基于 TiO2 的太阳能制氢光催化剂的设计和结构-活性关系的最新进展综述

IF 3.2 Q2 CHEMISTRY, PHYSICAL
Energy advances Pub Date : 2024-06-10 DOI:10.1039/D4YA00249K
Sunesh S. Mani, Sivaraj Rajendran, Thomas Mathew and Chinnakonda S. Gopinath
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引用次数: 0

摘要

决定光催化剂复合材料用于太阳能制氢(无论是否使用牺牲剂)效率的主要问题是高效的可见光收集特性、电荷载体的高效分离及其对氧化还原位点的利用以及稳定性。因此,在过去的几十年里,人们一直致力于采用不同的方法,通过整合复合材料的组成成分来改变上述特性。在本综述中,我们旨在总结最近在基于二氧化钛的光催化剂复合材料用于太阳能制氢领域取得的主要进展。首先,我们介绍了材料集成方面的最新进展,讨论了二氧化钛与不同类别材料的集成,包括贵金属/3D 金属、金属氧化物/硫化物/硒化物、其他低带隙半导体、C 基材料和染料敏化剂。此外,我们还讨论了材料集成如何帮助定制电子和光学特性,以实现太阳能制氢的活性调整。随后,我们详细讨论了复合材料在制备方法、形态、晶体学切面、粒度、掺杂剂、煅烧温度以及太阳能制氢的结构-活性关系等方面的物理化学和电子特性的关键变化。此外,我们还讨论了以薄膜形式制造光催化剂的重要性,以及在不同的反应器设置中进行太阳能制氢以提高其光催化性能,同时解决设备可扩展性的问题。尽管在这一领域取得了重大进展,但要实现太阳能制氢的实际应用,仍需提高太阳能到氢气的转换效率。在这种情况下,通过整体水分裂将水直接转化为氢气,以及利用合适的光催化剂从废水或生物质成分中生产可再生氢气,都是提高能效的一些可行方法,而上述方向的持续研究是非常可取的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A review on the recent advances in the design and structure–activity relationship of TiO2-based photocatalysts for solar hydrogen production

A review on the recent advances in the design and structure–activity relationship of TiO2-based photocatalysts for solar hydrogen production

A review on the recent advances in the design and structure–activity relationship of TiO2-based photocatalysts for solar hydrogen production

The major issues that determine the efficiency of photocatalyst composite materials for solar hydrogen production, with or without a sacrificial agent, are efficient visible light harvesting properties, efficient separation of charge carriers and their utilization of redox sites, and stability. Thus, significant efforts have been devoted in the past few decades to modify the above characteristics by integrating constituent components of composites using different approaches. In the present review, we aim to summarize the recent advances, predominantly, in the area of TiO2-based photocatalyst composites for solar hydrogen production. Firstly, we present the recent progress in material integration aspects by discussing the integration of TiO2 with different categories of materials, including noble/3d metals, metal oxides/sulphides/selenides, other low bandgap semiconductors, C-based materials, and dye sensitizers. Furthermore, we discuss how material integration helps in tailoring the electronic and optical properties for activity tuning in solar H2 production. Subsequently, critical changes in the physico-chemical and electronic properties of composites with respect to their preparation methods, morphology, crystallographic facets, particle size, dopant, calcination temperature, and structure–activity relationship to solar hydrogen production are addressed in detail. Moreover, we discuss the importance of fabricating a photocatalyst in a thin film form and performing solar hydrogen production in different reactor set-ups for enhancing its photocatalytic performance, while addressing device scalability. Despite the significant advancements made in this field, solar-to-hydrogen conversion efficiency still needs to be improved to realise the practical application of solar hydrogen production. In this case, the direct conversion of water to hydrogen via overall water splitting and renewable H2 production from wastewater or biomass components by employing suitable photocatalysts are some possible ways to improve the energy efficiency, and continuous research in the above directions is highly desirable.

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