Beyond conventional skyrmions in synthetic antiferromagnets

TL;DR

This paper demonstrates the engineering of synthetic antiferromagnets with two skyrmion families, controlled by external magnetic fields and interlayer exchange, enabling programmable 3D spin textures for advanced computing applications.

Contribution

It introduces a novel SAF design with chemically distinct layers that supports multiple skyrmion states controlled by effective magnetic fields.

Findings

Two distinct skyrmion families observed in different field regimes.

Skyrmions reside only in the CoFeB layers influenced by RKKY exchange.

Effective-field control enables programmable 3D spin textures.

Abstract

Magnetic skyrmions are topologically protected spin textures that can act as reconfigurable nanoscale information carriers. In synthetic antiferromagnets (SAFs), interlayer exchange coupling offers an additional control parameter beyond the interfacial Dzyaloshinskii-Moriya interaction (DMI) and magnetic anisotropy. Here, we engineer a SAF composed of two chemically distinct ferromagnets (CoB and CoFeB), in which the external magnetic field and interlayer exchange act asymmetrically on the sublattices. The competition of these effects, acting as a resultant effective-field, gives rise to two distinct skyrmion families in different field regimes. In large fields, conventional-polarity skyrmions nucleate, with core antiparallel to the external field, whereas in smaller fields an inverse-polarity skyrmion state emerges as the effective-field reverses sign and almost saturates the CoFeB layers. Return-point memory measurements confirm independent nucleation pathways for the two families. Using element-resolved x-ray magnetometry, correlative magnetic force and Lorentz transmission electron microscopies, and parameter-matched micromagnetic modelling, we show that all textures reside only in the CoFeB layers, which experience a Ruderman-Kittel-Kasuya-Yosida (RKKY) exchange field originating from the CoB layers. This effective-field method provides a robust route to programmable three-dimensional spin textures with controlled polarity in selected layers of a multilayer with potential for applications in skyrmion-based computing and spin-logic architectures.