Song Yao-Dong, Wang Liang, Wang Qian-Ting
College of Mathematics and Physics, Fujian University of Technology, Fuzhou, Fujian, 350118, People's Republic of China.
State Key Laboratory of Structural Chemistry, Fujian Institute of Research on the Structure of Matter, Chinese Academy of Sciences, Fuzhou, Fujian, 350002, People's Republic of China.
J Mol Model. 2018 Jul 18;24(8):210. doi: 10.1007/s00894-018-3734-4.
The adsorption properties of common gas molecules (NO, NH, and SO) on the surface of 3N-graphene and Al/3N graphene fragments are investigated using density functional theory. The adsorption energies have been calculated for the most stable configurations of the molecules on the surface of 3N-graphene and Al/3N graphene fragments. The adsorption energies of Al/3N graphene-gas systems are -220.5 kJ mol for Al/3NG-NO, -111.9 kJ mol for Al/3NG-NH, and -347.7 kJ mol for Al/3NG-SO, respectively. Compared with the 3N-graphene fragment, the Al/3N graphene fragment has significant adsorption energy. Furthermore, the molecular orbital, density of states, and electron densities distribution were used to explore the interaction between these molecules and the surface. We found that orbital hybridization exists between these molecules and the Al/3N graphene surface, which indicates that doping Al significantly increases the interaction between the gas molecules and Al/3N graphene. In addition, compared with Li, Al can more powerfully enhance adsorption of the 3N-graphene fragment. The results indicate that Al/3N graphene can be viewed as a new nanomaterial adsorbent for NO, NH, and SO.
采用密度泛函理论研究了常见气体分子(NO、NH和SO)在3N-石墨烯和Al/3N石墨烯片段表面的吸附特性。计算了这些分子在3N-石墨烯和Al/3N石墨烯片段表面最稳定构型的吸附能。Al/3N石墨烯-气体体系中,Al/3NG-NO的吸附能为-220.5 kJ/mol,Al/3NG-NH的吸附能为-111.9 kJ/mol,Al/3NG-SO的吸附能为-347.7 kJ/mol。与3N-石墨烯片段相比,Al/3N石墨烯片段具有显著的吸附能。此外,利用分子轨道、态密度和电子密度分布来探究这些分子与表面之间的相互作用。我们发现这些分子与Al/3N石墨烯表面之间存在轨道杂化,这表明掺杂Al显著增强了气体分子与Al/3N石墨烯之间的相互作用。此外,与Li相比,Al能更有效地增强3N-石墨烯片段的吸附作用。结果表明,Al/3N石墨烯可被视为一种用于吸附NO、NH和SO的新型纳米材料吸附剂。