Highly active air electrode catalysts for Zn-air batteries: Catalytic mechanism and active center from obfuscation to clearness

Wenhui Deng, Zirui Song, Mingjun Jing, Tianjing Wu, Wenzhang Li, Guoqiang Zou
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Abstract

Carbon-based materials have been found to accelerate the sluggish kinetic reaction and are largely subject to the overall Zn-air batteries (ZABs) property, while their full catalytic mechanism is still not excavated because of the indistinct internal structure and immature in-situ technology. Up to now, systematic methods have been utilized to study and design promising high-performance carbon-based catalysts. To resolve the real active units and catalytic mechanism, developing molecular catalyst is a significant strategy. Herein, the review will initiate to briefly introduce the working principle and composition of ZABs. An important statement is correspondingly provided about the typical structure and catalytic mechanisms for the air cathode material. It also presents the tremendous endeavors on the catalytic performance and stability of carbon-based material. Furthermore, combined with theoretical calculation, the self-defined active sites are analyzed to understand the catalytic character, where the molecular catalyst is subsequently summarized and discussed through highlighting the unambiguous and controllable structure, in the hope of surfacing the optimum catalyst. Building on the fundamental understanding of carbon-based and molecular catalysts, this review is expected to provide guidance and direction toward designing future mechanistic studies and ORR electrocatalysts.

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用于锌-空气电池的高活性空气电极催化剂:从模糊到清晰的催化机理和活性中心
碳基材料可加速迟缓的动力学反应,并在很大程度上影响锌-空气电池(ZABs)的整体性能,但由于其内部结构不清晰和原位技术不成熟,其完整的催化机理仍未被挖掘出来。迄今为止,人们一直在利用系统方法研究和设计有前景的高性能碳基催化剂。要解决真正的活性单元和催化机理,开发分子催化剂是一项重要战略。本综述将首先简要介绍 ZAB 的工作原理和组成。相应地,对空气阴极材料的典型结构和催化机制进行了重要阐述。文章还介绍了在碳基材料的催化性能和稳定性方面所做的巨大努力。此外,还结合理论计算,分析了自定活性位点,以了解催化特性,并通过突出明确可控的结构,对分子催化剂进行了总结和讨论,希望能找到最佳催化剂。基于对碳基催化剂和分子催化剂的基本理解,本综述有望为未来的机理研究和 ORR 电催化剂设计提供指导和方向。
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Issue Information Front Cover: Carbon Neutralization, Volume 3, Issue 6, November 2024 Inside Back Cover Image: Carbon Neutralization, Volume 3, Issue 6, November 2024 Back Cover Image: Carbon Neutralization, Volume 3, Issue 6, November 2024 A chronicle of titanium niobium oxide materials for high-performance lithium-ion batteries: From laboratory to industry
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