A new class of nonreciprocal spin waves on the edges of 2D antiferromagnetic honeycomb nanoribbons

Abstract

Antiferromagnetic two-dimensional (2D) materials are currently under intensive theoretical and experimental investigations in view of their potential applications in antiferromagnet-based magnonic and spintronic devices. Recent experimental studies revealed the importance of magnetic anisotropy and Dzyaloshinskii-Moriya interactions (DMI) on the ordered ground state and the magnetic excitations in these materials. Here we present a robust classical field theory approach to analyze the effect of magnetic anisotropy and Dzyaloshinskii-Moriya interactions (DMI) on the edge and bulk spin waves in 2D antiferromagnetic nanoribbons. We predict the existence of a new class of nonreciprocal edge spin waves characterized by opposite polarizations in opposite directions. These novel edge spin waves are induced by the DMI and are fundamentally different from conventional nonreciprocal spin waves for which the polarization is independent of the propagation direction. Aside this breakthrough in the field of antiferromagnetic spin waves, the study further analysis the effect of the edges structure on the magnetic excitations. In particular, we show that anisotropic bearded edges nanoribbons act as magnetic topological insulators with exceptionally interesting potentials for applications in magnonics.