Advances and challenges with SOEC high temperature co-electrolysis of CO2/H2O: Materials development and technological design

Shuang Zong , Xiufei Zhao , Linda L. Jewell , Yusheng Zhang , Xinying Liu
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Abstract

Higher electrolysis efficiency than that achieved with conventional electrolysis and integrated fuel production would help to reduce dependence on bio-energy further. In this regard, solid oxide electrolyzer (SOEC) technology is of particular interest because of its unrivaled conversion efficiency, due to the favorable thermodynamics and kinetics at higher operating temperatures. In particular, SOEC high-temperature co-electrolysis (HTCE) of CO2/H2O can convert CO2 into valuable chemicals and fuels, which will help to reduce reliance on fossil fuels and mitigate greenhouse gas emissions. In this report, we present a comprehensive overview of recent research progress made with SOEC HTCE of CO2/H2O. The main focus areas are the development history, the basic principle and the reaction mechanism of HTCE of CO2/H2O using SOEC. The fuel electrode and oxygen electrode materials for SOEC HTCE of CO2/H2O are classified and introduced. The factors that affect the co-electrolysis reaction process are also described in detail, and the optimization strategy of the process conditions is explained to provide a better understanding of the SOEC HTCE process. The challenges and possible future development directions are also suggested, as guidance for future research.

Abstract Image

SOEC 高温共电解 CO2/H2O 的进展与挑战:材料开发与技术设计
与传统电解和综合燃料生产相比,更高的电解效率将有助于进一步减少对生物能源的依赖。在这方面,固体氧化物电解槽(SOEC)技术因其在较高工作温度下有利的热力学和动力学特性而具有无与伦比的转换效率,因此特别受到关注。特别是,SOEC CO2/H2O 高温共电解(HTCE)技术可将 CO2 转化为有价值的化学品和燃料,这将有助于减少对化石燃料的依赖并减少温室气体排放。在本报告中,我们全面概述了 CO2/H2O SOEC HTCE 的最新研究进展。重点介绍利用 SOEC 进行 CO2/H2O HTCE 的发展历程、基本原理和反应机理。对 SOEC CO2/H2O HTCE 的燃料电极和氧气电极材料进行了分类和介绍。此外,还详细描述了影响共电解反应过程的因素,并解释了工艺条件的优化策略,以便更好地理解 SOEC HTCE 过程。此外,还提出了面临的挑战和未来可能的发展方向,为今后的研究提供指导。
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