Materials, Electrodes, and Electrolytes Advances for Next Generation Lithium-based Anode-Free Batteries

IF 2.9 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Shubhadeep Pal, Xiaozhe Zhang, B. Babu, Xiaodong Lin, Jiande Wang, A. Vlad
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引用次数: 3

Abstract

The high volumetric stack energy density (∼ 750Wh L−1) is a must for grasping the practical application of electric vehicles with more than 100 km per day driving range. Such achievement requires significant advances in state-of-the-art battery technologies. The anode-free, derived from the metal-battery concept, germinates as one of the future potential battery configurations due to the highest, nearly theoretical gravimetric and volumetric energy density. Thus, moving from the graphite-based anode, where lithium is stored as ions, to anode-free cells, wherein lithium is plated as metal, can change the scenario of the electrochemical energy storing devices both in terms of energy density and fundamental mechanism. Although an anode-free battery theoretically provides higher stack energy density than a Li-ion battery, current developments are still underoptimized as these can barely hold for several cycles at room temperature due to the absence of an active lithium reservoir and still severe losses at the anode side. Hence electrolyte engineering with suitable electrode material choice is highly desirable and extremely challenging in realizing next-generation anode-free batteries. Herein, we summarize the current developments and achievements in the direction of anode-free batteries. Central emphasis is set on electrolyte chemistries that should on one hand allow for high-efficiency initial nucleation, followed by subsequent electrodeposition and electrodissolution of lithium metal, while also forming stable anodic interphases with the high energy cathode materials currently in use. We also prospect for better batteries with higher energy density beyond the present status.
下一代锂基无阳极电池的材料、电极和电解质进展
高体积电堆能量密度(~750Wh L−1)是掌握100以上电动汽车实际应用的必要条件 每天行驶里程公里。这样的成就需要在最先进的电池技术方面取得重大进展。源自金属电池概念的无阳极电池,由于其接近理论的最高重量和体积能量密度,成为未来潜在的电池配置之一。因此,从以离子形式储存锂的石墨基阳极转移到以金属形式镀锂的无阳极电池,可以在能量密度和基本机制方面改变电化学储能装置的情况。尽管无阳极电池理论上提供了比锂离子电池更高的堆叠能量密度,但目前的发展仍然没有得到充分优化,因为由于缺乏活性锂储层,并且在阳极侧仍然存在严重损失,这些电池在室温下几乎无法维持数个循环。因此,在实现下一代无阳极电池方面,具有适当电极材料选择的电解质工程是非常理想的,并且极具挑战性。在此,我们总结了无阳极电池的发展现状和成就。重点放在电解质化学上,一方面应允许高效的初始成核,随后进行锂金属的电沉积和电溶解,同时与目前使用的高能阴极材料形成稳定的阳极界面。我们还展望了在目前的状态之外,具有更高能量密度的更好的电池。
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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来源期刊
CiteScore
3.60
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