旬石下跌團(tuán)隊(duì)在該領(lǐng)域工作匯總:[1]LingT,DaPF,ZhengXL,GeBH,HuZP,WuMY,DuXW,HuWB,JaroniecM,QiaoSZ*.Atomic-levelstructureengineeringofmetaloxidesforhigh-rateoxygenintercalationpseudocapacitance.Sci.Adv.2018,4,eaau6261[HighlightedbyNatureEnergy].[2]LingT,YanDY,WangH,JiaoY,HuZP,ZhengY,ZhengLR,MaoJ,LiuH,DuXW,JaroniecM,QiaoSZ*.Activatingcobalt(II)oxidenanorodsforhighlyefficientelectrocatalysisbystrainengineering.Nat.Commun.2017,8,1509[ESIhighlycitedpaper].[3]LingT,YanDY,JiaoY,WangH,ZhengY,ZhengXL,MaoJ,DuXW*,HuZP*,JaroniecM,QiaoSZ*.Engineeringsurfaceatomicstructureofsingle-crystalcobalt(Ⅱ)oxidenanorodsforsuperiorelectrocatalysis.Nat.Commun.2016,7,12876[ESIhighlycitedpaper].[4]MuC,MaoJ,GuoJ,GuoQ,LiZ,QinW,HuZ*,DaveyK,LingT*,QiaoSZ*.RationaldesignofspinelcobaltvanadateoxideCo2VO4forsuperiorelectrocatalysis.Adv.Mater.2020,32,DOI:10.1002/adma.201907168.[5]YangY,ZhangL,HuZ,ZhengY,TangC,ChenP,WangR,QiuK,MaoJ,LingT*,QiaoSZ.*Thecrucialroleofchargeaccumulationandspinpolarizationinactivatingcarbon-basedcatalystsforelectrocatalyticnitrogenreduction.Angew.Chem.Int.Ed.2020,59,DOI:10.1002/anie.201915001[VIPpaper].[6]LingT*,ZhangT,GeB,HanL,ZhengL,LinF,XuZ,HuW-B,DuX-W,DaveyK,QiaoSZ*.Welldispersednickleandzinctailoredelectronicstructureoftransitionmetaloxideforhighlyactivealkalinehydrogenevolutionreaction.Adv.Mater.2019,31,1807771.[7]LiY-J,CuiL,DaP-F,QiuK-W,QinW-J,HuW-B,DuX-W,DaveyK,LingT*,QiaoS-Z.Multi-scalestructuralengineeringofNi-dopedCoOnanosheetsforzinc-airbatterieswithhigh-powerdensity.Adv.Mater.2018,30,1804653.[8]MengC,LingT*,MaTY,WangH,HuZP,ZhouY,MaoJ,DuXW,JaroniecM,QiaoSZ*.AtomicallyandelectronicallycoupledPtandCoOhybridnanocatalystsforenhancedelectrocatalyticperformance.Adv.Mater.2017,29,1604607[ESIhighlycitedpaper].[9]ZhengXL,SongJP,LingT*,HuZP,YinPF,DaveyK,DuXW*,QiaoSZ*.StronglycoupledNafionmoleculesandorderedporousCdSnetworksforenhancedvisible-lightphotoelectrochemicalhydrogenevolution.Adv.Mater.2016,28,4935-4942[Backinsidecover].[10]LingT,WangJJ,ZhangH,SongST,ZhouYZ,ZhaoJ*,DuXW*.Freestandingultrathinmetallicnanosheets:materials,synthesis,andapplications.Adv.Mater.2015,27,5396-5402.[11]ZhangT,WuM-Y,YanD-Y,MaoJ,LiuH,HuW-B,DuX-W,LingT*,QiaoSZ*.EngineeringoxygenvacancyonNiOnanorodarraysforalkalinehydrogenevolution.NanoEnergy2018,43,103-109[ESIhighlycitedpaper].[12]ZhangH,LingT*,DuXW*.Gas-phasecationexchangetowardporoussingle-crystalCoOnanorodsforcatalytichydrogenproduction.Chem.Mater.2015,27,352-357.本文由CQR編譯���。然而�����,然氣目前這些氧化物材料固有的電導(dǎo)率較低����,限制了它們的實(shí)際應(yīng)用。實(shí)際電導(dǎo)率的測(cè)量結(jié)果表明�����,統(tǒng)計(jì)對(duì)比常見鈷氧化物CoO和Co3O4���,Co2VO4提高了幾個(gè)數(shù)量級(jí)。
他還獲得澳大利亞研究理事會(huì)(ARC)桂冠教授稱號(hào)(2017)�,局6價(jià)格埃克森美孚獎(jiǎng)(2016)��,局6價(jià)格ARC杰出研究員獎(jiǎng)(DORA�,2013)�,新興研究員獎(jiǎng)(2013���,美國(guó)化學(xué)學(xué)會(huì)ENFL部門)等�。通過實(shí)驗(yàn)和模擬的電子能量損失譜分析����,月下油天揭示了八面體位點(diǎn)的Co2+呈低自旋態(tài),eg僅填充一個(gè)電子(t2g6eg1)�����,有利于ORR的熱力學(xué)���。
然而�,旬石下跌目前很少報(bào)道這些材料用于高活性電催化領(lǐng)域�。
然氣(c)Co2VO4的原子級(jí)HAADF-STEM圖像及對(duì)應(yīng)的晶體結(jié)構(gòu)模型。在這些情況下���,統(tǒng)計(jì)具有多孔邊的多孔電極結(jié)構(gòu)可以促進(jìn)界面上的催化反應(yīng)�,這與氣體吸附/解吸���、電解質(zhì)離子擴(kuò)散和電子傳輸有關(guān)���。
因此����,局6價(jià)格在NCNT電極中摻雜氮雜原子的碳納米管可以有效地產(chǎn)生非金屬的電化學(xué)還原氧氣活性位點(diǎn)�。接受電子的氮原子在共軛碳納米管平面上的結(jié)合,月下油天似乎給予相鄰碳原子一個(gè)相對(duì)較高的正電荷密度���。
平行雙原子吸附可以有效地削弱O-O鍵�,旬石下跌促進(jìn)NCNT/GC電極的ORR����。1.元素?fù)诫s實(shí)現(xiàn)碳材料催化性能的提升碳納米材料,然氣尤其是石墨烯�����,然氣碳納米管等�����,因?yàn)樗鼈兙哂谐叩碾娮舆w移率��、從內(nèi)部到表面的電荷擴(kuò)散長(zhǎng)度短和較大的比表面積而備受關(guān)注��,石墨是由所有sp2共軛的多層石墨烯片構(gòu)成碳基面為六邊形�,層間沿橫向方向的范德華相互作用較弱。