请牢记！疫情期间，出差如何做好个人防控?

虽然PSVR看起来已经非常酷，请牢情期但一家名为FlamingToast的小公司不介意让它变得更酷炫一些。

采用超浓电解液，记疫间全电池放电电压从0.6V提高道0.95V，能量密度提高。出差（a）KFeMnHCF典型晶体结构。

做好（图17）图17 ZnHCF@MnO2作为水系锌离子电池正极。个人（图3）图3 典型碱金属离子嵌入机制。TEM验证了CoNi-HCF表面约15nm左右的NiHCF包覆层，防控该包覆层有效降低充放电循环过程中的晶格紊乱，并抑制副反应，因此获得优异的循环稳定性。

请牢情期（a）Zn2+在CoHCF框架结构中可逆嵌入/脱出。记疫间Kim,Jaekook,ElectrochemicallyInducedStructuralTransformationinaγ-MnO2CathodeofaHighCapacityZinc-IonBatterySystem.ChemistryofMaterials2015,27 (10), 3609−3620.[7]YangLiu,Y.Q.,WuxingZhang,ZhenLi,XiaoJi,LingMiao,LixiaYuan,XianluoHu,YunhuiHuang,SodiumstorageinNa-richNaxFeFe(CN)6nanocubes.NanoEnergy2015,12,386–393.[8]DaweiSu,A.M.,Shi-ZhangQiao,GuoxiuWang,High-CapacityAqueousPotassium-IonBatteriesforLarge-ScaleEnergyStorage.Adv. Mater.2017,29,1604007.[9]JinpengWu,J.S.,KehuaDai,ZengqingZhuo,L.AndrewWray,GaoLiu,Zhi-xunShen,RongZeng,YuhaoLu,WanliYang,ModificationofTransition-MetalRedoxbyInterstitialWaterinHexacyanometalateElectrodesforSodium-IonBatteries.J. Am.Chem.Soc.2017,139,18358−18364.[10]WeijieLi,C.H.,WanlinWang,QingbingXia,ShuleiChou,QinfenGu,BerntJohannessen,HuaKunLiu,andShixueDou,StressDistortionRestrainttoBoosttheSodiumIonStoragePerformanceofaNovelBinaryHexacyanoferrate.Adv.EnergyMater.2019,1903006.[11]PuHu,W.P.,BoWang,DongdongXiao,UtkarshAhuja,JulienRéthoré,KaterinaE.Aifantis,Concentration-GradientPrussianBlueCathodesforNa-IonBatteries.ACSEnergyLett.2020,5,100−108.[12]JinwenYin,Y.S.,ChangLi,ChenyangFan,ShixiongSun,YiLiu,JianPeng,LiQing,andJiantaoHan,InSituSelf-AssemblyofCore–ShellMultimetalPrussianBlueAnaloguesforHigh-PerformanceSodium-IonBatteries.ChemSusChem2019,12,4786–4790.[13]WenhaoRen,M.Q.,ZixuanZhu,MengyuYan,QiLi,LeiZhang,DongnaLiu,LiqiangMai,ActivationofSodiumStorageSitesinPrussianBlueAnaloguesviaSurfaceEtching.NanoLett.2017,17,4713−4718.[14]LingboRen,J.-G.W.,HuanyanLiu,MinhuaShao,BingqingWei,Metal-organic-framework-derivedhollowpolyhedronsofprussianblueanaloguesforhighpowergrid-scaleenergystorage.ElectrochimicaActa2019,321,134671.[15]DezhiYang,J.X.,Xiao-ZhenLiao,HongWang,Yu-ShiHe,Zi-FengMa,Prussianbluewithoutcoordinatedwaterasasuperiorcathodeforsodium-ionbatteries.Chem. Commun.2015,51,8181.[16]YangTang,W.Z.,LihongXue,XuliDing,TingWang,XiaoxiaoLiu,JingLiu,XiaochengLi,YunhuiHuang,Polypyrrole-promotedsuperiorcyclabilityandratecapabilityofNaxFe[Fe(CN)6]cathodesforsodiumionbatteries.J. Mater.Chem.A2016,4,6036.[17]KeLu,B.S.,YuxinZhang,HouyiMa,JintaoZhang,Encapsulationofzinchexacyanoferratenanocubeswithmanganeseoxidenanosheetsforhighperformancerechargeablezincionbatteries.J. Mater.Chem. A2017,5,23628.[18]DapengZhang,Z.Y.,JunshuZhang,HongzhiMao,JianYang,YitaiQian,Truncatedcobalthexacyanoferratenanocubesthreadedbycarbonnanotubesasahigh-capacityandhigh-ratecathodematerialfordual-ionrechargableaqueousbatteries.JournalofPowerSources2018,399,1-7.[19]QiYang,F.M.,ZhuoxinLiu,LongtaoMa,XinliangLi,DaliangFang,ShimouChen,SuojiangZhang,andChunyiZhi,ActivatingC-CoordinatedIronofIronHexacyanoferrateforZnHybrid-IonBatterieswith10000-CycleLifespanandSuperiorRateCapability.Adv. Mater.2019,31,1901521.[20]KosukeNakamoto,R.S.,YukiSawada,MasatoIto,andShigetoOkada,Over2VAqueousSodium-IonBatterywithPrussianBlue-TypeElectrodes.SmallMethods2019,3 (1800220).[21]XianyongWu,†YunkaiXu,§,†ChongZhang,†DanielP.Leonard,†AaronMarkir,†JunLu,*,‡andXiuleiJi,ReverseDual-IonBatteryviaaZnCl2Water-in-SaltElectrolyte.J. Am.Chem.Soc.2019,141,6338−6344.[22]XianyongWu,J.J.H.,WoochulShin,LuMa,TongchaoLiu,XuanxuanBi,YifeiYuan,YitongQi,T.WesleySurta,WenxiHuang,JoergNeuefeind,TianpinWu,P.AlexGreaney,JunLu,XiuleiJi Diffusion-freeGrotthusstopochemistryforhigh-rateandlong-lifeprotonbatteries.NatureEnergy2019,4,123–130.本文由作者团队供稿。

Li等[10]报道，出差Fe在Na1.60Mn0.833Fe0.167[Fe(CN)6]中掺杂，可降低Mn溶出和充放电过程中的结构应力 ，提高晶体热力学稳定性，因此表现出高的循环稳定性。

特别的，做好P离子与-C≡N-中的N配位，R离子与-C≡N-中的C配位组成三维框架结构。个人研究领域：纳米材料的设计及其在能源储存和转化上的应用。

防控（b）焦耳加热用于制备合金纳米颗粒的示意图及过程温度-时间变化曲线。国家优青基金、请牢情期泰山学者青年专家计划、山东省优秀青年基金和省自然科学杰出青年基金获得者。

（图片来源，记疫间ScienceBulletin）7.总结与展望最后本综述对不同非辐射加热方法制备纳米材料进行了总结。出差图5.2.（a-c）激光照射金属钴靶材制备CoOOH的示意图。