Magnetization Vorticity and Exchange Bias Phenomena in Arrays of Small Asymmetric Magnetic Rings

TL;DR

This study investigates vortex states and exchange bias phenomena in arrays of nanoscopic asymmetric magnetic rings, revealing how geometry and magnetic field orientation influence magnetic behavior at low temperatures.

Contribution

It demonstrates the control of exchange bias effects through geometrical constraints and magnetic field directions in nanoring arrays, extending understanding beyond thin film systems.

Findings

Vortex magnetic states confirmed in asymmetric rings at room temperature.

Negative exchange bias observed along and perpendicular to asymmetry axis at low temperatures.

Positive exchange bias observed at 45-degree orientation, showing tunability of magnetic effects.

Abstract

Arrays of nanoscopic magnetic asymmetric rings, 150 nm in outer diameter, are fabricated using the techniques of electron-beam lithography, angular deposition and ion-beam etching. Magnetic measurements for cobalt asymmetric rings at room temperature verifies previous reports of vortex magnetic state formation of a desired circulation direction for the application of external magnetic field along the asymmetry axis of the rings. However, the main theme of this article is the observation of exchange bias phenomena when the ring samples are cooled down to low temperature in the presence of a positive magnetic field. Very interestingly, the observed exchange bias effect is negative for along and perpendicular orientations of ring's asymmetry axis with respect to the in-plane external magnetic field. This is in good quantitative agreement with the random interface model proposed by Malozemoff et al. For the application of inplane external magnetic field at 45 degree with respect to the asymmetry axis, the exchange bias effect is positive. Unlike the exchange bias effects in thin films, this is a very unusual observation indicating that exchange bias phenomena of opposite natures can be manipulated by appropriate combination of geometrical constraint and external magnetic field direction, in addition to the interfacial interactions between ferromagnetic (FM) and antiferromagnetic (AFM) layer.