2023
DOI: 10.1088/1402-4896/acd284
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Enhancement of UV detection properties of ZnO thin films via Ni doping

Abstract: In this work pure and Ni-doped ZnO thin films have been deposited onto glass substrates using the spray pyrolysis technique. All films were deposited at constant deposition parameters but the Ni content was changed from 0 to 7 weight (wt) %. XRD results revealed the formation of a hexagonal ZnO phase whilst no other phases were detected. The crystallite size was determined using Scherrer's equation and found to be 45.9 nm for the pure film. Scanning electron microscope images show the formation of irregular gr… Show more

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Cited by 8 publications
(2 citation statements)
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“…The rise and recovery periods of the doped films were shorter than those of the pure films. The film with 7 wt % nickel had a minimum rise time of 0.09 s, whereas the film with 1 wt % nickel had a minimum decay time of 0.07 s. 86 Vanadium doping boosted the carrier density and created defect states, resulting in a considerable decrease in the electron−hole recombination rate and a high photocurrent when exposed to UV light. Compared to pristine ZnO-based PDs, the V/ZnObased PDs displayed a 156% increase in the photocurrent, as well as short reaction and recovery times.…”
Section: Nanostructured Zno-based Uv Pdsmentioning
confidence: 99%
“…The rise and recovery periods of the doped films were shorter than those of the pure films. The film with 7 wt % nickel had a minimum rise time of 0.09 s, whereas the film with 1 wt % nickel had a minimum decay time of 0.07 s. 86 Vanadium doping boosted the carrier density and created defect states, resulting in a considerable decrease in the electron−hole recombination rate and a high photocurrent when exposed to UV light. Compared to pristine ZnO-based PDs, the V/ZnObased PDs displayed a 156% increase in the photocurrent, as well as short reaction and recovery times.…”
Section: Nanostructured Zno-based Uv Pdsmentioning
confidence: 99%
“…The chemically modified Zn(Ni)O composite nanostructures show an altered bandgap electronic structure with a significant effect on the physical properties. The most recent studies are focused on the following: (i) the main optical properties (absorbance, photoluminescence) and constants, photoconductivity and low optical losses, linear and non-linear (third order) optical susceptibilities with opto-electronic prospects in quantum technologies [10], photodetection [11] and solar cells with high detector responsivity; (ii) the development of enhanced catalyst function [12,13] and surface (gas species) adsorption in numerous green chemistry applications, especially for photo-chemical [14] and gas sensing applications [15]; and (iii) notable thermoelectric [16] and acoustoelectronic [15] (with larger insertion loss and phase shift) characteristics.…”
Section: Introductionmentioning
confidence: 99%