Microstructure and bionic engineering of triphase reaction interface for zinc-air batteries

IF 33.6 1区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Progress in Materials Science Pub Date : 2024-08-27 DOI:10.1016/j.pmatsci.2024.101356
Shiyi Zeng , Gaigai Duan , Ruizhi Yu , Qin Qin , Shuijian He , Shaohua Jiang , Haoqi Yang , Xiaoshuai Han , Jingquan Han , Bao Yu Xia
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Abstract

Zinc-air batteries (ZABs) hold immense promise for energy storage due to their potential advantages over existing technologies in terms of electrochemical performance, cost, and safety. Nevertheless, the commercialization of ZABs is still limited by the slow cathode reaction, especially the oxygen reduction reaction (ORR) during discharge and the oxygen evolution reaction (OER) during charging. In the region of the triphase catalyst/electrolyte/gas interface that is decisive for the performance of ZABs, the low utilization of catalytic sites and the lack of oxygen transfer efficiency are the key constraints on the enhancement of performance. Recent advancements have aimed to address these interfacial limitations through innovative microstructure and bioinspired engineering approaches. This review delves into these latest developments, investigating interfacial issues at both the microscopic and mesoscopic levels. Furthermore, we explore the development of a comprehensive theory–structure–function relationship based on the triphase interface, encompassing in-depth understanding, structural considerations, and microenvironmental modulation. Finally, this review identifies the principal challenges, potential opportunities, and prospective avenues for the regulation of triphase interfaces. This review discusses established strategies and promising research directions aimed at further improving the performance of ZABs with the aim of advancing the commercialization of ZABs and paving the way toward clean and sustainable energy storage solutions.

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锌-空气电池三相反应界面的微观结构和仿生工程
锌空气电池(ZABs)在电化学性能、成本和安全性方面与现有技术相比具有潜在优势,因此在能源储存方面前景广阔。然而,锌空气电池的商业化仍然受到阴极反应缓慢的限制,尤其是放电时的氧还原反应(ORR)和充电时的氧进化反应(OER)。在对 ZAB 性能起决定性作用的催化剂/电解质/气体三相界面区域,催化位点利用率低和缺乏氧传递效率是提高性能的关键制约因素。最近的进展旨在通过创新的微结构和生物启发工程方法来解决这些界面限制。本综述深入探讨了这些最新进展,从微观和介观层面研究了界面问题。此外,我们还探讨了基于三相界面的综合理论-结构-功能关系的发展,包括深入理解、结构考虑和微环境调节。最后,本综述指出了调控三相界面的主要挑战、潜在机遇和前景。本综述讨论了旨在进一步提高 ZAB 性能的既定战略和有前途的研究方向,目的是推动 ZAB 的商业化,为实现清洁、可持续的能源存储解决方案铺平道路。
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来源期刊
Progress in Materials Science
Progress in Materials Science 工程技术-材料科学:综合
CiteScore
59.60
自引率
0.80%
发文量
101
审稿时长
11.4 months
期刊介绍: Progress in Materials Science is a journal that publishes authoritative and critical reviews of recent advances in the science of materials. The focus of the journal is on the fundamental aspects of materials science, particularly those concerning microstructure and nanostructure and their relationship to properties. Emphasis is also placed on the thermodynamics, kinetics, mechanisms, and modeling of processes within materials, as well as the understanding of material properties in engineering and other applications. The journal welcomes reviews from authors who are active leaders in the field of materials science and have a strong scientific track record. Materials of interest include metallic, ceramic, polymeric, biological, medical, and composite materials in all forms. Manuscripts submitted to Progress in Materials Science are generally longer than those found in other research journals. While the focus is on invited reviews, interested authors may submit a proposal for consideration. Non-invited manuscripts are required to be preceded by the submission of a proposal. Authors publishing in Progress in Materials Science have the option to publish their research via subscription or open access. Open access publication requires the author or research funder to meet a publication fee (APC). Abstracting and indexing services for Progress in Materials Science include Current Contents, Science Citation Index Expanded, Materials Science Citation Index, Chemical Abstracts, Engineering Index, INSPEC, and Scopus.
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