Self-consistent evaluation of effective Coulomb interaction of V atom and its importance to understand the comparative electronic behaviour of vanadium spinels

Abstract

In present work, we try to understand the importance of effective Coulomb interaction (Uef) between localized electrons of V atom to understand the comparative electronic behaviour of AV2O4 (A=Zn, Cd and Mg) compounds. The suitable values of d-linearization energy (Ed) of impurity V atom for calculating the Uef for these compounds are found to be ≥44.89 eV above the Fermi level. Corresponding to these values of Ed, the self-consistently calculated values of effective ULSDA (UPBEsol) for ZnV2O4, MgV2O4 and CdV2O4 are 5.73 (5.92), 6.06 (6.22) and 5.59 (5.71) eV, respectively. The calculated values of tUef (t is the transfer integral between neighbouring sites) increases with decreasing V-V distance from CdV2O4 to MgV2O4 to ZnV2O4 and are found to be consistent with experimentally reported band gap. The values of tUef for ZnV2O4, MgV2O4 and CdV2O4 are found to be 0.023, 0.020 and 0.018, respectively. Hence, CdV2O4 with small (large) tUef (experimental band gap) as compared to ZnV2O4 and MgV2O4 is found to be in localized-electron regime, while ZnV2O4 and MgV2O4 are intermediate between localized and an itinerant-electron regime. The calculated values of lattice parameters aLSDS (aPBEsol) are found to be 1.7\%, 2.0\% and 2.4\% (0.6\%, 0.7\% and 0.7\%) smaller than aexp for CdV2O4, MgV2O4 and ZnV2O4, respectively, which indicates that the PBEsol functional predicts the lattice parameters in good agreement with the experimental data.