固体物质的水分吸收及其对离子运输的影响。

Water uptake of solids and its impact on ion transport.

作者信息

Joos Markus, Kang Xiaolan, Merkle Rotraut, Maier Joachim

机构信息

Max Planck Institute for Solid State Research, Stuttgart, Germany.

出版信息

Nat Mater. 2025 Jun;24(6):821-834. doi: 10.1038/s41563-025-02143-8. Epub 2025 Mar 31.

DOI:10.1038/s41563-025-02143-8

PMID:40164795

Abstract

The interaction modes of water with (polar) solids are manifold, comprising surface adsorption and incorporation into the bulk, both in molecular and in dissociated form. This Review discusses these processes and the respective pronounced effects on the ionic transport properties. The concentration as well as the mobility of ionic carriers can vary by orders of magnitude depending on the water content on or within a solid. Selected materials examples, which are relevant for electrochemical devices (for example, low- and intermediate-temperature fuel cells) or which are of fundamental interest (such as molecular water acting as dopant in a lithium halide), are treated in more detail. Interrelations between hydration and electronic defects are also briefly touched upon.

摘要

水与（极性）固体的相互作用模式多种多样，包括表面吸附以及以分子形式和离解形式融入主体。本综述讨论了这些过程以及它们对离子传输性质的显著影响。离子载体的浓度和迁移率可能会因固体表面或内部的含水量而改变几个数量级。文中更详细地讨论了一些与电化学装置相关的材料实例（例如，低温和中温燃料电池）或具有基础研究意义的实例（如分子水作为卤化锂中的掺杂剂）。还简要提及了水合作用与电子缺陷之间的相互关系。

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固体物质的水分吸收及其对离子运输的影响。

Water uptake of solids and its impact on ion transport.

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