Magnetic coupling mechanisms in particle/thin film composite systems.

Giovanni A Badini Confalonieri,An Hui Lu,Durgamadhab Mishra,Gunther Eggeler,Maria J Benitez,Philipp Szary,Hartmut Zabel,Leonardo Agudo,Mathias Feyen,Oleg Petracic

doi:10.3762/bjnano.1.12

Abstract

Magnetic γ-Fe2O3 nanoparticles with a mean diameter of 20 nm and size distribution of 7% were chemically synthesized and spin-coated on top of a Si-substrate. As a result, the particles self-assembled into a monolayer with hexagonal close-packed order. Subsequently, the nanoparticle array was coated with a Co layer of 20 nm thickness. The magnetic properties of this composite nanoparticle/thin film system were investigated by magnetometry and related to high-resolution transmission electron microscopy studies. Herein three systems were compared: i.e. a reference sample with only the particle monolayer, a composite system where the particle array was ion-milled prior to the deposition of a thin Co film on top, and a similar composite system but without ion-milling. The nanoparticle array showed a collective super-spin behavior due to dipolar interparticle coupling. In the composite system, we observed a decoupling into two nanoparticle subsystems. In the ion-milled system, the nanoparticle layer served as a magnetic flux guide as observed by magnetic force microscopy. Moreover, an exchange bias effect was found, which is likely to be due to oxygen exchange between the iron oxide and the Co layer, and thus forming of an antiferromagnetic CoO layer at the γ-Fe2O3/Co interface.

Highlights

The study of composite magnetic nanostructures has received great interest due to the potential applications as permanent magnets or advanced data storage media [1,2,3,4,5]
We report a different approach to fabricate composite nanoparticle/thin-film materials, i.e., which combines the use of both chemical and physical growth methods
Self assembled magnetic NP/thin film composites were prepared by a combination of spin-coating and ion-beam sputtering techniques

Summary

Introduction

The study of composite magnetic nanostructures has received great interest due to the potential applications as permanent magnets or advanced data storage media [1,2,3,4,5]. The composite material can be successfully prepared over areas larger than 100 mm2 and is obtained by combining chemical synthesis of the NPs, their mechanical self-assembly on top of a substrate, and ion-beam sputtering of a magnetic layer.

Results

Conclusion