Observation of Self-Cavitating Envelope Dispersive Shock Waves in Yttrium Iron Garnet Thin Films

TL;DR

This paper reports the experimental observation of self-cavitating dispersive shock waves in a magnetic Yttrium Iron Garnet thin film, demonstrating complex nonlinear wave phenomena and their theoretical interpretation.

Contribution

It provides the first experimental evidence of self-cavitating envelope dispersive shock waves in magnetic films, linking experimental results with nonlinear Schrödinger equation theory.

Findings

Observation of envelope DSW formation in magnetic thin films

Detection of self-cavitation with zero power and phase jump

Agreement between experiments, theory, and simulations

Abstract

The formation and properties of envelope dispersive shock wave (DSW) excitations from repulsive nonlinear waves in a magnetic film are studied. Experiments involve the excitation of a spin-wave step pulse in a low-loss magnetic Y$_3$Fe$_5$O$_{12}$ thin film strip, in which the spin-wave amplitude increases rapidly, realizing the canonical Riemann problem of shock theory. Under certain conditions, the envelope of the spin-wave pulse evolves into a DSW that consists of an expanding train of nonlinear oscillations with amplitudes increasing from front to back, terminated by a black soliton. The onset of DSW self-cavitation, indicated by a point of zero power and a concomitant 180 phase jump, is observed for sufficiently large steps, indicative of the bidirectional dispersive hydrodynamic nature of the DSW. The experimental observations are interpreted with theory and simulations of the nonlinear Schr\"odinger equation.