Inertsampleproberequired.
12‐Sep‐03
10‐126‐18‐1‐D 0.1–5.0 0.01 mgFe/L Waters TotalsolubleironasFe(IIandIII);Ferrozine 6‐Jul‐09 0.05–5.0 indicator;560nm.Determinationin0.5%
HNO3matrix(preservation);dual‐rangemethodInertsampleproberequired.
10‐126‐18‐2‐A
2‐1000.1‐0.500
0.40.002
µgFe/LmgFe/L
Waters TotalSolubleandsolubleferrousiron,ferricironbysubtraction.2manifoldmethod.Ferrozine560nm.Inertsampleproberequired.
07‐Feb‐13
10‐126‐18‐3‐A
0.1‐5.0 0.04 mgFe/L Waters AlkalineUVdigestion,totaliron.Canmeasurefreeirononasecondchannelwithmethod10‐126‐18‐1‐DInlinemoduleandInertsampleproberequired.
22‐Oct‐10
31‐126‐18‐1‐A 0.5‐30mgFe/L 0.024 mgFe/L Brackish/Seawaters
TotalsolubleironasFe(IIandIII);TPTZindicator.600nm.Inertsampleproberequired.
15‐Sep‐03
31‐126‐18‐1‐B 0.05–0.5000.895‐8.95
0.004 mgFe/Lµg Fe/L
Brackish/Seawaters
TotalsolubleironasFe(IIandIII);TPTZindicator.600nm.Inertsampleproberequired.
15‐Sep‐03
31‐126‐19‐1‐A 0.50–30.00.00895‐0.537
0.23 mgFe/LmMFe/L
Brackish/Seawaters
TotalsolubleironasFe(II);TPTZindicator600nm.Inertsampleproberequired.
26‐Nov‐08
KjeldahlNitrogen(TKN)10‐107‐06‐2‐D# 0.5–20 0.07 mgN/L Waters Kjeldahldigests;Salicylate/nitroprusside;660
nm.mercurycatalyst;NPDESAccepted.Requiresastandardheater.
1‐May‐01
10‐107‐06‐2‐E# 0.1–5.0 0.018 mgN/L Waters Kjeldahldigests;Salicylate/nitroprusside;660nm.mercurycatalyst;NPDESAccepted.Requiresastandardheater.
5‐Dec‐07
10‐107‐06‐2‐H^ 0.1–5.0 0.034 mgN/L Waters Kjeldahldigests;Salicylate/nitroprusside;660 13‐May‐08
NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage37of68
coppercatalyst;NPDESEquivalent(351.2);followsStandardMethods(4500‐NORGD).nm.Requiresastandardheater.
10‐107‐06‐2‐I^ 0.5–20.0 0.10 mgN/L Waters Kjeldahldigests;Salicylate/nitroprusside;660coppercatalyst;NPDESEquivalent(351.2).Requiresastandardheater.
14‐May‐08
10‐107‐06‐2‐K^ 0.1–20.0 0.0093 mgN/L Waters Kjeldahldigests;mercurycatalyst;Salicylate/nitroprusside;660low‐flowmethod;NPDESEquivalent(351.2)Requiresastandardheater.
15‐May‐08
10‐107‐06‐2‐M^ 0.25–25 0.05 mgN/L Waters Kjeldahldigests;Salicylate/nitroprusside;660nm,coppercatalyst;NPDESEquivalent(351.2)Requiresastandardheater.
27‐Mar‐06
10‐107‐06‐2‐N^ 0.5–20 0.02 mgN/L Waters KjeldahldigestsSalicylate/nitroprusside;660nm;mercurycatalyst;UltraHigh
12‐Sep‐07
0.1–5.0 0.04 Throughputmethod(>125samples/hr.);multi‐rangemethod;NPDESEquivalent(351.2)Requiresastandardheater.
10‐107‐06‐2‐P^ 0.25–25 0.056 mgN/L Waters Kjeldahldigests;Salicylate/nitroprusside;660nm.coppercatalyst;UltraHighThroughputmethod(>125samples/hr.);NPDESEquivalent(351.2).Requiresastandardheater.
14‐Apr‐08
10‐107‐06‐2‐Q^ 0.5–20.00.1–5.0
0.10.04
mgN/L Waters Kjeldahldigests;Salicylate/nitroprusside;660nmmercurycatalyst;low‐flowmethod;multi‐rangemethodNPDESEquivalent(351.2).Requiresastandardheater.
8‐Dec‐09
10‐107‐06‐2‐S 0.2‐20 0.01 mgN/L Waters SimplifiedTKN(s‐TKNTM).520nm,cadmiumreduction.TwochannelmethodTNandNO2+NO3.S‐TKNbysubtraction.Requiresanin‐linemodule
14‐Jul‐10
10‐107‐06‐5‐F^ 0.1–10.0
0.01
mgN/L
Waters
Kjeldahldigests;590nm.Gasdiffusionmethod;copperormercurydigests.Canalsobeusedw/brackish/seawatersamples;ISO(11732).EquivalenttoPAI‐DK03
26‐Aug‐03
10‐107‐06‐5‐J 0.1‐5.00.25‐20
0.020.05
mgN/L Waters KjeldahlDigests,Salicylate/DCIC660nm.coppercatalyst.Gasdiffusionmethod.Sea/brackishwater.Canalsobeusedfor
26‐Sept‐12NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage38of68
Ammonia10‐107‐06‐6‐C^
0.5–20
0.21
mgN/L
Waters
Kjeldahldigests;mercurycatalyst;inlinedistillationmethod;NPDESEquivalent(351.2);samplesw/particulatesnotsuitable.Canbeusedwithbrackish/seawaterdigests.Salicylate/nitroprusside;660nm.Requiresanin‐linemoduleandastandardheater,ortwoheatedchannels(withoneheaternon‐standard)
13‐Aug‐08
10‐107‐06‐6‐D^ 0.5–20 0.25 mgN/L Waters Kjeldahldigests;coppercatalyst;inlinedistillationmethod;NPDESEquivalent(351.2);samplesw/particulatesnotsuitable.660nm.Canbeusedwithbrackish/seawaterdigests.Requiresanin‐linemoduleandastandardheaterortwoheatedchannels(withoneheaternon‐standard).
31‐Jul‐09
13‐107‐06‐1‐A 1.0–25.0 0.1 mgN/L Plantdigests Kjeldahldigests;seleniumoxidecatalystPhenate;630nm.Requiresastandardheater.
15‐Sep‐03
13‐107‐06‐2‐D* 10–150 0.5 mgN/L Plantdigests Kjeldahldigests;coppercatalyst;low‐flowmethodSalicylate/nitroprusside;660nm.Requiresastandardheater.
29‐Oct‐07
13‐107‐06‐2‐G* 1–50 0.12 mgN/L Plantdigests Kjeldahldigests;seleniumoxidecatalyst;requires10%sulfuricaciddigestSalicylate/nitroprusside;660nm.Requiresastandardheater.
15‐Sep‐03
14‐107‐06‐2‐A 5.0–200 0.04 mgN/L Fertilizers Kjeldahldigests;seleniumoxidecatalystSalicylate/nitroprusside;660nm.Requiresastandardheater.
15‐Sep‐03
15‐107‐06‐2‐E 30–300 mgN/L Feeds Kjeldahldigests;seleniumoxidecatalystSalicylate/nitroprusside;660nm.Requiresastandardheater.
15‐Sep‐03
15‐107‐06‐2‐F 7.5–300 0.75 mgN/L Feeds KjeldahldigestsSalicylate/nitroprusside;660nm.Requiresastandardheater.
15‐Sep‐03
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage39of68
KjeldahlPhosphorus(TKP)10‐115‐01‐1‐C# 0.1–5.0 0.015 mgP/L Waters TotalP;Kjeldahldigests;mercurycatalyst;
molybdatebasedmethod;880nm.NPDESAccepted.Requiresastandardheater.
15‐May‐01
10‐115‐01‐1‐D#
0.05–0.5
0.002
mgP/L
Waters
TotalP;Kjeldahldigests;mercurycatalyst;molybdatebasedmethod;880nmRequiresastandardheater.NPDESAccepted
26‐Dec‐00
10‐115‐01‐1‐I^ 0.1–5.0 0.007 mgP/L Waters TotalP;Kjeldahldigests;mercurycatalyst;molybdatebasedmethod;;880nmRequiresastandardheater.NPDESEquivalent(365.4);UltraHighThroughputmethod(>100samples/hr)
28‐Aug‐07
10‐115‐01‐2‐B^ 0.10–10 0.010 mgP/L Waters TotalP;Kjeldahldigests;coppercatalyst;molybdatebasedmethod;;880nmRequiresastandardheater.NPDESEquivalent(365.4)
27‐Mar‐06
10‐115‐01‐2‐C^ 0.1–5.0 0.025 mgP/L Waters TotalP;Kjeldahldigests;coppercatalyst;molybdatebasedmethod;UltraHighThroughputmethod(>120samples/hr);880nm.NPDESEquivalent(365.4);.Requiresastandardheater.
4‐Apr‐08
13‐115‐01‐1‐B* 1.0–50.0 0.08 mgP/L Plantextracts TotalP;Kjeldahldigests;coppercatalyst;molybdatebasedmethod;880nmRequiresastandardheater.
26‐Oct‐06
Magnesium SeealsoICsectionandHardness10‐112‐26‐1‐A 5.0–200 0.51 mgMg/L Waters Xylidylblue‐Imethod.520nm.Requiresan
internalsampleloopvalve.27‐Aug‐03
12‐112‐26‐1‐A 5.0–200 1.26 mgMg/L Soilextracts Morgansextractmethod;Xylidylblue‐Imethod.520nm.Requiresaninternalsampleloopvalve.
15‐Sep‐03
Manganese
10‐131‐35‐1‐A 0.005–0.30 0.0008 mgMn/L Waters ManganeseII;0.13%HNO3matrix 27‐Aug‐08
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage40of68
Formaldoxime,460nm.10‐131‐35‐1‐B
0.2–10
0.005
mgMn/L
Waters
ManganeseIIFormaldoxime,0.15%HNO3matrix 460nm.
15‐Sep‐03
10‐131‐35‐1‐D 12.5–250 5.0 µg Mn/L Waters ManganeseII;0.5%HNO3matrix.Formaldoxime,460nm.
15‐Sep‐03
12‐131‐35‐1‐A 0.5–2.0 0.01 mgMn/L Soilextracts Low‐flowmethod;0.1NHCl.Formaldoxime,460nm.
15‐Sep‐03
Molybdenum12‐123‐23‐1‐B 0.1–0.40 0.007 mgMo/L Soilextracts Low‐flowmethod.0.1NHCl.Iodine
method,420nm.Requiresastandardheater.
15‐Sep‐03
13‐123‐23‐1‐A 0.0625–0.25 0.0079 mgMo/L Plantextracts Low‐flowmethodAshedsamples,1MHClfinalmatrix.Iodinemethod,420nm.Requiresastandardheater.
15‐Sep‐03
Monochloramine10‐245‐00‐1‐A 0.01–2.0 0.0028 mgN/LasNH4Cl Waters Alkalinephenol‐basedmethod;630nm;
requiresastandardheater.low‐flowmethod;Usew/10‐107‐06‐1‐Lforfreeammonia
5‐Nov‐07
Nitrate+Nitrite SeealsoICsection10‐107‐04‐1‐A#* 0.2–20.0 0.01 mgN/L Waters Sulfanilamide/NED.Cdreductionmethod;520nm.
low‐flowmethod;NPDES/NPDWRAccepted29‐Nov‐07
10‐107‐04‐1‐B# 0.002–0.10 0.0003 mgN/L Waters Cdreductionmethod;Sulfanilamide/NED.520nm.NPDES/NPDWRAccepted
29‐Nov‐07
10‐107‐04‐1‐C# 0.01 –2.00.05‐5.0
0.0020.004
mgN/L Waters Sulfanilamide/NED.Cdreductionmethod;520nm.UltraHighThroughputmethod/120samplesperhour.NPDES/NPDWRAccepted;followsStandardMethods(4500‐NO3‐I)PreservedorunpreservedsampleswithnopHadjustmentneededforsamples.
14‐Jul‐08;Highrangesupportadded12Apr2013
10‐107‐04‐1‐F^ 1–50.0 0.12 mgN/L Waters Cdreductionmethod;Sulfanilamide/NED.520nm.NPDESEquivalent(353.2).Requiresaninternalsampleloopvalve.
1‐May‐08
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage41of68
10‐107‐04‐1‐H^ 5–80.0 0.027 mgN/L Waters Sulfanilamide/NEDCdreductionmethod;520nm.dialysismethod;NPDESEquivalent(353.2).
1‐May‐08
10‐107‐04‐1‐J# 0.10–10.0 0.012 mgN/L Waters Sulfanilamide/NED.Cdreductionmethod;dialysismethod;520nm.dialysismethod;.NPDES/NPDWRAccepted
29‐Nov‐07
10‐107‐04‐1‐K# 7‐700.5–5.0
1.00.07
µgN/LµM N
Waters Sulfanilamide/NED.Cdreductionmethod;520nm.low‐flowmethod;NPDES/NPDWRAccepted
29‐Nov‐07
10‐107‐04‐1‐L# 0.02–2.0 0.002 mgN/L Waters Sulfanilamide/NED.Cdreductionmethod;520nm.low‐flowmethod;NPDES/NPDWRAccepted
29‐Nov‐07
10‐107‐04‐1‐M 0.25–14 0.042 µgN/L Waters Sulfanilamide/NEDCdreductionmethod;540nm.2‐cmdetectormethod;QC8500only.Requiresastandardheater.PN58112allowsreplicateinjectionsfromasinglesampletube.
25‐Feb‐09
10‐107‐04‐1‐O# 0.05–10.0 0.007 mgN/L Waters Sulfanilamide/NED.Cdreductionmethod;520nm.NPDES/NPDWRAccepted
29‐Nov‐07
10‐107‐04‐1‐Q^ 0.005–0.8 0.0005 mgN/L Waters Cdreductionmethod;low‐flowmethod; 10‐Aug‐06 0.5–10 0.022 Sulfanilamide/NEDimidazolebuffer;520nm.
determinationinnon‐preservedandacidpreservedsamples;multi‐rangemethod;.NPDESEquivalent(353.2)
10‐107‐04‐1‐R#^* 0.002–0.25 0.0005 mgN/L Waters Sulfanilamide/NED.Cdreductionmethod;520nm.UltraHighThroughputmethod
16‐Apr‐08
0.025–20 0.0012 (>120samples/hr.);multi‐rangemethod;NPDESEquivalent;NPDWRAccepted
10‐107‐04‐2‐A#* 2–100 0.1 mgN/L Waters Sulfanilamide/NED.Hydrazinereduction.520nm.NPDES/NPDWRAccepted;followsStandardMethods(4500‐NO3‐I).Requiresastandardheater.
29‐Nov‐07
10‐107‐04‐2‐B# 0.05–1.0 0.002 mgN/L Waters Sulfanilamide/NED.Hydrazinereduction;520nm.NPDES/NPDWRAccepted;followsStandardMethods(4500‐NO3‐I)Requiresastandardheater.
29‐Nov‐07
10‐107‐04‐2‐C 0.005–0.2 0.0018 mgN/L Waters Sulfanilamide/NED.Hydrazinereduction.520nm.Requiresastandardheater.
25‐Aug‐03
10‐107‐04‐2‐D# 0.05–7 0.006 mgN/L Waters Sulfanilamide/NED.Hydrazinereduction;520nm.NPDES/NPDWRAccepted;followsStandardMethods(4500‐NO3‐I)Requiresastandardheater.
14‐Jan‐02
10‐107‐04‐5‐A 0.02–5.0 0.009 mgN/L Waters Sulfanilamide/NEDNitrateReductasemethod;540nm.Reagentsmust
9‐Feb‐09
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage42of68
0.2–20 0.023 bepurchasedfromNECi;multi‐rangemethod. 10‐107‐04‐6‐A
0.05–5.00.2–20
0.0050.022
mgN/L
Waters
Sulfanilamide/NEDUVNitrateReduction;PATENTPENDING540nm.In‐linemodulewithUVlamprequired.Multi‐rangemethod
4‐Sep‐09
12‐107‐04‐1‐A 0.2–40.0 mgN/L Soilextracts Sulfanilamide/NEDCdreductionmethod;520nmdeterminationin1mMCaCl2soilextracts
15‐Sep‐03
12‐107‐04‐1‐B 0.025–20.0 0.005 mgN/L Soilextracts Sulfanilamide/NEDCdreductionmethod;520nmdeterminationin2MKClsoilextracts;
21‐Aug‐03
12‐107‐04‐1‐C 0.2–20.0 mgN/L Soilextracts Sulfanilamide/NEDCdreductionmethod;520nmdeterminationinsaturated0.02MCaOsoilextracts
15‐Sep‐03
12‐107‐04‐1‐E 0.05–5.0 mgN/L Soilextracts Hydrazinereduction.Sulfanilamide/NED520nm1MKClsoilextracts.
15‐Sep‐03
12‐107‐04‐1‐F 0.01–2.0 0.0013 mgN/L Soilextracts Sulfanilamide/NEDCdreductionmethod;520nmdeterminationin2MKClsoilextracts
15‐Sep‐03
12‐107‐04‐1‐G 1.0–20.0 0.01 mgN/L Soilextracts Sulfanilamide/NEDCdreductionmethod;520nmdeterminationin0.0125MCaCl2soilextracts
15‐Sep‐03
12‐107‐04‐1‐H 0.05–10.0 0.011 mgN/L Soilextracts Sulfanilamide/NEDCdreductionmethod;520nm;determinationin0.5MK2SO4soilextracts
15‐Sep‐03
12‐107‐04‐1‐I 0.3–10 0.013 mgN/L Soilextracts Sulfanilamide/NEDCdreductionmethod;520nmimidazolebuffermethoddeterminationin2MKClsoilextracts;
06‐Dec‐06
12‐107‐04‐1‐J 0.025‐20 0.003 MgN/L SoilExtracts Sulfanilamide.NEDCdReductionMethod.520nm.UltraHighThroughoutmethod;120samplesperhour.2MKClextractsofsoils.
15‐Aug‐07
12‐107‐04‐5‐A 0.2–20 0.028 mgN/L Soilextracts Sulfanilamide/NEDNitrateReductasemethod;540nm.reagentsmustbepurchasedfromNECi2MKCl
28‐Jan‐09
12‐107‐04‐6‐A 0.2–20 0.015 mgN/L Soilextracts UVNitrateReduction;PATENTPENDINGSulfanilamide/NED520nm.2MKCl.Requiresanin‐linemodulewithUVlamp.
24‐Jun‐09
13‐107‐04‐1‐A 0.2–20.0 mgN/L Plantextracts
Sulfanilamide/NEDCdreductionmethod;520nm.Determinationin2%aceticacidextractsofplants.
15‐Sep‐03
13‐107‐04‐1‐B 0.02–2.0 0.003 mgN/L Plantextracts
Sulfanilamide/NEDCdreductionmethod;520nm.Determinationinwaterextractsofplants
15‐Sep‐03
14‐107‐04‐1‐A 1790–7140 mgN/kg Fertilizers Sulfanilamide/NEDCdreductionmethod;dialysismethod520nm.Dilutedliquidfertilizer.
15‐Sep‐03
14‐107‐04‐1‐B 30–300 0.38 mgN/L Fertilizers Sulfanilamide/NEDCdreductionmethod;520nm.Dialysismethod
15‐Sep‐03
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage43of68
14‐107‐04‐1‐C 30–70.0 mgN/L Fertilizers Sulfanilamide/NEDCdreductionmethod;520nm.dialysismethod
15‐Sep‐03
18‐107‐04‐1‐A 0.5–2.5 0.017 mgN/L Aqueousformulations
Sulfanilamide/NEDCdreductionmethod;520nm.Determinationin31%KOHsolutions.
15‐Sep‐03
18‐107‐04‐1‐D 0.02–0.75 0.0030 mgN/L Aqueousformulations
.Sulfanilamide/NEDCdreductionmethod;520nmDeterminationin2to20%NaClsolutions.
15‐Sep‐03
19‐107‐04‐1‐A 0.04–2.0 0.008 mgN/L Platingbaths
Sulfanilamide/NEDCdreductionmethod;520nm.Determinationinsulfuricacid
15‐Sep‐03
19‐107‐04‐1‐B 0.0125–2.0 0.0013 mgN/L Platingbaths
Sulfanilamide/NEDCdreductionmethod;520nm.Determinationin34%ZnSO4
15‐Sep‐03
20‐107‐04‐1‐B 0.025–0.5 mgNO2‐/L Foodstuffs Sulfanilamide/NEDCdreductionmethod;540nm.
Dialysismethod;determinationin16‐Sep‐03
0.25–5.0 0.018 mgNO3‐/L dairyproducts;ISO(14673‐3)
20‐107‐04‐1‐C 0.025–1.0 0.002 mgNO2‐/L Foodstuffs Sulfanilamide/NEDCdreductionmethod;540nm.
Dialysismethod;determination25‐Mar‐08
0.25–5.0 0.021 mgNO3‐/L indairyproducts;
26‐107‐04‐1‐A 10–50.0 0.103 mgN/L Tobaccoextracts
Sulfanilamide/NEDSulfanilamide/NEDCdreductionmethod;520nm.Determinationin0.005Msulfuricacid
16‐Sep‐03
26‐107‐04‐2‐A 10–100 0.25 mgN/L Tobaccoextracts
Sulfanilamide/NEDCdreductionmethod;520nmdeterminationin0.05Msulfuricacid.Requiresastandardheater.
16‐Sep‐03
30‐107‐04‐1‐A^ 0.05–1.003.57‐71.43
0.0029 mgN/LµM N/L
Brackish/Seawaters
Sulfanilamide/NEDCdreductionmethod;520nm.NPDESEquivalent.(353.2);followsStandardMethods(4500‐NO3‐I).
20‐Nov‐08
30‐107‐04‐1‐C^ 0.05–2.03.57‐142.86
0.0029 mgN/LµM N/L
Brackish/Seawaters
Sulfanilamide/NEDCdreductionmethod;520nmmulti‐rangemethod;NPDESEquivalent(353.2).
20‐Nov‐08
0.1 –100.0071‐0.713
0.0049 mgN/LmMN/L
31‐107‐04‐1‐A^ 17.5–701.25‐5.0
0.126 µgN/LµM N/L
Brackish/Seawaters
Sulfanilamide/NEDCdreductionmethod;520nm.NPDESEquivalent(353.2)
2‐May‐08
31‐107‐04‐1‐C^ 0.07–0.705.0‐50.0
0.00168 mgN/LµM N/L
Brackish/Seawaters
Sulfanilamide/NEDCdreductionmethod;520nm.NPDESEquivalent(353.2)
2‐May‐08
31‐107‐04‐1‐D^ 0.5–140.036‐1.0
0.2 µg N/LµM N/L
Brackish/ Sulfanilamide/NEDCdreductionmethod;540nmNPDESEquivalent(353.2)..Requiresastandard
2‐May‐08
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage44of68
Seawaters heater.
31‐107‐04‐1‐E^ 5–4000.36‐28.57
0.51 µg N/LµM N/L
Brackish/Seawaters
Sulfanilamide/NEDCdreductionmethod;540nmNPDESEquivalent(353.2).
19‐Aug‐03
31‐107‐04‐1‐F^ 0.25–140.018‐1.0
0.042 µg N/LµM N/L
Brackish/Seawaters
Sulfanilamide/NED.Cdreductionmethod;540nm.2‐cmdetectormethod;QC8500only;NPDESEquivalent(353.2).Requiresastandardheater.
8‐Jul‐08
31‐107‐04‐1‐G^
0.25–100.018‐0.7140.01–1.00.714‐71.43
0.050.002
mgN/LmMN/LmgN/LµM N/L
Brackish/Seawaters
Sulfanilamide/NEDCdreductionmethod;540nmUltraHighThroughputmethod.(>120samples/hr);multi‐range;NPDESEquivalent(353.2)
24‐Apr‐08
31‐107‐04‐1‐H^ 0.25–300.18‐2.143
0.025 mgN/LmMN/L
Brackish/Seawaters
Sulfanilamide/NEDCdreductionmethod;540nmcanalsousew/non‐salinematrix;NPDESEquivalent(353.2)
28‐Oct‐08
31‐107‐04‐1‐I 5–5000.357‐35.71
0.025 mgN/LmMN/L
Brackish/Seawaters
Sulfanilamide/NEDCdreductionmethod;540nm.Ultrahighlevel,inlinedialysismethod
12‐Jul‐09
31‐107‐04‐1‐J^ 1‐1000.071‐7.143
0.2 µg N/LµM N/L
Brackish/Seawaters
Sulfanilamide/NEDCdreductionmethod;520nm.NPDESEquivalent(353.2)
30‐Jun‐10
31‐107‐04‐1‐K 1‐1000.071‐7.143
0.2 µg N/LµM N/L
Brackish/Seawaters
Sulfanilamide/NED,Cdreductionmethod.Imidazolebuffer.540nm.NPDESEquivalent(353.2)
20‐May‐11
31‐107‐04‐5‐A 0.01 –5.01.43‐357.14
0.009 mgN/LµMN/L
Brackish/Seawaters
Sulfanilamide/NEDNitrateReductasemethod;540nm.EnzymaticreagentsmustbepurchasedfromNECi.
11‐Feb‐09
31‐107‐04‐6‐A 0.05–5.00.0036‐0.3570.2‐20.00.0143‐1.43
0.006 mgN/LmMN/LmgN/LmMN/L
Brackish/Seawaters
UVNitrateReduction;Sulfanilamide/NED540nm.Multi‐rangemethodPATENTPENDINGRequiresanin‐linemodulewithUVlamp.
19‐Jun‐09
60‐107‐04‐1‐A 0.0014–0.07 mgN/L Biologicalfluids
Sulfanilamide/NED,Cdreductionmethod;540nm.HEPESBufferLow‐flowmethod
16‐Sep‐03
80‐107‐04‐1‐A#^ 0.001–0.10 0.0002 mgN/L Waters Sulfamilamide/NEDCdreductionmethod;520nm.UltraLowFlowmethod(mustbe
10‐Jun‐09
0.01–1.0 0.001 runaloneorwithotherULFmethods, 0.10–10.0 0.002 pumpspeedis10);NPDESEquivalent(353.2);multi‐
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage45of68
rangemethod.
90‐107‐04‐2‐A 0.1‐6.0 mgN/L Water/Soils Sulfanilamide/NEDHydrazineReduction.520nm.MultipleMatrixMethod.Water,2MKCl,0.5MK2SO4,0.01MCaCl2.
27‐Jan‐11
Nitrite SeealsoICsection10‐107‐05‐1‐A#^ 0.01–10.0 0.005 mgN/LasNO2
‐ Waters Nitriteonly;Sulfanilamide/NED520nm.NPDESEquivalent/NPDWRAccepted(353.2)
29‐Nov‐07
10‐107‐05‐1‐B^ 0.014–0.07 0.0004 mgN/LasNO2‐ Waters Nitriteonly;Sulfanilamide/NED520nm.low‐flow
method;NPDESEquivalent(353.2)12‐May‐08
10‐107‐05‐1‐C^ 0.02–2.0 0.0016 mgN/LasNO2‐ Waters Nitriteonly;Sulfaniliamide/NED520nm.low‐
flowmethod;NPDESEquivalent(353.2)21‐Aug‐03
10‐107‐05‐1‐E 0.05–5.00.2–20
0.030.0008
mgN/LasNO2‐ Waters Nitriteonly;Sulfanilamide/NED540nm.
companionmethodforUV9‐Sep‐09
10‐107‐05‐1‐F 4–400 0.46 µgN/LasNO2‐ Waters Nitriteonly.Sulfanilamide/NED520nm. 22‐Feb‐10
10‐107‐06‐1‐M 0.25‐14 0.01 µgN/LasNO2‐ Nitriteonly.Sulfanilamide/NED540nm.
Requiresastandardheater.2cmflowcellQC8500Only.PN58112allowsreplicateinjections
5‐Aug‐10
10‐107‐05‐1‐O^ 10–1000 4.0 µgN/LasNO2‐ Waters Nitriteonly;low‐flowmethod;NPDESEquivalent
(353.2)13‐May‐08
31‐107‐05‐1‐A^ 17.5–701.25‐5.0
0.01
µgN/LasNO2‐
µMN/LasNO2
‐
Brackish/Seawaters
Nitriteonly;Sulfanilamide/NED540nm.NPDESEquivalent(353.2)
13‐May‐08
31‐107‐05‐1‐B^ 0.1 –150.007‐1.07
0.01 mgN/LasNO2‐
mMN/LasNO2
‐
Brackish/Seawaters
Nitriteonly;Sulfanilamide/NED540nm.NPDESEquivalent(353.2)
29‐Oct‐08
31‐107‐05‐1‐F^ 0.25‐140.0018‐1.0
0.01 µgN/LasNO2‐
µMN/LasNO2
‐
Brackish/Seawaters
Nitriteonly.Sulfanilamide/NED540nm.Requiresastandardheater.2cmflowcellQC8500Only.PN58112allowsreplicateinjections
5‐Aug‐10
80‐107‐05‐1‐A#^ 0.01 –1.00.1–10.0
0.0020.02
mgN/LasNO2‐ Waters Nitriteonly;Sulfanilamide/NED520nm.UltraLow
Flowmethod(mustberunaloneorwithotherULFmethods);NPDESEquivalent(353.2);multi‐rangemethod
5‐Jun‐09
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage46of68
Nitrogen‐TotalNitrogen10‐107‐04‐3‐A* 200–2000 5.6 µg N/L Waters Sulfanilamide/NEDCadmiumReduction;540
nm.TotalN;inlinemethod;alkalinepersulfatedigestion;samplesw/particulatesnotsuitable.In‐linesampleprepmodulerequired.Nitrate/Nitritesupportadded.
16‐Nov‐09
10‐107‐04‐3‐B* 0.5–30.0 0.1 mgN/L Waters Sulfanilamide/NEDimidazolebuffer;CadmiumReduction;540nm.TotalN;inlinemethod;alkalinepersulfatedigestionmethod;samplesw/particulatesnotsuitable.In‐linesampleprepmodulerequired.Nitrate/Nitritesupportadded.
16‐Nov‐09
10‐107‐04‐3‐C 0.5–10.0 0.011 mgN/L Waters Sulfanilamide/NEDCadmiumReduction;540nm.TotalN;inlinemethod;alkalinepersulfatedigestionmethod;samplesw/particulatesnotsuitableIn‐linesampleprepmodulerequired.
29‐Jun‐07
10‐107‐04‐3‐D 0.05–5.0 0.003 mgN/L Waters Sulfanilamide/NEDCadmiumReduction;540nm.TotalN;inlinemethod;alkalinepersulfatedigestionmulti‐rangemethod;
2‐Dec‐12
0.2–20.0 0.008 samplesw/particulatesnotsuitable.In‐linesampleprepmodulerequired.Nitrate/Nitritesupportadded..
10‐107‐04‐3‐E 0.05–10 0.005 mgN/L Waters Sulfanilamide/NED;CadmiumReduction;540nm.TotalN;inlinemethod;alkalinepersulfatedigestion;samplesw/particulatesnotsuitable In‐linesampleprepmodulerequired.
12‐Nov‐10
10‐107‐04‐3‐P 0.2–10.0 0.05 mgN/L Waters Sulfanilamide/NED;CadmiumReduction;540nm.TotalN;inlinemethod;alkalinepersulfatedigestion;followsStandardMethods(4500‐N‐B);samplesw/particulatesnotsuitable.
29‐Jun‐07
10‐107‐04‐4‐A 0.5–10 0.02 mgN/L Waters Sulfanilamide/NEDCadmiumreduction.520nm.TotalN;manualalkalinepersulfate
11‐Jan‐10
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage47of68
digestion;low‐flowmethod.
10‐107‐04‐4‐B 0.02–5.0 0.006 mgN/L Waters Sulfanilamide/NEDCadmiumReduction;520nm.BaseduponStandardMethod4500‐Norg(proposed)TotalN;dualmanualpersulfatedigest;totalphosphoruscanbemeasuredfromsamedigest
22‐Jun‐07
1.00–40.0 0.024 (10‐115‐01‐4‐B);multi‐rangemethod.Nitrate/Nitritesupportadded.
10‐107‐04‐4‐C 0.05‐5.0 0.00055 mgN/L Waters Sulfanilamide/NED.cadmiumreduction.Imidazolebuffer540nm.Single‐step,off‐line(autoclave)digestionmethod.TPcanbemeasuredfromthesamedigestate.
18‐Jun‐13
12‐107‐04‐3‐B 0.2–30.0 0.04 mgN/L Soilextracts Sulfanilamide/NEDCadmiumreduction,.540nm.TotalN;alkalinepersulfatedigestion;0.5MK2SO4extractsofsoils;inlinemodulerequired;samplesw/particulatesnotsuitable.
13‐Nov‐09
12‐107‐04‐3‐C 0.375‐30 0.05 mgN/L Soilextracts Sulfanilamide/NEDCadmiumreduction,.540nm.TotalN;0.5MK2SO4extractsofsoils;inlinemodulerequired;;persulfatedigestion;samplesw/particulatesnotsuitable.DissolvedOrganicCarbonmaybemeasuredinthesamedigestusing12‐140‐39‐5‐A
31‐107‐04‐3‐A 25–10001.79‐71.43
4.90 µg N/LµM N/L
Brackish/Seawaters
Sulfanilamide/NEDCadmiumreduction,.540nm.TotalN;alkalinepersulfateinlinedigestionmethod;samplesw/particulatesnotsuitable.
3‐Feb‐10
31‐107‐04‐3‐B 500–500035.71‐357.14
78 µg N/LµM N/L
Brackish/Seawaters
Sulfanilamide/NEDCadmiumreduction,.540nm.TotalN;alkalinepersulfateinlinedigestionmethodsamplesw/particulatesnotsuitable.
2‐Jul‐07
31‐107‐04‐4‐B
0.02–5.001.43‐357.141.0–40.00.071‐2.86
0.00680.111
mgN/LµM N/LmgN/LmMN/L
Brackish/Seawaters
Sulfanilamide/NEDCadmiumreduction,520nm.TotalN;manualpersulfatedigestionw/Cdreduction;low‐flowmethod;totalphosphoruscanbemeasuredfromsamedigest(31‐115‐01‐4‐B);multi‐rangemethod.
16‐Jun‐08
NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage48of68
31‐107‐04‐4‐C 0.02–5.001.43‐357.141.0–40.00.071‐2.86NO2+NO3‐N:2.5‐500NO2‐N:1‐125
0.00680.1110.440.2
mgN/LµM N/LmgN/LmMN/Lµg N/LµM N/Lµg N/LµM N/L
Brackish/Seawaters
Sulfanilamide/NEDCadmiumreduction,520nm.TotalN;manualdualpersulfatedigestionImidazole buffer; low-flow method; total phosphorus can be measured from same digest (31-115-01-4-B); Support for NO2 + NO3 and NO2 included.
21‐Feb‐12
Orthophosphate SeealsoICsection
10‐115‐01‐1‐A# 0.01–2.0 0.002 mgP/LasPO42‐ Waters Orthophosphate;molybdatebasedmethod;
880nm.NPDES/NPDWRAccepted;followsStandardMethods(4500‐P‐G).Requiresastandardheater.
29‐Nov‐07
10‐115‐01‐1‐B# 0.01–0.20 0.0007 mgP/LasPO42‐ Waters Orthophosphate;molybdatebasedmethod;
880nm.NPDES/NPDWRAccepted.Requiresastandardheater.
29‐Nov‐07
10‐115‐01‐1‐M# 1–100 0.1 µg P/LasPO42‐ Waters Orthophosphate;molybdatebasedmethod;
880nm.NPDES/NPDWRAccepted.Requiresastandardheater.
29‐Nov‐07
10‐115‐01‐1‐O*^ 1.0–20 0.045 mgP/LasPO42‐ Waters Orthophosphate;molybdatebasedmethod;
NPDESEquivalent(365.1);UltraHighThroughputmethod(>120samples/hr).880nm.Requiresastandardheater.
16‐Dec‐07
10‐115‐01‐1‐P# 0.05–2.00 0.005 mgP/LasPO42‐ Waters Orthophosphate;molybdatebasedmethod;
880nm.low‐flowmethod;NPDES/NPDWRAccepted.Requiresastandardheater.
29‐Nov‐07
10‐115‐01‐1‐Q# 0.010–0.20 0.0003 mgP/LasPO42‐ Waters Orthophosphate;molybdatebasedmethod;
880nm.low‐flowmethod;NPDES/NPDWRAccepted.880nm.Requiresastandardheater.
29‐Nov‐07
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage49of68
10‐115‐01‐1‐T#
0.025–2.5
0.005
mgP/LasPO4
2‐
Waters
Orthophosphate;molybdatebasedmethod;880nm.NPDES/NPDWRAccepted.Requiresastandardheater.
29‐Nov‐07
10‐115‐01‐1‐V#* 0.01–2.0 0.0012 mgP/LasPO42‐ Waters Orthophosphate;molybdatebasedmethod;
880nm.multi‐rangemethod;NPDES16‐Apr‐08
0.2–20.0 0.0046 Equivalent/NPDWRAccepted;UltraHighThroughputmethod(>125samples/hr)PN58112allowsreplicateinjectionsfromsinglesampletubes.Requiresastandardheater
10‐115‐01‐1‐W*^ 0.25–20 0.046 µg P/LasPO42‐ Waters Orthophosphate;molybdatebasedmethod;
880nm.2‐cmdetectormethod;QC8500only;forsampleswithverylowornosilicate;NPDESEquivalent(365.1).PN58112allowsreplicateinjectionsfromsinglesampletubes.Requiresanon‐standardheater.
22‐Feb‐08
10‐115‐01‐1‐Y*^ 0.5–100 0.164 µgP/LasPO42‐ Waters Orthophosphate;molybdatebasedmethod;
880nm.2‐cmdetectormethod;QC8500only;forsampleswithhighsilicate;NPDESEquiv‐alent(365.1)Requiresanon‐standardheater.
21‐Jul‐08
12‐115‐01‐1‐A 0.25–10.0 mgP/LasPO42‐ Soilextracts Orthophosphate;molybdatebasedmethod;
880nm.determinationinMehlichIIIsoilextracts.Requiresastandardheater.
17‐Sep‐03
12‐115‐01‐1‐B 0.01–1.0 0.006 mgP/LasPO42‐ Soilextracts Orthophosphate;molybdatebasedmethod;
880nm.determinationin0.5Mbicarbonate(Olsens)soilextracts.Requiresastandardheater
17‐Sep‐03
12‐115‐01‐1‐E 0.25–10.0 0.02 mgP/LasPO42‐ Soilextracts Orthophosphate;molybdatebasedmethod;
880nm.determinationin0.5Maceticacid,0.5Mammoniumacetatesoilextracts.Requiresastandardheater
17‐Sep‐03
12‐115‐01‐1‐I 0.5–20.0 0.02 mgP/LasPO42‐ Soilextracts Orthophosphate;molybdatebasedmethod;
880nm.determinationincalciumacetatesoilextracts.Requiresastandardheater
17‐Sep‐03
12‐115‐01‐1‐J 1.25–50.0 0.125 mgP/LasPO42‐ Soilextracts Orthophosphate;molybdatebasedmethod; 17‐Sep‐03
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage50of68
880nm.determinationincalciumlactatesoilextracts.Requiresastandardheater
12‐115‐01‐1‐K 1.0–30.0 mgP/LasPO42‐ Soilextracts Orthophosphate;molybdatebasedmethod;
880nm.determinationinMorganssoilextracts.Requiresastandardheater
17‐Sep‐03
12‐115‐01‐1‐L 0.05–6.0 0.01 mgP/LasPO42‐ Soilextracts Orthophosphate;molybdatebasedmethod;
.880nm.determinationinMorganssoilextracts.Requiresastandardheater
17‐Sep‐03
12‐115‐01‐1‐M 0.25–10 0.04 mgP/LasPO42‐ Soilextracts Orthophosphate;molybdatebasedmethod;
determinationinMehlichIIIsoilextracts.880nm.Requiresastandardheater
21‐Jun‐06
12‐115‐01‐1‐N 0.4–20 0.07 mgP/LasPO42‐ Soilextracts Orthophosphate;molybdatebasedmethod;
880nm.determinationinBray1,Bray2,MehlichI,MehlichIIIsoilextractsUltraHighThroughputmethod(>120samples/hr)Requiresastandardheater
04‐Sep‐07
12‐115‐01‐1‐O 0.1‐5.0 0.002 mgP/LasPO42‐ Soilextracts Orthophosphate;molybdatebasedmethod;
880nm.determinationin0.1NHClsoilextracts.Requiresastandardheater
15‐Dec‐10
12‐115‐01‐1‐P 0.1‐5.0 0.01 mgP/LasPO42‐ SoilExtracts Orthophosphate;molybdatebasedmethod;
880nm.determinationin0.5MH2SO4dissolvedashedsoil.Requiresastandardheater
27‐Jan‐12
12‐115‐01‐1‐Q 0.1‐10 0.004 mgP/LasPO42‐ SoilExtracts Orthophosphate;molybdatebasedmethod;
880nm.determinationin0.5Mbicarbonate(Olsen’s)soilextracts.Improvedthroughput‐nogasdiffusionblockneeded.Requiresastandardheater.
07May‐13
18‐115‐01‐1‐B 0.25–10 0.01 mgP/LasPO42‐ Aqueous
formulationsOrthophosphate;molybdatebasedmethod;determinationinupto10%NaClsolutions.880nm.Requiresastandardheaterand1mmpathlengthflowcell.
17‐Sep‐03
18‐115‐01‐1‐C 5–375 0.5 mgP/LasPO42‐ Aqueous
formulationsOrthophosphate;molybdatebasedmethod;880nm.determinationinwatertreatmentproducts.Requiresastandardheater
17‐Sep‐03
19‐115‐01‐1‐A 0.02–2.0 0.01 mgPO42‐/L Platingbaths Orthophosphate;molybdatebasedmethod;
880nm.determinationin34%zincsulfate.Requiresastandardheater.
17‐Sep‐03
NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage51of68
20‐115‐01‐2‐B 100–1500 0.71 mgP/LasPO42‐ Foodstuffs Orthophosphate;Vanadatebasedmethod.
470nm.Ashedsamples;finalmatrix1.2MHCl.
16‐Apr‐08
31‐115‐01‐1‐G^ 62–3102.0‐10.0
µgP/LasPO42‐
µM P/LasPO42‐
Brackish/Seawaters
Orthophosphate;molybdatebasedmethod;880nm.NPDESEquivalent(365.5).Requiresastandardheater
13‐May‐08
31‐115‐01‐1‐H^ 5–4000.16‐12.9
1.0 µg P/LasPO42‐
µM P/L as PO42‐
Brackish/Seawaters
Orthophosphate;molybdatebasedmethod;880nm.NPDESEquivalent(365.5).Requiresastandardheater
13‐May‐08
31‐115‐01‐1‐I^ 1‐1000.032‐3.23
0.25 µg P/LasPO42‐
µM P/L as PO42‐
Brackish/Seawaters
Orthophosphate;molybdatebasedmethod;880nm.NPDESEquivalent(365.5)Requiresastandardheater
13‐May‐08
31‐115‐01‐1‐J^ 0.01 –2.00.323‐64.52
0.002 mgP/LasPO42‐
µM P/L as PO42‐
Brackish/Seawaters
Orthophosphate;molybdatebasedmethod;880nm.NPDESEquivalent(365.5)
30‐Nov‐07
0.5‐200.016‐0.645
mgP/LasPO42‐
mMP/LasPO42‐
Requiresastandardheater
31‐115‐01‐1‐W^
0.25–200.008‐0.645
0.007
µg P/LasPO42‐
µM P/L as PO42‐
Brackish/Seawaters
Orthophosphate;molybdatebasedmethod;880nm2‐cmdetectormethod;QC8500only;forsampleswithverylowornosilicate;NPDESEquivalent(365.5).Requiresanon‐standardHeaterPN58112allowsreplicatesfromasinglesampletube.
22‐Feb‐08
31‐115‐01‐1‐Y*^ 0.5–1000.016‐3.23
0.164 µgP/LasPO42‐
µM P/L as PO42‐
Brackish/Seawaters
Orthophosphate;molybdatebasedmethod;880nm2‐cmdetectormethod;QC8500only;forsampleswithhighsilicate;NPDESEq.(365.5)Requiresanon‐standardheaterPN58112allowsreplicatesfromasinglesampletube.
29‐Feb‐08
80‐115‐01‐1‐A#^ 0.05–2.0 0.005 mgP/LasPO42‐ Waters Orthophosphate;Molybdatemethod.880
nmUltraLowFlowmethodmustberunaloneorwithotherultralowflowmethods.NPDWRaccepted.Requiresastandardheater.
5‐Jun‐09
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage52of68
pH
10‐304‐24‐2‐E 3.0–12.0 pHunits Waters Notforlow‐conductivitysamples.RequiresapHdetectormodule.
18‐Sep‐03
Phenol10‐210‐00‐1‐A# 5–200 0.6 µg phenol/L Waters Totalrecoverablephenol;4‐amino
antipyrenemethod;500nm.macrodistillationmethod;NPDESAccepted.
14‐Dec‐01
10‐210‐00‐1‐B# 0.05–2.0 0.0013 mgphenol/L Waters 4‐aminoantipyrenemethod;500nm.macrodistillationmethod;NPDESAccepted.
18‐Oct‐07
10‐210‐00‐1‐E^ 0.5‐100 0.25 µg phenol/L Waters Totalrecoverablephenol;4‐aminoantipyrenemethod;500nm.MacroorMidi(glass)distillationmethod;2cmflowcellQC8500only..
10‐Oct‐10
10‐210‐00‐1‐X^ 0.005–0.2 0.000856 mgphenol/L Waters Totalrecoverablephenolics;MicroDIST®method;4‐aminoantipyrenemethod;500nm.multi‐rangemethod;NPDESEquivalent(420.1).
3‐Sep‐09
0.05–2.0 0.0013 10‐210‐00‐1‐Y^ 0.5–50 0.4 mgphenol/L Waters MicroDIST®method;.4‐aminoantipyrene
method;500nm.NPDESEquivalent(420.1)13‐May‐08
10‐210‐00‐3‐A 2–200 0.28 µg phenol/L Waters Volatilephenol;4‐aminoantipyrenemethod;500nm.inlinemethod;samplesw/particulatesnotsuitable;ThisPNmanifoldonly
20‐Dec‐06
10‐210‐00‐3A51 QC8500115Vdedicatedchannel 10‐210‐00‐3A52 QC8500220Vdedicatedchannel 10‐210‐00‐3AU1 QC8500115Vdedicatedchannel;upgrade
module
10‐210‐00‐3AU2 QC8500220Vdedicatedchannel;upgrademodule
10‐210‐00‐3‐B 5–500 0.80 µg phenol/L Waters Volatilephenol;4‐aminoantipyrenemethod;500nm.inlinemethod;multi‐rangemethod;samplesw/
27‐Mar‐08
10–1000 2.15 particulatesnotsuitable;.ThisPNmanifoldonly
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage53of68
10‐210‐00‐3B51 QC8500115Vdedicatedchannel 10‐210‐00‐3B52 QC8500220Vdedicatedchannel 10‐210‐00‐3‐C*^ 2–200 0.61 µg phenol/L Waters Volatilephenol;4‐aminoantipyrenemethod;
500nm.inlinemethod;NPDESEquivalent(420.4);samplesw/particulatesnotsuitable.ThisPNmanifoldonly
15‐Oct‐08
10‐210‐00‐3C51*^ QC8500115Vdedicatedchannel 10‐210‐00‐3C52*^ QC8500220Vdedicatedchannel 10‐210‐00‐3‐D 1‐100 0.2 mgphenol/L Waters Volatilephenol;4‐aminoantipyrene
method;500nm.inlinemethod;;samplesw/particulatesnotsuitable;ThisPNmanifoldonly
08‐Mar‐13
10‐210‐00‐3‐D51 QC8500115Vdedicatedchannel 10‐210‐00‐3D52 QC8500220Vdedicatedchannel
Phosphorus(Other)10‐115‐01‐4‐K 10–1000 1.79 µg P/L Waters Suspendedphosphorus;molybdatebased
method;determinationin0.16NHCldigestionsolution.880nm.Requiresastandardheaterandglassstandardandsamplevials.
26‐Feb‐09
10‐115‐01‐4‐L
10–1000
0.83
µg P/L
Waters
Bio‐availablephosphorus;molybdatebasedmethod;880nm.Determinationin0.11NNaOHextracts.Requiresastandardheaterandglassstandardandsamplevials.
26‐Feb‐09
13‐115‐01‐2‐A 1.0–80 0.095 mgP/L Plants TotalPinashedplantmaterial(1MHClmatrix);Vanadatebasedmethod420nm.
6‐Feb‐95
13‐115‐01‐2‐B 20–100 0.2 mgP/L Plants TotalPinashedplantmaterial(1MHClfinalmatrix);Vanadatebasedmethod420nm
17‐Sep‐03
14‐115‐01‐2‐A 10–180 0.2 mgP/L Fertilizers TotalPinsolidfertilizers;Vanadatebasedmethod;HCldigest.420nm.
17‐Sep‐03
14‐115‐01‐2‐B 400–1600 0.2 mgP2O5/L Fertilizers TotalPinsolidfertilizers;Vanadatebasedmethod;420nm.HCl/HNO3digest;AOACmethodforTotalPinfertilizersandphosphaterock.Requiresaninternalsampleloopvalve.
17‐Sep‐03
NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage54of68
14‐115‐01‐2‐C 16.25–260 0.47 mgP2O5/L Fertilizers TotalPinfertilizers;Vanadatebasedmethod;420nm.HCl/HNO3digests;Assoc.ofFloridaPhosphateChemistsmethod.
17‐Jul‐08
14‐115‐01‐2‐E 72–180 0.02 mgP/L Fertilizers TotalPinfertilizers;Vanadatebasedmethod.420nm.
17‐Sep‐03
14‐115‐01‐2‐F 1200–2400 mgP2O5/L Fertilizers TotalPinfertilizers;Vanadatebasedmethod;420nm.digestin6%HCl.Requiresaninternalsampleloopvalve.
17‐Sep‐03
14‐115‐01‐2‐G 30–65 %P2O5 Fertilizers Vanadatebasedmethod;420nm.determinationofP2O5inphosphoricacid.Requiresaninternalsampleloopvalve.
17‐Sep‐03
14‐115‐01‐2‐H 20–600 mgP2O5/L Fertilizers AvailablephosphateVanadatebasedmethod;420nm.basedonAOACMethod#993.31andMagruderMethod41.60;determinationinammoniumcitrateextracts.Requiresastandardheater.
29‐Jan‐10
15‐115‐01‐3‐A 5.0–400 1.2 mgP2O5/L Feeds Availablephosphate;Vanadatebasedmethod;420nm.determinationinammoniumcitrateextracts.Requiresastandardheater.
17‐Sep‐03
15‐115‐01‐3‐B 20–800 1 mgP2O5/L Feeds Availablephosphate;Vanadatebasedmethod;420nm.determinationinammoniumcitrateextracts.420nm.Requiresastandardheater.
28‐Mar‐05
15‐115‐01‐3‐C 20.0‐2,500 5 mgP2O5/L Fertilizers/Feeds
Availablephosphate;Vanadatebasedmethod;420nm.determinationinammoniumcitrateorEDTA‐citrateextracts.BasedonAOACMethod#993.31andMagruderMethod41.60.(pumpspeed20).Requiresanon‐standardheater.
18‐May‐11
21‐115‐01‐1‐A 15–70 0.05 mgH3PO4/dL Beverages Orthophosphate;molybdatebasedmethod;880nm.ColaBeverages.RequiresastandardheaterandInternalSampleloopValve.
17‐Sep‐03
30‐115‐01‐4‐A 0.01 –0.500.32‐1.61
mgP/LµM P/L
Brackish/Seawaters
TotalP;molybdatebasedmethod;880nm.alkalinepersulfatemanualdigests.Requiresastandardheater.
17‐Sep‐03
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage55of68
Phosphorus,Total(AcidicPersulfate)
10‐115‐01‐1‐E# 0.2–10.0 0.1 mgP/L Waters TotalP;manualacidicpersulfatedigests;molybdatebasedmethod;880nm;requiresastandardheater.NPDESAccepted
8‐Nov‐01
10‐115‐01‐1‐F# 0.003–0.2 0.0009 mgP/L Waters TotalP;manualacidicpersulfatedigests;molybdatebasedmethod;880nm;requiresastandardheater.NPDESAccepted
5‐Dec‐07
10‐115‐01‐3‐A^ 0.1–10.0 0.007 mgP/L Waters TotalP;acidicpersulfatedigests;molybdatemethod,880nm.NPDESEquivalent(365.3);followsStandardMethods(4500‐P‐I);samplesw/particulatesnotsuitable.Requiresanin‐linesampleprepmodule.Canalsousefororthophosphorusoverthesamerange.
18‐Nov‐09
10‐115‐01‐3‐B*^ 0.1–4.0 0.01 mgP/L Waters TotalP;acidicpersulfatedigests;molybdatemethod;880nm;NPDESEquivalent(365.3);samplesw/particulatesnotsuitableRequiresanin‐linesampleprepmodule.Canalsousefororthophosphorusoverthesamerange.
18‐Nov‐09
10‐115‐01‐3‐C*^ 0.05–1.0 0.0011 mgP/L Waters TotalP;acidicpersulfatedigests;molybdatemethod;880nm.NPDESEquivalent(365.3);samplesw/particulatesnotsuitableRequiresanin‐linesampleprepmodule.Canalsousefororthophosphorusoverthesamerange.
18‐Nov‐09
10‐115‐01‐3‐E^ 10–500 1.4 µg P/L Waters TotalP;acidicpersulfatedigests;molybdatemethod;880nm.NPDESEquivalent(365.3);samplesw/particulatesnotsuitableRequiresanin‐linesampleprepmoduleandstandardheater.Canalsousefororthophosphorusoverthesamerange.
5‐Jul‐07
10‐115‐01‐3‐F^ 2–100 0.42 µg P/L Waters TotalP;acidicpersulfatedigests;molybdatemethod;880nmmethod;NPDESEquivalent(365.3);samplesw/particulatesnotsuitableRequiresanin‐linesampleprepmoduleandnon‐standardheater.
13‐Nov‐06
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage56of68
10‐115‐01‐4‐B 0.005–1.00.25‐10
0.00060.024
mgP/L Waters TotalP;manualpersulfatedigests;Molybdatemethod;880nm.Dualdigest‐totalnitrogencanbemeasuredfromsamedigest(10‐107‐04‐4‐B);Requiresablockdigesterandglasswareforthedigestion;glasscalibrationvials.Requiresastandardheater.Multirangemethod.
22‐Jun‐07
10‐115‐01‐4‐C 0.01‐1.0 0.002 mgP/L Waters Singlestep,off‐line(autoclave)digestionmethod.Molybdatemethod.880nm.TNcanbemeasuredfromthesamedigestate.(10‐107‐04‐4‐C)Requiresastandardheater.
26‐Jun‐13
10‐115‐01‐4‐I^ 0.2–20.0 0.026 mgP/L Waters TotalP;manualpersulfatedigests;Molybdatemethod;880nm.UltraHighThroughputmethod(120samples/hour)NPDESEquivalent(365.3)Requiresastandardheater.
11‐Nov‐08
10‐115‐01‐4‐J* 0.2–10 0.0033 mgP/L Waters TotalP;manualpersulfatedigests;Molybdatechemistry;880nm.UltraHighThroughputmethod(>125samples/hr)Requiresastandardheater.
27‐Aug‐07
10‐115‐01‐4‐S^ 0.2–10 0.002 mgP/L Waters TotalP;manualpotassiumpersulfatemanualdigests;Molybdatechemistry;880nm.low‐flowmethod;NPDESEquivalent(365.3).Requiresastandardheater.
27‐Aug‐03
10‐115‐01‐4‐U^ 0.01–0.2 0.0008 mgP/L Waters TotalP;manualpersulfatedigests;low‐flowmethod;Molybdatechemistry;880nm.NPDESEquivalent(365.3).glasscalibrationvials.Requiresastandardheater.
28‐Aug‐03
18‐115‐01‐3‐B 12.5–375 2.5 mgP/L Aqueousformulations
TotalP;In‐linemethod,molybdatebasedmethod;880nm.samplesw/particulatesnotsuitable.Requiresanin‐linemoduleandstandardheater.
5‐Jul‐07
31‐115‐01‐3‐D 0.050–1.01.63‐32.36
0.002 mgP/LµM P/L
Brackish/Seawaters
TotalP;molybdatemethod;880nm.inlinepersulfatedigestion;samplesw/particulatesnotsuitable.glasscalibrationvials.Requiresanin‐linesampleprepmodule.
5‐Jul‐07
31‐115‐01‐3‐F 2‐1000.065‐3.23
0.59 µg P/LµM P/L
Brackish/Seawaters
TotalP;molybdatebasedmethod;880nm,inlinepersulfatedigestion;samplesw/particulatesnotsuitableRequiresglassstandardandsamplevialsanin‐linesampleprepmodule, andnon‐standardheater.
13‐Oct‐08
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage57of68
31‐115‐01‐4‐A^ 12.5–4000.40‐12.9
1.66 µg P/LµM P/L
Brackish/Seawaters
TotalP;molybdatebasedmethod;880nm.manualpersulfatedigestion;Requiresastandardheaterandautoclaveforthedigestion.NPDESEquivalent(365.3)
17‐Sep‐03
31‐115‐01‐4‐B 0.005–1.00.16‐32.23
0.0038 mgP/LµM P/L
Brackish/Seawaters
TotalP;molybdatebasedmethod;880nm,manualpersulfatedigestion;low‐flowmethod;dual‐
12‐Dec‐09
OP:pP:
0.25–100.008‐0.3235–10000.16‐32.230.25–100.008‐0.3230.1‐5.0
0.03580.70.0130.015
mgP/LmMP/Lµg P/LmgP/LmgP/L
Digest.TotalNCanbemeasuredsimultaneouslyusing31‐107‐04‐4‐B;multi‐rangemethodCanalsoanalyzeparticulatephosphorusandorthophosphoruswiththismethod.Requiresastandardheaterandblockdigesterforthedigestion.
Potassium SeealsoICsection
10‐119‐03‐1‐A 2.0–100 0.33 mgK/L Waters Flameemissionmethod.FlameA.A.anddirectvoltagemodulerequired.
2‐Aug‐01
12‐119‐03‐1‐A 0.20–10.0 0.01 mgK/L Soilextracts Flameemissionmethod.AmmoniumacetateextractsofsoilsFlameA.A.anddirectvoltagemodulerequired.
17‐Sep‐03
12‐119‐03‐1‐B 1.0–50.0 0.2 mgK2O/L Soilextracts Flameemissionmethod.CalciumLactateextractsofsoils.FlameA.A.anddirectvoltagemodulerequired.
17‐Sep‐03
12‐119‐03‐1‐C 1.0–20.0 0.1 mgK2O/L Soilextracts Flameemissionmethod.CalciumAcetateextractsofsoils.FlameA.A.anddirectvoltagemodulerequired.
17‐Sep‐03
12‐119‐03‐1‐D 5–200 0.126 mgK/L Soilextracts Flameemissionmethod;determinationinMorgan’ssoilextracts.FlameA.A.anddirectvoltagemodulerequired.
17‐Sep‐03
13‐119‐03‐1‐B 100–400 0.14 mgK/L Plantextracts Flameemissionmethod.Digestedash.FlameA.A.anddirectvoltagemodulerequired.
17‐Sep‐03
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage58of68
14‐119‐03‐1‐A 80–320 gK2O/g Fertilizers Flameemissionmethod.Dilutedliquidfertilizer.FlameA.A.anddirectvoltagemodulerequired.
17‐Sep‐03
14‐119‐03‐1‐B 5–250 0.4 mgK/L Fertilizers Flameemissionmethod.HCldigestsofsolidfertilizer.Inertprobe,FlameA.A.anddirectvoltagemodulerequired.
17‐Sep‐03
14‐119‐03‐1‐C 100–250 mgK/L Fertilizers Flameemissionmethod.DilutedfertilizersFlameA.A.anddirectvoltagemodulerequired.
17‐Sep‐03
14‐119‐03‐1‐D 20–450 1.02 mgK2O/L Fertilizers Flameemissionmethod;K2Oinammoniumcitrateoroxalateextractsoffertilizer.Inertprobe,FlameA.A.anddirectvoltagemodulerequired.
24‐Sep‐07
ReducingSubstances26‐246‐00‐1‐A 200–2500 20 mgglucose/L Tobacco
ExtractsAsglucose.Ferricyanidemethod,420nm.5%Aceticacidextract. BaseduponISOmethod15153:2003(E). MaynotgiveidenticalresultstoISO15154(Whichuseswaterextracts).420nm.Requiresastandardheater.
18‐May‐10
ReducingSugars26‐201‐01‐2‐A 20–2500 6.5 mg
glucose/LTobaccoExtracts
Ferricyanidemethod,420nm.Thismethodissensitivetoreducingsubstancesotherthansugarsthatarepresentintobacco.Pre‐valvedialysistoexcludecolor.Requiresastandardheater.
18‐May‐10
Silicate 10‐114‐27‐1‐A# 0.2–20 0.04 mgSiO2/L Waters Molybdatereactivemethod;820nm.ANSA
reductionNPDESAccepted13‐Sep‐00
10‐114‐27‐1‐B^ 10–100 0.58 µg SiO2/L Waters Molybdatereactivemethod;Stannouschloridereductant.820nm.Plasticsampleandstandardvialsandstandardheaterrequired.UltraHighThroughputmethod(>120samples/hr);NPDESEquivalent;followsStandardMethods(4500‐SiO2‐C)
30‐Oct‐07
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage59of68
10‐114‐27‐1‐C^ 2.5–100 0.61 µg SiO2/L Waters Molybdatereactivemethod;Stannouschloridereductant.820nm.Plasticsampleandstandardvialsandstandardheaterrequired.2cmdetectormethod;QC8500only;NPDESEquivalent;followsStandardMethods(4500‐SiO2‐C)
17‐Feb‐09
31‐114‐27‐1‐A^ 1,202‐6,00920–100
0.2
µgSiO2/LµM SiO2/L
Brackish/Seawaters
Molybdatereactivemethod;Stannouschloridereductant.820nm.Requiresastandardheater.NPDESEquivalent(USGSI‐2700‐85)
17‐Sep‐03
31‐114‐27‐1‐B^ 75.0‐300.451.25–5.0
0.01 µgSiO2/LµM SiO2/L
Brackish/Seawaters
Molybdatereactivemethod;Stannouschloridereductant.820nm.Requiresastandardheaterandplasticsamplevials.NPDESEquivalent(USGSI‐2700‐85)
17‐Sep‐03
31‐114‐27‐1‐D^ 10–17000.166‐28.29
1.43 µg SiO2/LµM SiO2/L
Brackish/Seawaters
Molybdatereactivemethod;Stannouschloridereductant.820nm.Requiresastandardheater.NPDESEquivalent(USGSI‐2700‐85)
17‐Sep‐03
31‐114‐27‐1‐E^ 2.5–1000.042‐1.66
0.606 µg SiO2/LµM SiO2/L
Brackish/Seawaters
Molybdatereactivemethod;820nm,2cmdetectormethod;QC8500only;Requiresastandardheaterandplasticsampleandstandardvials.NPDESEquivalent(USGSI‐2700‐85)
28‐Feb‐08
31‐114‐27‐1‐F^ 0.5–300.0083‐0.499
0.050.00083
mgSiO2/LmMSiO2/L
Brackish/Seawaters
Molybdatereactivemethod;Stannouschloridereductant820nm,NPDESEquivalent.(USGSI‐2700‐85).Requiresastandardheater.
23‐Oct‐08
31‐114‐27‐2‐A 60.09‐60091‐100
0.60.1
µg SiO2/LµM SiO2/L
Brackish/Seawaters
Molybdatereactivemethod;Ascorbicacidreductant820nm.NPDESEquivalent(366.0)Requiresastandardheaterandplasticsampleandstandardvials.
23‐Nov‐10
Sodium SeealsoICsection
10‐111‐32‐1‐A^ 5.0–300 1.2 mgNa/L Waters Flameemissionmethod;NPDESEquivalent;followsStandardMethods(3500Na‐B)FlameA.A.anddirectvoltagemodulerequired.
27‐Aug‐03
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage60of68
SorbicAcid
26‐228‐38‐1‐A 2.0–10.0 0.18 mgsorbicacid/L
Tobaccoextracts
2‐thiobarbituricacid 530nm.Dialysismethod.0.1NH2SO4extractant.Requiresastandardheater.
17‐Sep‐03
Sulfate SeealsoICsection10‐116‐10‐1‐A 3.0–300 0.95 mgSO4
2‐/L Waters Turbidimetricmethod;420nm. 28‐Aug‐0310‐116‐10‐1‐C 0.5–10.0 0.2 mgSO4
2‐/L Waters Turbidimetricmethod;420nm 28‐Aug‐0310‐116‐10‐1‐E 10–100 0.6 mgSO4
2‐/L Waters Turbidimetricmethod;420nm 29‐Aug‐0310‐116‐10‐1‐G 50–2000 mgSO4
2‐/L Waters Turbidimetricmethod;low‐flowmethod;420nm. 17‐May‐08
10‐116‐10‐2‐A^ 5.0–100 1.8 mgSO42‐/L Waters Methylthymolbluemethod;460nm.NPDES
Equivalent(375.2);followsStandardMethods(4500‐SO4‐G)
28‐Aug‐03
10‐116‐10‐2‐B#^
50–300 7.2 mgSO42‐/L Waters Methylthymolbluemethod;460nm.NPDES
Equivalent/NPDWRAccepted28‐Aug‐03
10‐116‐10‐2‐E^ 2–40 0.36 mgSO42‐/L Waters Methylthymolbluemethod;460nm.NPDES
Equivalent(375.2)24‐Apr‐08
10‐116‐10‐3‐A^ 10–300 3.0 mgSO42‐/L Waters Turbidimetricmethod;420nm.basedonASTM
method.NPDESEquivalent18‐Mar‐10
12‐116‐10‐1‐D 1–20 0.67 mgSO42‐/L Soilextracts Turbidimetricmethod;420nm.determinationin
8Mmonobasiccalciumphosphatesoilextracts.16‐Sep‐03
14‐116‐10‐1‐A 10–360 mgSO42‐/L Fertilizers Turbidimetricmethod;420nm.HCldigest 16‐Sep‐03
25‐116‐10‐3‐B 1‐2512.5‐150
0.442.5
gNa2SO4/L Brine Turbidimetricmethod.420nm.MultiRangemethod.Veryhighrangesamples(g/L).Requiresa1mmflowcell
08‐May‐12
25‐116‐10‐3‐C 1‐25 0.6 gNa2SO4/L 50%Caustic Turbidimetricmethod.420nm.Samplesarediluted1:2(to25%NaOH)priortotheanalysis.
08‐May‐12
29‐116‐10‐3‐A 12.5‐500 4.0 mgSO42‐/L Brines.
Produced/Fracturingwater
Turbidimetricmethod.420nm. 03‐Mar‐11
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage61of68
Sulfide10‐116‐29‐1‐A^ 0.02 –2.0 0.005 mgS/L Waters Methylenebluemethod;.660nm.MicroDIST®
method;0.25MNaOHfinalmatrixRequiresaMicroDistblockandtubesandstandardheater.Distillationrequired;NPDESEquivalent;followsStandardMethods(4500‐S‐I)
24‐May‐08
10‐116‐29‐1‐C^ 25–100 0.58 mgS/L Waters Methylenebluemethod;.660nm.0.25MNaOHdistillationrequired;RequiresMicroDistblockandtubesandstandardheater.Distillationrequired;NPDESEquivalent;followsStandardMethods(4500‐S‐I)NPDESEquivalent;followsStandardMethods(4500‐S‐I)
24‐May‐08
10‐116‐29‐1‐D^ 0.01‐1.0 0.001 mgS/L Waters Methylenebluemethod.660nm.SamplespreservedwithNaOH(0.025M)andzincacetate.Nodistillation.Requiresastandardheater.
1‐Dec‐10
10‐116‐29‐1‐X 0.02–2.00 0.005 mgS/L Waters Methylenebluemethod;660nm.MicroDIST®method;multi‐rangemethod
23‐Mar‐10
1–100 0.023 RequiresaMicroDistblockandtubesandstandardheaterifDistillationrequired(Musthavefinalmatrixof0.25MNaOH)
10‐116‐29‐3‐A 0.01–2.0 0.006 mgS/L Waters Inlinedistillationmethod;660nm.Requirestwodedicatedchannelswithonestandardandonenon‐standardheater;samplesw/particulatesnotsuitablemanifoldonly
4‐Oct‐07
10‐116‐29‐3A51 Dedicatedchannels;QC8500115V 10‐116‐29‐3A52 Dedicatedchannels;QC8500220V 10‐116‐29‐3‐B 1.0–10.0 0.2 mgS/L Waters Inlinedistillationmethod;660nm.requirestwo
dedicatedchannels;Requirestwodedicatedchannelswithonestandardandonenon‐standardheatersamplesw/particulatesnotsuitable;manifoldonly
5‐Jul‐07
10‐116‐29‐3B51 Dedicatedchannels;QC8500115V 10‐116‐29‐3B52 Dedicatedchannels;QC8500220V
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage62of68
12‐116‐29‐3‐A 0.01–2.0 0.008 mgS/L Soilextracts Inlinedistillationmethod;660nm.determinationin1MNaOHsoilextracts;Requirestwodedicatedchannelswithonestandardandonenon‐standardheaterSoilextractsmustbefilteredpriortoanalysis(samplesw/particulatesnotsuitable).
20‐Aug‐08
Sulfite10‐116‐11‐1‐A 0.25–2.0 0.03 mgSO3
2‐/L Waters Pararosanalinemethod;560nm.UltraHighThroughputmethod.Requiresastandardheater.
4‐Apr‐08
21‐116‐11‐2‐D 0.5–30 0.25 mgSO32‐/L Beverages Pararosanalinemethod560nm.Determinationin
beersandwines.Requiresastandardheater.16‐Sep‐03
SulfurDioxide24‐116‐42‐1‐A 0.08–2.4 0.008 mgSO2/L Airsamplefilter
extractsPararosanalinemethod560nm.Determinationofairextractsin0.04Mpotassiumtetrachloromercurate(TCM)solutions.Requiresastandardheater.
18‐Sep‐03
Surfactants(MBAS)10‐306‐00‐1‐C 0.025–2.0
0.010–1.0
0.0040.0056
mg/LasLASmg/LasSDS
Waters Methylenebluemethod;650nm.dualextractionmethod.SDSorLAS.Glasscalibrationandstandardvialsmustbeused.
19‐Dec‐08
10‐306‐00‐1‐D^ 0.010–1.0 0.0024 mgSDS/L Waters Methylenebluemethod;650nm.singleextractionmethod;NPDESEquivalent;followsStandardMethods(5540‐C).SDS.Glasscalibrationandstandardvialsmustbeused.
25‐Mar‐08
10‐306‐00‐1‐E 0.1 –20.0 0.05 mgSDS/L Waters Methylenebluemethod;650nm.dualextractionmethod(SDSonly)Glasscalibrationandstandardsvialsmustbeused.
29‐Sep‐05
Thiocyanate10‐229‐00‐1‐A 0.1–2.0 0.02 mgSCN‐/L Waters Ferricthiocyanatemethod.460nm. 16‐Sep‐0312‐229‐00‐1‐A 0.05–2.0 0.008 mgSCN‐/L Soilextracts Ferricthiocyanatemethod.460nm
Determinationin1MNaOHsoilextracts.Extractsmustbefilteredpriortoanalysis.
1‐Sep‐08
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage63of68
Urea10‐206‐00‐1‐A 0.1–20 0.007 mgN/Las
UreaWaters Diacetylmonoxime/thiosemicarbazide.530nm.
Cannotberunsimultaneouslyw/othermethodsasuses0.84MNaClwashsolution.Requiresnon‐standardheaterand60positionsampleracks.
17‐Apr‐08
10‐206‐00‐1‐B 15–500 3.3 µg N/LasUrea
Waters Diacetylmonoxime/thiosemicarbazide.530nm.Cannotberunsimultaneouslyw/othermethodsasuses0.84MNaClwashsolution.Requiresnon‐standardheaterand60positionsampleracks.
15‐Apr‐08
12‐206‐00‐1‐A 0.1‐20 0.027 mgN/LasUrea
SoilExtracts Diacetylmonoxime/thiosemicarbazide.530nm.2MKCl/5mgPMAextractsofsoil..Requiresnon‐standardheater
15‐Mar‐13
14‐206‐00‐2‐A 75–600 1.0 mgN/LasUrea
Fertilizers Sodiumsalicylate‐basedmethod.660nm.Ureaseenzymaticmethod;mustberunw/ammoniamethod14‐107‐06‐2‐CRequiresastandardheaterand1mmpathlengthflowcell.
16‐Sep‐03
14‐206‐00‐3‐B 4500–18000 NA mgN/LasUrea
Fertilizers DMABmethod.440nm. 16‐Sep‐03
14‐206‐00‐3‐C 60–600 0.97 mgN/LasUrea
Fertilizers DMABmethod.440nm 16‐Sep‐03
14‐206‐00‐3‐D 60–150 0.07 mgN/LasUrea
Fertilizers DMABmethod440nm. 16‐Sep‐03
31‐206‐00‐1‐A 10–4000.714‐28.57
2.9 µg N/LasUreaµM N/LasUrea
Brackish/Seawaters
Diacetylmonoxime/thiosemicarbazidemethod.530nm.Requiresnon‐standardheaterand60positionsampleracks.
16‐Sep‐03
31‐206‐00‐1‐B 0.025–5.001.79‐357.14
0.004 mgN/LasUreaµM N/LasUrea
Brackish/Seawaters
Multi‐rangemethod.Diacetylmonoxime/thiosemicarbazide.530nm.Requiresnon‐standardheaterand60positionsampleracks.
7‐Dec‐07
0.2 –200.0143‐1.429
0.026 mgN/LasUreamMN/LasUrea
NEW
MethodNo Range MDL Units Matrix Comments RevDate
^EquivalentundertheMUR(NPDES)
#USEPAAcceptedPage64of68
Zinc
10‐130‐18‐2‐A 0.1–5.0 0.007 mgZn/L Waters Zinconmethod.620nm. 16‐Sep‐0312‐130‐18‐2‐A 1.25–5.0 0.004 mgZn/L Soilextracts Zinconmethod;620nm.3low‐flowmethod.
0.1MHCl.17‐Sep‐03
For Technical Assistance, Price Information and Ordering
In the U.S.A.Call toll-free (800) 247-7613.
Outside the U.S.A.Contact the LACHAT office or distributor serving you.
On the Worldwide Webwww.lachatinstruments.com
E-mail for Supportsupport@lachatinstruments.com
E-mail for Salessales@lachatinstruments.com
LITL022 Rev 7J13 Printed in U.S.A.
©Hach Company 2013. All rights reserved.
World HeadquartersP.O. Box 608
Loveland, CO 80539-0608Telephone: (970) 669-3050
Fax: (970) 461-3915
Local Distributor: