溶剂化
电解质
化学物理
财产(哲学)
钠
分子动力学
化学
材料科学
计算化学
分子
物理化学
有机化学
哲学
电极
认识论
作者
Sakengali Kazhiyev,Mohammad Tahmidul Alam,Atreiu Vacchi Sanz,Krishna Shah,Lei Cheng,Yu Zhou
标识
DOI:10.1016/j.jpowsour.2025.238235
摘要
Sodium-ion batteries (SIBs) are promising cost-effective and sustainable alternatives to lithium-ion batteries (LIBs) for large-scale energy storage. However, their development is limited by slow ion transport due to the larger ionic radius of Na + and challenges in forming stable solid electrolyte interphases (SEIs). Moreover, fundamental differences in ionic size, chemical reactivity, and electrochemical behavior between Na + and Li + hinder the direct transfer of design principles from LIBs to SIBs. To address these issues, electrolyte engineering, particularly with high-concentration electrolytes, has shown potential to enhance interfacial stability and suppress dendrite formation. In this study, we applied a combination of density functional theory (DFT), ab initio molecular dynamics (AIMD), and classical molecular dynamics (CMD) simulations to investigate solvation structure-property relationships in sodium bis(fluorosulfonyl)imide dimethoxyethane (NaFSI/DME) electrolytes. Our results reveal that, at low concentrations (1–2 M), Na + primarily forms solvent-separated and contact ion pairs, and ion transport is dominated by vehicular motion involving co-diffusion with FSI − . Free DME molecules are readily reduced, forming reactive intermediates such as sodium methoxide (NaOCH 3 ), which destabilize the SEI. At high concentrations (4–5 M), Na + is preferentially coordinated by FSI − , forming extended ionic aggregates. The transport mechanism shifts to structural diffusion, where Na + migrates by hopping between FSI − sites, resulting in increased correlated transference numbers. Moreover, the reduction of Na-FSI-DME clusters favors the formation of stable SEI components such as NaF and Na 2 O. These findings elucidate how solvation environments and ion transport mechanisms evolve with concentration and highlight the critical role of high-concentration electrolytes in stabilizing interfacial chemistry. This work offers molecular-level insights to guide the design of Na electrolytes with enhanced ion dynamics and robust SEI formation.
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