Synthesis, Structure Transformation, and Electrochemical Properties of Li2MgSi as a Novel Anode for Li-lon Batteries

In this work, a novel hexagonal Li2MgSi anode is successfully prepared through a hydrogen‐driven chemical reaction technique. Electrochemical tests indicate significantly improved cycling stability for the as‐synthesized Li2MgSi compared with that of Mg2Si. Ball‐milling treatment induces a polymorph...

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Bibliographic Details
Published in:Advanced functional materials 2014-07, Vol.24 (25), p.3944-3952
Main Authors: Liu, Yongfeng, Ma, Ruijun, He, Yanping, Gao, Mingxia, Pan, Hongge
Format: Article
Language:English
Subjects:
anodic materials
cyclic stability
hydrogen-driven chemical reaction
Li-ion batteries
Li2MgSi
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Summary:In this work, a novel hexagonal Li2MgSi anode is successfully prepared through a hydrogen‐driven chemical reaction technique. Electrochemical tests indicate significantly improved cycling stability for the as‐synthesized Li2MgSi compared with that of Mg2Si. Ball‐milling treatment induces a polymorphic transformation of Li2MgSi from a hexagonal structure to a cubic structure, suggesting that the cubic Li2MgSi is a metastable phase. The post‐24‐h‐milled Li2MgSi delivers a maximum capacity of 807.8 mAh g−1, which is much higher than that of pristine Li2MgSi. In particular, the post‐24‐h‐milled Li2MgSi retains 50% of its capacity after 100 cycles, which is superior to cycling stability of Mg2Si. XRD analyses correlated with CV measurements do not demonstrate the dissociation of metallic Mg and/or Li–Mg alloy involved in the lithiation of Mg2Si for the Li2MgSi anode, which contributes to the improved lithium storage performance of the Li2MgSi anode. The findings presented in this work are very useful for the design and synthesis of novel intermetallic compounds for lithium storage as anode materials of Li‐ion batteries. A novel hexagonal Li2MgSi is successfully synthesized through a hydrogen‐driven chemical reaction technique, which exhibits significantly improved cycling stability with respect to that of Mg2Si as an anode material for Li‐ion batteries. Ball milling induces a polymorphic transformation of Li2MgSi from the hexagonal phase to the cubic phase and further improves the electrochemical lithium storage properties.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.201304287