High-responsivity self-powered UV photodetector performance of pristine and V-doped ZnO nano-flowers

Wurtzite ZnO nanostructures are suitable for high-performance, self-powered photodetectors (PDs) because of their attractive optoelectronic properties. In this study, highly sensitive ultra-violet self-powered PDs with high responsivity/detectivity and large external quantum efficiency was developed by V-doped ZnO nanoflower samples onto an ITO glass substrate. Highly faceted pristine and V-doped ZnO nanoflowers were produced using a simple, low-cost co-precipitation method. The presence of Na+ ions in the precursor solution appeared to control the morphology of the nanomaterial. Various physicochemical characterizations showed that the variation of the Na+ ion concentration inhibits the reaction at selected regions, causing the branching of nanostructures to form ZnO nanoflowers. Room- and low-temperature photoluminescence studies showed that V-doping increases the extrinsic carrier density and produces many intrinsic and extrinsic defect states, which reduce the e(-)-h(+) recombination rate significantly and produce a large photocurrent under UV illumination. The V-ZnO-based self-powered UV PD device showed a 156 % increase in photocurrent compared to pristine ZnO-based PDs, with very short response/recovery times of 0.22/0.23 s under 382 nm UV illumination of 1.14 mW/cm(2), and excellent responsivity (5.1 x 10(3) mA/W), very high external quantum efficiency (5.5 x 10(4) %), and large detectivity (4.0 x 10(13) Jones). Therefore, the current work presents a simple way to obtain high-performance self-powered UV PDs that can open up a new horizon to fabricate new-generation optoelectronic devices for diverse applications.

Automated summary

In this study, highly sensitive self-powered photodetectors (PDs) with V-doped ZnO nanoflower samples on an ITO glass substrate were developed. V-ZnO-based PDs showed higher photocurrent, shorter response/recovery times, and excellent responsivity, external quantum efficiency, and detectivity compared to pristine ZnO-based PDs.