Unconventional strategies to break through the efficiency of light-driven water splitting: A review

Electron Pub Date : 2023-08-23 DOI:10.1002/elt2.4
Kang Wang, Dingwang Huang, Xiaowei Li, Kuang Feng, Ming Shao, Jiabao Yi, Weidong He, Liang Qiao
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引用次数: 1

Abstract

Semiconductor-based solar-driven water splitting technology is an environmentally friendly and cost-effective approach for the production of clean fuels. The overall solar-to-hydrogen efficiency of semiconductor-based photo(electro)catalysts is jointly determined by factors, such as light absorption efficiency of the photo(electro)catalysts, internal separation efficiency of charge carriers, and injection efficiency of surface charges. However, the traditional improvement strategies, such as morphology control, functional layer modification, and band alignment engineering, still have certain limitations in enhancing the conversion efficiency of the photo(electro)catalytic water splitting. Recently, unconventional enhancement strategies based on surface plasmonic effects, piezoelectric effects, thermoelectric effects, and magnetic effects have provided unique pathways for improving the solar-to-hydrogen efficiency of photo(electro)catalysts. Therefore, this review outlines the fundamental concepts of these physical effects and elucidates their intrinsic mechanisms in enhancing the efficiency of photo(electro)catalysts for water splitting process through practical application examples. Ultimately, the future development of unconventional strategies for enhancing photo(electro)catalytic water splitting is envisioned.

Abstract Image

突破光驱动水分解效率的非常规策略:综述
基于半导体的太阳能驱动水分解技术是生产清洁燃料的一种环保且具有成本效益的方法。半导体基光(电)催化剂的总太阳能-氢气效率由因素共同决定,如光(电(电)催化器的光吸收效率、电荷载体的内部分离效率和表面电荷的注入效率。然而,传统的改进策略,如形态控制、功能层改性和能带排列工程,在提高光(电)催化水分解的转化效率方面仍然存在一定的局限性。最近,基于表面等离子体效应、压电效应、热电效应和磁效应的非常规增强策略为提高光(电)催化剂的太阳能-氢气效率提供了独特的途径。因此,本文概述了这些物理效应的基本概念,并通过实际应用实例阐明了它们在提高水分解过程光(电)催化剂效率方面的内在机制。最终,展望了未来发展用于增强光(电)催化水分解的非常规策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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