机译:1d WO3纳米棒/ 2D WO3?X纳米薄片同源结结构,用于增强电荷分离和转移到有效的光电化学性能
School of Materials Science and EngineeringTianjin Chengjian UniversityTianjin 300384 P. R. China;
School of Materials Science and EngineeringTianjin Chengjian UniversityTianjin 300384 P. R. China;
School of Materials Science and EngineeringTianjin Chengjian UniversityTianjin 300384 P. R. China;
School of Materials Science and EngineeringTianjin Chengjian UniversityTianjin 300384 P. R. China;
Institute of Advanced Electrochemical Energy &
School of Materials Science and EngineeringXi'an University of TechnologyXi'an 710048 P. R. China;
homojunctions; hydrothermal synthesis; nanostructures; photoelectrochemistry; water splitting;
机译:1d WO3纳米棒/ 2D WO3?X纳米薄片同源结结构,用于增强电荷分离和转移到有效的光电化学性能
机译:基于超薄类石墨氮化碳/ WO3半导体纳米异质结构的工程高效电荷转移,用于制造高性能非酶促光电化学葡萄糖传感器
机译:具有增强的界面电荷分离和全光谱光催化性能的分支WO3 @ W18O49同质化的合成
机译:基于1D TiO_2纳米棒和2D MnO_2纳米载体的3D分层体系结构高性能超级电容器
机译:通用结构环(Xxx-Pro-Gly-Yyy-Pro-Gly)的模型环六肽的合成和构象分析:相转移裂解方法,1D和2D NMR光谱以及荧光能量转移实验。
机译:改进的WO3 / CuWO4复合光阳极中用于光电化学水氧化的电荷分离
机译:高效的WO3 PhotoNode由PT层和PlasmOnic AG改装,用于增强电荷分离和转移以促进光电化学表演