Mechanism of Spin-Orbit Torques in Platinum Oxide Systems

Spin-Orbit Torque (SOT) Magnetic Random-Access Memories (MRAM) have shown promising results toward the realization of fast, non-volatile memory systems. Oxidation of the heavy-metal (HM) layer of the SOT-MRAM has been proposed as a method to increase its energy efficiency. But the results are widely divergent due to the difficulty in controlling the HM oxidation because of its low enthalpy of formation. Here, these differences are reconciled by performing a gradual oxidation procedure, which allows correlating the chemical structure to the physical properties of the stack. As an HM layer, Pt is chosen because of the strong SOT and the low enthalpy of formation of its oxides. The evidence of an oxide inversion layer at the ferromagnet (FM)/HM interface is found: the oxygen is drawn into the FM, while the HM remains metallic near the interface. Moreover, the oxygen migrates in the volume of the FM layer rather than being concentrated at the interface. Consequently, it is found that the intrinsic magnitude of the SOT is unchanged compared to the fully metallic structure. The previously reported apparent increase of SOTs is not intrinsic to platinum oxide and instead arises from systemic changes produced by oxidation.

Automated summary

In Spin-Orbit Torque (SOT) Magnetic Random-Access Memories (MRAM), oxidation of the heavy-metal (HM) layer has been proposed to increase energy efficiency. By gradually oxidizing the stack, systemic changes and the presence of an oxide inversion layer are found.