Improving Si Anode Performance by Forming Copper Capped Copper-Silicon Thin Film Anodes for Rechargeable Lithium Ion Batteries

[Display omitted] •Cu layer is deposited on the substrate as a transition zone to improve the adhesion•Highly adherent CuSi films are deposited by magnetron sputtering•Cu layer is deposited on CuSi film to improve the anode performance•Top Cu layer acts as a glue to improve the physical and the mech...

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Bibliographic Details
Published in:Electrochimica acta 2015-07, Vol.170, p.63-71
Main Authors: Polat, B.D., Keles, O.
Format: Article
Language:English
Subjects:
anode
Copper-Silicon film
electrochemical impedance analysis
lithium ion batteries
magnetron sputtering
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Summary:[Display omitted] •Cu layer is deposited on the substrate as a transition zone to improve the adhesion•Highly adherent CuSi films are deposited by magnetron sputtering•Cu layer is deposited on CuSi film to improve the anode performance•Top Cu layer acts as a glue to improve the physical and the mechanical properties•EIS analyses are done at different SOC for the pristine and 30 cycled samples In this work, we deposit a bare and a Cu capped CuSi films (that contains 10 %at. Cu 3μm thicknesses) by magnetron sputtering. The samples are galvanostatically tested with C/12 rate: the Cu capped CuSi film delivers 850mAhg−1 after 30th cycles, and it retains stable up to 100 cycle with 99% coulombic efficiency, whilst the bare CuSi film performs a gradual decrease in capacity over 100 cycles. To understand the electrochemical process kinetics, influence the cycling performance, the impedance is measured by using impedance spectroscopy in equilibrium conditions at various states of charges. The results show Cu atoms being ductile, form a network to prevent the electronic isolation of Si particles or delamination of the film. Plus, they buffer the mechanical stress generated in the electrode following the volumetric changes during cycling. In the presence of the Cu top layer the surface reactivity of the CuSi electrode, and its interaction with the electrolyte, is also changed leading to a stable passive film formation and longer cycle life. Therefore, the top layer does not only exert remarkable favorable effects on the capacity, but also improves the coulombic efficiency and the rate capability of the electrode.
ISSN:0013-4686
1873-3859
DOI:10.1016/j.electacta.2015.04.131