Materials & Design (Dec 2018)
Ultraviolet-light-driven charge carriers tunability mechanism in graphene
Abstract
Tuning the charge carrier concentrations of graphene is a fundamental feature to obtain highly efficient electronic and optoelectronic devices. We investigate the carrier density modulation in graphene by exposure of ultraviolet (UV) light in O2 and N2 atmosphere. The upshift in charge neutrality point of graphene field-effect transistor is observed by UV irradiation with O2 environment which attributes to the enhancement in hole concentration, while carrier modulation of graphene reverses to pristine state in N2 environment under UV irradiation. Furthermore, we are able to interpret the absorption or dissociation mechanism of oxygen atoms on graphene and their recombination with nitrogen atoms to the formation of NO or NO2 molecules, using density functional theory computation in generalized gradient approximation and Bader charge analysis. In addition, charge carrier modulation of graphene by UV irradiation under gas environment show no degradation effect in mobility of device. The experimental results corroborated with computational analysis rectify the utilization of such promising technique for graphene applicability in electronic devices. Keywords: Graphene, Ultraviolet irradiation, Reversible modulation, First-principle calculations
