Physical and Optical Properties of Silicon Doped LaOF: Gd3+ Nanoparticles Prepared by Combustion Method
Authors
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Department of Physics, Maharani’s Science College for Women Palace Road, Bangalore – 560001, Karnataka ,IN
A. Jayasheelan -
Department of Physics, B.M.S. Instutite of Technology, Bangalore – 560064, Karnataka ,INR. Venkatesh
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Maharani Science College for women, Bengaluru ,INN. Hanumantharaju
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Department of Physics, Government First College, Kunigal – 572130, Karnataka ,ING. Chandrashekaraiah
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Department of Physics, Maharani’s Science College for Women Palace Road, Bangalore – 560001, Karnataka ,INK. K. Mohankeshava
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Department of Physics, Government College, Gubbi – 572216 Karnataka ,INJ. Shivakumar
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Department of Physics, Sai Vidya Institute of Technology, Bangalore – 560064, Karnataka ,INP. Shankar
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Department of Physics, Maharani’s Science College for Women Palace Road, Bangalore – 560001, Karnataka ,INV. C. Veeranna Gowda
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Department of Physics, Maharani’s Science College for Women Palace Road, Bangalore – 560001, Karnataka ,INKaranam Madhavi
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Department of Physics, Maharani’s Science College for Women Palace Road, Bangalore – 560001, Karnataka ,INWajeeha Sultana
DOI:
https://doi.org/10.18311/jmmf/2023/33537Keywords:
Combustion, Gd3 , LaOF, Optical, Physical, Rare Earth, SiliconAbstract
The bandgap energy and density of the sample were found by the analytical method. The density was found to increase up to 5 mol%, depicting the compactness of the sample and then decreasing with gadolinium content. Molar volume (Vm), Gd3+ ion concentration (N), refractive index (n), electronic polarizability (αe), reflection loss (RL), polaron radius (rp), internuclear distance (ri), field strength(F), dielectric constant(ɛ) of the sample were calculated.
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This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
Accepted 2023-09-22
Published 2023-09-22
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