Highly Sensitive and Self Powered Ultraviolet Photo Detector based on ZnO Nanorods Coated with TiO2

Abstract

Nanorods (NRs) of crystalline ZnO coated with thin layers of TiO2(ZnO@TiO2) were fabricated with the help of the spin coating technique followed by the hydrothermal method. Scanning electron microscopy (SEM) and X-ray diffraction analysis confirms the morphology and structural stability of as-prepared NRs. The optical band gaps of the NRs were estimated, and a clear blue shift toward the UV region has been detected. When UV light falls on as-prepared device (i.e., in the "ON" state), a significant increase in photocurrent (IUV) at zero voltage supply was observed from 6 μA to 17 μA while in the "OFF" state, the dark current (Idark), increases from 0.08 μA to 0.6 μA with ZnO@TiO2 NRs as compared to bare ZnO NRs respectively. Responsivity and detectivity of TiO2 coated ZnO NRs based device found maximum in UV region unlike bare ZnO NRs. Enhanced photocurrent achieved by the growth of TiO2 layers on ZnO NRs is 250 μA as compared to bare ZnO NRs for which it is 35 μA at 10 V voltage supply under the ultraviolet irradiation (illumination intensity of 1 mW/cm2). Furthermore, theoretical calculations have been performed using the first-principles density-functional theory to understand the effects of heterostructure NRs on the electronic and optical properties of TiO2 coated ZnO.