Stability and localization of nanoscale skyrmions and bimerons in an all-magnetic van der Waals heterostructure

Abstract: Magnetic solitons such as skyrmions and bimerons show great promise for both fundamental research and spintronic applications. Stabilizing and controlling topological spin textures in atomically thin van der Waals (vdW) materials has gained tremendous attention due to high tunability, enhanced functionality, and miniaturization. Using rigorous first-principles calculations and atomistic spin simulations, we predict the existence of multiple magnetic solitons in an all-magnetic vdW heterostructure Fe$_3$GeTe$_2$/Cr$_2$Ge$_2$Te$_6$ (FGT/CGT). N\'eel-type skyrmions are formed at both sides of FGT/CGT with opposite chirality. Skyrmions at the FGT layer and bimerons at the CGT layer persist in the heterostructure at zero field, while the latter undergoes bimeron-skyrmion transformation if a field is applied. We further demonstrate that, although skyrmions and bimerons are topologically equivalent, they exhibit very different localization behavior. Skyrmions are isotropically localized, while bimerons exhibit anisotropic nonlocality, leading to finite-size effects. We analyze how this affects the stability of bimerons in confined materials. Our work represents an important step forward in the fundamental properties of topological spin textures and paves the way toward skyrmionic devices based on atomically thin vdW heterostructures.