TY - JOUR
T1 - Superior Active and Durable Air Electrode for Protonic Ceramic Cells by Metal-Oxide Bond Engineering
AU - Yu, Xiaole
AU - Ge, Lin
AU - Mi, Yaowei
AU - Wu, Bangze
AU - Yu, Zhexiang
AU - Jin, Zhanheng
AU - Zhao, Zenan
AU - He, Bingyu
AU - Chen, Han
AU - Zheng, Yifeng
AU - Cui, Sheng
N1 - Publisher Copyright:
© 2025 Wiley-VCH GmbH.
PY - 2025/2/25
Y1 - 2025/2/25
N2 - Protonic ceramic cells (PCCs) have been identified as promising energy conversion devices, offering flexible fuel options and reduced operating consumption at intermediate temperatures. However, the application of traditional cobalt-based perovskite air electrodes in PCCs is hindered by their insufficient durability and high coefficient of thermal expansion. In this study, a straightforward metal-oxygen bond engineering is conducted, introducing a single-phase perovskite, Ba0.95La0.05(Fe0.8Zn0.2)0.9Ni0.1O3−δ (BLFZN0.1), as a substitution for cobalt-based perovskite. BLFZN0.1 demonstrates superior electrochemical properties, with an area-specific resistance of 0.015 Ω cm2 at 700 °C, and demonstrates reliable durability over 100 h. The introduction of Ni element increases the concentration of oxygen defects and enhances the oxygen catalytic activity. As a result, a protonic ceramic fuel cell using BLFZN0.1 air electrode achieves the highest peak power density (1353 mW cm⁻2 at 700 °C) yet recorded for cells with BLFZ-based air electrodes. Furthermore, the single cell with BLFZN0.1 exhibits remarkable current density (1.66 A cm−2 at 700 °C) in the electrolysis mode, highlighting its potential for application in electrolysis devices. This study presents an effective and straightforward strategy for modifying PCC air electrodes with high electrochemical performance and comparable durability, thereby facilitating their commercial application.
AB - Protonic ceramic cells (PCCs) have been identified as promising energy conversion devices, offering flexible fuel options and reduced operating consumption at intermediate temperatures. However, the application of traditional cobalt-based perovskite air electrodes in PCCs is hindered by their insufficient durability and high coefficient of thermal expansion. In this study, a straightforward metal-oxygen bond engineering is conducted, introducing a single-phase perovskite, Ba0.95La0.05(Fe0.8Zn0.2)0.9Ni0.1O3−δ (BLFZN0.1), as a substitution for cobalt-based perovskite. BLFZN0.1 demonstrates superior electrochemical properties, with an area-specific resistance of 0.015 Ω cm2 at 700 °C, and demonstrates reliable durability over 100 h. The introduction of Ni element increases the concentration of oxygen defects and enhances the oxygen catalytic activity. As a result, a protonic ceramic fuel cell using BLFZN0.1 air electrode achieves the highest peak power density (1353 mW cm⁻2 at 700 °C) yet recorded for cells with BLFZ-based air electrodes. Furthermore, the single cell with BLFZN0.1 exhibits remarkable current density (1.66 A cm−2 at 700 °C) in the electrolysis mode, highlighting its potential for application in electrolysis devices. This study presents an effective and straightforward strategy for modifying PCC air electrodes with high electrochemical performance and comparable durability, thereby facilitating their commercial application.
KW - Metal–oxygen bonds engineering
KW - air electrodes
KW - oxygen defect concentrations
KW - protonic ceramic cells
UR - http://www.scopus.com/inward/record.url?scp=85216597975&partnerID=8YFLogxK
U2 - 10.1002/smll.202408607
DO - 10.1002/smll.202408607
M3 - 文章
AN - SCOPUS:85216597975
SN - 1613-6810
VL - 21
JO - Small
JF - Small
IS - 8
M1 - 2408607
ER -