Spiral multiferroics as a natural skyrmion racetrack

Abstract: Magnetic skyrmions are particle-like spin textures with a nontrivial topology, which ensures their stability even at the nanometer scale. This feature establishes skyrmions as promising information carriers for novel magnetic storage and processing devices, e.g., racetrack memories. However, their fate in various magnetic backgrounds is poorly understood. Here, we show that spiral multiferroics, some of the simplest noncollinear magnets, host bimerons -- skyrmionic textures formed by vortex-antivortex pairs. The bimeron carries magnetic and ferroelectric dipole moments that remarkably depend on its position relative to the spiral background. This property enables precise positioning of the bimeron using a slowly rotating magnetic field, as a $2\pi$ field rotation shifts the bimeron by one spiral period. We also investigate the non-adiabatic regime that occurs when the rotation frequency exceeds a critical threshold. The results establish a new paradigm in which the background endows topological spin textures with unique functionalities, highlighting spiral multiferroics as a natural skyrmion racetrack.