机译:通过定制单体设计效率提高氮化碳电化学电池
Max Planck Inst Colloids & Interfaces Dept Colloid Chem D-14474 Potsdam Germany|City Univ Hong Kong Dept Phys & Mat Sci 83 Tat Chee Ave Kowloon Hong Kong Peoples R China|City Univ Hong Kong CFP 83 Tat Chee Ave Kowloon Hong Kong Peoples R China|City Univ Hong Kong Shenzhen Res Inst Shenzhen 518057 Peoples R China;
Helmholtz Zentrum Berlin Mat & Energie GmbH Inst Solar Fuels & Operando Characterizat Solar F D-12489 Berlin Germany;
City Univ Hong Kong Dept Phys & Mat Sci 83 Tat Chee Ave Kowloon Hong Kong Peoples R China|City Univ Hong Kong CFP 83 Tat Chee Ave Kowloon Hong Kong Peoples R China|City Univ Hong Kong Shenzhen Res Inst Shenzhen 518057 Peoples R China;
Helmholtz Zentrum Berlin Mat & Energie GmbH Inst Solar Fuels & Operando Characterizat Solar F D-12489 Berlin Germany;
City Univ Hong Kong Dept Phys & Mat Sci 83 Tat Chee Ave Kowloon Hong Kong Peoples R China|City Univ Hong Kong CFP 83 Tat Chee Ave Kowloon Hong Kong Peoples R China|City Univ Hong Kong Shenzhen Res Inst Shenzhen 518057 Peoples R China;
Max Planck Inst Colloids & Interfaces Dept Colloid Chem D-14474 Potsdam Germany;
机译:通过三步缩聚光催化和光电化学免疫传感器轻松合成具有增强的光电化学特性的二维定制石墨碳氮化物
机译:用于高性能光电化学电池的晶体脸量身定制的石墨碳氮化物膜
机译:可见/近红外光响应Vopc /碳氮化物纳米复合材料:Vopc敏化氮化物,提高光电电化学双氯芬酸容纳蛋白的光电转换效率
机译:用于高效硅太阳能电池的无硅烷PECVD碳氮化硅(SiC
机译:使用Doherty技术提高氮化镓HFET技术中微微小区基站功率放大器MMIC的效率。
机译:剪裁碳纳米管以提高厌氧条件下酸橙10的电子班车效率
机译:硅上的石墨化碳氮化物纳米发射体:由丰富的地球材料组成的光电化学异质结,可增强氢的释放