Role of 4p-3d orbital hybridization on band gap engineering of heavy metal glass for optoelectronic applications

•We have demonstrated that incorporation of highly electronegative p-block ions into heavy metal glasses can effectively depress their electronic band gap.•The 4p-3d orbital hybridization of SeO2 and Cr2O3 in heavy metal glass gets success to reduce dramatically the glass Urbach tail and Fermi level...

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Veröffentlicht in:	Journal of alloys and compounds 2014-08, Vol.605, p.157-163
Hauptverfasser:	El-Diasty, Fouad, Moustafa, F.A., Abdel-Wahab, F.A., Abdel-Baki, M., Fayad, A.M.
Format:	Artikel
Sprache:	eng
Schlagworte:	Banded structure Chalcogenide oxides Chemical bond approach Condensed matter: electronic structure, electrical, magnetic, and optical properties Electronic structure Elliott model Exact sciences and technology Excitation Excitons Glass Heavy metals Optical constants: refractive index, complex dielectric constant, absorption, reflection and transmission coefficients, emissivity Optical properties and condensed-matter spectroscopy and other interactions of matter with particles and radiation Optical properties of bulk materials and thin films Optoelectronics Orbitals p- and d-block elements hybridization Physics Two-photon absorption
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container_title	Journal of alloys and compounds
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creator	El-Diasty, Fouad Moustafa, F.A. Abdel-Wahab, F.A. Abdel-Baki, M. Fayad, A.M.
description	•We have demonstrated that incorporation of highly electronegative p-block ions into heavy metal glasses can effectively depress their electronic band gap.•The 4p-3d orbital hybridization of SeO2 and Cr2O3 in heavy metal glass gets success to reduce dramatically the glass Urbach tail and Fermi level while increasing the two-photon absorption coefficient one order of magnitude rather than conventional semiconductor glasses.•Applying Elliott’s model on linear absorption of the glass indicates that the glass has a direct band gap structure. Optoelectronic properties of glasses can be engineered by understanding the electronic structure and the symmetry of electronic states across the band gap where the chemical bonding is the origin of such electronic structure. Thus, series of heavy metal lead borate glasses of the composition 0.25B2O3–0.75PbO is prepared by melt quenching technique for Vis–IR photonics applications. Hybridization of p- and d-block elements, through co-substitution of Cr2O3 and SeO2, by B2O3, is used to tune effectively the glass electronic structure characteristics such as; band gap energy, Fermi level, and Urbach exciton–phonon coupling. Two-photon absorption coefficient is determined to elucidate the glass nonlinear sub-interband transitions. Chemical bond approach is applied to analyze and explain the obtained glass properties. The excitons excitation is discussed by applying Elliott’s model which indicates direct interband transition nature of the glass that is assisted by the existence of stable Frenkel excitons.
doi_str_mv	10.1016/j.jallcom.2014.03.162
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Optoelectronic properties of glasses can be engineered by understanding the electronic structure and the symmetry of electronic states across the band gap where the chemical bonding is the origin of such electronic structure. Thus, series of heavy metal lead borate glasses of the composition 0.25B2O3–0.75PbO is prepared by melt quenching technique for Vis–IR photonics applications. Hybridization of p- and d-block elements, through co-substitution of Cr2O3 and SeO2, by B2O3, is used to tune effectively the glass electronic structure characteristics such as; band gap energy, Fermi level, and Urbach exciton–phonon coupling. Two-photon absorption coefficient is determined to elucidate the glass nonlinear sub-interband transitions. Chemical bond approach is applied to analyze and explain the obtained glass properties. 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subjects	Banded structure Chalcogenide oxides Chemical bond approach Condensed matter: electronic structure, electrical, magnetic, and optical properties Electronic structure Elliott model Exact sciences and technology Excitation Excitons Glass Heavy metals Optical constants: refractive index, complex dielectric constant, absorption, reflection and transmission coefficients, emissivity Optical properties and condensed-matter spectroscopy and other interactions of matter with particles and radiation Optical properties of bulk materials and thin films Optoelectronics Orbitals p- and d-block elements hybridization Physics Two-photon absorption
title	Role of 4p-3d orbital hybridization on band gap engineering of heavy metal glass for optoelectronic applications
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