Reconfigurable topological spin wave beamsplitters and interferometers

TL;DR

This paper demonstrates reconfigurable topological spin wave devices, including beamsplitters and interferometers, leveraging topologically protected chiral edge spin waves in ferromagnetic honeycomb lattices, offering robustness and tunability.

Contribution

It introduces a new class of reconfigurable magnonic devices based on topological exchange spin waves in ferromagnetic honeycomb lattices, overcoming scalability issues of conventional magnonics.

Findings

Topologically protected chiral edge spin waves exist in ferromagnetic honeycomb lattices with specific interactions.

Spin wave beamsplitters and interferometers can be designed using domain walls to manipulate topological spin waves.

Devices are reconfigurable and robust against perturbations and defects.

Abstract

Conventional magnonic devices use three classes of magnetostatic waves that require detailed manipulation of magnetization structure that makes the design and the device/circuitry scalability difficult tasks. Here, we demonstrate that devices based on topological exchange spin waves do not suffer from the problem with additional nice features of nano-scale wavelength and high frequency. Two results are reported. 1) A perpendicular ferromagnet on a honeycomb lattice is generically a topological magnetic material in the sense that topologically protected chiral edge spin waves exist in the band gap as long as spin-orbit induced nearest-neighbor pseudodipolar interaction (and/or next-nearest neighbor Dzyaloshinskii-Moriya interaction) is present. 2) As a proof of concept, spin wave beamsplitters and spin wave interferometers are designed by using domain walls to manipulate the propagation of topologically protected chiral spin waves. Since magnetic domain walls can be controlled by magnetic fields or electric current/fields, one can essentially draw, erase and redraw different spin wave devices and circuitry on the same magnetic plate so that the proposed devices are reconfigurable and tunable. Devices made from magnetic topological materials are robust against both internal and external perturbations such as the spin wave frequency variation and device geometry as well as defects.