质子
电子
电化学
材料科学
热传导
化学
物理
核物理学
电极
物理化学
复合材料
作者
Muhammad Faisal Anwar,Muhammad Afzal,Muhammad Khalid,Muhammad Imran Asghar,Liangdong Fan,Sining Yun,Touseef Ahmad,Li Sun,Peter D. Lund,Bin Zhu
标识
DOI:10.1021/acsmaterialslett.5c00855
摘要
Proton conduction in oxides (PCOs) is traditionally explained by hydration-based equilibrium models, which assume sufficient proton uptake from moisture or hydrogen. However, this static hydration-based framework fails under real operating conditions of proton ceramic fuel cells, where proton injection and field-driven dynamic processes dominate. This disconnection has led to an underestimation of proton concentration and mobility, also limiting the development of advanced PCOs. Here, we establish a distinct fundamental and experimental framework based on electrochemical proton injection (EPI) and proton–electron spillover, which are dynamic processes enabling an enhanced proton transport both in bulk and across grain boundary domains. Supported by in situ electrochemical impedance spectroscopy and the distribution of relaxation time, we demonstrate that EPI surpasses the conductivity ceiling imposed by the hydration-limited models. This urgent correction restores the true basis of proton transport and suggests a transformative strategy for designing next-generation oxide electrolytes for electrochemical energy devices.
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