Non-reciprocal coherent all-optical switching between magnetic multi-states

TL;DR

This paper demonstrates experimental and computational evidence of laser-induced non-reciprocal magnetization switching in garnets, revealing polarization-dependent trajectories and switching times, with implications for energy-efficient magnetic control.

Contribution

It introduces a novel understanding of polarization-dependent, non-reciprocal all-optical magnetization switching in magnetic garnets, combining experimental and computational insights.

Findings

Distinct magnetization precession trajectories identified

Switching times depend on light polarization and initial states

Topological symmetry influences switching pathways

Abstract

We present experimental and computational findings of the laser-induced non-reciprocal motion of magnetization during ultrafast photo-magnetic switching in garnets. We found distinct coherent magnetization precession trajectories and switching times between four magnetization states, depending on both directions of the light linear polarization and initial magnetic state. As a fingerprint of the topological symmetry, the choice of the switching trajectory is governed by an interplay of the photo-magnetic torque and magnetic anisotropy. Our results open a plethora of possibilities for designing energy-efficient magnetization switching routes at arbitrary energy landscapes.