简编
分解水
路径(计算)
铟
硫化锌
制氢
硫化氢
生产(经济)
纳米技术
工程物理
环境科学
计算机科学
材料科学
氢
锌
工艺工程
工程类
光电子学
物理
化学
光催化
硫黄
冶金
地理
催化作用
考古
生物化学
程序设计语言
宏观经济学
量子力学
经济
作者
Wei‐Kean Chong,Boon‐Junn Ng,Lling‐Lling Tan,Siang‐Piao Chai
摘要
Photocatalytic water splitting represents a leading approach to harness the abundant solar energy, producing hydrogen as a clean and sustainable energy carrier. Zinc indium sulfide (ZIS) emerges as one of the most captivating candidates attributed to its unique physicochemical and photophysical properties, attracting much interest and holding significant promise in this domain. To develop a highly efficient ZIS-based photocatalytic system for green energy production, it is paramount to comprehensively understand the strengths and limitations of ZIS, particularly within the framework of solar-driven water splitting. This review elucidates the three sequential steps that govern the overall efficiency of ZIS with a sharp focus on the mechanisms and inherent drawbacks associated with each phase, including commonly overlooked aspects such as the jeopardising photocorrosion issue, the neglected oxidative counter surface reaction kinetics in overall water splitting, the sluggish photocarrier dynamics and the undesired side redox reactions. Multifarious material design strategies are discussed to specifically mitigate the formidable limitations and bottleneck issues. This review concludes with the current state of ZIS-based photocatalytic water splitting systems, followed by personal perspectives aimed at elevating the field to practical consideration for future endeavours towards sustainable hydrogen production through solar-driven water splitting.
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