Publication Type : Journal Article
Publisher : Computational Condensed Matter
Source : Computational Condensed Matter, Vol. 14, pp. 27-35, March 2018
Url : https://www.sciencedirect.com/science/article/abs/pii/S2352214317302034
Campus : Chennai
School : School of Engineering
Department : Electronics and Communication
Year : 2018
Abstract : The cubic double perovskites A2ZnWO6 (A = Ba, Sr and Ca) are studied to understand the effect of A cation site, using the density functional theory (DFT) based full potential augmented plane wave method (FP-LAPW) with GGA and mBJ exchange correlation potentials. The structural robustness and stability are investigated using the bond lengths and the total energy. The band structure and density of states suggest that all these cubic double perovskites are indirect wide band gap semiconductors. The band gap varies from 3.90 eV (2.97 eV) for Ba2ZnWO6 system to 3.40 eV (2.8 eV) for Ca2ZnWO6 system using mBJ (GGA) exchange correlation potentials. Our studies suggest that A cation site modification has a strong effect on physical and electronic properties, in contrast to the structural robustness. The lattice parameter decreases from 8.19 Å to 7.9 Å from Ba to Ca at alkali cation site and the electronic band gap variation follows the common cation rule. The charge densities show enhanced localization of charges near the zinc and oxygen sites with increasing alkali cation atomic radii. In addition, we discuss the impact of A cation site modification on the dielectric and optical properties for A2ZnWO6 double perovskites.
Cite this Research Publication : R. Chaurasiya, S. Auluck, A. Dixit, Cation modified A2(Ba, Sr and Ca) ZnWO6 cubic double perovskites: A theoretical study, Computational Condensed Matter, Vol. 14, pp. 27-35, March 2018