Performance Investigation of a Nickel Cermet Anode Modified with Copper, Alkaline Earth Metal Oxide, Boron, and Perovskite for Direct Methane Fuel Cell

Q4 Energy Journal of Nuclear Energy Science and Power Generation Technology Pub Date : 2021-04-26 DOI:10.21926/JEPT.2102024

A. Chien, E. Lin, Nicole J. Ye

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引用次数: 1

Abstract

The metallic copper, alkaline earth metal oxide, boron, and perovskite were incorporated on the surface of a Ni-cermet anode, and the performance of the modified Solid Oxide Fuel Cell (SOFC) anode was evaluated. The cell performance was analyzed by voltage-current characteristics (V-I curve) and H2-CH4 step reactions (P-t curve) in a potentiostatic mode. Besides, we also determined if a metallic phase or high electronic conductivity of the anode is important for a cell to perform well when H2 is used as a fuel, whereas both conductivity and anti-coking capability are critical while using CH4 as a fuel. The results showed that the anodes containing magnesium oxide (MgO), lanthanum strontium titanate (La0.4Sr0.4TiO3−γ), and boron were relatively resistant to the degradation in the CH4 environment when compared with others. The underlying mechanism varied mainly with electronic and structural promotion by the dopants as well as their material compatibility with the Ni-cermet substrate. These findings were evidenced and supported by surface analysis as well as in-situ infrared and mass spectroscopic studies too.

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直接甲烷燃料电池用铜、碱土金属氧化物、硼和钙钛矿改性镍金属陶瓷阳极的性能研究

将金属铜、碱土金属氧化物、硼和钙钛矿掺入镍金属陶瓷阳极表面，对改性固体氧化物燃料电池(SOFC)阳极的性能进行了评价。通过恒电位模式下的电压-电流特性(V-I曲线)和H2-CH4阶反应(P-t曲线)对电池性能进行分析。此外，我们还确定了当H2用作燃料时，阳极的金属相或高电子导电性是否对电池的良好性能很重要，而当使用CH4作为燃料时，导电性和抗结焦能力至关重要。结果表明:含氧化镁(MgO)、钛酸锶镧(La0.4Sr0.4TiO3−γ)和硼的阳极在CH4环境中具有较强的抗降解能力;其基本机理主要与掺杂剂的电子和结构促进作用以及与镍金属陶瓷衬底的材料相容性有关。这些发现得到了表面分析以及现场红外和质谱研究的证实和支持。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Nuclear Energy Science and Power Generation Technology Energy-Energy Engineering and Power Technology

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