电解重整为固体废物注入新生命

EES catalysis Pub Date : 2023-08-29 DOI:10.1039/D3EY00147D
Yingxin Ma, Yu Zhang, Wenfang Yuan, Mengmeng Du, Sailei Kang and Bocheng Qiu
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引用次数: 0

摘要

升级可再生电力系统容量的努力,加上减轻我们对有限化石资源的依赖,促进了对具有经济竞争力和环境友好技术的探索,这些技术可以引导可再生原料转化为燃料、化学品和材料。一种有吸引力的补救措施是利用无处不在的固体废物(如生物质和塑料)作为平台前体,合成全球日常使用的有价值的化学品。尽管生物质的定义功能不同于塑料,但它们在聚合物性质和连接组成单体的键类型方面具有相当大的结构相似性,从而在它们的增值途径之间建立了密切的相关性。因此,将生物质和塑料废物升级为商品化学品的电重整方法是可行的,同时也很有趣。在这篇综述中,我们将生物质和塑料的电化学定价进行了比较,重点是阐明每种记录反应的最先进催化剂,并评估其相应的技术经济性。同时,对固体废物的预处理方法以及计算模拟和操作光谱的进展进行了详细的综述。最后,我们全面讨论了催化剂和反应器优化、大规模操作以及技术灵活性和兼容性方面的新挑战。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Electroreforming injects a new life into solid waste

Electroreforming injects a new life into solid waste

The drive to upgrade the system capacity for renewable electricity, coupled with relieving our reliance on the finite fossil resources, promotes the exploration for economically competitive and environmentally friendly technologies that can steer the conversion of the renewable feedstocks into fuels, chemicals, and materials. An appealing remedy is to utilize ubiquitous solid waste (e.g., biomass and plastics) as platform precursors to synthesize valuable chemicals used globally on a daily basis. Although the defined functionality of biomass differs from that of plastics, they share considerable structural similarities in terms of the polymeric nature and the type of bonds connecting the constituent monomers, thereby establishing an intimate correlation between their valorization routes. Electroreforming methodology towards upgrading of biomass and plastic wastes into commodity chemicals coupled with hydrogen evolution is thus viable and meanwhile remains intriguing. In this review, we draw parallels between electrochemical valorization of biomass and plastics, with a focus on elucidating the state-of-the-art catalysts for each documented reaction and evaluating their corresponding techno-economy. In parallel, the pretreatment methodologies for raw solid waste and the progress in computational simulations and operando spectroscopies are reviewed in detail. We conclude with a comprehensive discussion of the emerging challenges for catalyst and reactor optimization, large-scale operation, and technology flexibility and compatibility.

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