新型纳米材料在传感器中的运用结论与参考文献,化工论文

新型纳米材料在传感器中的运用结论与以下为参考文献,化工论文本篇论文目录导航：【题目】【第一章】【第二章】【第三章】【第四章】【结论/以下为参考文献】新型纳米材料在传感器中的运用结论与以下为参考文献结论采用纳米材料构建传感界面，是当下电化学传感领域的研究热门之一。纳米材料具有优良的导电性、良好的电催化性能、大的比外表积、较强的吸附能力等优点，当用于修饰电极时，能够很好地改善电极界面性能。本论文制备了几种新型纳米材料，并构建电化学传感器，主要包括下面几个部分：1、以电化学复原氧化石墨烯的方式方法制备石墨烯〔RGO〕，构建镉离子电化学传感器。石墨烯大的比外表积、良好的导电性、较强的吸附能力以及电催化性能明显提高了镉离子的响应电流信号，显着地改善了电极的分析性能。该传感器制备方式方法简便快速，能够反复屡次使用，并且能够应用于实际样品测定。2、采用葡萄糖作为复原剂与聚乙烯吡咯烷酮〔PVP〕为稳定剂，制备一种新型绿色金纳米颗粒〔AuNP〕，构建无酶的过氧化氢〔H2O2〕电化学传感器，该传感器具有灵敏度高，选择性好，线性范围宽，检测限低等优点。3、选用电化学复原氧化石墨烯法制备石墨烯，运用氧化亚铜纳米球为牺牲模板快速合成硫化铜空心球〔CuSHNs〕，基于石墨烯和硫化铜空心球纳米复合材料构建无酶的过氧化氢电化学传感器。由于石墨烯具有大的比外表积、良好的导电性等优点，且能够与硫化铜空心球产生良好的协同作用，显着提高了传感器对过氧化氢的电催化活性。所研制的传感器具有制作方式方法简单、灵敏度高、抗干扰能力强等优点，为石墨烯复合材料制备传感器提供了一种新的方式方法。以下为参考文献[1]汪尔康。21世纪的分析化学。北京：科学出版社，1999:217-218.[2]周鑫，杨健茂，刘建允，等。静电纺ZnO/碳复合纳米纤维修饰电极制备及对痕量铅的测定。分析化学，2020,42〔7〕：985-990.[3]ZhaoJ,YanYL,LiGX,etal.Anamperometricbiosensorforthedetectionofhydrogenperoxidereleasedfromhumanbreastcancercells.BiosensorsandBioelectronics,2020,41:815-819.[4]TarlaniA,FallahM,LotfiB,etal.NewZnOnanostructuresasnon-enzymaticglucosebiosensors.BiosensorsandBioelectronics,2021,67:601-607.[5]TabriziMA,ShamsipurM.Alabel-freeelectrochemicalDNAbiosensorbasedoncovalentim-mobilizationofsalmonellaDNAsequencesonthenanoporousglassycarbonelectrode.BiosensorsandBioelectronics,2021,69:100-105.[6]GuYJ,JuC,NiuYJ,etal.Detectionofcirculatingtumorcellsinprostatecancerbasedoncarboxylatedgrapheneoxidemodifiedlightaddressablepotentiometricsensor.BiosensorsandBioelectronics,2021,66:24-31.[7]WangSP,WuZS,ShenGL,etal.AnovelelectrochemicalimmunosensorbasedonorderedAunano-prickleclusters.BiosensorsandBioelectronics,2008,24〔4〕：1020-1026.[8]张先恩。生物传感器。北京：化学工业出版社，2005:58-150.[9]KatoN,CarusoF.Homogeneous,CompetitiveFluorescenceQuenchingImmunoassayBasedonGoldNanoparticle/PolyelectrolyteCoatedLatexParticles.JournalofPhysicalChemistryB,2005,109〔42〕：l9604-l9612.[10]WeiH,GuoZB,ZhuZW,eta1.SensitiveDetectionofAntibodyagainstAntigenFlofYersiniaPestisbyanAntigenSandwichMethodusingaPortableFiberOpticBiosensor.SensorsandActuatorsB:Chemical,2007,127〔2〕：525-530.[11]ClarkLC,LyonsC.Electrodesystemsforcontinuousmonitoringincardiovascularsurgery.AnnalsoftheNewYorkAcademyofSciences,1962,102〔1〕：29-45.[12]ChenKJ,PillaiKC,HwangBJ,etal.BimetallicPtM〔M=Pd,Ir〕nanoparticledecoratedmulti-walledcarbonnanotubeenzyme-free,mediator-lessamperometricsensorforH2O2.BiosensorsandBioelectronics,2020,33〔1〕：120-127.[13]IbupotoZH,ShahSMUA,KhunK,WillanderM.ElectrochemicalL-lacticacidsensorbasedonimmobilizedZnOnanorodswithlactateoxidase.Sensors,2020,12〔3〕：2456-2466.[14]CaiXJ,GaoX,WangLS,WuQ,LinXF.Alayer-by-layerassembledandcarbonnanotubes/goldnanoparticles-basedbienzymebiosensorforcholesteroldetection.SensorsandActuatorsB:Chemical,2020,181:575-583.[15]Ivekovi?D,JapecM,SolarM,?ivkovi?N.Amperometricuricacidbiosensorwithimprovedanalyticalperformancesbasedonalkaline-stableH2O2transducer.InternationalJournalofElectrochemicalScience,2020,7:3252-3264.[16]UpdikeSJ,HicksGP.TheEnzymeElectrode.Nature,1967,214〔5092〕：986-988.[17]DaigleF,LeechD.Reagentlesstyrosinaseenzymeelectrode:effectsofenzymeloading,electrolytepH,ionicstrength,andtemperature.AnalyticalChemistry,1997,69〔20〕：4108-4112.[18]GuilbaulGG,MontalvoJG.AnEnzymeElectrodeforSubstrateUrea.JournaloftheAmericanChemicalSociety,1970,92〔8〕：2533-2534.[19]DiviesC.Remarksonethanoloxidationbyanacetobaeterxylinummicrobialeleetrode.AnnalsofMicrobiology,1975,126〔2〕：175-186.[20]LiuY,WangDW,YouTY,etal.AnovelandsimpleroutetoprepareaPtnanoparticle-loadedcarbonnanofiberelectrodeforhydrogenperoxidesensing.BiosensorsandBioelectronics,2018,26〔11〕：4585-4590.[21]GaoHC,XiaoF,DuanHW,etal.One-stepelectrochemicalsynthesisofPtNinanoparticle-graphenenanocompositesfornonenzymaticamperometricglucosedetection.ACSAppliedMaterialsInterfaces,2018,3〔8〕：3049-3057.[22]LiFY,BaiHY,DaiZH,etal.Anonenzymaticcholesterolsensorconstructedbyusingporoustubularsilvernanoparticles.BiosensorsandBioelectronics,2018,25〔10〕：2356-2360.[23]DuJ,YueRR,DuYK,etal.Nonenzymaticuricacidelectrochemicalsensorbasedongraphene-modifiedcarbonfiberelectrode.ColloidsandSurfacesA:PhysicochemicalandEngineeringAspects,2020,419:94-99.[24]石士考。纳米材料的特性及其应用。大学化学，2001,6〔2〕：39-42.[25]DanielMC,AstrueD.Goldnanoparticles:assembly,supramolecularchemistry,quaumm-size-relatedproperties,andapplicationstowardbiology,catalysis,andnanotechnology.ChemicalReviews,2004,104〔1〕：293-346.[26]薛增泉。纳米科技探寻求索。北京：清华大学出版社，2002:1-101.[27]张全勤，张继文。纳米技术新进展。北京：国防工业出版社，2005:46-102.[28]GongKP,DongY,MaoLQ,etal.Novelelectrochemicalmethodforsensitivedeterminationofhomocysteinewithcarbonnanotube-basedelectrodes.BiosensorsandBioelectronics,2004,20〔2〕：253-259.[29]TsaiYC,LiSC,LiaoSW.Electrodepositionofpolypyrrolemultiwalledcarbonnanotubeglucoseoxidasenanobiocompositefilmforthedetectionofglucose.BiosensorsandBioelectronics,2006,22〔4〕：495-500.[30]ShahrokhianS,GhalkhaniM,AdeliM,etal.Multi-walledcarbonnanotubeswithimmobilisedcobaltnanoparticleformodificationofglassycarbonelectrode:Applicationtosensitivevoltammetricdeterminationofthioridazine.BiosensorsandBioelectronics,201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