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Toward waterproof magnesium metal anodes by uncovering water-induced passivation and drawing water-tolerant interphases

Engineering and Technology

Toward waterproof magnesium metal anodes by uncovering water-induced passivation and drawing water-tolerant interphases

Y. Li, X. Feng, et al.

This groundbreaking research conducted by Yuanjian Li, Xiang Feng, Gaoliang Yang, Wei Ying Lieu, Lin Fu, Chang Zhang, Zhenxiang Xing, Man-Fai Ng, Qianfan Zhang, Wei Liu, Jun Lu, and Zhi Wei Seh unveils the formation of detrimental MgH₂ during the passivation of magnesium in aqueous environments. Discover how a revolutionary hydrophobic interphase design results in stable cycling of magnesium batteries, paving the way for advancements in multivalent metal battery technology.

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Playback language: English
Abstract
Magnesium (Mg) metal is a promising anode for high-energy, cost-effective multivalent metal batteries but suffers from severe surface passivation, especially in aqueous solutions. This research reveals that MgH₂, along with MgO and Mg(OH)₂, forms during water-induced Mg passivation. The formation mechanism, spatial distribution, and detrimental effects of MgH₂ are revealed through experiments and theory. A graphite-based hydrophobic and Mg²⁺-permeable interphase, applied via pencil drawing, enables stable cycling in symmetric cells (>900 h) and full cells (>500 cycles) even after water contact. This understanding of MgH₂-involved passivation and the design of waterproof Mg anodes advances Mg metal battery development.
Publisher
Nature Communications
Published On
Oct 30, 2024
Authors
Yuanjian Li, Xiang Feng, Gaoliang Yang, Wei Ying Lieu, Lin Fu, Chang Zhang, Zhenxiang Xing, Man-Fai Ng, Qianfan Zhang, Wei Liu, Jun Lu, Zhi Wei Seh
Tags
Magnesium
battery technology
MgH₂
passivation
interphase design
multivalent metals
aqueous solutions

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