Direct Observation of Magnon Modes in Kagome Artificial Spin Ice with Topological Defects

TL;DR

This study observes how topological defects in kagome artificial spin ice influence magnon modes, revealing potential for reprogrammable magnonic devices through defect control and microwave switching.

Contribution

It provides the first direct observation of magnon modes confined by topological defects in kagome artificial spin ice, combining experimental and simulation insights.

Findings

Magnon resonances depend on defect configurations.

Dirac strings and monopole pairs significantly modify magnon frequencies.

Work enables reprogrammable magnonics via defect manipulation.

Abstract

We investigate spin dynamics of artificial spin ice (ASI) where topological defects confine magnon modes in Ni$_{81}$Fe$_{19}$ nanomagnets arranged on an interconnected kagome lattice. Brillouin light scattering microscopy performed on magnetically disordered states exhibit a series of magnon resonances which depend on topological defect configurations detected by magnetic force microscopy. Nanomagnets on a Dirac string and between a monopole-antimonopole pair show pronounced modifications in magnon frequencies both in experiments and simulations. Our work is key for the creation and annihilation of Dirac strings via microwave assisted switching and reprogrammable magnonics based on ASIs.