Toward thin and stable anodes for practical lithium metal batteries: A review, strategies, and perspectives

IF 10.7 Q1 CHEMISTRY, PHYSICAL EcoMat Pub Date : 2023-09-28 DOI:10.1002/eom2.12416
Jiyoung Lee, Seung Hyun Jeong, Jong Seok Nam, Mingyu Sagong, Jaewan Ahn, Haeseong Lim, Il-Doo Kim
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Abstract

The lithium metal battery (LMB) is a promising energy storage platform with a distinctively high energy density in theory, outperforming even those of conventional Li-ion batteries. In practice, however, the actual achievable energy density of LMBs is significantly limited due to the Li metal anode (LMA) being too thick (50–250 μm), and there are difficulties with expanding the highly reactive Li metal into large-format cells due to safety concerns. Therefore, the recent focus of LMB research is headed toward the development of a thin and stable LMA. However, as the thickness of Li anode decreases (≤20 μm) and the absolute size of the battery cell increases, interfacial reactions on the Li surface become more active, potentially leading to fatal thermal runaway. In this regard, there is still much demand for the development of novel manufacturing technologies to overcome this issue and produce thin and stable Li metal. Considering these things, in this review, we initially examine the fundamentals regarding the deployment of LMAs using a number of essential metrics. Then, we introduce recent strategies employed for designing thin and stable Li anodes including host matrix architecturing, interface stabilization, and other advanced modifications. Finally, we propose future directions for the realization of practical LMBs and their potential applications in various battery systems, encompassing Na, K, and Zn-based batteries. We anticipate that ultra-thin and ultra-stable metal anodes would find widespread utilization in secondary battery applications with high-power requirements.

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为实用锂金属电池开发薄而稳定的阳极:回顾、战略和展望
锂金属电池(LMB)是一种前景广阔的储能平台,理论上具有明显的高能量密度,甚至优于传统的锂离子电池。但在实践中,由于锂金属阳极(LMA)太厚(50-250 μm),而且出于安全考虑,很难将高活性锂金属扩展到大尺寸电池中,因此锂金属电池的实际能量密度受到很大限制。因此,近年来 LMB 研究的重点是开发薄而稳定的 LMA。然而,随着锂阳极厚度的减小(≤20 μm)和电池绝对尺寸的增大,锂表面的界面反应会变得更加活跃,有可能导致致命的热失控。因此,仍然需要开发新的制造技术来克服这一问题,生产出薄而稳定的金属锂。考虑到这些问题,在本综述中,我们首先使用一些基本指标来研究有关锂金属氧化物部署的基本原理。然后,我们介绍了设计薄而稳定的锂阳极所采用的最新策略,包括主基体架构、界面稳定和其他先进的修改。最后,我们提出了实现实用 LMB 的未来方向及其在各种电池系统(包括 Na、K 和 Zn 电池)中的潜在应用。我们预计,超薄、超稳定金属阳极将在具有高功率要求的二次电池应用中得到广泛应用。
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来源期刊
CiteScore
17.30
自引率
0.00%
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0
审稿时长
4 weeks
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