Caustic spin wave beams in soft, thin films: properties and classification

TL;DR

This paper investigates caustic spin wave beams in soft, thin ferromagnetic films, combining analytical modeling and experiments to classify and understand their properties, with potential applications in broadband, low-divergence wave focusing.

Contribution

It introduces a systematic analytical framework for classifying caustic spin wave beams and validates it through experiments, highlighting two cases with broadband excitation and narrowband, low-divergence beams.

Findings

Validated theoretical predictions with time-resolved microscopy.

Identified cases enabling broadband excitation to produce narrowband beams.

Provided tools for systematic survey of caustic spin wave phenomena.

Abstract

In the context of wave propagation, caustics are usually defined as the envelope of a finite-extent wavefront; folds and cusps in a caustic result in enhanced wave amplitudes. Here, we tackle a related phenomenon, namely the existence of well-defined beams originating solely from the geometric properties of the corresponding dispersion relation. This directional emission, termed caustic beam, is enabled by a stationary group velocity direction, and has been observed first in the case of phonons. We propose an overview of this "focusing" effect in the context of spin waves excited in soft, thin ferromagnetic films. Based on an analytical dispersion relation, we provide tools for a systematic survey of caustic spin wave beams. Our theoretical approach is validated by time-resolved microscopy experiments using the magneto-optical Kerr effect. Then, we identify two cases of particular interest both from fundamental and applicative perspectives. Indeed, both of them enable broadband excitations (in terms of wave vectors) to result in narrowband beams of low divergence.