ZnO for Photoelectrochemical Hydrogen Generation

IF 4.2 4区环境科学与生态学 Q2 ENGINEERING, ENVIRONMENTAL Clean Technologies and Environmental Policy Pub Date : 2023-10-20 DOI:10.3390/cleantechnol5040063

Dina Bakranova, David Nagel

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Abstract

The rise in the Earth’s surface temperature on an annual basis has stimulated scientific and engineering interest in developing and implementing alternative energy sources. Besides cost, the main requirements for alternative energy sources are renewability and environmental friendliness. A prominent representative that allows the production of “green” energy is the conversion of solar photons into a practical energy source. Among the existing approaches in solar energy conversion, the process of photoelectrochemical (PEC) hydrogen extraction from water, which mimics natural photosynthesis, is promising. However, direct decomposition of water by sunlight is practically impossible since water is transparent to light waves longer than 190 nm. Therefore, applying a photoelectrochemical process using semiconductor materials and organic compounds is necessary. Semiconductor materials possessing appropriately positioned valence and conduction bands are vital constituents of photoelectrodes. Certain materials exhibit semiconductor characteristics that facilitate the reduction-oxidation (RedOx) reaction of water (H2O) under specific circumstances. ZnO holds a unique position in the field of photocatalysis due to its outstanding characteristics, including remarkable electron mobility, high thermal conductivity, transparency, and more. This article offers an overview of studies exploring ZnO’s role as a photocatalyst in the generation of hydrogen from water.

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光电化学制氢用ZnO

地球表面温度每年都在上升，这激发了科学和工程对开发和实施替代能源的兴趣。除了成本之外，对替代能源的主要要求是可再生和环境友好。能够产生“绿色”能源的一个突出代表是将太阳能光子转化为实用的能源。在现有的太阳能转换方法中，模拟自然光合作用的光电化学从水中提取氢的方法是很有前途的。但是，由于水对波长超过190纳米的光波是透明的，因此用太阳光直接分解水实际上是不可能的。因此，应用半导体材料和有机化合物的光电化学过程是必要的。具有合适位置的价带和导带的半导体材料是光电极的重要组成部分。某些材料表现出半导体特性，在特定情况下促进水(H2O)的还原氧化(RedOx)反应。ZnO具有优异的电子迁移率、高导热性、透明性等特性，在光催化领域占有独特的地位。本文综述了氧化锌作为光催化剂在水制氢中的作用。

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来源期刊

Clean Technologies and Environmental Policy 环境科学-工程：环境

CiteScore

8.10

自引率

7.00%

发文量

179

审稿时长

8 months

期刊介绍： This journal publishes papers that aid in the development, demonstration, and commercialization of cleaner products and processes as well as effective environmental policy strategies. As its title suggests, the journal has two major thrusts: Clean Technologies and Environmental Policy. The Clean Technology thrust addresses the science and engineering of clean technologies. Moreover, it examines mathematical and computer-based methods and models for designing, analyzing, and measuring the cleanliness of products and processes. The Environmental Policy thrust covers research advances in scientific, social, behavioral, and economics disciplines that are relevant to complex environmental policy issues. In addition to research papers, the journal offers policy-oriented commentaries from world renowned leaders in environmental technology and policy research. It also features special issues focusing on topics of international concern.