Three-axis torque investigation of interfacial exchange coupling in a NiFe/CoO bilayer micromagnetic disk

TL;DR

This study introduces a three-axis micromagnetic resonator technique to measure interfacial exchange coupling effects in NiFe/CoO bilayers, revealing detailed anisotropy behaviors and training effects at cryogenic temperatures.

Contribution

It presents a novel three-axis resonator method for simultaneous torque measurements, enabling detailed analysis of exchange bias and anisotropies in bilayer nanostructures.

Findings

Confirmed exchange bias via shifted hysteresis loops at cryogenic temperatures.

Observed training effects that did not diminish interfacial coupling features.

Fitted hysteresis data with macrospin Landau-Lifshitz-Gilbert model parameters.

Abstract

Micrometer diameter bilayers of NiFe (permalloy, Py) and cobalt oxide (CoO) deposited on nanomechanical resonators were used to investigate exchange bias effects. The mechanical compliances of two resonator axes were enhanced by severing one torsion arm, resulting in a unique three-axis resonator that responds resonantly to torques generated by a three-axis RF field. Our technique permits simultaneous measurement of three orthogonal torque components. Measurements of the anisotropies associated with interfacial exchange coupling effects have been made. At cryogenic temperatures, observations of shifted linear hysteresis loops confirmed the presence of exchange bias from the Py/CoO interface. An in-plane rotating DC bias field was used to probe in-plane anisotropies through the out-of-plane torque. Training effects in the rotational hysteresis data were observed and showed that features due to interfacial coupling did not diminish irrespective of substantial training of the unidirectional anisotropy. The data from the rotational hysteresis loops were fit with parameters from a macrospin solution to the Landau-Lifshitz-Gilbert equation. Each parameter of the exchange bias model accounts for specific features of the rotational loop.