电解质
电化学
化学物理
分子动力学
反应性(心理学)
电化学窗口
分子
化学
电化学电位
理论(学习稳定性)
材料科学
电场
水模型
电极
无机化学
分析化学(期刊)
光谱学
物理化学
电化学电池
领域(数学)
热力学
电极电位
化学稳定性
工作(物理)
密度泛函理论
表征(材料科学)
作者
Sourav Palchowdhury,Stefan Ringe,Saeyeon Lee,Minhaeng Cho
摘要
A recent study reported a super-concentrated lithium-potassium acetate-based water-in-bisalt (WiBS) electrolyte. Notably, this system exhibits a high electrochemical stability window of ∼3 V despite the absence of a conventional solid electrolyte interphase. Intriguingly, vibrational spectroscopy revealed a systematic redshift of the O-D stretch of HOD in this electrolyte with increasing salt concentration, contradicting the idea that the enhanced electrochemical stability is positively correlated with the strength of the O-H bond. To explore the atomic factors determining such extended electrochemical stability of this WiBS, we investigate the molecular distributions and water reactivity at the electrified electrode-electrolyte interface using constant potential classical molecular dynamics simulations. By identifying truly interfacial molecules, we uncover a diminishing surface concentration of water molecules at the electrodes, which likely leads to a delayed onset of electrochemical processes. Furthermore, the reduced magnitude of the perturbing electric field along the reaction coordinates for electrochemical water splitting provides an atomic-level explanation for the enhanced electrochemical stability observed in this dual-cation system.
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