Impact of solid-electrolyte interphase reformation on capacity loss in silicon-based lithium-ion batteries

Impact of solid-electrolyte interphase reformation on capacity loss in silicon-based lithium-ion batteries

High-density silicon composite anodes show large volume changes upon charging/discharging triggering the reformation of the solid electrolyte interface (SEI), an interface initially formed at the silicon surface. The question remains how the reformation process and accompanied material evolution, in...

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Bibliographic Details
Published in:Communications materials Vol. 4; no. 1; pp. 44 - 12
Main Authors: Vorauer, T., Schöggl, J., Sanadhya, S. G., Poluektov, M., Widanage, W. D., Figiel, L., Schädler, S., Tordoff, B., Fuchsbichler, B., Koller, S., Brunner, R.
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 06-06-2023
Nature Publishing Group
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Subjects:
639/301/299/891
639/4077/4079/891
Anodes
Chemistry and Materials Science
Composite structures
Cycles
Electrolytes
Electrolytic cells
Evolution
Interface stability
Lithium-ion batteries
Material properties
Materials Science
Microscopy
Rechargeable batteries
Silicon
Solid electrolytes
Stability analysis
Workflow
X ray microscopy
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Description
Summary:High-density silicon composite anodes show large volume changes upon charging/discharging triggering the reformation of the solid electrolyte interface (SEI), an interface initially formed at the silicon surface. The question remains how the reformation process and accompanied material evolution, in particular for industrial up-scalable cells, impacts cell performance. Here, we develop a correlated workflow incorporating X-ray microscopy, field-emission scanning electron microscopy tomography, elemental imaging and deep learning-based microstructure quantification suitable to witness the structural and chemical progression of the silicon and SEI reformation upon cycling. The nanometer-sized SEI layer evolves into a micron-sized silicon electrolyte composite structure at prolonged cycles. Experimental-informed electrochemical modelling endorses an underutilisation of the active material due to the silicon electrolyte composite growth affecting the capacity. A chemo-mechanical model is used to analyse the stability of the SEI/silicon reaction front and to investigate the effects of material properties on the stability that can affect the capacity loss. The solid electrolyte interface reformation process and material evolution in silicon composite anodes is not well understood. Here, the authors develop a correlated workflow to study the structural and chemical progression of silicon and solid electrolyte interface reformation upon cycling.
ISSN:2662-4443
2662-4443
DOI:10.1038/s43246-023-00368-1