A review of the preparation process and anode stabilization strategies of Zn microbatteries

iEnergy Pub Date : 2024-03-01 DOI:10.23919/IEN.2024.0003

Xin Guo;Sajian Wu;Xiaojun Guo;Dexu Zheng;Yan Zhu;Jishuang Liu;Xinxin Xing;Haoxiang Zhang;Shengzhong Frank Liu

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Abstract

As a burgeoning energy storage technology, Zn microbatteries (ZMBs) exhibit expansive potential for applications. This article initially presents a method for fabricating ZMBs utilizing interdigitated electrodes, employing advanced techniques such as 3D printing, screen printing, laser etching, and electrodeposition. These methodologies play a crucial role in mitigating anode-related issues, consequently enhancing battery performance. Subsequently, the challenges encountered by ZMBs anodes, including dendrite formation, corrosion passivation, hydrogen evolution, and Zn cycle exfoliation, are thoroughly examined. Lastly, a comprehensive strategy for stabilizing the anode is delineated, encompassing anode material selection, anode structure construction, interface engineering, and electrolyte optimization. In essence, the preparation and fine-tuning of ZMBs present ongoing challenges. With continued research and development efforts, it is anticipated that ZMBs will attain efficient, stable, and secure performance on the microscale, offering enduring and dependable energy solutions for applications in miniature electronic devices and wearable technology.

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锌微型电池的制备工艺和阳极稳定策略综述

作为一种新兴的储能技术，锌微电池（ZMB）展现出巨大的应用潜力。本文初步介绍了一种利用相互咬合电极制造 ZMB 的方法，其中采用了 3D 打印、丝网印刷、激光蚀刻和电沉积等先进技术。这些方法在缓解阳极相关问题方面发挥了重要作用，从而提高了电池性能。随后，深入研究了 ZMB 阳极遇到的挑战，包括枝晶形成、腐蚀钝化、氢演化和锌循环剥离。最后，阐述了稳定阳极的综合策略，包括阳极材料选择、阳极结构构建、界面工程和电解质优化。从本质上讲，ZMB 的制备和微调是一项持续的挑战。随着研发工作的不断深入，预计 ZMB 将在微米尺度上实现高效、稳定和安全的性能，为微型电子设备和可穿戴技术的应用提供持久可靠的能源解决方案。

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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