Electronic Structure of Chromium Trihalides beyond Density Functional Theory

Abstract

We explore the electronic band structure of free standing monolayers of chromium trihalides, CrX3, X= Cl, Br, I, within an advanced ab-initio theoretical approach based in the use of Green's function functionals. We compare the local density approximation with the quasi-particle self-consistent GW approximation (QSGW) and its self-consistent extension (QSGW) by solving the particle-hole ladder Bethe-Salpeter equations to improve the effective interaction W. We show that at all levels of theory, the valence band consistently changes shape in the sequence ClBrI, and the valence band maximum shifts from the M point to the point. However, the details of the transition, the one-particle bandgap, and the eigenfunctions change considerably going up the ladder to higher levels of theory. The eigenfunctions become more directional, and at the M point there is a strong anisotropy in the effective mass. Also the dynamic and momentum dependent self energy shows that QSGW adds to the localization of the systems in comparison to the QSGW thereby leading to a narrower band and reduced amount of halogens in the valence band manifold.

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