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I agree, do not show this message again.Features of the optical absorption, phonon spectrum and glass transition in As-Se, As-Se-S, As-Se-Te chalcogenide semiconductors
R. I. ALEKBEROV1,2,* , A. I. ISAYEV1, S. I. MEKHTIYEVA1
Affiliation
- Institute of Physics named after academician G.M. Abdullayev's of Azerbaijan National Academy of Sciences, G. Javidave 13, AZ1143 Baku, Azerbaijan
- Azerbaijan State University of Economics (UNEC), st.Istiqlaliyyat6, Baku, AZ 1001, Azerbaijan
Abstract
The optical properties, phonon spectrum, amorphousness and glass transition temperature of As40Se60, As40Se30Те30, As40Se30S30, As33,3Se33,3S33,4, As33,3Se33,3Te33,4 chalcogenide glasses have been studied by optical, Raman spectroscopy, X-ray diffraction and differential scanning calorimetry (DSC)methods. Ithasbeen determined the values of optical band gap(Eg), energy of Urbach(U), the bands of Raman scattering, glass transition temperature(Tg) and also wascalculated the parameters characterizing the amorphous matrix as cohesive energy(CE), the average bond energy(〈𝐸〉)average coordination number(Z), the average value of the atomic volume (Va), packing density (κ) and compactness (δ) in studied compositions. The results show that,there is correlation between the cohesive energy (CE), the glass transition temperature(Tg), the average bond energy (〈𝐸〉)and the optical band gap (Eg).
Keywords
Chalcogenide, Glass, Amorphous, Cohesive energy.
Submitted at: Jan. 14, 2020
Accepted at: Dec. 7, 2020
Citation
R. I. ALEKBEROV, A. I. ISAYEV, S. I. MEKHTIYEVA, Features of the optical absorption, phonon spectrum and glass transition in As-Se, As-Se-S, As-Se-Te chalcogenide semiconductors, Journal of Optoelectronics and Advanced Materials Vol. 22, Iss. 11-12, pp. 596-605 (2020)
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