Unusual behavior of coercivity in Hf/GdFeCo bilayer with MgO cap layer by electric current

Ngo Trong Hai,Ivan Kindiak,Jong-Ching Wu,Lin-Xiu Ye,Ramesh Chandra Bhatt,K A Zvezdin,Chun-Ming Liao,Te-Ho Wu,Vladislav Yurlov

doi:10.1063/5.0023636

Abstract

We investigate the Hf/GdFeCo bilayer with the MgO cap layer for both rare earth (RE)-rich and transition metal (TM)-rich configurations of the ferrimagnetic sublattice in the presence of the perpendicular field. We study the coercivity using the anomalous Hall effect (AHE) technique by multiple measurements on the same sample. In the first set of measurements and at low electric currents, coercivity sharply drops because of the oxygen diffusion at the interface between MgO and GdFeCo when the AHE probe current is applied. During the subsequent measurements on the RE-rich sample, we observe a moderate decrease in coercivity at low currents and the coercivity increases in a high current range. Such nonlinear dependence of coercivity on electric current can be explained by the competing interplay of the spin–orbit torque (SOT) and the Joule heating effects. On the other hand, for the TM-rich case, the SOT effect is observed over a widely applied current range.

Highlights

Kim et al have investigated spin–orbit torque (SOT) associated with heavy metal/ferrimagnetic/oxide (HM/FI/Ox) order on Pt/GdFeCo/MgO multilayers using the spintorque ferromagnetic resonance (ST-FMR) technique.[20]
We investigate the Hf/GdFeCo bilayer with the MgO cap layer for both rare earth (RE)-rich and transition metal (TM)-rich configurations of the ferrimagnetic sublattice in the presence of the perpendicular field
During the subsequent measurements on the RE-rich sample, we observe a moderate decrease in coercivity at low currents and the coercivity increases in a high current range

Summary

Introduction

Kim et al have investigated spin–orbit torque (SOT) associated with heavy metal/ferrimagnetic/oxide (HM/FI/Ox) order on Pt/GdFeCo/MgO multilayers using the spintorque ferromagnetic resonance (ST-FMR) technique.[20]. The experimental data exhibit that the Hf/GdFeCo bilayer capped by MgO changes its magnetic properties during the early first stage of anomalous Hall effect (AHE) measurements.

Results

Conclusion