Deep-Ultraviolet (DUV)-Induced Doping in Single Channel Graphene for Pn-Junction

The electronic properties of single-layer, CVD-grown graphene were modulated by deep ultraviolet (DUV) light irradiation in different radiation environments. The graphene field-effect transistors (GFETs), exposed to DUV in air and pure O-2, exhibited p-type doping behavior, whereas those exposed in vacuum and pure N-2 gas showed n-type doping. The degree of doping increased with DUV exposure time. However, n-type doping by DUV in vacuum reached saturation after 60 min of DUV irradiation. The p-type doping by DUV in air was observed to be quite stable over a long period in a laboratory environment and at higher temperatures, with little change in charge carrier mobility. The p-doping in pure O-2 showed ~15% de-doping over 4 months. The n-type doping in pure N-2 exhibited a high doping effect but was highly unstable over time in a laboratory environment, with very marked de-doping towards a pristine condition. A lateral pn-junction of graphene was successfully implemented by controlling the radiation environment of the DUV. First, graphene was doped to n-type by DUV in vacuum. Then the n-type graphene was converted to p-type by exposure again to DUV in air. The n-type region of the pn-junction was protected from DUV by a thick double-coated PMMA layer. The photocurrent response as a function of Vg was investigated to study possible applications in optoelectronics.

Automated summary

The electronic properties of single-layer, CVD-grown graphene were affected by deep ultraviolet (DUV) light irradiation in different radiation environments, leading to p-type or n-type doping. The degree of doping increased with exposure time, with n-type doping in vacuum reaching saturation after 60 minutes. Additionally, p-type doping in air exhibited higher stability, while n-type doping in nitrogen gas was relatively unstable over time.