2022年大唐发电市场化交易电量约1997亿千瓦时 占比约80.88%

电市电量（D）（C）中相应的Tafel图。

智能选床系统，场化是一个充满无限可能的领域，场化特别是在物联网时代，星港家居将会倾注更多的研发，挖掘更多的AI智慧潜能，运用科技让更多的人睡得更好，让更多人享受到智能带来的美好生活!接下来，星港家居将以荣登《环球人物》为全新起点，不断攀登高峰，秉持品质生活梦想家与健康睡眠创造者的使命，启动全新的发展征程。正是这种不断自我超越的精神，交易让星港家居在智能产品上全面发力，创新性推出D20人工智能睡眠系统。

借助权威杂志扩大品牌影响力《环球人物》由我国权威媒体机构《人民日报》主管、约17亿主办，发行量极大，是极具权威性和影响力的综合时政类期刊。2022年末，千瓦星港家居打造了一个名为眯兔的卡通形象，并以NICETO眯兔(meetyou)为主题，推出了以床垫、软床、沙发为组合的三件套主推产品。围绕改善更多人睡眠的品牌理念，时占星港家居将打好智慧睡眠系统这张牌。

星港家居线下门店店态逐渐多样化、比约精细化，摒弃了以往家居大卖场的形式，呈现出买手店、家居体验馆、CTNR集装箱等多种新型门店店态。中国权威杂志《环球人物》用标榜品牌力量的版面，电市电量介绍中国十大床垫品牌星港，以及它的品牌传奇。

渠道布局开启体验式新零售星港家居历来重视渠道布局，场化其投入的力度赶超行业内众多知名品牌。

随着《环球人物》的广泛推广与传播，交易星港家居年轻时尚的品牌形象，也会传递到更多追求格调生活品位的家庭。【团队在该领域工作汇总】(1)GuanweiCui,XiuliYang,YujiaZhang,YaqiFan,PingChen,HongyuCui,YanLiu,XifengShi,QiaoyanShang,andBoTang*,Round-the-clockPhotocatalyticHydrogenProductionwithHighEfficiencybyaLongAfterglowMaterial.Angew.Chem.Int.Ed.,Accepted,DOI:10.1002/anie.201810544.(2)GuanweiCui,WenWang,MingyueMa,JunfengXie,XifengShi,NingDeng,JianpingXin,andBoTang*，约17亿IR-DrivenPhotocatalyticWaterSplittingwithWO2-NaxWO3HybridConductorMaterial.NanoLett.,2015,15,7199-7203.(3)Guan-weiCui,Wei-liangWang,Ming-yueMa,MingZhang,Xin-yuanXia,Feng-yunHan,Xi-fengShi,Ying-qiangZhao,Yu-BinDongandBoTang*.RationaldesignofcarbonandTiO2assemblymaterials:coveredorstrewn,whichisbetterforphotocatalysis?Chem.Commun.,2013,49,6415-6417.(4)Xi-FengShi,Xin-YuanXia,Guan-WeiCui*,NingDeng,Ying-QiangZhao,Lin-HaiZhuo,BoTang*.MultipleexcitongenerationapplicationofPbSquantumdotsinZnO@PbS/grapheneoxideforenhancedphotocatalyticactivity.Appl.Catal.B:Environ.,2015,163,123-128.(5)YingqiangZhao,Ming-YueMa,Guan-WeiCui*,Xi-FengShi,Feng-YunHan,Xin-YuanXia,BoTang*.ANewStrategytoRealizeEfficientSpacialChargeSeparationonCarbonaceousPhotocatalyst. Carbon,2014,73,333-337.(6)JunfengXie*,JianpingXin,RuoxingWang,XiaodongZhang,FengcaiLei,HaichaoQu,PinHao,GuanweiCui,BoTang*andYiXie*.Sub-3nmPoresinTwo-DimensionalNanomeshPromotingtheGenerationofElectroactivePhaseforRobustWaterOxidation. NanoEnergy,2018,53,74-82.(7)JunfengXie*,HaichaoQu,FengcaiLei,XuPeng,WeiweiLiu,LiGao,PinHao,GuanweiCuiandBoTang*.PartiallyAmorphousNickel-IronLayeredDoubleHydroxideNanosheetArraysforRobustBifunctionalElectrocatalysis.J.Mater.Chem.A,2018,6,16121-16129.(8)QianWang*,BohuiDong,YingqiangZhao,FangHuang,JunfengXie,GuanweiCui,BoTang*.Controllablegreensynthesisofcrassulapeforata-likeTiO₂withhighphotocatalyticactivitybasedondeepeutecticsolvent(DES).Chem.Eng.J.,2018,348,811-819.(9)XifengShi,JiahuiZhang,GuanweiCui*,NingDeng,WenWang,QianWang,andBoTang*.PhotocatalyticH₂evolutionimprovementforHfree-radicalstabilizationbyelectrostaticinteractionofaCu-BTCMOFwithZnO/GO.NanoRes.,2018,11,979-987.(10)RanWang,GangLi*,AndongZhang,WenWang,GuanweiCui,Jian-FengZhao,ZhiqiangShi*andBoTang*.EfficientEnergy-LevelModificationofNovelPyran-annulatedPeryleneDiimidesforPhotocatalyticWaterSplitting.Chem.Commun.,2017,53,6918-6921.(11)JunfengXie,JianpingXin,GuanweiCui,XinxiaZhang,LijieZhou,YunlongWang,WeiweiLiu,CaihuaWang,MeiNing,XinyuanXia,YingqiangZhaoandBoTang*.Verticallyalignedoxygen-dopedmolybdenumdisulfidenanosheetsgrownoncarbonclothrealizingrobusthydrogenevolutionreaction.Inorg.Chem.Front.,2016,3,1160-1166.(12)PinHao,JianTian,YuanhuaSang,Chia-ChiTuan,GuanweiCui,XifengShi,CPWong,BoTang*andHongLiu*.1DNi-CoOxideandSulfideNanoarray/CarbonAerogelHybridNanostructuresforAsymmetricSupercapacitorswithHighEnergyDensityandExcellentCycleStability.Nanoscale,2016,8,16292-16301.(13)YingqiangZhao,FengyunHan,QianWang,Guan-WeiCui*,Xi-FengShi,Xin-YuanXia,JunfengXie,YongLiandBoTang*.Core–ShellCompositesBasedonMultiwalledCarbonNanotubesandCesiumTungstenBronzetoRealizeChargeTransportBalanceforPhotocatalyticWaterOxidation,ChemCatChem,2016,8,624-630.(14)XinyuanXia,NingDeng,GuanweiCui,JunfengXie,XifengShi,YingqiangZhao,QianWang,WenWangandBoTang*.NIRlightinducedH2evolutionbyametal-freephotocatalyst. Chem.Commun.,2015,51,10899-10902(15)Xi-FengShi,NaLi,KeZhao,Guan-WeiCui,Ying-QiangZhao,Ming-YueMa,Ke-HuaXu,PingLi,Yu-BinDong*,BoTang*.Adye-sensitizedFeOOH-CNTphotocatalystwiththreeelectrontransferchannelsregulatedbyhydrogenbonding. Appl.Catal.B:Environ.,2013,136-137,334-340.。

千瓦图2Sr2MgSi2O7:Eu2+,Dy3+的光学性质和光电响应表征a)Sr2MgSi2O7:Eu2+,Dy3+和Sr2MgSi2O7的紫外/可见吸收光谱。b)用500W高压汞灯照射15min后，时占Sr2MgSi2O7:Eu2+,Dy3+和Sr2MgSi2O7在黑暗条件下制氢量随时间的变化。

比约c)光催化反应前Dy3d和Dy4d的XPS光谱。由于Eu2+(198pm)、电市电量Dy3+(192μm)和Sr2+(195pm)的半径相似，电市电量前两种离子可以完全取代Sr2+，同时在合成过程中保持其晶胞尺寸，在掺杂的稀土离子周围形成可以存储电子的氧空位。