电催化驱动的可持续塑料废物再循环

Electron Pub Date : 2024-04-29 DOI:10.1002/elt2.34
Gaihong Wang, Zhijie Chen, Wei Wei, Bing-Jie Ni
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引用次数: 0

摘要

塑料废弃物数量大、天然耐降解,在全球引发了越来越多的环境问题。为实现塑料废弃物的升级再循环,电催化驱动工艺因其操作条件温和、反应选择性高、碳排放低等优点而成为一种极具吸引力的选择。在此,本综述全面概述了通过电催化将塑料废弃物升级的过程。具体而言,本文讨论了关键的电氧化过程,包括塑料电转化过程中的目标产物、中间产物和反应途径。随后,总结了先进的电化学系统,包括塑料单体阳极氧化和增值阴极还原以及光参与电解过程的整合。重点介绍了具有更高活性的电催化剂的设计策略,并阐明了塑料废弃物电催化氧化的催化机理。为促进电化学驱动的塑料废物可持续升级再循环,进一步提出了挑战和机遇。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Electrocatalysis-driven sustainable plastic waste upcycling

Electrocatalysis-driven sustainable plastic waste upcycling

With large quantities and natural resistance to degradation, plastic waste raises growing environmental concerns in the world. To achieve the upcycling of plastic waste into value-added products, the electrocatalytic-driven process is emerging as an attractive option due to the mild operation conditions, high reaction selectivity, and low carbon emission. Herein, this review provides a comprehensive overview of the upgrading of plastic waste via electrocatalysis. Specifically, key electrooxidation processes including the target products, intermediates and reaction pathways in the plastic electro-reforming process are discussed. Subsequently, advanced electrochemical systems, including the integration of anodic plastic monomer oxidation and value-added cathodic reduction and photo-involved electrolysis processes, are summarized. The design strategies of electrocatalysts with enhanced activity are highlighted and catalytic mechanisms in the electrocatalytic oxidation of plastic waste are elucidated. To promote the electrochemistry-driven sustainable upcycling of plastic waste, challenges and opportunities are further put forward.

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