Multifunctional diamond-based catalysts: Promising candidates for energy conversions in extreme environments—A mini-review

Electron Pub Date : 2024-07-01 DOI:10.1002/elt2.45
Ziwei Zhao, Xiaowu Gao, Hansong Zhang, Keran Jiao, Pengfei Song, Yumin Zhang, Yongjie Wang, Jiaqi Zhu
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Abstract

In order to properly utilize the abundant CO2 and water resources, various catalytic materials have been developed to convert them into valuable chemicals as renewable fuels electrochemically or photochemically. Currently, most studies are conducted under mild laboratory conditions, but for some extreme environments, such as Mars and space stations, there is an urgent need to develop new catalysts satisfying such special requirements. Conventional catalytic materials mainly focus on metals and narrow bandgap semiconductor materials, while the research on wide and ultrawide bandgap materials that can inherently withstand extreme conditions has not received enough attention. Given the robust stability and excellent physico-chemical properties of diamond, it can be expected to perform in harsh environments for electrocatalysis or photocatalysis that has not been investigated thoroughly. Here, this review summarizes the catalytic functionality of diamond-based electrodes with various but tunable product selectivity to obtain the varied C1 or C2+ products, and discusses some important factors playing a key role in manipulating the catalytic activity. Moreover, the unique solvation electron effect of diamond gives it a significant advantage in photocatalytic conversions which is also summarized in this mini-review. In the end, prospects are made for the application of diamond-based catalysts under various extreme conditions. The challenges that may be faced in practical applications are also summarized and future breakthrough directions are proposed at the end.

Abstract Image

多功能金刚石催化剂:在极端环境中进行能量转换的理想候选者--微型综述
为了合理利用丰富的二氧化碳和水资源,人们开发了各种催化材料,通过电化学或光化学方法将其转化为有价值的化学品,作为可再生燃料。目前,大多数研究都是在温和的实验室条件下进行的,但对于一些极端环境,如火星和空间站,迫切需要开发新的催化剂来满足这些特殊要求。传统的催化材料主要集中在金属和窄带隙半导体材料上,而本身就能承受极端条件的宽带隙和超宽带隙材料的研究还没有得到足够的重视。鉴于金刚石具有强大的稳定性和优异的物理化学特性,它有望在恶劣环境中发挥电催化或光催化的作用,但这方面的研究还不够深入。本综述总结了金刚石电极的催化功能,它具有多种可调的产物选择性,可获得不同的 C1 或 C2+ 产物,并讨论了在操纵催化活性过程中起关键作用的一些重要因素。此外,金刚石独特的溶解电子效应使其在光催化转化方面具有显著优势,本微型综述也对此进行了总结。最后,还展望了金刚石催化剂在各种极端条件下的应用前景。最后还总结了实际应用中可能面临的挑战,并提出了未来的突破方向。
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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