Performance degradation mechanism of lithium compounds ceramic fuel cell with GDC as electrolyte

IF 6.4 3区环境科学与生态学 Q2 ENERGY & FUELS Carbon Resources Conversion Pub Date : 2023-09-01 DOI:10.1016/j.crcon.2023.03.004

Kai Wei , Rui Zhang , Gang Chen , Zhuo Chen , Ruixin Dai , Xiaohong Lv , Shujiang Geng

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引用次数: 1

Abstract

The performance degradation mechanism of ceramic fuel cell with NCAL (Ni_0.8Co_0.15Al_0.05LiO₂) as symmetrical electrode and GDC as electrolyte in H₂ is investigated. It is found that under the condition of 550 °C and constant current density of 0.2 A·cm⁻², the output voltage of the cell is about 1.005 V in the initial 10 h and remains relatively stable. After 10 h, the voltage of the cell began to decrease gradually, and by 50 h, the voltage had decreased to 0.522 V. The results testing electrochemical performance of the cell and characterizing the cell materials before and after test using SEM, TOF-SIMS and FTIR indicate that the distribution of Li₂O/LiOH/Li₂CO₃ compounds generated from NCAL anode in the cell plays a vital role in significantly improving the ionic conductivity of electrolyte and gas tightness of the cell. The dynamic migration of molten salt destroyed the continuity of molten salt in the cell, which in turn adversely impacted the ionic conductivity of electrolyte, gas tightness of the cell, and electrochemical reactions on both sides of the cathode and anode. These finally lead to the degradation of the cell performance.

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以GDC为电解质的锂化合物陶瓷燃料电池性能退化机理

研究了以NCAL (Ni0.8Co0.15Al0.05LiO2)为对称电极，GDC为电解质的陶瓷燃料电池在H2中的性能退化机理。研究发现，在550 °C和0.2 A·cm−2恒定电流密度条件下，电池在初始10 h内输出电压约为1.005 V，并保持相对稳定。10 h后，电池的电压开始逐渐下降，到50 h时，电压已降至0.522 V。通过SEM、TOF-SIMS和FTIR对电池电化学性能的测试以及测试前后电池材料的表征结果表明，NCAL阳极生成的Li2O/LiOH/Li2CO3化合物在电池中的分布对显著提高电解质离子电导率和电池气密性起着至关重要的作用。熔盐的动态迁移破坏了熔盐在电池中的连续性，进而对电解质的离子电导率、电池的气密性以及阴极和阳极两侧的电化学反应产生不利影响。这些最终导致电池性能的下降。

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来源期刊

Carbon Resources Conversion Materials Science-Materials Science (miscellaneous)

CiteScore

9.90

自引率

11.70%

发文量

审稿时长

10 weeks

期刊介绍： Carbon Resources Conversion (CRC) publishes fundamental studies and industrial developments regarding relevant technologies aiming for the clean, efficient, value-added, and low-carbon utilization of carbon-containing resources as fuel for energy and as feedstock for materials or chemicals from, for example, fossil fuels, biomass, syngas, CO2, hydrocarbons, and organic wastes via physical, thermal, chemical, biological, and other technical methods. CRC also publishes scientific and engineering studies on resource characterization and pretreatment, carbon material innovation and production, clean technologies related to carbon resource conversion and utilization, and various process-supporting technologies, including on-line or off-line measurement and monitoring, modeling, simulations focused on safe and efficient process operation and control, and process and equipment optimization.

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