Theoretical study of dissolved gas molecules in transformer oil adsorbed on intrinsic and Cr-doped InP3 monolayer

Transition metal doping plays a significant role to regulate the electronic properties of the material substrates. In this paper, the effect of Cr dopant on InP3 monolayer and its adsorption performances to H-2, C2H2 and CH4 were studied to explore the application potential of Cr-InP3 for three dissolved gases in transformer oil with density functional theory (DFT). The adsorption behavior of intrinsic and Cr-doped InP3 monolayers to three gas molecules were simulated in terms of the charge transfer, density of states and molecular orbital, etc. Results illustrated that the electronic structure of InP3 monolayer could be sharply swayed with Cr dopant, as confirmed by the obviously asymmetry of densities of states around the Fermi level and the generation of magnetic moment of whole system. Besides, the Cr doping with high activation could effectively improve the adsorption properties of InP3 monolayer for three gas molecules. The Cr-InP3 monolayer shows more perfect adsorption performance towards C2H2 molecule in all Cr-InP3 adsorption systems, and might be a promising sensitive material for detection of C2H2 gas. The electrical conductivity and recovery time of Cr-InP3 adsorption systems were discussed to evaluate the applicability of the proposed material in three dissolved gases.

Automated summary

The study investigated the effect of Cr doping on the adsorption properties of InP3 monolayer, showing that Cr doping could significantly improve the adsorption performance to H-2, C2H2, and CH4, with a particularly strong affinity towards C2H2. The Cr-InP3 monolayer may potentially serve as a sensitive material for detecting C2H2 gas.