Influence of doping concentration on the zinc doped nickel oxide nanostructures: morphological, structural, and optical properties

Norfarariyanti Parimon and Mamat, M.H. and Shameem Banu, I.B. and Vasimalai, N. and Suriani, A.B. and Mohamed, A. and Ahmad, M.K. and Rusop, M. (2021) Influence of doping concentration on the zinc doped nickel oxide nanostructures: morphological, structural, and optical properties. In: 4th National Conference on Wind and Earthquake Engineering, NCWE 2020, 16 - 17 October 2020, Putrajaya, Malaysia.

[img] Text
Influence of doping concentration on the zinc doped nickel oxide nanostructures_ morphological, structural, and optical properties_ABSTRACT.pdf

Download (65kB)
[img] Text
Influence of doping concentration on the zinc doped nickel oxide nanostructures_ Morphological, structural, and optical properties.pdf
Restricted to Registered users only

Download (1MB) | Request a copy

Abstract

The zinc doped nickel oxide (Zn:NiO) nanostructures with 0 at.% (UD), 1 at.% (1ZNO), and 2 at.% (2ZNO) of Zn concentrations were successfully deposited on the NiO seed-coated glass substrates. The films were successfully produced from two synthesis techniques: the sol-gel spin coating for NiO seed-coated and the solution immersion for the Zn:NiO nanostructures. The films were then pre-baked at 150 °C and subsequently annealed at 500 °C. The Zn doping concentrations affecting NiO in terms of morphological, structural, and optical properties were investigated. The surface morphologies and cross-sectional images of the Zn:NiO nanostructures were observed by field emission scanning microscopy. The observation showed that the groups of nanoflower (NF), which were grown above the nanosheet (NS) array were gradually decreased with the increasing percentage of the Zn doping. The thickness of the NS also drastically decreases as the Zn dopant is increased. The thicknesses measured are 910 nm, 410 nm, and 100 nm for UD, 1ZNO, and 2ZNO, respectively. The X-ray diffraction analysis showed the Zn:NiO peak intensities were affected and decreased as the Zn doping is increased. Take into account the significant differences in the (200) plane, the crystal parameters were calculated. The dislocation density, interplanar spacing, lattice parameter, and unit cell volume increased as the Zn doping increased. Meanwhile, the average crystallite size reduces when the percentage of Zn doping is increased. This condition makes the Zn:NiO nanostructures are promising for sensing applications due to enhanced surface area. The strain and stress values of the Zn:NiO showed the tensile strain and compressive stress, respectively. The transmittance spectra showed the transparencies in the visible region within 400 to 800 nm wavelength increases when the percentage of Zn doping is increased. The average transmittance percentages are 32.1 %, 62.8 %, and 67.0 % for UD, 1ZNO, and 2ZNO, respectively. The optical bandgap increases sharply as the Zn doping increased from 3.55 to 4.75 eV.

Item Type: Conference or Workshop Item (Paper)
Keyword: Cadmium oxide , Spray pyrolysis , Crystallite size
Subjects: T Technology > TN Mining engineering. Metallurgy > TN1-997 Mining engineering. Metallurgy > TN600-799 Metallurgy
Department: FACULTY > Faculty of Engineering
Depositing User: SAFRUDIN BIN DARUN -
Date Deposited: 17 Nov 2021 10:22
Last Modified: 17 Nov 2021 10:22
URI: https://eprints.ums.edu.my/id/eprint/31076

Actions (login required)

View Item View Item