Mott Transition of MnO under Pressure: Comparison of Correlated Band Theories

TL;DR

This study compares four correlated band theory methods to analyze the pressure-induced Mott transition in MnO, revealing different transition types and properties predicted by each method.

Contribution

It provides a systematic comparison of LDA+U, pseudo-SIC, hybrid functional, and SIC-LSD methods for MnO under pressure, highlighting their differing predictions of electronic and magnetic transitions.

Findings

All methods predict a first-order volume and moment collapse.

Transition types vary: insulator-to-metal, insulator-to-insulator, and insulator-to-semimetal.

The methods show different critical pressures and transition characteristics.

Abstract

The electronic structure, magnetic moment, and volume collapse of MnO under pressure are obtained from four different correlated band theory methods; local density approximation + Hubbard U (LDA+U), pseudopotential self-interaction correction (pseudo-SIC), the hybrid functional (combined local exchange plus Hartree-Fock exchange), and the local spin density SIC (SIC-LSD) method. Each method treats correlation among the five Mn 3d orbitals (per spin), including their hybridization with three O $2p$ orbitals in the valence bands and their changes with pressure. The focus is on comparison of the methods for rocksalt MnO (neglecting the observed transition to the NiAs structure in the 90-100 GPa range). Each method predicts a first-order volume collapse, but with variation in the predicted volume and critical pressure. Accompanying the volume collapse is a moment collapse, which for all methods is from high-spin to low-spin (5/2 to 1/2), not to nonmagnetic as the simplest scenario would have. The specific manner in which the transition occurs varies considerably among the methods: pseudo-SIC and SIC-LSD give insulator-to-metal, while LDA+U gives insulator-to-insulator and the hybrid method gives an insulator-to-semimetal transition. Projected densities of states above and below the transition are presented for each of the methods and used to analyze the character of each transition. In some cases the rhombohedral symmetry of the antiferromagnetically ordered phase clearly influences the character of the transition.