目前,重庆作安光催化被广泛运用在各大领域,包括水分解,固氮,污染物分解,有机光合作用等等。
新加坡的材料研究主要集中在两所高校——新加坡国立大学和新加坡南洋理工大学,月电易工当然也有一些其他研究机构,比如A*STAR。在前段时间路透社旗下的ClarivateAnalytics公布的2018年全球高引学者的榜单中,力直在材料研究这一部分,新加坡共有21人入选,位列全球第四。
在美国签证难度增加的当下,接交去新加坡读博士和做博后看起来也是一种不错的选择。这份PPT汇总了部分新加坡材料领域的大牛,重庆作安希望对正在考虑做博后和申请博士的你,有一些帮助~如果有补充,请在评论区讨论,与大家共同交流。这里大佬云集,月电易工这里经费充裕。
这个成绩对于国土面积不大、力直人口基数不大的新加坡而言,是一个非常令人瞩目的成绩。欢迎大家到材料人宣传科技成果并对文献进行深入解读,接交投稿邮箱:[email protected].投稿以及内容合作可加编辑微信:cailiaorenVIP.
实际上,重庆作安韩国为首的LGDisplay已经将重心转向OLED,而三星也在研发融合OLED技术的量子点新型电视,液晶技术的寿命真的要到头了。
【摘要】随着韩国和中国品牌的崛起,月电易工日系消费电子巨头频频衰败,月电易工目前电视领域活的还算过得去也就剩下索尼和夏普,曾经的松下、东芝、日立、三洋等巨头品牌已经雄风不再,相对而言,松下电视还算不错,至少在等离子时代滋润了一些时日,不过最终不得不转战液晶领域,令人惋惜。力直代表性工作:WeinaZhang#,BingZheng#,WenxiongShi,XinyiChen,ZhilingXu,ShuzhouLi,YongguiRobinChi,YanhuiYang,JunLu*,WeiHuang*,FengweiHuo*.Site-SelectiveCatalysisofaMultifunctionalLinearMolecule:TheStericHindranceofMetal–OrganicFrameworkChannels.AdvancedMaterials,2018,30(23),1800643.BinghuaZou,YuanyuanChen,YihanLiu,RuijieXie,QinjieDu,TaoZhang,YuShen,BingZheng,ShengLi,JianshengWu,WeinaZhang,WeiHuang*,XinHuang*,FengweiHuo*.RepurposedLeatherwithSensingCapabilitiesforMultifunctionalElectronicSkin.AdvancedScience,2018,JinjuGuan,YuHu,YuWang,HongfengLi,ZhilingXu,TaoZhang,PengWu,SuoyingZhang,GengwuXiao,WenlanJi,LinjieLi,MeixuanZhang,YunFan,LinLi,BingZheng,WeinaZhang,WeiHuang*,FengweiHuo*.ControlledEncapsulationofFunctionalOrganicMoleculeswithinMetal-OrganicFrameworks:InSituCrystallineStructureTransformation.AdvancedMaterials,2017,29(12),1606290.WenxianLiu,JijiangHuang,QiuYang,ShijiWang,XiaomingSun,WeinaZhang,JunfengLiu*,FengweiHuo*.Multi-shelledHollowMetal-OrganicFrameworks.AngewandteChemieInternationalEdition,2017,56(20),5512-5516.QiuYang#,WenxianLiu#,BingqingWang,WeinaZhang,XiaoqiaoZeng,CongZhang,YongjiQin,XiaomingSun,TianpinWu,JunfengLiu*,FengweiHuo*,JunLu*.Regulatingthespatialdistributionofmetalnanoparticleswithinmetal-organicframeworkstoenhancecatalyticefficiency.NatureCommunications,2017,8,14429.YaqingLiu,HongWang,WenxiongShi,WeinaZhang,JiancanYu,BevitaK.Chandran,ChenlongCui,BowenZhu,ZhiyuanLiu,BinLi,CaiXu,ZhilingXu,ShuzhouLi,WeiHuang,FengweiHuo*,XiaodongChen*.Alcohol-MediatedResistance-SwitchingBehaviorinMetal-OrganicFramework-BasedElectronicDevices.AngewandteChemieInternationalEdition,2016,55(31),8884-8888.WeinaZhang,YayuanLiu,GuangLu,YongWang,ShaozhouLi,ChenlongCui,JinWu,ZhilingXu,DanbiTian,WeiHuang,JosephS.DuCheneu,W.DavidWei,HongyuChen,YanhuiYang,FengweiHuo*.MesoporousMetal-OrganicFrameworkswithSize-,Shape-,andSpace-Distribution-ControlledPoreStructure.AdvancedMaterials,2015,27(18):2923-2929.WeinaZhang,GuangLu,ChenlongCui,YayuanLiu,ShaozhouLi,WenjinYan,ChongXing,YongguiRobinChi,YanhuiYang,FengweiHuo*.AFamilyofMetal-OrganicFrameworksExhibitingSize-SelectiveCatalysiswithEncapsulatedNoble-MetalNanoparticles.AdvancedMaterials,2014,26(24),4056-4060.GuangLu,ShaozhouLi,ZhenGuo,OmarK.Farha,BradG.Hauser,XiaoyingQi,YiWang,XinWang,SanyangHan,XiaogangLiu,JosephS.DuChene,HuaZhang,QichunZhang,XiaodongChen,JanMa,SayChyeJoachimLoo,WeiD.Wei,YanhuiYang,JosephT.Hupp*,FengweiHuo*.Impartingfunctionalitytoametal-organicframeworkmaterialbycontrollednanoparticleencapsulation.NatureChemistry,2012,4(4),310-316.ShaozhouLi,WenxiongShi,GuangLu,ShuzhouLi,SayChyeJoachimLoo,FengweiHuo*.UnconventionalNucleationandOrientedGrowthofZIF-8CrystalsonNon-PolarSurface.AdvancedMaterials,2012,24(44),5954-5958.FengweiHuo#,GengfengZheng#,XingLiao,LouiseR.Giam,JinanChai,XiaodongChen,WooyoungShim,ChadA.Mirkin*.Beampenlithography.NatureNanotechnology,2010,5(9),637-640.FengweiHuo#,ZijianZheng#,GengfengZheng,LouiseR.Giam,HuaZhang,ChadA.Mirkin*.Polymerpenlithography.Science,2008,321(5896),1658-1660.本文由大兵哥供稿。
目前已经开发了许多种方法,接交包括配体交换,接交缺陷构造,模板法,超临界流体合成等,其中表面活性剂辅助的模板法由于其普适、易得性以及孔结构的可调性受到了广泛的青睐。重庆作安d)没有配体的S-Cu-BTC-PVP前体。
月电易工图四:HP-MOF的内部结构和空间分布HP-MOF的TEM图像:A)Cu-BTC。并将该方法成功拓展应用于具有轮桨结构的Cu-MOF上,力直如Cu-BTC和MOF-505。