Reorientation in Antiferromagnetic Multilayers: Spin-Flop Transition and Surface Effects

TL;DR

This paper reviews and generalizes theoretical models of magnetization processes in antiferromagnetic multilayers, explaining surface effects, spin-flop transitions, and phase diagrams, with implications for magnetic device applications.

Contribution

It provides a unified theoretical framework for understanding complex reorientational phenomena and resolves the long-standing surface spin-flop problem in antiferromagnetic multilayers.

Findings

Resolved the surface spin-flop problem in antiferromagnetic layers.

Explained differences in reorientation transitions in various multilayer systems.

Developed phase diagrams for magnetic states in antiferromagnetic multilayers.

Abstract

Nanoscale superlattices with uniaxial ferromagnetic layers antiferromagnetically coupled through non-magnetic spacers are recently used as components of magnetoresistive and recording devices. In the last years intensive experimental investigations of these artificial antiferromagnets have revealed a large variety of surface induced reorientational effects and other remarkable phenomena unknown in other magnetic materials. In this paper we review and generalize theoretical results, which enable a consistent description of the complex magnetization processes in antiferromagnetic multilayers, and we explain the responsible physical mechanism. The general structure of phase diagrams for magnetic states in these systems is discussed. In particular, our results resolve the long standing problem of a ``surface spin-flop'' in antiferromagnetic layers. This explains the different appearance of field-driven reorientation transitions in systems like Fe/Cr (001) and (211) superlattices, and in [CoPt]/Ru multilayers with strong perpendicular anisotropy.