Control of magnon frequency combs in magnetic rings
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Using Brillouin light scattering microscopy, we study the rich dynamics in magnetic disks and rings governed by non-linear interactions, focusing on the role of vortex core dynamics on the spin-wave eigenmode spectrum. By strongly exciting quantized magnon modes in magnetic vortices, self-induced magnon Floquet states are populated by the intrinsic nonlinear coupling of magnon modes to the vortex core gyration. In magnetic rings, however, this generation is suppressed even when exciting the system over a large power range. To retrieve the rich nonlinear dynamics in rings, we apply external in-plane magnetic fields by which the vortex core is restored. Our findings demonstrate how to take active control of the nonlinear processes in magnetic structures of different topology.
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Cited by 1 Pith paper
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Field-driven triggering of self-induced Floquet magnons in a magnetic vortex
An applied magnetic field shifts the vortex core orbit to trigger or suppress self-induced Floquet magnons forming frequency combs in magnetic tunnel junctions.
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