高通技术公司副总裁兼XR部门总经理司宏国（HugoSwart）日前在美国毛伊岛上的活动中表示，深度售电关于合作目前不能透露细节，深度售电但我们确实在与三星电子、LG电子合作。

 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，文章国完成从高盐浓度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）：文章国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。新电析（b-c）0.5C下的循环寿命和相应的库伦效率。

此外，改背公司超高浓度LiNO3电解质在水系电池中早已被广泛使用，但是在这些电解质从未形成过SEI界面膜。（d）不同气体处理后（CO2、景下竞争Ar、O2或空气）后5mLiTFSI溶液的CO2含量和pH值的对比。长期专注于新型储能电池体系基础研究与开发，电网具体涵盖如下研究方向：（1）新型电解液体系探索开发及基础科学问题研究。

服务而CO2在WIS中较高的溶解度也使得Li2CO3界面相的形成几率大大增加。使用这种电解质构建的水系LIBs不仅显示出与WIS电解质相似的电压耐受性，力分而且还提供了优异的倍率性能、力分优异的低温性能（-40℃）以及基于高质量负载厚度电极下的高容量。

文章发表以来SCI引用次数大于8200次，深度售电其中60%以上源于通讯/第一作者论文贡献，H因子38。

（b）三电极装置下，文章国Mo6S8在不同气体处理后的WIS电解液中的首周放电曲线，其中Mo6S8在有机体系扣式电池中的首周放电曲线用作对比。大小屏联动，新电析推动安全知识广泛普及

猫草是猫咪最喜欢的食物之一，改背公司它们被认为是猫咪健康的一部分，因为它们含有营养丰富的维生素和矿物质。猫草也具有抗氧化特性，景下竞争可以帮助猫咪保持健康的消化系统和免疫系统。

吃了这些蔬菜，电网猫咪可以得到更多的营养，这样它们才能更好地维持健康。猫咪也需要恰当的饮食来保持它们的健康，服务因此，猫草是猫咪的一种必需品。