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A quantitative figure of merit for battery SEI films and their use as functional solid-state electrolytes

功勋 电解质 电池(电) 固态 材料科学 化学工程 计算机科学 工程类 光电子学 工程物理 化学 物理 热力学 功率(物理) 物理化学 电极
作者
Bo Liu,Dingyi Zhao,Katelyn Lyle,Xintong Yuan,Po-Hung Chen,Xinyue Zhang,Jin Koo Kim,Tianyu Wang,Haoyang Wu,Chongzhen Wang,Jiayi Joey Yu,Keyue Liang,Jung Tae Kim∥,Kaiyan Liang,Yuzhang Li
出处
期刊:
标识
DOI:10.26434/chemrxiv-2025-r4t5c
摘要

As a key passivation film that governs battery operation, the solid electrolyte interphase (SEI) has long been credited for enabling high-performance batteries or blamed for their eventual death. However, qualitative descriptions of the SEI often found in the literature (e.g., “conductive”, “passivating”) highlight our incomplete understanding of this layer, where even the most basic properties foundational to SEI function remain difficult to measure. Here, we quantify SEI conductivities and SEI transference numbers using a separator-free Cu|SEI|Li architecture that treats the SEI as a functional solid-state electrolyte (SSE). We discover that while any SEI property alone (e.g., electronic conductivity) is weakly correlated (R2<0.71) with battery performance (e.g., Coulombic efficiency), a strong correlation (R2>0.99) can be achieved by defining the “SEI cT number” as a product between the SEI transference number (T) and the ratio of SEI conductivities (c). Analogous to the thermoelectric figure of merit (i.e., zT), SEI cT quantitatively benchmarks the holistic impact of SEI properties on battery performance and underscores the pitfalls of citing such properties in isolation. Perhaps most strikingly, we demonstrate that Li metal deposition and stripping at room temperature is possible in our separator-free Cu|SEI|Li cell, confirming that the SEI can function precisely as an SSE. Together, these results enrich our understanding of the SEI, not just as a passivation layer but as a functional structure that can potentially have important implications for solid-state batteries.
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