此外,博海乐视还称,博海从今年年初开始,其内部在酝酿一种新的平台运营方式,并预计在12月上线,乐视视频将推出全新的版权合作模式,在APP内新增点播厅的呈现形式
利用同步辐射技术来表征材料的缺陷,拾贝化学环境用于机理的研究已成为目前的研究热点。目前材料的形貌表征已经是绝大多数材料科学研究的必备支撑数据,再抢一个新颖且引人入胜的形貌电镜图也是发表高水平论文的不二法门。
![[博海拾贝0306]我觉得我还能再抢救下!](http://936932.sqi-international.com/uploads/images/992707.jpg)
限于水平,救下必有疏漏之处,欢迎大家补充。UV-vis是简便且常用的对无机物和有机物的有效表征手段,博海常用于对液相反应中特定的产物及反应进程进行表征,如锂硫电池体系中多硫化物的测定。Kim课题组在锂硫电池的正极研究中利用原位TEM等形貌和结构的表征,拾贝深入的研究了材料的电化学性能与其形貌和结构的关系(Adv.EnergyMater.,2017,7,1602078.),拾贝如图三所示。
![[博海拾贝0306]我觉得我还能再抢救下!](http://936932.sqi-international.com/uploads/images/9927071.jpg)
利用原位TEM等技术可以获得材料形貌和结构实时发生的变化,再抢如微观结构的转化或者化学组分的改变。目前,救下国内的同步辐射光源装置主要有北京同步辐射装置,救下(BSRF,第一代光源),中国科学技术大学的合肥同步辐射装置(NSRL,第二代光源)和上海光源(SSRF,第三代光源),对国内的诸多材料科学的研究起到了巨大的作用。
![[博海拾贝0306]我觉得我还能再抢救下!](http://936932.sqi-international.com/uploads/images/9927072.jpg)
Figure1.AnalysisofO-vacancydefectsonthereducedCo3O4nanosheets.(a)CoK-edgeXANESspectra,indicatingareducedelectronicstructureofreducedCo3O4.(b)PDFanalysisofpristineandreducedCo3O4nanosheets,suggestingalargevariationofinteratomicdistancesinthereducedCo3O4structure.(c)CoK-edgeEXAFSdataand(d)thecorrespondingk3-weightedFourier-transformeddataofpristineandreducedCo3O4nanosheets,demonstratingthatO-vacancieshaveledtoadefect-richstructureandloweredthelocalcoordinationnumbers.XRDXRD全称是X射线衍射,博海即通过对材料进行X射线衍射来分析其衍射图谱,博海以获得材料的结构和成分,是目前电池材料常用的结构组分表征手段。
Fig.2In-situXRDanalysisoftheinteractionsduringcycling.(a)XRDintensityheatmapfrom4oto8.5oofa2.4mgcm–2cellsfirstcycledischargeat54mAg–1andchargeat187.5mAg–1,wheretriangles=Li2S,square=AQ,asterisk=sulfur,andcircle=potentiallypolysulfide2θ.(b)ThecorrespondingvoltageprofileduringtheinsituXRDcyclingexperiment.材料形貌表征在材料科学的研究领域中,拾贝常用的形貌表征主要包括了SEM,拾贝TEM,AFM等显微镜成像技术。再抢[6]微观结构使Co3S4的电化学性能优于迄今为止报道的用于铝离子电池的大多数其他阴极材料。
[8]单个纳米片的特征是具有几个原子层厚度,救下并且它们以最小化的堆叠进行分层排列。博海图3. MS⊂C球的制备过程。
拾贝【参考文献】[1] JingweiChen,DanielH.C.Chua,PooiSeeLee,TheAdvancesofMetalSulfidesandInSituCharacterizationMethodsbeyondLiIonBatteries:Sodium,Potassium,andAluminumIonBatteries,SmallMethods 2019,1900648.[2] ZiliangChen,RenbingWu,MiaoLiu,HaoWang,HongbinXu,YanhuiGuo,YunSong,FangFang,XuebinYu,DalinSun,GeneralSynthesisofDualCarbon-ConfinedMetalSulfidesQuantumDotsTowardHigh-PerformanceAnodesforSodium-IonBatteries,Adv.Funct.Mater. 2017,27,1702046.[3]YangLiu,YongjinFang,ZhiweiZhao,ChangzhouYuan,XiongWen(David)Lou,ATernaryFe1−xS@PorousCarbonNanowires/ReducedGrapheneOxideHybridFilmElectrodewithSuperiorVolumetricandGravimetricCapacitiesforFlexibleSodiumIonBatteries,Adv.EnergyMater. 2019,1803052.[4]LaifaShen,YiWang,FeixiangWu,IgorMoudrakovski,PetervanAken,JoachimMaier,YanYu,HierarchicalMetalSulfide/CarbonSpheres:GeneralizedSynthesisandExcellentSodiumStoragePerformance,Angew.Chem.Int.Ed. 2019,131,7316-7321.[5]ZhongchenZhao,ZhengqiangHu,RuishunJiao,ZhanhongTang,PengDong,YadongLi,ShandongLi,HongsenLi,TailoringMulti-LayerArchitecturedFeS2@CHybridsforSuperiorSodium-,Potassium-andAluminum-IonStorage,EnergyStorageMater.2019,22,228-234.[6]HuchengLi,HuicongYang,ZhenhuaSun,YingShi,Hui-MingCheng,FengLi,AHighlyReversibleCo3S4 MicrosphereCathodeMaterialforAluminum-IonBatteries,NanoEnergy 2019,56, 100-108.[7]HongGao,TengfeiZhou,YangZheng,QingZhang,YuqingLiu,JunChen,HuakunLiu,ZaipingGuo,CoSQuantumDotNanoclustersforHigh-EnergyPotassium-IonBatteries,Adv.Funct.Mater.2017,1702634.[8] JunhuaZhou,LuWang,MingyeYang,JinghuaWu,FengjiaoChen,WenjingHuang,NaHan,HualinYe,FeipengZhao,YouyongLi,YanguangLi,HierarchicalVS2 NanosheetAssemblies:AUniversalHostMaterialfortheReversibleStorageofAlkaliMetalIons,Adv.Mater. 2017,1702061.[9]MingleiMao,ChunyuCui,MingguangWu,MingZhang,TaoGao,XiulinFan,JiChen,TaihongWang,JianminMa,ChunshengWang,FlexibleReS2 Nanosheets/N-dopedCarbonNanofibers-BasedPaperasaUniversalAnodeforAlkali(Li,Na,K)IonBattery,NanoEnergy 2018, 45,346-352.本文由夏天的白羊供稿。当被评估为钠离子电池的自支撑阳极时,再抢Fe1-xS@PCNWs/rGO电极在0.1Ag-1的连续循环100次后表现出优异的可逆容量(573-89mAhg-1)。
