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EPS1232323231231.1500902.1001243.100124、EPS。NH+4-NNO-2-N0.140.15g/gVSS·d80.1%97.0%TN65.8%N2O0.92mg/LTN2.52%pH。EPSEPS226.9mg/gVSSEPS58.9%EPSTB-EPSEPS77.1%。TB-EPS165.546.1AU/mgC·L。。PCR-cloneX703A1000-4602201611-0035-0551478013QAK201502E-mailpyz@bjut.edu.cnNitrogenRemovalPerformanceandEPSCharacteristicsofAnammoxGranularSludgewithHighActivityWANGShan-yun1JIAFang-xu23JINPeng-fei23GAOMeng-jia23MABin23PENGYong-zhen1231.StateKeyLaboratoryofUrbanWaterResourceandEnvironmentHarbinInstituteofTechnologyHarbin150090China2.KeyLaboratoryofBeijingforWaterQualityScienceandWaterEnvironmentRecoveryEngineeringBeijingUniversityofTechnologyBeijing100124China3.EngineeringResearchCenterofBeijingBeijingUniversityofTechnologyBeijing100124ChinaAbstractThenitrogenremovalperformanceEPScharacteristicsandthree-dimensionalfluores-cencespectrumofAnammoxgranularsludgeforthetreatmentofwastewaterwithlowammoniaconcentra-tionwereinvestigated.TheresultsshowedthatAnammoxgranularsludgeexhibitedhighactivityandtheaveragedegradationratesofNH+4-NandNO-2-Nwere0.14g/gVSS·dand0.15g/gVSS·dwithremovalratesof80.1%and97.0%respectively.TheremovalrateofTNwas65.8%.Inthis·53·321120166CHINAWATER&WASTEWATERVol.32No.11Jun.2016processN2Owasproducedwithshort-timeaccumulationandthepeakconcentrationwas0.92mg/Laccountingfor2.52%ofTNconversionrate.InadditionpHvaluecouldindicatetheendofAnammoxreaction.TheanalysisofdifferentlayersofEPScomponentsshowedthatprotein226.9mg/gVSSwasthemaincomponentinallEPSlayersaccountingfor58.9%ofthetotalEPS.TB-EPSaccountedfor77.1%ofthetotalEPS.Three-dimensionalfluorescencespectrumanalysisshowedthattheproteininEPSwasmainlytyrosineandtryptophanwiththefluorescenceintensityof165.5AU/mgC·Land46.1AU/mgC·Lrespectively.TheseresultscanprovidetheoreticalbasisforthefuturestudyonAnammoxgranularsludge.KeywordsAnammoxgranularsludgePCR-clonelayeredextracellularpolymericsub-stancesEPSthree-dimensionalfluorescencespectrumAnammoxN2O12。13。34。56。EPS。EPSSlime、LB-EPSTB-EPS7。ChenTang56EPS。EPSEPS。UASB、、N2OpHEPS。11.1UASB。3.8L19∶1。30±1℃pH。NH+4-NNO-2-N31.6±3.731.2±2.9mg/L。1.21000mLSBR1。2~31000mL95%Ar+5%CO215minNH+4-NNO-2-N30mg/L8。30℃30minNH+4-N、NO-2-NNO-3-N5mL。N2OpH。1SBRFig.1SchematicdiagramofSBRsystemforcharacteristicsofN-removal·63·3211.watergasheat.com1.3NH+4-N、NO-2-NNO-3-N。VSS、COD9。TIC、TOC、TC0.45μmTOC。N2OUnisenseN2O。pHWTW。1.41.4.17。1.4.2EPSFolin-DNADNA10。1.4.3EPSFP-650011。200~400nmEx290~550nmEm51nm。TOC10mg/L。22.12。2Fig.2Characteristicsofhigh-NremovalbyAnammoxgranulessludgeMLVSS1356mg/LNH+4-NNO-2-N0.140.15g/gVSS·d80.1%97.0%NO-3-N0.07g/gVSS·dTN26.9%TN0.24g/gVSS·d65.8%。12。N2O。N2O150min0.92mg/L0.006g/gVSS·dTN2.52%N2O90min0.010g/gVSS·d。Ma3UASBN2O0.006%。-N2O5.1%~6.6%13。N2O14N2ON2。pH。。2.2EPS、DNAEPSTB-EPS296.8mg/gVSSEPS77.1%LB-EPSSlime66.122.1mg/gVSSEPS17.2%5.7%3。3EPSDNA、Fig.3ConcentrationoforganicsubstancesalongWASflocslayers3DEEMspectraofEPSfromdifferentlayersEPSSlime、LB-EPS、TB-EPS90.2%、90.6%49.5%。TB-EPS46%LB-EPS4.9%Slime。TB-EPSLB-EPS·73·.watergasheat.comEPS3211/0.930.05。DNAEPS4%。、DNA226.9、140.018.2mg/gVSSEPS58.9%、36.4%4.7%。EPSEPS56。EPSCa2+、Mg2+、K+15。4.7%2%~15%16DNAEPS。EPSPelletEPS38.5%。TB-EPS29.7%。TB-EPSPellet10。Li7SlimeLB-EPS。2.3EPSEPS4。4EPSFig.43DEEMspectraofEPSfromdifferentlayersEPS。EPSPeakⅠEx/Em=200~250/300~350nmPeakⅡEx/Em=260~290/300~350nmEPS。SlimePeakⅢEx/Em=200~250/380~450nmPeakⅣEx/Em=240~300/420~470nmEPS。SlimeLB-EPSTB-EPS、EPS。SlimeEPS。EPS。EPS。TB-EPS165.5AU/mgC·L46.1AU/mgC·LSlimeLB-EPS10AU/mgC·L。EPSEPSEPSTB-EPS。15。、。3①·83·3211.watergasheat.comNH+4-NNO-2-N0.140.15g/gVSS·d80.1%97.0%TN65.8%N2O0.92mg/LTN2.52%pH。②EPSEPS226.9mg/gVSSEPS58.9%EPSTB-EPSEPS77.1%。③EPSTB-EPS165.546.1AU/mgC·L。1KartalBvanNiftrikLKeltjensJTetal.Anammox—growthphysiologycellbiologyandmetabolismJ.AdvMicrobPhysiol201260211-262.2KuenenJG.Anammoxbacteriafromdiscoverytoappli-cationJ.NatRevMicrobiol20086320-326.3MaBWangSCaoSetal.BiologicalnitrogenremovalfromsewageviaanammoxRecentadvancesJ.Biore-sourTechnol2016200981-990.4LacknerSGilbertEMVlaeminckSEetal.Full-scalepartialnitritation/anammoxexperiences—AnapplicationsurveyJ.WaterRes201455292-303.5ChenTTZhengPShenLD.Growthandmetabolismcharacteristicsofanaerobicammonium-oxidizingbacteriaaggregatesJ.ApplMicrobiolBiotechnol201397125575-5583.6TangCJZhengPWangCHetal.Performanceofhigh-loadedANAMMOXUASBreactorscontaininggran-ularsludgeJ.WaterRes2011451135-144.7LiXLPengYZRenNQetal.EffectoftemperatureonshortchainfattyacidsSCFAsaccumulationandmicrobiologicaltransformationinsludgealkalinefermen-tationwithCaOH2adjustmentJ.WaterRes20146134-45.8VandeGraafAAdeBruijnPRobtersonLAetal.Autotrophicgrowthofanaerobicammonium-oxidizingmi-cro-organismsinafluidizedbedreactorJ.Microbiolo-gy199614282187-2196.9.4M.2002.10.EPSJ.201233103522-3528.11KorakJADotsonADSummersRSetal.Criticala-nalysisofcommonlyusedfluorescencemetricstocharac-terizedissolvedorganicmatterJ.WaterRes2014491327-338.12.J.201434123078-3085.13DeslooverJDeClippeleirHBoeckxPetal.Floc-basedsequentialpartialnitritationandanammoxatfullscalewithcontrastingN2OemissionsJ.WaterRes20114592811-2821.14.N2OJ.201466114653-466