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作为硫载体,伏逆多孔结构提供足够的空间以容纳活性硫并缓冲电极的体积膨胀。(e)HNCM700/S,变器HNCM800/S,HNCM900/S,HNCM800/80%S和N-CNTs/S正极的循环性能。
零电入选2014-2018年爱思唯尔中国高被引学者。压穿越测材料人投稿以及内容合作可加编辑微信:cailiaokefu。台达通过(c)不同电流密度下的倍率比较。
伏逆(j)HNCM800/S的STEM图像和元素分布图。此外,变器通过在空气中简单加热处理制备CNT/Co3O4微球。
欢迎大家到材料人宣传科技成果并对文献进行深入解读,零电投稿邮箱[email protected]。
具有一定含量的N-掺杂不仅可以提高CNT的电子导电性,压穿越测还可以提高润湿性和化学亲和性,从而在锂离子电池和电催化剂中得到更广泛的应用。台达通过而光催化条件下的化学转化则可以有效的将光能转化为化学能。
杂化材料中COF含量的不同,伏逆其催化效果也有差异。经过染料敏化后,变器产氢速率可以提高61%,达到16.3mmolg-1h-1。
参考文献:零电[1]LinusStegbauer,KatharinaSchwinghammer,BettinaV.Lotsch,AHydrazone-BasedCovalentOrganicFrameworkforPhotocatalyticHydrogenProduction.ChemicalScience,2014,5,2789-2793.[2]JayshriThote,HarshithaBarikeAiyappa,AparnaDeshpande,DavidDíaz Díaz,SreekumarKurungot,RahulBanerjee,ACovalentOrganicFramework–CadmiumSulfideHybridasaPrototypePhotocatalystforVisible-Light-DrivenHydrogenProduction.Chemistry–AEuropeanJournal,2014,20,15961-15965.[3]TanmayBanerjee,FrederikHaase,GökcenSavasci,KerstinGottschling,ChristianOchsenfeld,BettinaV.Lotsch,Single-SitePhotocatalyticH2 EvolutionfromCovalentOrganicFrameworkswithMolecularCobaloximeCo-Catalysts.JournaloftheAmericanChemicalSociety,2017,139,16228-16234.[4]BishnuP.Biswal,HugoA.Vignolo-González,TanmayBanerjee,LarsGrunenberg,GökcenSavasci,KerstinGottschling,JürgenNuss,ChristianOchsenfeld,BettinaV.Lotsch,SustainedSolarH2 EvolutionfromaThiazolo[5,4-D]Thiazole-BridgedCovalentOrganicFrameworkandNickel-ThiolateClusterinWater.JournaloftheAmericanChemicalSociety,2019,141,11082-11092.[5]XiaoyanWang,LinjiangChen,SamanthaY.Chong,MarcA.Little,YongzhenWu,Wei-HongZhu,RobClowes,YongYan,MartijnA.Zwijnenburg,ReinerSebastianSprick,AndrewI.Cooper,Sulfone-ContainingCovalentOrganicFrameworksforPhotocatalyticHydrogenEvolutionfromWater.NatureChemistry,2018,10,1180-1189.[6]ShuaiBi,CanYang,WenbeiZhang,JunsongXu,LingmeiLiu,DongqingWu,XinchenWang,YuHan,QifengLiang,FanZhang,Two-DimensionalSemiconductingCovalentOrganicFrameworksViaCondensationatArylmethylCarbonAtoms.NatureCommunications,2019,10,2467.[7]Pi-FengWei,Ming-ZhuQi,Zhi-PengWang,San-YuanDing,WeiYu,QiangLiu,Li-KeWang,Huai-ZhenWang,Wan-KaiAn,WeiWang,Benzoxazole-LinkedUltrastableCovalentOrganicFrameworksforPhotocatalysis.JournaloftheAmericanChemicalSociety,2018,140,4623-4631.[8]MohitoshBhadra,SharathKandambeth,ManojK.Sahoo,MatthewAddicoat,EkambaramBalaraman,RahulBanerjee,TriazineFunctionalizedPorousCovalentOrganicFrameworkforPhoto-OrganocatalyticE–ZIsomerizationofOlefins.JournaloftheAmericanChemicalSociety,2019,141,6152-6156.[9]SizhuoYang,WenhuiHu,XinZhang,PeileiHe,BrianPattengale,CunmingLiu,MelissaCendejas,IveHermans,XiaoyiZhang,JianZhang,JierHuang,2D CovalentOrganicFrameworksasIntrinsicPhotocatalystsforVisibleLight-DrivenCO2 Reduction.JournaloftheAmericanChemicalSociety,2018,140,14614-14618.[10]WanfuZhong,RongjianSa,LiuyiLi,YajunHe,LingyunLi,JinhongBi,ZanyongZhuang,YanYu,ZhigangZou,ACovalentOrganicFrameworkBearingSingleNiSitesasaSynergisticPhotocatalystforSelectivePhotoreductionofCO2 toCO.JournaloftheAmericanChemicalSociety,2019,141,7615-7621.[11] 共价有机框架光催化剂的设计、零电合成、表征及应用.王怀震;兰州大学硕士论文;2015本文由石楠花落Say-goodbye供稿。TFPT-COF属于介孔材料,压穿越测其孔径为3.8nm,比表面积为1603m2,孔体积为1.03cm3/g。