Journal article icon

Journal article

Unravelling electro-chemo-mechanical processes in graphite/silicon composites for designing nanoporous and microstructured battery electrodes

Abstract:
Silicon is a promising negative electrode material for high-energy batteries, but its volume changes during cell cycling cause rapid degradation, limiting its loading to about 10 wt.% in conventional graphite/Si composite electrodes. Overcoming this threshold requires evidence-based design for the formulation of advanced electrodes. Here we combine multimodal operando imaging techniques, assisted by structural and electrochemical characterizations, to elucidate the multiscale electro-chemo-mechanical processes in graphite/Si composite negative electrodes. We demonstrate that the electrochemical cycling stability of Si particles strongly depends on the design of intraparticle nanoscale porous structures, and the encapsulation and loss of active Si particles result in excessive charging current being directed to the graphite particles, increasing the risk of lithium plating. We also show that heterogeneous strains are present between graphite and Si particles, in the carbon-binder domain and the electrode’s porous structures. Focusing on the volume expansion of the electrode during electrochemical cycling, we prove that the rate performance and Si utilization are heavily influenced by the expansion of the carbon-binder domain and the decrease in porosity. Based on this acquired knowledge, we propose a tailored double-layer graphite/Si composite electrode design that exhibits lower polarization and capacity decay compared with conventional graphite/Si electrode formulations.
Publication status:
Published
Peer review status:
Peer reviewed

Actions

Authors

More by this author
Role:
Author
ORCID:
0000-0003-1566-1509
More by this author
Institution:
University of Oxford
Role:
Author
ORCID:
0000-0001-8434-4764
More by this author
Role:
Author
ORCID:
0000-0002-5232-1477
More by this author
Role:
Author
ORCID:
0000-0002-3202-6825


More from this funder
Funder identifier:
https://ror.org/0526snb40


Publisher:
Nature Research
Journal:
Nature Nanotechnology More from this journal
Volume:
20
Issue:
11
Pages:
1656-1666
Publication date:
2025-10-24
Acceptance date:
2025-09-02
DOI:
EISSN:
1748-3395
ISSN:
1748-3387


Language:
English
Pubs id:
2302271
UUID:
uuid_7332df81-c3e9-49a2-acbb-7066c53eb064
Local pid:
pubs:2302271
Source identifiers:
3480610
Deposit date:
2025-11-18
ARK identifier:
This ORA record was generated from metadata provided by an external service. It has not been edited by the ORA Team.

Terms of use


Views and Downloads






If you are the owner of this record, you can report an update to it here: Report update to this record

TO TOP