posted on 2023-12-28, 20:16authored byWenjun Jiang, Chao Fu, Gaoyi Li, Shuang Zhang, Donghui Xu, Laicai Li
In
this paper, density functional theory (DFT) is used to study
the hydrogen evolution catalytic mechanisms of NH3BH3 using five different catalysts, including one pristine g-C3N4 and four single metal atoms that belong to the
platinum group (i.e., Rh, Ru, Pd, and Pt) supported by g-C3N4 (denoted as M/g-C3N4 catalysts
hereafter). In short, three possible reaction paths of NH3BH3 hydrogen evolution are studied for each catalyst,
and the optimal reaction path is determined by comparing the energy
barrier of each path’s rate-limiting step. We find that the
single metal atom catalysts supported by g-C3N4 can significantly improve the hydrogen evolution efficiency of NH3BH3, among which the Rh/g-C3N4 catalyst performs best among all the catalysts explored in this
work. At the same time, the electronic structures of the five catalysts
are calculated, which indicate that the band gaps of the five catalysts
are inversely proportional to their catalytic activities. Our results
not only explain the catalytic reaction mechanism reported in previous
experimental studies from a microscopic view but also reveal the correlation
between the physical properties of catalysts and their catalytic activity.