Micromagnetic modeling of magnon coherent states in a nonuniform magnetic field

TL;DR

This paper uses micromagnetic simulations to demonstrate the formation of long-range coherent magnon states in a nonuniform magnetic field, advancing understanding of magnon Bose condensation.

Contribution

It provides the first micromagnetic modeling evidence of coherent magnon states with spatially inhomogeneous amplitude in nonuniform fields.

Findings

Coherent magnon states form under high excitation conditions.

These states extend over long distances.

The amplitude is spatially inhomogeneous, phase is homogeneous.

Abstract

The study of the dynamics of magnetically ordered states in strong excitation through micromagnetic modeling has become relevant due to the observation of magnon Bose condensation. In particular, the question has arisen about the possibility of describing the coherent quantum state by the quasi-classical Landau-Lifshitz-Gilbert equations. We performed micromagnetic simulations of magnetization precession with a high angle of deviation in an out-of-plane nonuniform dc field. Our results confirm the formation of coherent magnon state under conditions of high excitation. This coherent state extends over long distances and described by a spatially inhomogeneous amplitude and a homogeneous precession phase.