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揭示GdBaSrCoCuO(≥1)固体氧化物电池氧电极的电催化活性

Unveiling the Electrocatalytic Activity of the GdBaSrCoCuO ( ≥ 1) Oxygen Electrodes for Solid Oxide Cells.

作者信息

Li Keyun, Świerczek Konrad, Winiarz Piotr, Brzoza-Kos Agnieszka, Stępień Anna, Du Zhihong, Zhang Yang, Zheng Kun, Cichy Kacper, Niemczyk Anna, Naumovich Yevgeniy

机构信息

Faculty of Energy and Fuels, AGH University of Science and Technology, al. A. Mickiewicza 30, 30-059 Krakow, Poland.

AGH Centre of Energy, AGH University of Science and Technology, ul. Czarnowiejska 36, 30-054 Krakow, Poland.

出版信息

ACS Appl Mater Interfaces. 2023 Aug 23;15(33):39578-39593. doi: 10.1021/acsami.3c08667. Epub 2023 Aug 9.

DOI:10.1021/acsami.3c08667
PMID:37558244
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10450687/
Abstract

The A-site cation-ordered GdBaSrCoCuO (GBSCC) double perovskites are evaluated regarding the development of high-performance oxygen electrodes for reversible solid oxide cells (rSOCs). The aims are to maximally decrease the content of toxic and expensive cobalt by substitution with copper while at the same time improving or maintaining the required thermomechanical and electrocatalytic properties. Studies reveal that compositions with 1 ≤ ≤ 1.15 are particularly interesting. Their thermal and chemical expansions are decreased, and sufficient transport properties are observed. Complementary density functional theory calculations give deeper insight into oxygen defect formation in the considered materials. Chemical compatibility with LaSrGaMgO (LSGM) and CeGdO (GDC) solid electrolytes is evaluated. It is documented that the GdBaSrCoCuO oxygen electrode enables obtaining very low electrode polarization resistance () values of 0.017 Ω cm at 850 °C as well as 0.111 Ω cm at 700 °C, which is lower in comparison to that of GdBaSrCoCuO (respectively, 0.026 and 0.204 Ω cm). Systematic distribution of relaxation times analyses allows studies of the electrocatalytic activity and distinguishing elementary steps of the electrochemical reaction at different temperatures. The rate-limiting process is found to be oxygen atom reduction, while the charge transfer at the electrode/electrolyte interface is significantly better with LSGM. The studies also allow elaborating on the catalytic role of the Ag current collector as compared with Pt. The electrodes manufactured using materials with = 1 and 1.1 permit reaching high power outputs, exceeding 1240 mW cm at 850 °C and 1060 mW cm at 800 °C, for the LSGM-supported cells, which can also work in the electrolysis mode.

摘要

对A位阳离子有序的GdBaSrCoCuO(GBSCC)双钙钛矿进行了评估,以用于开发可逆固体氧化物电池(rSOC)的高性能氧电极。目标是通过用铜替代来最大程度地减少有毒且昂贵的钴的含量,同时改善或保持所需的热机械和电催化性能。研究表明,1≤≤1.15的成分特别有趣。它们的热膨胀和化学膨胀减小,并且观察到足够的传输性能。互补的密度泛函理论计算更深入地了解了所考虑材料中的氧缺陷形成。评估了与LaSrGaMgO(LSGM)和CeGdO(GDC)固体电解质的化学相容性。据记载,GdBaSrCoCuO氧电极在850℃时能够获得非常低的电极极化电阻()值0.017Ω·cm,在700℃时为0.111Ω·cm,与GdBaSrCoCuO相比更低(分别为0.026和0.204Ω·cm)。弛豫时间分析的系统分布允许研究电催化活性并区分不同温度下电化学反应的基本步骤。发现限速过程是氧原子还原,而使用LSGM时电极/电解质界面处的电荷转移明显更好。这些研究还允许阐述与Pt相比Ag集电器的催化作用。对于LSGM支撑的电池,使用= 1和1.1的材料制造的电极在850℃时能够达到超过1240mW·cm²的高功率输出,在800℃时为1060mW·cm²,并且还可以在电解模式下工作。

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