热氢化或等离子氢化法制备的黑色二氧化钛的特性和光催化应用

Manjunath Veeranna Shinnur, MariaPia Pedeferri, Maria Vittoria Diamanti
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引用次数: 0

摘要

近几十年来,用于能源和环境应用的 TiO2 纳米材料光催化剂引起了研究人员的兴趣。宽带隙(3-3.2 eV)限制了光的吸收量,相对较高的电荷载流子重组限制了光催化活性,这些都是关键瓶颈。2011 年,黑色二氧化钛的发现引发了全球研究的关注,为解决这一难题带来了新的希望。黑色二氧化钛纳米结构表面存在的 Ti3+ 物种和氧空位等缺陷(因氧化物在还原过程后呈现的颜色而得名)是增强紫外线到可见光的光学吸收的原因。本综述重点介绍了最近在开发黑色二氧化钛纳米材料方面取得的进展,包括对合成过程的描述,重点是将二氧化钛转化为黑色二氧化钛的等离子体和热方法,对黑色二氧化钛特性的讨论,以及黑色二氧化钛的各种应用,最后还讨论了一些必须解决的重要问题,以实现所期望的未来发展,特别是在太阳能生产和污染物分解方面。
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Properties and photocatalytic applications of black TiO2 produced by thermal or plasma hydrogenation

TiO2 nanomaterial photocatalysts for energy and environmental applications have attracted the interest of researchers in recent decades. The broad bandgap (3–3.2 eV), which limits the quantity of light absorption, and the relatively high charge-carrier recombination, which limits photocatalytic activity, are the key bottlenecks. The discovery of black TiO2 in 2011 sparked global research attention and renewed optimism for solving this challenge. The presence of defects such as Ti3+ species and oxygen vacancies at the surface of black TiO2 nanostructures – so called due to the color assumed by the oxide following a reduction process - is responsible for enhancing the optical absorption of UV to visible light. This review focuses on recent advancements in the development of black TiO2 nanomaterials, including description of the synthesis processes, focused on plasma and thermal methods to convert TiO2 to black TiO2, discussion of black TiO2 properties, and diverse applications of black TiO2, and concludes by addressing some essential concerns that must be tackled to unleash the desired future developments, particularly for solar energy production and pollutants decomposition.

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来源期刊
Current Research in Green and Sustainable Chemistry
Current Research in Green and Sustainable Chemistry Materials Science-Materials Chemistry
CiteScore
11.20
自引率
0.00%
发文量
116
审稿时长
78 days
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