Gas Sensing of Monolayer GeSe: A First-Principles Study.

The adsorption of various gas molecules (H2, H2O, CO, NH3, NO and NO 2) on monolayer GeSe were investigated by first-principles calculations. The most stable configurations, the adsorption energies, and the amounts of charge transfer were determined. Owing to the appropriate adsorption energies and the non-negligible charge transfers, monolayer GeSe could be a promising candidate as a sensor for NH3, CO, NO and NO2. According to the band structures of the H2O, CO, NH3, NO and NO2 adsorbed systems, the reductions of the bandgaps are caused by the orbital hybridizations between the gas molecules and the underlying GeSe. The partial densities of states reveal the degrees of these orbital hybridizations. The mechanisms of charge transfer are discussed in the light of both traditional and orbital mixing charge transfer theories. The charge transfer of the paramagnetic molecules NO and NO2 could be governed by both charge transfer mechanisms, while for the other gas molecules H2, H2O, CO and NH3, it was most likely determined by the mixing of the HOMO or LUMO with the GeSe orbitals. Monolayer GeSe can be a promising candidate for sensing NH3, CO, NO, and NO2 on the base of the appropriate adsorption energies and the non-negligible charge transfers. The charge transfers of the paramagnetic molecules (NO and NO2) are governed by both the traditional and the orbital mixing charge transfer theories, while for NH3 and CO, it is most likely determined by the mixing of the molecular HOMO or LUMO with the orbitals of GeSe. [ABSTRACT FROM AUTHOR]