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Accelerated Degradation of All-Solid-State Batteries Induced through Volumetric Occupation of the Carbon Additive in the Solid Electrolyte Domain

Authors
Kim, Hyun-seungPark, SejinKang, SoraJung, Jae YupKim, KyungsuYu, Ji-SangKim, Dong-WonLee, Jong-WonSun, Yang-KookCho, Woosuk
Issue Date
Dec-2024
Publisher
John Wiley & Sons Ltd.
Keywords
all-solid-state batteries; areal capacity; carbon additives; electrode design; sulfide electrolytes
Citation
Advanced Functional Materials, v.34, no.49, pp 1 - 8
Pages
8
Indexed
SCIE
SCOPUS
Journal Title
Advanced Functional Materials
Volume
34
Number
49
Start Page
1
End Page
8
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/211159
DOI
10.1002/adfm.202409318
ISSN
1616-301X
1616-3028
Abstract
The accelerated oxidative degradation observed in all-solid-state batteries (ASSBs), particularly focusing on the argyrodite solid electrolyte in conjunction with Ni-rich positive electrode surfaces is demonstrated. The formation of oxidative intermediates of the solid electrolyte oxidation process increases the amount of oxidation on the NCM surface with conductive carbon. The introduction of high-weight-composition conductive carbon additives results in a reduction of solid electrolytes within the positive electrode and the amount of solid electrolytes retained after formation. Consequently, cells with high concentrations of carbon additives demonstrate a decrease in both the cycle and power performances of ASSBs. The energy density of ASSBs is significantly limited by the fundamental failure mechanism induced by conductive carbon, particularly pronounced in cells with high active material contents. Consequently, this study provides pivotal insights for the design of high-energy-density ASSBs with NCM electrodes and high active material contents. To mitigate failure induced by high-volumetric-occupied carbon additives, carbon fiber-type additives are further utilized to interconnect the NCMs by decreasing the occupation of the solid electrolyte domain by carbon. Morphological alteration of the carbon additive significantly improves the electrochemical performance of ASSBs by preventing the deterioration of the electrode structure even after prolonged cycling and suppressing electrolyte degradation.
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COLLEGE OF ENGINEERING (DEPARTMENT OF CHEMICAL ENGINEERING)
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