过电位
碳纳米管
密度泛函理论
材料科学
催化作用
Pourbaix图
从头算
曲率
计算化学
化学物理
杠杆
电化学
氧化还原
纳米技术
从头算量子化学方法
工作(物理)
弯曲
结构稳定性
碳纤维
电催化剂
势能
分子动力学
流离失所(心理学)
平面的
纳米电子学
化学
作者
Xi Nie,Yina Guo,Li Wei,Zilin Shen,Zhonglong Zhao
标识
DOI:10.1021/acs.jpcc.5c08406
摘要
The development of efficient CO2 reduction reaction (CO2RR) catalysts remains a persistent challenge in renewable energy research. Although metal–nitrogen-carbon single-atom catalysts (M–N–C SACs) exhibit promising performance, their catalytic mechanisms are incompletely understood. In this work, constant-potential grand canonical density functional theory simulations reveal the directional curvature as a critical design lever for activating NiN4-doped carbon nanotubes (NiN4–CNTs). We demonstrate that bending direction─particularly zigzag-aligned (m, 0) and chiral-aligned (2m, m) curvature─synergistically controls both the magnitude of out-of-plane Ni displacement and electronic restructuring, enhancing dz2─p orbital hybridization with intermediates and triggering a spin-state transition. This directional tuning facilitates spontaneous *CO2δ− formation at low potentials, reducing the CO2RR overpotential by up to 62% versus planar configurations and outperforming other curvature alignments. Robust stability under electrochemical operating conditions is confirmed by constructing Pourbaix diagrams and performing constrained ab initio molecular dynamics simulations. This work establishes curvature-optimized NiN4–CNTs as high-performance CO2RR catalysts and provides fundamental insights into orbital-level regulation for SAC design.
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