Modeling and simulation of external electric field application for diisopropyl methylphosphonate sensing through B12N12 fullerene

Abstract

The external electric field can effectually enhance the electronic and optical features of low dimensional systems. Hence, the corresponding atomic structure and adsorption feature changes of a B12N12 fullerene under different applied external electric fields for dimethyl methylphosphonate (DMMP) detection were evaluated. The adsorption of DMMP on the B12N12 surface has been calculated using density functional theory (DFT) and time dependent density functional theory (TDDFT) by the PBE (Perdew-Burke-Ernzerhof) functional to study the effects of the parallel (EX) and transverse (EY) external electric fields on the structural and optoelectronic features of the pure fullerene. Through the analysis of the binding energy it is found that B12N12 fullerenes, in the presence of a parallel external electric field (EX = 0.15 a.u.), are energetically favored when compared to B12N12 fullerenes in the presence of a transverse external electric field (EY = 0.15 a.u.). The results demonstrate that a transverse external electric field ranging from 0.005 a.u. to 0.015 a.u. could enhance the DMMP sensitivity of the B12N12 fullerene (with a significant reduction of energy band gap), which potentially could aid in the development of a room temperature DMMP gas sensor. The adsorption and desorption of DMMP could be controlled by external electric field too, which has the potential for applications in itself, relative to DMMP collection and storage.