人工光合作用
化学工程
人造光
分解水
可见光谱
可持续能源
材料科学
纳米技术
物理
化学
光电子学
光催化
可再生能源
光学
电气工程
催化作用
工程类
生物化学
照度
作者
Xinyu Wang,Boyang Zhang,Jicong Zhang,Xiaoyu Jiang,Kaiwei Liu,Haifeng Wang,Xinyi Yuan,Haiyi Xu,Yijun Zheng,Guijun Ma,Chao Zhong
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2024-06-12
卷期号:10 (24): eadn6211-eadn6211
被引量:13
标识
DOI:10.1126/sciadv.adn6211
摘要
Semi-artificial Z-scheme systems offer promising potential toward efficient solar-to-chemical conversion, yet sustainable and stable designs are currently lacking. Here, we developed a sustainable hybrid Z-scheme system capable for visible light-driven overall water splitting by integrating the durability of inorganic photocatalysts with the interfacial adhesion and regenerative property of bacterial biofilms. The Z-scheme configuration is fabricated by drop casting a mixture of photocatalysts onto a glass plate, followed by the growth of biofilms for conformal conductive paste through oxidative polymerization of pyrrole molecules. Notably, the system exhibited scalability indicated by consistent catalytic efficiency across various sheet areas, resistance observed by remarkable maintaining of photocatalytic efficiency across a range of background pressures, and high stability as evidenced by minimal decay of photocatalytic efficiency after 100-hour reaction. Our work thus provides a promising avenue toward sustainable and high-efficiency artificial photosynthesis, contributing to the broader goal of sustainable energy solutions.
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