Non-linear spin-wave excitation at low bias fields

TL;DR

This paper investigates non-linear spin-wave excitation at low magnetic bias fields, revealing limitations of existing models and proposing a new theoretical framework supported by experimental data from time-resolved X-ray magnetic circular dichroism.

Contribution

It introduces a novel model of parametric spin-wave excitation that accurately describes low bias field behavior, extending the understanding of non-linear ferromagnetic resonance.

Findings

Existing models fail at low bias fields

New critical modes with amplitude phase oscillations identified

Model accurately predicts threshold amplitudes and decay rates

Abstract

Non-linear magnetization dynamics is essential for the operation of many spintronics devices. For microwave assisted switching of magnetic elements the low field regime is of particular interest. In addition a large number of experiments uses high amplitude FMR in order to generate d.c. currents via spin pumping mechanism. Here we use time resolved X-ray magnetic circular dichroism experiments to determine the number density of excited magnons in magnetically soft Ni_80Fe_20 thin films at small bias fields and large rf-excitation amplitudes. Our data shows that the common model of non-linear ferromagnetic resonance is not suitable to describe the low bias field limit. Here we derive a new model of parametric spin-wave excitation which correctly predicts threshold amplitudes and decay rates also at low bias fields. In fact a new series of critical modes with amplitude phase oscillations is found, generalizing the theory of parametric spin-wave excitation.