loading page

Understanding the Intrinsic Mechanism of High-Performance Electrocatalytic Nitrogen Fixation by Heterogenization of Homonuclear Dual Atom Catalyst
  • +9
  • Yuefei Zhang,
  • Yu Yang,
  • Yu Zhang,
  • Xuefei Liu,
  • Wenjun Xiao,
  • Degui Wang,
  • Gang Wang,
  • Zhen Wang,
  • Jinshun Bi,
  • Jincheng Liu,
  • Xun Zhou,
  • Wentao Wang
Yuefei Zhang
Guizhou Normal University
Author Profile
Yu Yang
Guizhou Normal University
Author Profile
Yu Zhang
Shanxi Key Laboratory of Advanced Semiconductor Optoelectronic Devices and Integrated Systems.
Author Profile
Xuefei Liu
Guizhou Normal University

Corresponding Author:201307129@gznu.edu.cn

Author Profile
Wenjun Xiao
Guizhou Normal University
Author Profile
Degui Wang
Guizhou Normal University
Author Profile
Gang Wang
Guizhou Normal University
Author Profile
Zhen Wang
Guizhou Normal University
Author Profile
Jinshun Bi
Guizhou Normal University
Author Profile
Jincheng Liu
Nankai University
Author Profile
Xun Zhou
Guizhou Normal University
Author Profile
Wentao Wang
Guizhou Education University
Author Profile

Abstract

A heteronuclear dual transition metal atom catalyst is a promising strategy to solve and relieve the increasing energy and environment crisis. However, the role of each atom still does not efficiently differentiate due to the high activity but low detectivity of each transition metal in the synergistic catalytic process when considering the influence of heteronuclear induced atomic difference for each transition metal atom, thus seriously hindering intrinsic mechanism finding. Herein, we proposed coordinate environment vary induced heterogenization of homonuclear dual transition metal, which inherits the advantage of heteronuclear transition metal atom catalyst but also controls the variable of the two atoms to explore the underlying mechanism. Based on this proposal, employing density functional theory study and machine learning, 23 kinds of homonuclear transition metals are doping in four asymmetric C3N for heterogenization to evaluate the underlying catalytic mechanism. Our results demonstrate that five catalysts exhibit excellent catalytic performance with a low limiting potential of -0.28 to -0.48 V. In the meantime, a new mechanism, ‘capture-charge distribution-recapture-charge redistribution’, is developed for both side-on and end-on configuration. More importantly, the pronate site of the first hydrogenation is identified based on this mechanism. Our work not only initially makes a deep understanding of the transition dual metal-based heteronuclear catalyst indirectly but also broadens the development of complicated homonuclear dual atom catalysts in the future.
Submitted to Energy & Environmental Materials
05 Mar 2024Review(s) Completed, Editorial Evaluation Pending
09 Mar 2024Editorial Decision: Revise Major
30 Mar 20241st Revision Received
02 Apr 2024Submission Checks Completed
02 Apr 2024Assigned to Editor
02 Apr 2024Review(s) Completed, Editorial Evaluation Pending
17 Apr 2024Reviewer(s) Assigned