Carbon coating of air-sensitive insulating transition metal fluorides: An example study on α-Li3FeF6 high-performance cathode for lithium ion batteries

[Display omitted] •Carbon coating is practicable on insulating transition metal fluorides.•Coated α-Li3FeF6 particles exhibit improved electrochemical performances.•Iron reduction is avoided by controlled thermal decomposition of glucose.•Partial hydrolysis occurs onto the surface forming a nanocomp...

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Published in:Journal of materials science & technology 2020-10, Vol.55, p.107-115
Main Authors: Basa, Anna, Wojtulewski, Sławomir, Kalska-Szostko, Beata, Perkowski, Maciej, Gonzalo, Elena, Chernyayeva, Olga, Kuhn, Alois, García-Alvarado, Flaviano
Format: Article
Language:English
Subjects:
Carbon coating
Cathode
Hydrolysable fluoride
Lithium battery
Lithium iron fluoride
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Summary:[Display omitted] •Carbon coating is practicable on insulating transition metal fluorides.•Coated α-Li3FeF6 particles exhibit improved electrochemical performances.•Iron reduction is avoided by controlled thermal decomposition of glucose.•Partial hydrolysis occurs onto the surface forming a nanocomposite. Li3FeF6 has been the focus of research of fluorine-based cathode materials for lithium-ion batteries. Because of the low electronic conductivity of Li3FeF6, the decrease of particle size, by an energy-consuming long-time ball milling process with carbon, is necessary to achieve a high electrochemical performance. The most successful method to enhance electrochemical activity, carbon coating, seemed to be impracticable, so far, for sensitive fluorides like Li3FeF6. In this work, carbon coating on Li3FeF6 particles has been successfully achieved for the first time, while avoiding both extended hydrolysis and Fe(III)-Fe(II) reduction. The heat treatment and atmosphere, yielding the maximal transformation of organic carbon to both graphitised and disordered carbon, has been determined. Carbon coating, with a thickness of approximately 2.5 nm, has been achieved by controlled thermal decomposition of glucose, under air, at 300 °C. Raman and X-ray photoelectron spectroscopy (XPS) experiments have proved the existence of carbon and Fe2O3 on the surface of Li3FeF6 nanoparticles. XPS spectroscopy indicates the presence of organic residues from glucose decomposition. Attempts to further reduce the organic carbon content results in a decrease of the amorphous carbon coating layer. Optimised carbon-coated Li3FeF6 nanoparticles deliver 122 mA h g-1 (85% of theoretical capacity) significantly higher than that of a non-coated sample (58 mA h g-1). Even more, a significant beneficial effect of carbon coating on both capacity retention and coulombic efficiency is observed.
ISSN:1005-0302
1941-1162
DOI:10.1016/j.jmst.2019.10.002