Sustainable nanostructured electrolyte additives for stable metal anodes

IF 42.9 Q1 ELECTROCHEMISTRY

eScience Pub Date : 2024-08-01 DOI:10.1016/j.esci.2024.100248

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Abstract

Metal anodes (e.g., Li and Zn) are promising candidates for high-energy and high-power rechargeable batteries. However, the commercialization of metal anodes is hampered by irregular dendrite growth, which severely deteriorates the safety and cyclability of metal anodes. Optimizing the electrolyte by nanostructured additives to regulate the metal deposition shows great potential since the electrochemically nonreactive feature endows the regulation function with good sustainability. In this manuscript, the fundamental dendrite formation models and key parameters for stabilizing metal anode are first discussed. The progress and functional mechanism of nanostructured additives for regulating the metal deposition are summarized in terms of regulatory model, i.e., deposition-, adsorption- and dispersion-type. Finally, we also provide a detailed concluding outlook, pointing out the future trend of selecting new nanostructured additive candidates and elucidating synergistic effects and underlying mechanisms with the key attention being given to the assessments of practicality.

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用于稳定金属阳极的可持续纳米结构电解质添加剂

金属阳极（如锂和锌）是高能量和高功率充电电池的理想候选材料。然而，金属阳极的商业化受到不规则枝晶生长的阻碍，这严重降低了金属阳极的安全性和循环性。通过纳米结构添加剂优化电解质以调节金属沉积显示出巨大的潜力，因为电化学非反应特性使调节功能具有良好的可持续性。本手稿首先讨论了树枝晶形成的基本模型和稳定金属阳极的关键参数。从沉积型、吸附型和分散型等调控模式的角度，总结了纳米结构添加剂调控金属沉积的进展和功能机理。最后，我们还进行了详细的总结性展望，指出了选择新的纳米结构添加剂候选物、阐明协同效应和内在机制的未来趋势，并重点关注了实用性评估。

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来源期刊

eScience

CiteScore

33.70

自引率

0.00%

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