Deep-learning-assisted insights into molecular transport in heterogeneous electrolyte films on electrodes

IF 7.9 2区 综合性期刊 Q1 CHEMISTRY, MULTIDISCIPLINARY Cell Reports Physical Science Pub Date : 2024-09-06 DOI:10.1016/j.xcrp.2024.102196
Linhao Fan, Ruiwang Zuo, Yumeng Zhou, Aoxin Ran, Xing Li, Qing Du, Kui Jiao
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Abstract

Mass transfer in electrolyte films on electrodes is crucial to the performance of electrochemical energy devices, which is difficult or impossible to observe experimentally. Here, we develop a framework utilizing deep learning to analyze vast molecular dynamics (MD) data to reveal the molecular-level transport properties in electrolyte films. This framework contains physical feature analysis and selection based on MD simulations, surrogate model training, structure-transport relationship analysis, and structure discovery. This framework is then applied to explore oxygen transport in fuel cells, which allows the transport properties and their relationships to the structural characteristics of electrolyte films to be revealed, and thus, the critical features limiting oxygen transport are identified. Accordingly, increasing the catalyst surface hydrophilicity and suppressing the electrolyte film density fluctuation are favorable for oxygen transport. Moreover, this framework is transferable to revealing similar molecular-level transport phenomena in electrolyte films that widely exist in other electrochemical energy devices.

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深度学习辅助洞察电极上异质电解质薄膜中的分子传输
电极上电解质薄膜中的质量传输对电化学能源设备的性能至关重要,但这很难或根本无法在实验中观察到。在此,我们开发了一个利用深度学习分析大量分子动力学(MD)数据的框架,以揭示电解质薄膜的分子级传输特性。该框架包含基于 MD 模拟的物理特征分析和选择、代用模型训练、结构-传输关系分析和结构发现。然后将此框架应用于探索燃料电池中的氧气传输,从而揭示传输特性及其与电解质薄膜结构特征的关系,进而确定限制氧气传输的关键特征。因此,增加催化剂表面亲水性和抑制电解质膜密度波动有利于氧气传输。此外,这一框架还可用于揭示其他电化学能源装置中广泛存在的电解质薄膜中类似的分子级传输现象。
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来源期刊
Cell Reports Physical Science
Cell Reports Physical Science Energy-Energy (all)
CiteScore
11.40
自引率
2.20%
发文量
388
审稿时长
62 days
期刊介绍: Cell Reports Physical Science, a premium open-access journal from Cell Press, features high-quality, cutting-edge research spanning the physical sciences. It serves as an open forum fostering collaboration among physical scientists while championing open science principles. Published works must signify significant advancements in fundamental insight or technological applications within fields such as chemistry, physics, materials science, energy science, engineering, and related interdisciplinary studies. In addition to longer articles, the journal considers impactful short-form reports and short reviews covering recent literature in emerging fields. Continually adapting to the evolving open science landscape, the journal reviews its policies to align with community consensus and best practices.
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