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Fe3+-Derived Boosted Charge Transfer in an FeSi4P4Anode for Ultradurable Li-Ion Batteries
- Source :
- ACS Nano; 20220101, Issue: Preprints
- Publication Year :
- 2022
-
Abstract
- Ion and electron transportation determine the electrochemical performance of anodes in metal-ion batteries. This study demonstrates the advantage of charge transfer over mass transport in ensuring ultrastable electrochemical performance. Additionally, charge transfer governs the quality, composition, and morphology of a solid–electrolyte interphase (SEI) film. We develop FeSi4P4-carbon nanotube (FSPC) and reduced-FeSi4P4-carbon nanotube (R-FSPC) heterostructures. The FSPC contains abundant Fe3+cations and negligible pore contents, whereas R-FSPC predominantly comprises Fe2+and an abundance of nanopores and vacancies. The copious amount of Fe3+ions in FSPC significantly improves charge transfer during Li-ion battery tests and leads to the formation of a thin monotonic SEI film. This prevents the formation of detrimental LiP and crystalline-Li3.75Si phases and the aggregation of discharging/recharging products and guarantees the reformation of FeSi4P4nanocrystals during delithiation. Thus, FSPC delivers a high initial Coulombic efficiency (>90%), exceptional rate capability (616 mAh g–1at 15 A g–1), and ultrastable symmetric/asymmetric cycling performance (>1000 cycles at ultrahigh current densities). This study deepens our understanding of the effects of electron transport on regulating the structural and electrochemical properties of electrode materials in high-performance batteries.
Details
- Language :
- English
- ISSN :
- 19360851 and 1936086X
- Issue :
- Preprints
- Database :
- Supplemental Index
- Journal :
- ACS Nano
- Publication Type :
- Periodical
- Accession number :
- ejs60530638
- Full Text :
- https://doi.org/10.1021/acsnano.2c04170