不同方法制备PrNi_(0.5)Co_(0.5)O_(3-δ)阴极的性能对比研究  被引量：1

作　　者：时焕岗[1,2,3] 于洋 渠吉发 谭文轶 Shi Huangang;Yu Yang;Qu Jifa;Tan Wenyi(International Joint Laboratory of Green&Low Carbon Development,Nanjing 211167,China;NJIT Research Center,The Key Laboratory of Carbon Neutrality and Territory Optimization,Ministry of Natural Resources,Nanjing 211167,China;School of Environmental Engineering,Nanjing Institute of Technology,Nanjing 211167,China)

机构地区：[1]自然资源部碳中和与国土空间优化重点实验室南京工程学院研究中心,江苏南京211167 [2]江苏省绿色低碳发展国际合作联合实验室,江苏南京211167 [3]南京工程学院环境工程学院,江苏南京211167

出　　处：《稀有金属》2023年第1期186-192,共7页Chinese Journal of Rare Metals

基　　金：国家自然科学基金项目(51302135,51678291);自然资源部碳中和与国土空间优化重点实验室南京工程学院研究中心开放基金项目(CNT202208);江苏省配电网智能技术与装备协同创新中心开放基金项目(XTCX202211)资助。

摘　　要：采用固相反应法和乙二胺四乙酸-柠檬酸(EDTA-CA)联合络合法分别合成了PrNi_(0.5)Co_(0.5)O_(3-δ) (PNC)材料,用于质子导体固体氧化物燃料电池(H-SOFCs)的阴极。通过X射线衍射(XRD)研究了材料在不同煅烧条件后的相结构,通过比表面积及孔径分析仪(BET)研究材料的比表面积和孔结构,用扫描电子显微镜(SEM)观察了材料的微观结构,通过能量色散X射线谱仪(EDS)分析材料的元素分布,通过电化学阻抗谱(EIS)分析了材料作为H-SOFCs阴极使用时的极化电阻。结果表明,通过EDTA-CA联合络合法制备的粉体相结构更加稳定,且元素分布也更加均匀。EIS分析结果表明,通过两种方法制备的阴极材料在BaZr_(0.1)Ce_(0.7)Y_(0.1)Yb_(0.1)O_(3-δ)(BZCYYb)电解质上的氧还原过程活化能相近,但通过EDTA-CA联合络合法制备的阴极具有更低的极化电阻,500℃时对称电池上的极化电阻降低68%。As an efficient energy conversion device, fuel cell can efficiently convert the chemical energy of fuel into electricity at operating temperature which is an ideal power generation technology for carbon neutral society. Unlike other fuel cells, solid oxide fuel cells(SOFCs) operate at relatively high temperatures and do not use noble metal materials for electrodes, which greatly reduces the cost of fuel cells. At the same time, SOFCs also have the advantages of fuel flexibility, and gas, liquid and even solid fuels can generate electricity in SOFCs. SOFCs can be mainly divided into oxygen oxygen-ion conducting solid oxide fuel cells(O-SOFCs) and proton conducting solid oxide fuel cells(H-SOFCs) according to the conduction mechanism of the electrolyte. Since the activation energy of proton conduction is lower than that of oxygen-ion, H-SOFCs can work at relatively lower operating temperatures(400~700 ℃). The reduction of working temperature reduces the difficulty in sealing and thermal management of SOFCs, which facilitates their application. However, as the operating temperature decreases, the oxygen reduction process at the cathode of SOFCs becomes more difficult, and the increase in the resistance of the cathode directly affects the output performance of the fuel cell. The development of high-performance cathodes suitable for use in mid-low temperature SOFCs has become a current research hotspot. In recent years, the use of triple conducting cathodes(TCCs) in H-SOFCs has received more attention and research. Theses cathodes can conduct protons, oxygen ions and electrons(H^(+)/O_(2)^(-)/e^(-)) at the same time, which extending the reaction interface of the cathode process to the entire cathode surface and interior and greatly improving the efficiency of the cathode reaction process. At present, the mechanical mixing of multiphase materials, the one-step synthesis of multiphase nanocomposites, and solution impregnation can be used to design TCC cathodes, and the study of achieving triple conductivity through a

关 键 词：固体氧化物燃料电池(SOFCs) 阴极 阻抗 对称电池 

分 类 号：TM911[电气工程—电力电子与电力传动]