Impact of Mo doping on photo-sensing properties of ZnO thin films for advanced photodetection applications

Abstract

This work explored the impact of Mo-doping on the structural, optical, photophysical, and electrical characteristics of ZnO thin films and their potential application to the UV light detection properties was investigated. The hexagonal structure of the films without any impurities or extra phases was confirmed by X-ray diffraction and FT-Raman spectroscopy. The crystallite size reduced from 36 nm to 25 nm with the addition of 3 wt% of Mo in ZnO. The EDX/SEM e-mapping verified the elemental composition and uniform Mo doping throughout the films. The FESEM images revealed spherical nanoparticles with smaller grains size for higher Mo-doping levels. The absorption spectra were recorded from UV to NIR range, and the bandgap was observed to increase from 3.25 eV for pure ZnO to 3.42 for 3% Mo-doped ZnO sample. The Mo-doped ZnO film showed PL quenching, which indicates charge transfer and suppression of defect sates in the ZnO films via Mo-doping. The time-resolved fluorescence spectra (TRFS) of these films revealed that the carrier lifetime increased from 80 ps for pure ZnO to 144 ps for 3% Mo-doped ZnO thin film. The electrical parameters including resistivity, carrier mobility, concentrations, and sheet resistance of fabricated films were evaluated by Hall-effect measurement. The resistivity and mobility were observed to decrease from 9.33×104 Ω.cm, 55.1 cm2/V.s to 2.03×103 Ω.cm 15.4 cm2/V.s for 3% Mo-doped ZnO thin film, while carrier density increased. The photodetection study demonstrated that the responsivity, detectivity, external quantum efficiency and response time of devices were significantly enhanced with Mo idoping.