蒸汽重整
动力学蒙特卡罗方法
甲烷
催化作用
氢
分压
制氢
动能
材料科学
蒙特卡罗方法
热力学
化学动力学
梯田(农业)
化学物理
动力学
化学
物理化学
基本反应
反应速率
甲烷转化炉
反应机理
氨生产
化学反应
多相催化
化学工程
密度泛函理论
部分氧化
水煤气变换反应
反应级数
作者
Zeyu Wu,Sai Sharath Yadavalli,Carlos Fonte,Michail Stamatakis
标识
DOI:10.1021/acscatal.6c01172
摘要
Methane Steam Reforming (MSR) is a critical process for hydrogen production in the chemical industry. Nickel-based catalysts are usually preferred for MSR due to their high activity and low cost. Several studies have shown that step edges and defects on Ni surfaces have a strong influence on the MSR kinetics. However, a detailed mechanistic-level understanding of the MSR reaction on stepped Ni surfaces has remained elusive. In this work, we have developed a DFT-parameterized Kinetic Monte Carlo (KMC) model to investigate the detailed kinetics of MSR reaction on stepped Ni surfaces (which contain step and terrace sites) and compare them systematically against the (111) facet. Comparisons of the predicted MSR turnover frequencies (TOFs) on Ni(211) and Ni(111) surfaces indicate that the TOF on Ni(211) exhibits strong temperature dependence, whereas Ni(111) is more sensitive to the partial pressure of CH4. Additionally, we found that the step sites are more active in adsorbing and dissociating water, suggesting that higher water partial pressure improves Ni(211) performance. To further understand the role of step sites, we extended our analysis by changing the density of the step sites in the KMC lattice, providing insights into the broader impact of step density on catalytic behavior. These findings contribute to a deeper understanding of the reaction mechanisms governing MSR on stepped Ni surfaces, offering valuable insights for optimizing catalyst design and improving hydrogen production efficiency.
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