Thermal squeezing and nonlinear spectral shift of magnons in antiferromagnetic insulators

TL;DR

This paper studies how magnon-magnon interactions at finite temperatures affect the dispersion, polarization, and resonance modes of magnons in antiferromagnetic insulators, revealing nonlinear effects that alter magnon properties.

Contribution

It introduces a self-consistent Hartree-Fock approach to analyze nonlinear thermal magnon interactions and their impact on magnon dispersion and polarization in antiferromagnetic insulators.

Findings

Nonlinear interactions cause temperature-dependent shifts in magnon bandgap and resonance modes.

Magnon polarization is altered, with modes becoming elliptical due to nonlinear effects.

Thermal nonlinear interactions break local U(1) symmetry, affecting magnon mode polarization.

Abstract

We investigate the effect of magnon-magnon interactions on the dispersion and polarization of magnons in collinear antiferromagnetic (AF) insulators at finite temperatures. In two-sublattice AF systems with either uniaxial or biaxial magnetocrystalline anisotropies, we implement a self-consistent Hartree-Fock mean-field approximation to explore the nonlinear thermal interactions. The resulting nonlinear magnon interactions separate into two-magnon intra- and interband scattering processes. Furthermore, we compute the temperature dependence of the magnon bandgap and AF resonance modes due to nonlinear magnon interactions for square and hexagonal lattices. In addition, we study the effect of magnon interactions on the polarization of magnon modes. We find that although the noninteracting eigenmodes in the uniaxial case are circularly polarized, but in the presence of nonlinear thermal interactions the local U(1) symmetry of the Hamiltonian is broken. The attractive nonlinear interactions squeeze the low-energy magnon modes and make them elliptical. In the biaxial case, on the other hand, the bare eigenmodes of low energy magnons are elliptically polarized but thermal nonlinear interactions squeeze them further. Direct measurements of the predicted temperature-dependent AF resonance modes and their polarization can be used as a tool to probe the nonlinear interactions. Our findings establish a framework for exploring the effect of thermal magnon interactions in technologically important magnetic systems, such as magnetic stability of recently discovered two-dimensional magnetic materials, coherent transport of magnons, Bose-Einstein condensation of magnons, and magnonic topological insulators.