Recent advances in plasma-based methane reforming for syngas production

IF 9.3 2区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Current Opinion in Green and Sustainable Chemistry Pub Date : 2024-12-01 DOI:10.1016/j.cogsc.2024.100981

Kaiyi Wang , Xuping Ren , Geyuan Yin , Erjiang Hu , Hao Zhang

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Abstract

Methane reforming, a pivotal process for converting the greenhouse gases CO₂ and CH₄ into valuable syngas, can be efficiently conducted using plasma technology at relatively low temperatures. This minireview highlights recent advancements in plasma-based methane reforming technologies, particularly dry reforming (DRM), with a focus on reaction performance, plasma-catalysis and carbon deposition. Microwave (MW) plasma-based DRM achieves high conversion, offers strong processing capabilities, and operates without the need for catalysts or electrodes, making it highly promising for industrial-scale applications. The integration of plasma with catalysts, especially in dielectric barrier discharge (DBD), significantly reduces the operation temperature of the DRM process. Bi-reforming (BRM) and tri-reforming of methane (TRM), which involve the addition of H₂O and/or O₂ to the dry reforming process, improve syngas quality by producing a more optimal H₂/CO ratio close to 2. Meanwhile, these approaches significantly reduce the carbon deposition, enhancing reactor stability and extending its operational lifespan.

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等离子体甲烷重整合成气研究进展

甲烷重整是将温室气体CO2和CH4转化为有价值的合成气的关键过程，利用等离子体技术可以在相对较低的温度下高效地进行。本文重点介绍了等离子体甲烷重整技术的最新进展，特别是干式重整（DRM），重点介绍了反应性能、等离子体催化和碳沉积。基于微波（MW）等离子体的DRM实现了高转化率，提供了强大的处理能力，并且在不需要催化剂或电极的情况下运行，使其在工业规模应用中具有很大的前景。等离子体与催化剂的集成，特别是在介质阻挡放电（DBD）中，显著降低了DRM工艺的操作温度。甲烷的双重整（BRM）和三重整（TRM）在干重整过程中加入H2O和/或O2，通过产生接近2的更优的H2/CO比来提高合成气质量。同时，这些方法显著减少了碳沉积，提高了反应堆的稳定性，延长了反应堆的使用寿命。

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来源期刊

Current Opinion in Green and Sustainable Chemistry Chemical Engineering-Catalysis

CiteScore

16.00

自引率

2.20%

发文量

140

审稿时长

103 days

期刊介绍： The Current Opinion journals address the challenge specialists face in keeping up with the expanding information in their fields. In Current Opinion in Green and Sustainable Chemistry, experts present views on recent advances in a clear and readable form. The journal also provides evaluations of the most noteworthy papers, annotated by experts, from the extensive pool of original publications in Green and Sustainable Chemistry.