Optical and electrical properties of NiO for possible dielectric applications

Nickel oxide (NiO) is a versatile wide band gap semiconductor material. At present, transparent conducting oxide films find application as transparent electrodes and window coatings for opto-electronic devices but most are n-type. However p-type conducting films, of which NiO is one, are required a...

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Main Authors: Andre Venter, Johannes R. Botha
Format: Article
Language:English
Published: Academy of Science of South Africa 2011-01-01
Series:South African Journal of Science
Online Access:http://archive.sajs.co.za/index.php/SAJS/article/view/268
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spelling doaj-7fd449e0d92447aeb5ba2b5ec6f0828d2020-11-24T20:56:03ZengAcademy of Science of South AfricaSouth African Journal of Science0038-23531996-74892011-01-011071/210.4102/sajs.v107i1/2.268268Optical and electrical properties of NiO for possible dielectric applicationsAndre Venter0Johannes R. Botha1NMMUDepartment of Physics, Nelson Mandela Metropolitan University, Port ElizabethNickel oxide (NiO) is a versatile wide band gap semiconductor material. At present, transparent conducting oxide films find application as transparent electrodes and window coatings for opto-electronic devices but most are n-type. However p-type conducting films, of which NiO is one, are required as optical windows for devices where minority carrier injection is required. In this study, nickel (Ni) was resistively deposited on glass substrates and oxidised (isochronally) in oxygen at temperatures ranging from 300 ˚C to 600 ˚C. The oxidised Ni layers were subsequently characterised using scanning electron microscopy (SEM), X-ray diffraction (XRD) and UV-visible photospectrometry in the range 200 nm – 1000 nm. The four point probe method (van der Pauw geometry) was used to determine the sheet resistances of the oxidised films. SEM results of the surface revealed a strong dependence of the surface texture and particle size on the oxidation temperature and time. XRD performed on the oxidised Ni indicated progressive transformation from nanograined polycrystalline Ni to NiO at elevated temperatures. Film thicknesses, particle sizes, energy band gap and wavelength-dependent refractive indices were determined from transmission and absorbance data.http://archive.sajs.co.za/index.php/SAJS/article/view/268
collection DOAJ
language English
format Article
sources DOAJ
author Andre Venter
Johannes R. Botha
spellingShingle Andre Venter
Johannes R. Botha
Optical and electrical properties of NiO for possible dielectric applications
South African Journal of Science
author_facet Andre Venter
Johannes R. Botha
author_sort Andre Venter
title Optical and electrical properties of NiO for possible dielectric applications
title_short Optical and electrical properties of NiO for possible dielectric applications
title_full Optical and electrical properties of NiO for possible dielectric applications
title_fullStr Optical and electrical properties of NiO for possible dielectric applications
title_full_unstemmed Optical and electrical properties of NiO for possible dielectric applications
title_sort optical and electrical properties of nio for possible dielectric applications
publisher Academy of Science of South Africa
series South African Journal of Science
issn 0038-2353
1996-7489
publishDate 2011-01-01
description Nickel oxide (NiO) is a versatile wide band gap semiconductor material. At present, transparent conducting oxide films find application as transparent electrodes and window coatings for opto-electronic devices but most are n-type. However p-type conducting films, of which NiO is one, are required as optical windows for devices where minority carrier injection is required. In this study, nickel (Ni) was resistively deposited on glass substrates and oxidised (isochronally) in oxygen at temperatures ranging from 300 ˚C to 600 ˚C. The oxidised Ni layers were subsequently characterised using scanning electron microscopy (SEM), X-ray diffraction (XRD) and UV-visible photospectrometry in the range 200 nm – 1000 nm. The four point probe method (van der Pauw geometry) was used to determine the sheet resistances of the oxidised films. SEM results of the surface revealed a strong dependence of the surface texture and particle size on the oxidation temperature and time. XRD performed on the oxidised Ni indicated progressive transformation from nanograined polycrystalline Ni to NiO at elevated temperatures. Film thicknesses, particle sizes, energy band gap and wavelength-dependent refractive indices were determined from transmission and absorbance data.
url http://archive.sajs.co.za/index.php/SAJS/article/view/268
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