固体氧化物电池中电解质过程的阻抗分析

IF 2.6 4区工程技术 Q3 ELECTROCHEMISTRY

Fuel Cells Pub Date : 2023-10-06 DOI:10.1002/fuce.202300035

Felix Kullmann, Cedric Grosselindemann, Luis Salamon, Franz‐Martin Fuchs, André Weber

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引用次数: 0

摘要

电化学阻抗谱和弛豫时间分布是研究固体氧化物电池(SOC)极化过程的有力工具。通常测量的极化电阻仅归因于电极中的极化现象，而假定电解液作为纯欧姆串联电阻。在这项研究中，通过阻抗谱研究了电解质支持的SOC，其标称工作温度范围为700-900°C，温度低至350°C。在如此低的温度下，电解质的介电极化被转移到可访问的频率范围内，从而提供了对反卷积和量化的附加过程的访问。讨论了钆掺杂二氧化铈扩散阻挡层和电极层等附加层对晶界和晶界电解质过程的影响程度。

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Impedance analysis of electrolyte processes in a solid oxide cell

Abstract Electrochemical impedance spectroscopy and the distribution of relaxation times are powerful tools to study polarization processes in solid oxide cells (SOC). Commonly the measured polarization resistance is solely attributed to polarization phenomena in the electrodes whereas the electrolyte is assumed to act as purely ohmic series resistance. In this study an electrolyte supported SOC is investigated by impedance spectroscopy from the nominal operating temperature range of 700–900°C down to temperatures as low as 350°C. At such low temperatures the dielectric polarization of the electrolyte is shifted into the accessible frequency range, providing access to additional processes which are deconvoluted and quantified. It is discussed to which extent the additional layers like gadolinia doped ceria diffusion barrier and electrode layers influence the electrolyte processes as grain and grain boundary.

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来源期刊

Fuel Cells 工程技术-电化学

CiteScore

5.80

自引率

3.60%

发文量

审稿时长

3.7 months

期刊介绍： This journal is only available online from 2011 onwards. Fuel Cells — From Fundamentals to Systems publishes on all aspects of fuel cells, ranging from their molecular basis to their applications in systems such as power plants, road vehicles and power sources in portables. Fuel Cells is a platform for scientific exchange in a diverse interdisciplinary field. All related work in -chemistry- materials science- physics- chemical engineering- electrical engineering- mechanical engineering- is included. Fuel Cells—From Fundamentals to Systems has an International Editorial Board and Editorial Advisory Board, with each Editor being a renowned expert representing a key discipline in the field from either a distinguished academic institution or one of the globally leading companies. Fuel Cells—From Fundamentals to Systems is designed to meet the needs of scientists and engineers who are actively working in the field. Until now, information on materials, stack technology and system approaches has been dispersed over a number of traditional scientific journals dedicated to classical disciplines such as electrochemistry, materials science or power technology. Fuel Cells—From Fundamentals to Systems concentrates on the publication of peer-reviewed original research papers and reviews.