Electrolyte-dominated reversible Na ion storage in Na0.4V2O5 using the DME-based electrolyte for high-performance Na-ion batteries
- Authors
- Kang, Hyokyeong; Ryu, Seongje; Son, Deokhyeon; Kansara, Shivam; Lim, Sunggun; Lee, Hyeonju; Shin, Hyeyoung; Park, Hayoung; Jeon, Yonggoon; Park, Jungwon; Xiong, Shizhao; Yu, Ji-Sang; Gu, Yang; Jung, Yun-Chae; Xiao, Biwei; Wang, Jian; Hwang, Jang-Yeon
- Issue Date
- Jun-2026
- Publisher
- ELSEVIER
- Keywords
- Na-ion batteries; Cathode; Electrolyte; Co-intercalation; Interphase; CEI layer
- Citation
- NANO ENERGY, v.152, pp 1 - 12
- Pages
- 12
- Indexed
- SCIE
SCOPUS
- Journal Title
- NANO ENERGY
- Volume
- 152
- Start Page
- 1
- End Page
- 12
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/213830
- DOI
- 10.1016/j.nanoen.2026.111862
- ISSN
- 2211-2855
2211-3282
- Abstract
- Layered Na0.4V2O5 (NVO) is a promising high-capacity cathode material for Na-ion batteries (NIBs), yet its practical application is severely hampered by rapid capacity degradation in conventional carbonate-based electrolytes. Herein, we uncover a stark performance dichotomy where an 1,2-dimethoxyethane (DME)-based electrolyte enables exceptional cycling stability, retaining 84.1% capacity over 250 cycles at 2 C, and superior rate capability. This stands in stark contrast to the catastrophic failure observed in a standard ethylene carbonate/diethyl carbonate (EC/DEC) electrolyte. The EC/DEC-based electrolyte leads to an unstable, organic-rich cathode electrolyte interphase (CEI) layer due to the continuous interfacial decomposition with insertion of solvent into crystal structure, leading to the rapid capacity failure. In contrast, the DME-based electrolyte forms a [Na-DME]* dominated solvation structure that suppresses continuous solvent and anion decomposition, enabling the formation of a thin, inorganic-rich, and stable CEI layer. This unique interfacial environment subsequently facilitates reversible [Na-DME]* co-intercalation into the NVO crystal structure. In situ X-ray diffraction reveals a highly reversible solvent co-intercalation mechanism involving solvated [Na-DME]* complexes, which density functional theory calculations show to be kinetically favored due to their high desolvation energy barrier. This advantageous co-intercalation mechanism, operating synergistically with the formation of a remarkably stable cathode-electrolyte interface, unlocks exceptional cycling stability and rate capability, suggesting an effective methodology for enhancing charge storage in NIBs.
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