Your search keyword '"Arya, B. S."' showing total 2 results

1. First-principles calculations to investigate structural, electronic, mechanical, optical, thermophysical and vibrational properties of TaFeSb.

Author

Gour, Atul, Rathore, Rahul, Singh, Sadhna, and Arya, B. S.

Subjects

PHONON dispersion relations, ELASTICITY, BULK modulus, THERMOPHYSICAL properties, THERMOELECTRIC apparatus & appliances, THERMOELECTRIC materials, DENSITY functional theory

Abstract

In this work, the structural, electronic, mechanical, optical, thermophysical and phonon properties of TaFeSb are investigated using density functional theory in stable cubic state. On the basis of elastic properties reported, it is confirmed that this compound shows hardness (due to high bulk modulus), is ductile and has anisotropic nature. The band structure and density of states calculations of TaFeSb exhibit semiconducting nature. Various optical properties viz. high absorption and low reflectivity are calculated, which confirm its applications in optoelectronics. The thermophysical properties of TaFeSb at high temperatures and high pressures are studied for the first time, which can pave new directions to thermoelectric applications at high temperatures and high pressures. It is found that TaFeSb follows Debye T3 law and Dulong–Petit limit at elevated temperatures and pressures. Moreover, we have done detailed analysis on phonon dispersion relation, density of phonon states and thermal properties of TaFeSb, which would help in heat dissipation in computer chips and thermoelectric devices. [ABSTRACT FROM AUTHOR]

Published

2022

2. High pressure phase transition and elastic properties of americium telluride.

Author

Aynyas, Mahendra, Rukmangad, Aditi, Arya, B. S., and Sanyal, S. P.

Subjects

PHASE transitions, HIGH pressure (Technology), ELASTICITY, AMERICIUM compounds, CRYSTAL structure, CRYSTALLOGRAPHY, LATTICE constants, DEBYE temperatures

Abstract

The structural and elastic properties of Americium Telluride (AmTe) have been investigated by using a modified inter-ionic potential theory (MIPT). This theory is capable of explaining first order phase transition with a crystallographic change NaCl to CsCl structure for this compound. The values of optimized lattice constant, phase transition pressure, zero pressure bulk modulus and second order elastic constants (C11, C44) agree well with their corresponding experimental data. Debye temperature (θD) is also calculated for this compound for the first time. [ABSTRACT FROM AUTHOR]

Published

2013