Structural, electronic, and magneto-optical properties of YVO$_3$

TL;DR

This study investigates the structural, electronic, and magneto-optical properties of YVO$_3$, revealing phase transitions, electronic band structure, and Kerr effect behavior related to orbital ordering and magnetic phases.

Contribution

It provides a comprehensive analysis combining experimental optical measurements with band structure calculations and ligand field considerations for YVO$_3$.

Findings

Identified two structural phase transitions at 75 K and 200 K.

YVO$_3$ is confirmed as a Mott-Hubbard insulator with a 1.6 eV gap.

Observed Kerr effect correlates with magnetic and orbital ordering.

Abstract

Optical and magneto-optical properties of YVO$_3$ single crystal were studied in FIR, visible, and UV regions. Two structural phase transitions at 75 K and 200 K were observed and established to be of the first and second order, respectively. The lattice has an orthorhombic $Pbnm$ symmetry both above 200 K as well as below 75 K, and is found to be dimerized monoclinic $Pb11$ in between. We identify YVO$_3$ as a Mott-Hubbard insulator with the optical gap of 1.6 eV. The electronic excitations in the visible spectrum are determined by three $d$-bands at 1.8, 2.4, and 3.3 eV, followed by the charge-transfer transitions at about 4 eV. The observed structure is in good agreement with LSDA+$U$ band structure calculations. By using ligand field considerations, we assigned these bands to the transitions to the $^4A_{2g}$, $^2E_{g} + ^2T_{1g}$, and $^2T_{2g}$ states. The strong temperature dependence of these bands is in agreement with the formation of orbital order. Despite the small net magnetic moment of 0.01 $\mu_B$ per vanadium, the Kerr effect of the order of $0.01^\circ$ was observed for all three $d$-bands in the magnetically ordered phase $T_{\text{N\'eel}}<116 K$. A surprisingly strong enhancement of the Kerr effect was found below 75 K, reaching a maximum of $0.1^\circ$. The effect is ascribed to the non-vanishing net orbital magnetic moment.