Comparative Investigations on Ni-Doped and ZnTe Monolayers for SF Decomposition Characteristic Gases Based on Density Functional Theory.

When SF decomposition is caused by partial discharges, characteristic gases such as HS, SO, SOF, and SOF are generated in high-voltage equipment, which poses a great threat to the regular operation of power equipment. Based on density functional theory, the adsorption and sensing characteristics of these four gases on a ZnTe monolayer and Ni-ZnTe are investigated in terms of adsorption energy, charge transfer, differential charge density, microscopic state density, desorption time, and sensitivity in this paper. Through comparative analysis, the doping of transition metal significantly opens the band gap and ensures that the desorption times of HS (538 s at 298 K), SO (1.76 s at 498 K), and SOF (4.30 s at 498 K) are effectively reduced in the case of more intense chemisorption. The adsorption energies of the three gases on Ni-ZnTe are -1.25, -0.87, and -1.21 eV, respectively. The values of band gap changes are -0.508, +0.458, and -0.748 eV, respectively, compared to the values before adsorption (1.110 eV). The more obvious difference between the band gaps of the four adsorption systems after doping also ensures that the substrate has a better resistance to cross-talk when detecting gases. Therefore, the Ni-ZnTe monolayer shows excellent potential in monitoring HS, SO, and SOF when the three gases coexist and works well as an adsorbent for SOF.