Adsorption of H2 and C2H2 onto Rh-decorated InN monolayer and the effect of applied electric field

InN monolayer with graphene-like morphology and desirable electronic property is a promising candidate for gas sensing application. In this paper, we study the adsorption and sensing performances of the Rh-decorated InN (Rh-InN) monolayer upon two typical dissolved gases in the transformers oil, namely H-2 and C2H2, to explore its potential to evaluate the working condition of the transformers. Rh atom conducts n-doping on the pristine InN surface with E-b of -2.01 eV. Also, chemisorption is determined for H-2 and C2H2 adsorption on the Rh-InN surface given that the E-ad of -0.88 and -2.15 eV, respectively. The opposite changing trend of E-g in H-2 and C2H2 systems manifests the resistance-based sensing mechanism for selective detection of two gas species. The applied electric field supports the work function analysis that an Rh-InN monolayer possesses a strong potential for field-effect transistor sensor application in terms of H-2 and C2H2 detection, wherein the charge-transfer in the gas systems is tunable by altering the voltage. Moreover, the excessive electric field is not considered to be suggestible since it can impact the geometric stability of the Rh-InN monolayer. This theoretical work is meaningful to exploit novel sensing 2D materials to guarantee the good operation of the power system.

Automated summary

This paper investigates the adsorption and sensing performances of Rh-decorated InN monolayer on H-2 and C2H2, and suggests the potential of Rh-InN monolayer for evaluating the working condition of transformers. The charge-transfer in the gas systems can be tuned by altering the voltage, making Rh-InN monolayer promising for H-2 and C2H2 detection.