DFT insights into oxygen vacancy formation and chemical looping dry reforming of methane on metal-substituted CeO2 (111) surface

IF 4.3 3区 工程技术 Q2 ENGINEERING, CHEMICAL
Mingyi Chen, Zeshan Wang, Yuelun Li, Yuxin Wang, Lei Jiang, Huicong Zuo, Linan Huang, Yuhao Wang, Dong Tian, Hua Wang, Kongzhai Li
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Abstract

The oxygen vacancy formation energy and chemical looping dry reforming of methane over metal-substituted CeO2 (111) are investigated based on density functional theory calculations. The calculated results indicate that among the various metals that can substitute for the Ce atom in the CeO2(111) surface, Zn substitution results in the lowest oxygen vacancy formation energy. For the activation of CH4 on CeO2 (111) and Zn-substituted CeO2 (111) surfaces, the calculated results illustrate that the dissociation process of CH3(ads) is very difficult on pristine surfaces and unfavorable for CHO(ads) on substituted surfaces. Furthermore, the dissociative adsorption of CO and H2 on the Zn-substituted CeO2 (111) surface requires high energy, which is unfavorable for syngas production. This work demonstrates that excessive formation of oxygen vacancy can lead to excessively high adsorption energies, thus limiting the conversion efficiency of the reaction intermediates. This finding provides important guidance and application prospects for the design and optimization of oxygen carrier materials, especially in the field of chemical looping dry methane reforming to syngas.

Abstract Image

DFT 对金属取代 CeO2 (111) 表面氧空位形成和甲烷化学循环干重整的见解
基于密度泛函理论计算,研究了金属取代的 CeO2 (111) 上的氧空位形成能和甲烷的化学循环干重整。计算结果表明,在可以替代 CeO2(111)表面 Ce 原子的各种金属中,Zn 的替代导致氧空位形成能最低。对于 CeO2(111)和 Zn 取代的 CeO2(111)表面上 CH4 的活化,计算结果说明在原始表面上 CH3(吸附)的解离过程非常困难,而在取代表面上 CHO(吸附)的解离过程不利。此外,CO 和 H2 在 Zn 取代的 CeO2 (111) 表面上的解离吸附需要很高的能量,这不利于合成气的生产。这项研究表明,氧空位的过度形成会导致过高的吸附能,从而限制反应中间产物的转化效率。这一发现为载氧材料的设计和优化提供了重要的指导和应用前景,尤其是在化学循环干甲烷重整制合成气领域。
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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来源期刊
CiteScore
7.60
自引率
6.70%
发文量
868
审稿时长
1 months
期刊介绍: Frontiers of Chemical Science and Engineering presents the latest developments in chemical science and engineering, emphasizing emerging and multidisciplinary fields and international trends in research and development. The journal promotes communication and exchange between scientists all over the world. The contents include original reviews, research papers and short communications. Coverage includes catalysis and reaction engineering, clean energy, functional material, nanotechnology and nanoscience, biomaterials and biotechnology, particle technology and multiphase processing, separation science and technology, sustainable technologies and green processing.
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