Charge and Orbital Orderings, and Frustration in Quasi-one-dimensional Ferrimagnetic Insulator β-V2O(PO4)

Abstract

Using ab initio calculations based on the correlated band theory, we have investigated the quasi-one-dimensional chain system β-V2O(PO4), showing both charge and spin orderings. Even in the uncorrelated region, the pure transition from the tetragonal to the monoclinic structure leads to a sizable charge difference between the two types of V ions, regardless of magnetic orders. In the ferrimagnetic phase, inclusion of the on-site Coulomb repulsion U leads to a full orbital-polarization of V1 (t2g3, S=32) and V2 (a1g1eg1, S=1) above Uceff≈3.5 eV, leading to local spin moments of 2.30 and --1.54 μB, respectively, with small orbital moments of several hundredth μB. So, the net moment is nearly 1 μB per formula unit, which is about 2--3 times larger than the experimental value. Our results show significant variations, strongly depending on the strength of Ueff, in energy differences between various magnetic states as well as a small magnetic anisotropy. These results suggest that the substantial difference between the calculated and experimental moments is attributed to quantum fluctuation of the pyrochlore-like weakly linked V4 tetrahedral structure. Our findings are expected to provide a good platform to investigate the interplay among the charge-, spin-, and lattice-degrees of freedom, and geometrical frustration.