Edge and corner skin effects of chirally coupled magnons characterized by a topological winding tuple

Abstract

We investigate a long-ranged coupled and non-Hermitian two-dimensional array of nanomagnets, fabricated on a thin magnetic substrate and subjected to an in-plane magnetic field. We predict topology-driven edge and corner skin effects of magnetic eigenmodes with the localization position at boundaries precisely characterized by a topological winding tuple ( W1, W2). By varying the direction of the in-plane field, all magnon states pile up either at different edges of the array with ( W1= 1, W2=0) or ( W1=0, W2= 1), or at different corners characterized by ( W1= 1, W2= 1). Exploiting the non-Hermitian topology is potentially helpful for designing useful magnonic metasurface in the future.