Dirac magnons in honeycomb ferromagnets
Sergey S. Pershoguba, Saikat Banerjee, J.C. Lashley, Jihwey Park, Hans, {\AA}gren, Gabriel Aeppli, and Alexander V. Balatsky

TL;DR
This paper investigates how magnon-magnon interactions influence Dirac magnons in honeycomb ferromagnets, revealing significant momentum-dependent effects and explaining historical neutron scattering anomalies.
Contribution
It extends ferromagnet theory to non-Bravais honeycomb layers, demonstrating the impact of interactions on Dirac magnon stability and properties.
Findings
Magnon-magnon interactions cause momentum-dependent band renormalization.
The theory explains previously unexplained neutron scattering data.
Honeycomb ferromagnets exhibit dispersive surface and edge states.
Abstract
The discovery of the Dirac electron dispersion in graphene led to the question of the Dirac cone stability with respect to interactions. Coulomb interactions between electrons were shown to induce a logarithmic renormalization of the Dirac dispersion. With a rapid expansion of the list of compounds and quasiparticle bands with linear band touching, the concept of bosonic Dirac materials has emerged. We consider a specific case of ferromagnets consisting of the Van der Waals-bonded stacks of honeycomb layers, e.g chromium trihalides CrX3 (X = F, Cl, Br and I), that display two spin wave modes with energy dispersion similar to that for the electrons in graphene. At the single particle level, these materials resemble their fermionic counterparts. However, how different particle statistics and interactions affect the stability of Dirac cones has yet to be determined. To address the role of…
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