Ni-Silica-based Catalysts for CH4 Reforming by CO2 with Enhanced Stability: Recent Designs and the Impacts of Ni Confinement, Promoters, and Core-Shell Structures

Q4 Energy

Journal of Nuclear Energy Science and Power Generation Technology Pub Date : 2021-01-26 DOI:10.21926/JEPT.2101007

O. Daoura, Maya Boutros, F. Launay

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引用次数: 1

Abstract

CO2 reforming of CH4, also referred to as the Dry Reforming of Methane (DRM), is considered an excellent method to produce H2 and CO (syngas), which are known to be used for the production of higher alkanes and oxygenates. Despite nickel’s moderate toxicity, Ni-based heterogeneous catalysts are considered excellent candidates for use in DRM due to their reasonable performances and economic advantages. However, these materials also present severe drawbacks, such as sintering of the active phase and coke (carbon) deposition, which may, in certain cases, lead to severe catalyst deactivation. Several synthesis strategies, mostly based on the stabilization of nickel through oxide support, have been developed to overcome these issues. Silica-based materials are investigated widely due to their availability, high surface area, and the confinement capacity conferred by their controlled porosity. The present review summarizes the progress in the design of Ni/silica-based catalysts for the dry reforming of methane between the years 2015 and 2018. The different strategies implemented are discussed to assist future research works in designing the anti-coking and anti-sintering nickel-silica-based catalysts.

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具有增强稳定性的CO2重整CH4的Ni-硅基催化剂:最新设计和Ni约束、促进剂和核壳结构的影响

CH4的CO2重整，也被称为甲烷的干重整(DRM)，被认为是生产H2和CO(合成气)的一种极好的方法，这两种合成气已知用于生产高级烷烃和含氧化合物。尽管镍的毒性适中，但由于其合理的性能和经济优势，镍基非均相催化剂被认为是DRM中应用的优秀候选人。然而，这些材料也存在严重的缺点，例如活性相烧结和焦(碳)沉积，这在某些情况下可能导致严重的催化剂失活。为了克服这些问题，已经开发了几种合成策略，主要是基于通过氧化物支撑镍的稳定。硅基材料由于其可用性、高表面积和可控孔隙率所带来的约束能力而受到广泛的研究。本文综述了2015年至2018年甲烷干重整用镍/硅基催化剂的设计进展。讨论了不同策略的实施，以帮助未来的研究工作，设计抗焦化和抗烧结镍硅基催化剂。

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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Journal of Nuclear Energy Science and Power Generation Technology Energy-Energy Engineering and Power Technology

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