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36620166ActaScientiaeCircumstantiaeVol.36No.6Jun.2016No.2014ZB04No.21277052SupportedbytheFundoftheStateKeyLaboratoryofSubtropicalBuildingScienceNo.2014ZB04andtheNationalNaturalScienceFoundationofChinaNo.212770521989—E-mail18814116869@163.com*E-mailfesqzhou@scut.edu.cnBiographyLUOJingjing1989—femaleE-mail18814116869@163.com*CorrespondingauthorE-mailfesqzhou@scut.edu.cnDOI10.13671/j.hjkxxb.2015.0731.2016.J.3661955-1961LuoJJZhouSQXuMYetal.2016.Electricitygenerationandrecoveryofnitrogenandphosphorusinthesingle-chambermicrobialfuelcellJ.ActaScientiaeCircumstantiae3661955-1961112*111.5100062.5106412015-07-102015-10-292015-11-04MicrobialFuelCellMFC、.1000Ω371mV301.6mW·m-22.4A·m-2200Ω.4mmol·L-1.72h6hCOD、TNTP93.3%、19.7%44.8%.TNTP79.6%95.2%.MFC.0253-2468201606-1955-07X703AElectricitygenerationandrecoveryofnitrogenandphosphorusinthesingle-chambermicrobialfuelcellLUOJingjing1ZHOUShaoqi12*XUMingyi1TAOQinqin11.SchoolofEnvironmentandEnergySouthChinaUniverisityofTechnologyGuangzhou5100062.StateKeyLaboratoryofSubtropicalBuildingScienceSouthChinaUniverisityofTechnologyGuangzhou510641Received10July2015receivedinrevisedform29October2015accepted4November2015AbstractAnair-cathodesingle-chambermicrobialfuelcellMFCwasinvestigatedtostudyitspowergenerationandtheremovaloforganicmattersnitrogenandphosphorusinthesimulatedwastewater.Withanexternalresistorof1000ΩthemaximumvoltageoftheMFCreached371mV.Besidesitsmaximumpowerdensityandmaximumcurrentdensitywere301.6mW·m-2and2.4A·m-2.TheinternalresistanceoftheMFCwasabout200Ωfromthetest.TheMFCgeneratedelectricitywellwhentheconcentrationoftheNH4Clwas4mmol·L-1.Alsothedegradationrateofpollutantswasmuchbetter.ItwasconcludedthattheoptimisticoperationtimeoftheMFCwas72handthebestaerationtimeoftheanolytewas6h.Thedegradationefficiencyofchemicaloxygendemandtotalnitrogenandtotalphosphorusoftheanodechambereffluentare93.3%19.7%and44.8%.Aftertheanolytewasaeratedtheremovalefficiencyofthetotalphosphorusandtotalnitrogenincreasedto79.6%and95.2%comparedwiththeanodechamberinfluent.MoreoverthroughscanningelectronmicroscopecapableofenergydispersivespectroscopySEM-EDSitwasobservedthatthesphericalbacteriaaccountedforthemainpartofthebacteriaintheanodechamber.AndtheneedlecrystalsofstruviteonthecathodeelectrodesurfaceoftheMFCwerealsoobserved.Keywordsnitrogensourcephosphorusremovalelectricityproductionsimulatedwastewater1Introduction.、、.Cordelletal.20093650~100.Shuetal.2006100m31kg6.3tP2O5..MFC.2013MFC2MFC.MFC2013MFC119.6mVCOD82.4%MFC40d85%MFC.2013182.5mV10dCOD96.5%16d93.5%96.7%MFC.Ichihashi2012MFCCOD.Zang2012MFC.MFC.MFCN、PCOD、NH4ClMFCMFC.2Materialsandmethods2.1MFCMFCLiu20041a3cm4cm28mL.MFC2h.MFC7cm230%PTFE460%PTFE0.5mg·cm-2.1000Ω.MFC1b.1abFig.1SchematicofsinglechamberMFCaandaerationdeviceb2.2.1∶1.5.96g·L-1NaHCO3、1.00g·L-1NaC2H3O2、0.54g·L-1KH2PO40.21g·L-1NH4ClpH7.0.30±1℃.2.3MFCKeithleyM27002002pHpHPHS-25CODTPNO-3-N、NO-2-NNH+4-N、N-1--3.UV2800Merlin.659163Resultsandanalysis3.1MFC10dMFC72h50mV371mV.MFC0~9999Ω50~5000Ω.II=U/RPP=U×I/AUVRΩAm2.2MFC.301.6mW·m-2MFC200Ω.2MFC、Fig.2SchematicofelectricityproductioncellpolarizationcurvesandpowerdensitycurvesoftheMFC3.2MFC.3a、3b.MFC6h3c、3dMFC.、3e3f.Mg2++NH+4+PO3-4+6H2O=MgNH4PO4·6H2O..Doyle2002pHpHMgNH4PO4·6H2OpH8.3gCusick20123gMg、PNMgNH4PO4·6H2O.7591363Fig.3SEM-EDSimages3.3MFC4mmol·L-1NH4Cl.1、2、48mmol·L-1NH4ClMFCMFC310d4.4NH4ClMFCNH4Cl326、350、371307mV.NH4ClMFCNH4Cl2011.NH4Cl4mmol·L-1371mV.201250mg·L-1.NH4Cl8mmol·L-1112mg·L-1MFC307mV.859164NH4ClFig.4EffectonpowergenerationwithdifferentNH4Clconcentration3.4MFCCOD3.4.1MFCCOD30℃MFC6dCODCOD5.MFC72hCOD79.9%.MFC50mVCOD66mg·L-1MFC7mVCOD93.3%2014MFCCOD100mg·L-1.5MFCCODFig.5SchematicoftheconcentrationofCODalongwiththeoperationtimeoftheMFC3.4.2MFC4mmol·L-1NH4Cl11TP、NO-3-N、NO-2-NNH+4-N.196hTN20%MFCNH+4-N.TP72h45%96h20mVTP35.4%..1MFCTable1Effectontheremovalofnitrogenandphosphoruswithdifferentoperationtimet/hNO-3-N/mg·L-1NO-2-N/mg·L-1NH+4-N/mg·L-1TNTP/mg·L-1TP240.02≈0.0046.916.0%115.27.1%480.300.114911.8%100.419.0%720.810.2746.612.1%68.444.8%961.031.5643.919.7%80.0935.4%3.5MFCMFC72h50mVMFCpH7.3TNTP50%.TNTPMFCDO2.8~3.5mg·L-18h1hTPpH6.9591366TPpHFig.6DiagramofthechangeofTPnitrogenandpH6hTN79.6%TP95.2%.6pH9.17.NO-3-NNO-2-NNH+4-N38mg·L-12mg·L-1TP65.8mg·L-15.9mg·L-1.6hTP.DO2011..NH+4-N2012NH+4-N.6h.MFC6h.4ConclusionsMFC4mmol·L-1.MFC72h.MFCCOD19.7%.95.2%79.6%.MFC.ReferencesCordellDDrangertJOWhiteS.2009.ThestoryofphosphorusGlobalfoodsecurityandfoodforthoughtJ.GlobalEnvironmentalChange192292-305CusickRDLoganBE.2012.PhosphaterecoveryasstruvitewithinasinglechambermicrobialelectrolysiscellJ.BioresourceTechnology1072110-115DoyleJDParsonsSA.2002.StruviteformationcontrolandrecoveryJ.WaterResearch36163925-3940IchihashiOHirookaK.2012.RemovalandrecoveryofphosphorusasstruvitefromswinewastewaterusingmicrobialfuelcellJ.BioresourceTechnology114303-307LiuHLoganBE.2004.Electricitygenerationusinganair-cathodesinglechambermicrobialfuelcellinthepresenceandabsenceofaprotonexchangemembraneJ.EnvironmentalScience&Technology38144040-4046.2011.DOJ.43442-46.2012.J.351111-114.2013.CODJ