材料科学
介电谱
电解
电化学
化学工程
电极
合金
碳纤维
解吸
氧化物
烧结
功率密度
电流密度
冶金
镍
电解质
分析化学(期刊)
沉积(地质)
无机化学
作者
Min Jun Oh,Sooin Lee,Jeeho Hong,Kyung Joong Yoon,Ho‐Il Ji,Ji‐Won Son,Jong‐Ho Lee,Kyeounghak Kim,Jongsup Hong,Sungeun Yang,Jongsup Hong,Sungeun Yang
摘要
ABSTRACT Electrochemical CO₂ reduction using solid oxide electrolysis cells (SOECs) directly converts CO 2 into value‑added chemicals, mitigating greenhouse‑gas emissions. Nickel (Ni) is the conventionally used fuel‑electrode electrocatalyst, yet its intrinsic catalytic behavior is underexplored. This study systematically evaluates Ni alloyed with 5 at% Fe, Co, or Cu for changes in microstructure, electrochemical activity, and carbon coking resistance. Model electrodes fabricated by pulsed laser deposition are analyzed by scanning and transmission electron microscopy, X‑ray diffraction, and X‑ray absorption spectroscopy, which confirm homogeneous alloy formation and show that additive metals modulate active site density by modulating sintering behavior, thereby tuning the triple‐phase‐boundary density in the order Ni > Ni–Cu > Ni–Co > Ni–Fe. Electrochemical impedance spectroscopy reveals that the apparent activation energy ( E a ) related to surface reaction decreases for all samples, accelerating CO 2 electrolysis, while sensitivity to the CO/CO 2 ratio rises when the alloying element is less prone to CO 2 dissociation. Diffuse reflectance Fourier‑transform infrared spectroscopy and density functional theory calculations indicate that Co and Fe facilitate CO 2 dissociation, whereas Cu facilitates fast desorption of product species and enhances turnover activity. Cu alloying markedly suppresses carbon coking, whereas Co exacerbates it. Enhanced performance and durability are validated by impedance and Galvano‐static measurements. These findings demonstrate that Ni–Cu alloy electrodes offer a practical route to boost SOEC efficiency and mitigate coking with minimal structural change.
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