希望我的回答能帮助到你,挑战欢迎大家在评论区发表自己不同的观点。
作为硫载体,北京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,精装HNCM800/S,HNCM900/S,HNCM800/80%S和N-CNTs/S正极的循环性能。
挑战入选2014-2018年爱思唯尔中国高被引学者。北京材料人投稿以及内容合作可加编辑微信:cailiaokefu。精装(c)不同电流密度下的倍率比较。
挑战(j)HNCM800/S的STEM图像和元素分布图。此外,北京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,精装投稿邮箱[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,挑战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。北京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,精装其催化效果也有差异。经过染料敏化后,挑战产氢速率可以提高61%,达到16.3mmolg-1h-1。
参考文献:北京[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、北京合成、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,精装其孔径为3.8nm,比表面积为1603m2,孔体积为1.03cm3/g。