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Coupling of S@aerogel and Si/SiOx Nanospheres Electrodes with "Polysulfide" Salt-Free Electrolytes in a Fluorine-Free Lithium-Ion Batteriesopen access

Authors
Agostini, MarcoHwang, Jang-YeonJankowski, PiotrPark, HyeonaLee, ChaiwonKim, HansuXiong, ShizhaoCavallo, CarmenCeleste, ArcangeloWoo, Sang-GilSun, JinhuaBrutti, SergioSun, Yang-KookMatic, Aleksandar
Issue Date
Sep-2025
Publisher
WILEY
Keywords
fluorine-free lithium-ion batteries; "salt-free" electrolyte; solid electrolyte interphase stability; sulfur/silicon electrodes
Citation
Small Structures, v.6, no.9, pp 1 - 8
Pages
8
Indexed
SCIE
SCOPUS
Journal Title
Small Structures
Volume
6
Number
9
Start Page
1
End Page
8
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/210057
DOI
10.1002/sstr.202500096
ISSN
2688-4062
2688-4062
Abstract
Li-ion batteries play a pivotal role in powering electric vehicles and storing renewable energy. To enable their widespread adoption, it is imperative to explore new materials that reduce costs and enhance energy density. Sulfur and silicon exhibit promising characteristics as cathodes and anodes, respectively, and perform well in Li half-cells. However, their effective coupling in Li-ion configurations presents challenges. A major hurdle lies in identifying an electrolyte that ensures stable interphases and prolonged cycling while prioritizing safety and cost-effectiveness. This study introduces a groundbreaking approach by customizing a "salt-free" electrolyte solution compatible with both Li/sulfur and Li/silicon cells. The innovation involves dissolving lithium polysulfide in a diglyme solvent to facilitate Li-ion transfer. This improves cell safety due to the low flammability of the solvent and the absence of fluorine, while also ensuring faster Li-ion transport and prolonged stability of the solid electrolyte interphase. By integrating this tailored electrolyte with engineered electrodes, including a free-standing reduced graphene oxide aerogel with approximate to 74% sulfur and high areal capacity Si/SiOx nanospheres, a unique "salt-free" Li-ion battery configuration is demonstrated. The findings present a promising avenue for developing cost-effective, safe, high-performance lithium-ion batteries.
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