First-principles study of the gap in the spin excitation spectrum of the CrI$_3$ honeycomb ferromagnet

TL;DR

This study uses first-principles calculations to explain the origin of the gap in the spin excitation spectrum of CrI$_3$, attributing it to spin-orbit and inter-layer interactions, aligning with experimental observations.

Contribution

It provides a detailed first-principles explanation for the spin gap in CrI$_3$, highlighting the roles of spin-orbit coupling and inter-layer effects, which were previously debated.

Findings

The gap results from spin-orbit and inter-layer interactions.

Inter-layer effects cause the gap's displacement and magnitude increase.

Theoretical results agree with experimental data.

Abstract

The nature of the gap observed at the zone border in the spin-excitation spectrum of CrI$_3$ quasi-2D single crystals is still controversial. We perform first-principles calculations based on time-dependent density-functional perturbation theory, which indicate that the observed gap results from a combination of spin-orbit and inter-layer interaction effects. The former give rise to the anisotropic spin-spin interactions that are responsible for its very existence, while the latter determine both its displacement from the K point of the Brillouin zone due to the in-plane lattice distortions induced by them, and an enhancement of its magnitude, in agreement with experiments and previous theoretical work based on a lattice model.