Determination of optical parameters of zinc oxide nanofibre deposited by electrospinning technique

Bolarinwa, H.S.; Onuu, Michael U.; Fasasi, A.Y.; Alayande, Samson Oluwagbemiga; Animasahun, Lukman O.; Abdulsalami, Ibrahim Olasegun; Fadodun, Olatomide G.; Egunjobi, I.A.

doi:10.1016/j.jtusci.2017.01.004

Cited by 44 publications

(17 citation statements)

References 39 publications

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“…Band gap was determined by extrapolating the straight portion to the photon energy axis at 0, the band gap was found to be between 3.30 eV and 3.60 eV. This band gap values are in line with works reviewed by [7,18,19]. Figure 9 shows the crystal structural studies of the ZnO nanofilm deposited at 30 seconds.…”

Section: Optical Propertiessupporting

confidence: 80%

“…Many techniques have been used for depositing high quality ZnO thin films. Some of them are electrodeposition technique [5,6], electrospinning technique [7], pulsed laser deposition [8], RF sputtering [9], chemical solution deposition [10,11], electron beam evaporation [12,13], the sol -gel method [14], spray pyrolysis [15,16], ultrasonic spray pyrolysis technique [3].…”

Section: Introductionmentioning

confidence: 99%

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Effect of Dip Time on Electrodeposited Zinc Oxide Nanofilm

Okoli¹

2018

AJMSP

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Nanofilms of Zinc Oxide (ZnO) were fabricated from solutions of zinc tetraoxosulphate heptahydrate, citric acid, and sodium hydroxide onto a Fluorine Tin Oxide (FTO) conductive glass by elecrodeposition process. Time as bath parameter was varied. Three samples with time interval of 30 seconds, 60 seconds and 90 seconds were fabricated. Absorbance of the films was determined with the help of spectrophotometer. Other optical properties of the nanofilms were calculated using the appropriate equations from the literature. The deposited nanofilms have high absorbance in UV region and low absorbance in VIS -NIR region. Transmittance of the nanofilms is low in UV region and high in VIS -NIR region. Reflectance of the films is low throughout the UV -VIS -NIR regions. The optimal optical thickness of 270 nm was obtained at 90 seconds. The bandgap of the nanofilms obtained is between 3.30 to 3.60 eV. Average crystallite size of 43.04 nm was obtained for the deposited ZnO thin film.

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Section: Optical Propertiessupporting

confidence: 80%

Section: Introductionmentioning

confidence: 99%

Effect of Dip Time on Electrodeposited Zinc Oxide Nanofilm

Okoli¹

2018

AJMSP

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“…Dielectric and magnetic properties of lossless and lossy materials influence the electromagnetic field distribution. Relative permittivity (ε = ε − jε ) and relative permeability (μ = μ − jμ) defines the dielectric and magnetic properties of the materials, respectively, and influence the reflection of EM waves at the interfaces and the attenuation of the wave within the materials [43,47,48]. Here ε and μ are the real parts and express the energy stored in the material when the electromagnetic field is passed through it.…”

Section: Characterization Of Synthesized Particlesmentioning

confidence: 99%

Absorption of electromagnetic waves in sandstone saturated with brine and nanofluids for application in enhanced oil recovery

Ali

Soleimani

Yahya

et al. 2020

Journal of Taibah University for Science

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In this study, scattering parameters of sandstone saturated with brine and nanofluids are evaluated experimentally and numerically for the application in enhanced oil recovery (EOR). Zinc Oxide (ZnO) and Bismuth ferrite BiFeO 3 (BFO) nanoparticles were synthesized via facile sol-gel method followed by nanofluid preparation. Sandstone samples were saturated with brine and nanofluids for 48 h. Electromagnetic properties of the saturated sandstones were measured experimentally using the vector network analyzer, and the scattering parameters of the samples were studied numerically by finite element method. BFO displayed higher permeability value of 1.52 and 1.30, as well as superior dielectric permittivity value 11.55 and 6.59 for real and imaginary parts, respectively. In addition, the sandstone saturated with BFO showed an impressive reflection loss (RL) value of −9.77 dB at high frequency. Conclusively, BiFeO 3 nanofluids showed the best potential to enhance oil recovery which can be accredited to the superior electromagnetic properties of BFO. ARTICLE HISTORY

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“…The concentration of the phases as given by the match3 software for Rietveld refinement shows that the amount of the Zn 2 SnO 4 increases from 51.5% to 61.2% and the ZnO decreases from 48.5% to 38.8% as the concentration of the zinc decreases and tin increases in the sample. In our earlier work [34], we reported the preferred growth direction for ZnO at [100], the shift in the 2θ position for the ZnO in the ZnO-Zn 2 SnO 4 is attributed to the interaction between the ZnO and the Zn 2 SnO 4 . The calculated crystallite size for the diffraction peaks using Scherrer relationship given Equation (1) is 14.78, 13.29, 12.31, 13.57 and 12.69 nm for 5% Sn, 10% Sn, 15% Sn, 20% Sn and 25% Sn respectively.…”

Section: Structural Characterisationmentioning

confidence: 99%

Effect of tin on bandgap narrowing and optical properties of ZnO–Zn₂SnO₄ electrospun nanofibre composite

Bolarinwa

Onuu

Animashaun

et al. 2020

Journal of Taibah University for Science

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The quest for improved visible light absorption in ZnO-based photocatalysts and photodetectors is a prevailing research problem. One method of solving this problem is by narrowing the band gap of this material well into the range of visible light energy. In this work, we have demonstrated considerable band narrowing into the visible region in our electrospun ternary ZnO-Zn 2 SnO 4 nanofibres. We also showed that band narrowing is highly dependent on the amount of Sn in the synthesized composite which could be attributed to the creation of localized states in the ZnO band and the attendant structural changes. However, beyond 15%wt doping there were observed changes in the trend of the bandgap reduction, crystallite sizes, and width of the localized states in the ternary ZnO-Zn 2 SnO 4 band. The details of experimental procedures and discussion of results have been included in this paper.

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Determination of optical parameters of zinc oxide nanofibre deposited by electrospinning technique

Cited by 44 publications

References 39 publications

Effect of Dip Time on Electrodeposited Zinc Oxide Nanofilm

Effect of Dip Time on Electrodeposited Zinc Oxide Nanofilm

Absorption of electromagnetic waves in sandstone saturated with brine and nanofluids for application in enhanced oil recovery

Effect of tin on bandgap narrowing and optical properties of ZnO–Zn₂SnO₄ electrospun nanofibre composite

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Determination of optical parameters of zinc oxide nanofibre deposited by electrospinning technique

Cited by 44 publications

References 39 publications

Effect of Dip Time on Electrodeposited Zinc Oxide Nanofilm

Effect of Dip Time on Electrodeposited Zinc Oxide Nanofilm

Absorption of electromagnetic waves in sandstone saturated with brine and nanofluids for application in enhanced oil recovery

Effect of tin on bandgap narrowing and optical properties of ZnO–Zn2SnO4 electrospun nanofibre composite

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Effect of tin on bandgap narrowing and optical properties of ZnO–Zn₂SnO₄ electrospun nanofibre composite