Controlling the Valence State of Cu Dopant in α‑Fe2O3 Anodes: Effects on Crystal Structure and the Conversion Reactions with Alkali Ions

Doping is one of the most important ways to tailor the performance of energy materials. However, the crystal structure of doped materials is usually oversimplified as a simple substitution of dopants. Here, we characterized the doped α-Fe2O3 with different Cu cations using synchrotron X-ray diffract...

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Published in:Chemistry of materials 2019-02, Vol.31 (4), p.1268-1279
Main Authors: Zhang, Jiliang, Lau, Vincent Wing-hei, Liao, Chang-Zhong, Wong, Kam Wa, Lee, Gi-Hyeok, Zou, Feng, Chang, Chung-Kai, Sheu, Hwo-Shuenn, Kang, Yong-Mook
Format: Article
Language:English
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Summary:Doping is one of the most important ways to tailor the performance of energy materials. However, the crystal structure of doped materials is usually oversimplified as a simple substitution of dopants. Here, we characterized the doped α-Fe2O3 with different Cu cations using synchrotron X-ray diffraction, X-ray absorption, and X-ray photoelectron spectroscopy, and electrochemically evaluated it as an anode in lithium batteries. The results suggest that doping is not the simple replacement of Fe3+ sites by Cu2+ or Cu+ but induces a complex local structure change, which may be a characteristic of this class of materials. In Cu+-doped samples, Cu+ not only replaces the Fe3+ site and distorts the FeO6 octahedra, but also gives rise to oxygen vacancies in CuO6 octahedra in the bulk structure and peroxides at the surface, leading to uniform precipitation of Cu as a conductive and buffering agent. These CuO6 octahedra also facilitate homogeneous reactions (electrochemical reduction of Cu+ and Fe3+ together) and the formation of high quality solid-electrolyte interface (SEI) layers. All these factors account for its improved electrochemical performance (discharge capacity of 841(25) mAh/g against 758(21) mAh/g of undoped one, after 80 cycles at 100mA/g). In Cu2+-doped samples, Cu2+ takes both Fe3+ and empty octahedral interstitial sites, forming linear clusters of three neighboring CuO6 octahedra. Such medium-range phase separation causes electrochemical reduction to metallic Cu before the reduction of Fe3+, leading to inactive surface Cu that contributes to poor SEI layers and deteriorates its electrochemical performances. The present work allows a better understanding of how doping affects the crystallographic structures and offers insights into how this strategy can be employed to improve electrochemical performance, in contrast to the ambiguity over material properties associated with the commonly accepted model of simple atomic replacement.
ISSN:0897-4756
1520-5002
DOI:10.1021/acs.chemmater.8b03977