Ab-initio prediction of the mechanical, magnetic and thermoelectric behaviour of perovskite oxides XGaO3 (X = Sc, Ti, Ag) using LDA+U functional: For optoelectronic devices

The mechanical, magnetic and thermoelectric properties of spin polarized XGaO3 (X = Sc, Ti, Ag) perovskite oxides in cubic phase have been investigated using LDA + U functional through ab-initio study based on density functional theory (DFT) in the framework of WIEN2K simulation code. The Full Poten...

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Veröffentlicht in:Journal of molecular graphics & modelling 2020-09, Vol.99, p.107621-107621, Article 107621
Hauptverfasser: Hussain, Muhammad Iqbal, Khalil, R.M. Arif, Hussain, Fayyaz, Rana, Anwar Manzoor, Imran, Muhammad
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Sprache:eng
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Zusammenfassung:The mechanical, magnetic and thermoelectric properties of spin polarized XGaO3 (X = Sc, Ti, Ag) perovskite oxides in cubic phase have been investigated using LDA + U functional through ab-initio study based on density functional theory (DFT) in the framework of WIEN2K simulation code. The Full Potential Linearized Augmented Plane Wave (FP-LAPW) technique along with PBE-GGA functional have been used to optimize the systems and determining exchange-correlation potential. However, in order to address on-site self-interactions error and overcome limitations of PBE-GGA functional, LDA + U has been employed because Hubbard parameter ‘U’ is found an appropriate remedy to consider on-site self-interactions, and to calculate improved electronic energy band gap. All spin polarized band structures reveal indirect band gap with different energies Eg (eV) such as ↑↓ 0.98 eV for ScGaO3, ↑1.05 eV and ↓1.70 eV for TiGaO3, ↑1.13 eV and ↓2.19 eV for AgGaO3. Thus, all compounds are semiconductor in nature. The analysis of spin polarized total and partial density of states unveil that ScGaO3 is non-magnetic material, whereas, TiGaO3 and AgGaO3 are characterized by strong exchange splitting of 3d (Ti) and 4d (Ag) states with significant spin magnetic moments, i.e., 1.0002 μB and −2.0002 μB, respectively. The elastic constants, i.e., Bulk, Young and Shear moduli, Poisson’s coefficient, Anisotropy factor, Pugh’s ratio, Cauchy pressure and melting temperature are calculated through Viogt-Reuss-Hill approximation. The thermoelectric response of the considered perovskites has been determined through semi-classical Boltzmann transport theory in the framework of BoltzTraP simulation code. Basic understandings of the mechanical, magnetic and thermoelectric properties of these compounds are studied for the first time in this manuscript. [Display omitted] •LDA + U functional better estimates band gap energy by considering on-site columbic interactions.•The studied compounds belong to semiconductor category.•TiGaO3 and AgGaO3 exhibit ductile nature, while, ScGaO3 is brittle material.•ScGaO3 is non-magnetic, whereas, TiGaO3 and AgGaO3 have significant spin magnetic moments.•The thermoelectric characters are elucidated as function of temperature.
ISSN:1093-3263
1873-4243
DOI:10.1016/j.jmgm.2020.107621