此外，大厂低浓度下成本也可以降低一半。

月入（d）2C下的长循环性能。近年来发表SCI论文共计63篇（IF10,52篇),引用次数：家考1000次（2篇）、100次（21篇）。

（b）根据1m、大厂5m、10m和15m电解质的差示扫描量热结果所得的LiTFSI-H2O二元相图。基于该低浓度电解质的水系LIBs表现出优异的动力学性能，月入包括倍率性能和耐低温（-40℃）以及高负载厚电极下的性能。图四、家考CO2处理前后CO2与TFSI阴离子的相互作用（a）CO2处理前后5mSIW电解质的13C、1H和17O核磁共振谱。

利用该发现，大厂作者引入了CO2作为水系电解质的界面成膜添加剂，从而使得界面特性和体相电解质特性分离，即不再依赖于超高盐浓度。（b）不同浓度电解质（1m、月入5m、10m、15m和21m）用CO2气体处理后的FTIR光谱。

 超高盐浓度Water-in-salt水系电解液SEI膜形成机制研究（JournaloftheAmericanChemicalSociety,139,18670,(2017)） 超高盐浓度Water-in-salt水系电解液离子输运机制研究（ACSNano,11,10462,(2017)/J.Phys.Chem.C,125,22,(2021)） 超高盐浓度Water-in-salt抑制电极溶解机制研究（AdvancedEnergyMaterials,10,36,(2020)）2.提出富CO2宽电位水系电解液实现SEI膜精准调控，家考完成从高盐浓度Water-in-Salt到低盐浓度Salt-in-water转变（NatureChemistry,2021）3.基于宽电位水系电解液开发出系列水系锂/钠电池 2.3V高电压水系锂离子储能电池（LiMn2O4/Mo6S8）（Science,350,938,(2015)）2.5V高电压水系锂离子储能电池（LiMn2O4/TiO2）（AngewandteChemie-InternationalEdition,55,7136,(2016)） 2.8V高电压水系锂离子储能电池（LiMn2O4/TiO2(B)）（EnergyStorageMaterials,42,438,(2021)） 2.5V高电压水系钠离子储能电池（Na1.88Mn[Fe(CN)6]0.97·1.35H2O/NaTiOPO4）（AdvancedMaterials,32,2,(2020)）长寿命钠离子储能电池（Na0.66[Mn0.66Ti0.34]O2/NaTi2(PO4)3）（AdvancedEnergyMaterials,7,(2017)） 长寿命锂离子储能电池（LiFePO4/Mo6S8）（JournalofMaterialsChemistryA,4,6639,(2016)）水系电池方面发表文章（按照年代排序）：家考1.JinmingYue,JinkaiZhang,YuxinTong,MingChen,LiluLiu,Liwei,Jiang,TianshiLv,Yong-shengHu,HongLi,XuejieHuang,LinGu,GuangFeng,KangXu*,LiuminSuo*,LiquanChen,AqueousinterphaseformedbyCO2bringselectrolytesbacktosalt-in-waterregime.NatureChemistry,(2021).https://doi.org/10.1038/s41557-021-00787-y.2.AnxingZhou,YuanLiu,XiangzhenZhu,XinyanLi,JinmingYue,XianguoMa,LinGu*,Yong-ShengHu*,HongLi*,XuejieHuang*,LiquanChen*,LiuminSuo*,TiO2(B)AnodeforHigh-voltageAqueousLi-IonBatteries,EnergyStorageMaterials,42,438-444,(2021)3.JinmingYue,LiuminSuo*,ProgressinRechargeableAqueousAlkali-IonBatteriesinChina,EnergyFuels,35,11,9228–9239(2021)4.PanTan#,JinmingYue#,LiuminSuo*,LiangHong*et.al.,Solid-likeNano-Anion-ClusterConstructsFreeLithium-ionConductingSuper-FluidFrameworkinWater-in-saltElectrolyte.J.Phys.Chem.C,125,22,11838–11847(2021)5.BinghangLiu,LiuminSuo*,et.al.,Sandwich-structureCorrosion-resistantCurrentCollectorforAqueousBatteries.ACSAppliedEnergyMaterials,4,5,4928–4934(2021)6.JinmingYue,LiangdongLin,LiweiJiang,QiangqiangZhang,YuxinTong,LiuminSuo*,Yong‐shengHu,HongLi,XuejieHuang,LiquanChen,InterfaceConcentrated-ConfinementSuppressingCathodeDissolutioninWater-in-SaltElectrolyte.AdvancedEnergyMaterials,10,36,2000665(2020)7.LiweiJiang,LiluLiu,JinmingYue,QiangqiangZhang,AnxingZhou,OlegBorodin*,LiuminSuo*,HongLi,LiquanChen,KangXuandYong-ShengHu*,High-VoltageAqueousNa-IonBatteryEnabledbyInert-Cation-AssistedWater-in-SaltElectrolyte.AdvancedMaterials,32,2,1904427(2020)8.AnxingZhou,LiweiJiang,JinmingYue,YuxinTong,QiangqiangZhang,ZejingLin,BinghangLiu,ChuanWu,LiuminSuo*,Yong-ShengHu,HongLiandLiquanChen,Water-in-SaltElectrolytePromotesHigh-CapacityFefe(Cn)(6)CathodeforAqueousAl-IonBattery.ACSAppliedMaterialsInterfaces,11,41356,(2019)9.LiuminSuo,DahyunOh,YuxiaoLin,ZengqingZhuo,OlegBorodin,TaoGao,FeiWang,AkihiroKushima,ZiqingWang,Ho-CheolKim,YueQi,WanliYang,FengPan,JuLi,KangXuandChunshengWang,HowSolid-ElectrolyteInterphaseFormsinAqueousElectrolytes.JournaloftheAmericanChemicalSociety,139,18670,(2017)10.LiuminSuo,OlegBorodin,YueshengWang,XiaohuiRong,WeiSun,XiiulinFan,ShuyinXu,MarshallA.Schroeder,ArthurV.Cresce,FeiWang,ChongyinYang,Yong-ShengHu,KangXuandChunshengWang,Water-in-SaltElectrolyteMakesAqueousSodium-IonBatterySafe,Green,andLong-Lasting.AdvancedEnergyMaterials,7,(2017)11.OlegBorodin#,LiuminSuo#,MalloryGobet,XiaomingRen,FeiWang,AntonioFaraone,JingPeng,MarcoOlguin,MarshallSchroeder,MichaelS.Ding,EricGobrogge,ArthurvonWaldCresce,StephenMunoz,JosephA.Dura,SteveGreenbaum,ChunshengWangandKangXu*,LiquidStructurewithNano-HeterogeneityPromotesCationicTransportinConcentratedElectrolytes.ACSNano,11,10462,(2017)12.LiuminSuo,OlegBorodin,WeiSun,XiulinFan,ChongyinYang,FeiWang,TaoGao,ZhaohuiMa,MarshallSchroeder,ArthurvonCresce,SelenaM.Russell,MichelArmand,AustenAngell,KangXu*andChunshengWang,AdvancedHigh-VoltageAqueousLithium-IonBatteryEnabledbyWater-in-BisaltElectrolyte.AngewandteChemie-InternationalEdition,55,7136,(2016)13.LiuminSuo,FudongHan,XiulinFan,HuiliLiu,KangXuandChunshengWang,Water-in-SaltElectrolytesEnableGreenandSafeLi-IonBatteriesforLargeScaleElectricEnergyStorageApplications.JournalofMaterialsChemistryA,4,6639,(2016)14.LiuminSuo,OlegBorodin,TaoGao,MarcoOlguin,JanetHo,XiulinFan,ChaoLuo,ChunshengWang*andKangXu,Water-in-SaltElectrolyteEnablesHigh-VoltageAqueousLithium-IonChemistries.Science,350,938,(2015)本文由CQR编译。

大厂（b-c）0.5C下的循环寿命和相应的库伦效率。结合实验和理论研究表明，月入将催化剂纳米颗粒限制在离散的a平面条带上在稳定小纳米颗粒方面起着关键作用。

简而言之，家考这项工作有望为新型石墨烯/AlN-陶瓷-混合基热调节器在热管理相关领域的设计和应用提供一个全新的概念，家考特别是在大功率CPETs中的应用更广阔的领域。当用于组装ZAB时，大厂它显示出172mWcm–2的最大功率密度，大于Pt/C(120mWcm–2 )和Pt/C+Ir/C(86mWcm–2 )的功率密度。

月入7.（Small）用于高密度SWNT阵列生长的受限Fe催化剂：催化剂-基材相互作用工程的新领域高密度单壁碳纳米管（SWNT）阵列因其卓越的性能而被认为是下一代集成电路的最佳构建模块之一。家考石墨烯的高载流子迁移率和优异的热/电导率使其成为极好的候选材料。