Fabrication of self-powered photodetector materials based on Ni-doped ZnO/p-Si heterojunctions

TL;DR

This study demonstrates that Ni-doped ZnO films grown on p-Si substrates can function as self-powered photodetectors, with doping levels influencing nanostructure, electrical properties, and response times, advancing energy-efficient optoelectronic devices.

Contribution

It introduces a method to optimize ZnO-based self-powered photodetectors via controlled Ni doping, analyzing structural and electrical effects for improved performance.

Findings

Ni doping reduces nanostructure size significantly.

Self-powered photodetectors show high photo-to-dark-current ratios.

Doped samples exhibit faster photoresponse times.

Abstract

In this paper, Ni-doped ZnO films were grown on a p-type silicon substrate via spray pyrolysis. The Ni dopant concentrations were varied by adjusting the weight ratio between Zinc Acetate Dehydrate (ZAD) and Nickel Chloride Hexahydrate (NCH), resulting in the ZnO, ZnO:Ni1%, and ZnO:Ni3% samples. Field-effect scanning electron microscopy (FESEM) images revealed that Ni doping significantly reduced the nanostructure size from 326 nm (ZnO) to 146 nm (ZnO:Ni3%). Similarly, X-ray diffraction (XRD) analysis also shows the decrease of the crystallite size with increasing Ni doping, from 44 nm (ZnO) to 35 nm (ZnO:Ni3%). Current-voltage (I-V) measurements were conducted at a bias voltage of 0 and 5 V to examine electrical and self-powered photodetection properties. All samples demonstrate self-powered photodetector performance. At the bias of 0 V, the undoped ZnO exhibited a higher photo-to-dark-current ratio (162) as compared to ZnO:Ni1% (18) and ZnO:Ni3% (16). The ZnO:Ni3% samples displayed faster rise (0.4 s) and fall times (1.7 s) as compared to the pure ZnO (10.8 s for rise time and 9.1 s for fall time), highlighting their potential for applications requiring rapid photoresponse. The findings provide valuable insights into optimizing the performance of ZnO-based photodetectors through controlled Ni doping, enabling advancements in self-powered photodetection technology for energy-efficient optoelectronic devices.