Evolution of the Spin Hall Magnetoresistance in Cr2O3/Pt bilayers close to the N\'eel temperature

Abstract

We study the evolution of magnetoresistance with temperature in thin film bilayers consisting of platinum and the antiferromagnet Cr2O3 with its easy axis out of the plane. We vary the temperature from 20 - 60C, close to the N\'eel temperature of Cr2O3 of approximately 37C. The magnetoresistive response is recorded during rotations of the external magnetic field in three mutually orthogonal planes. A large magnetoresistance having a symmetry consistent with a positive spin Hall magnetoresistance is observed in the paramagnetic phase of the Cr2O3, which however vanishes when cooling to below the N\'eel temperature. Comparing to analogous experiments in a Gd3Ga5O12/Pt heterostructure, we conclude that a paramagnetic field induced magnetization in the insulator is not sufficient to explain the observed magnetoresistance. We speculate that the type of magnetic moments at the interface qualitatively impacts the spin angular momentum transfer, with the 3d moments of Cr sinking angular momentum much more efficiently as compared to the more localized 4f moments of Gd.