Orbital torque of Cr-induced magnetization switching in perpendicularly magnetized Pt/Co/Pt/Cr heterostructures

The spin-orbit torque via the spin Hall effect of heavy metals has shown promising prospect in driving the magnetization switching in spintronic devices due to the generated spin current from heavy metals. Recently, the 3d-light metals have been predicted the ability to generate orbital current and the associated orbital torques from the orbital Hall effect. However, few experiments have been carried out since it is quite hard to directly detect the orbital current-generated orbital torque. Here, we report an effective method to demonstrate the strong orbital torques in light metal Cr through a conversion process from orbital current to spin current by introducing the Pt interfacial layer in perpendicularly magnetized symmetric Pt/Co/Pt structures. A quite large and monotonically growth of orbital torque efficiency in Pt/Co/Pt/Cr with the increase of the thickness of Cr layer is obtained with the largest effective orbital torque efficiency around 2.6 Oe/(MA center dot cm(-2)) (1 Oe = 79.5775 A center dot m(-1)). The ability of orbital torque to drive the magnetization switching is also reported with the critical switching current density down to the order of 10(6) A center dot cm(-2). Our findings prove the efficiency for switching the magnetization from light metal Cr layers through the orbital Hall effect.

Automated summary

We demonstrate the strong orbital torques in light metal Cr through a conversion process from orbital current to spin current by introducing the Pt interfacial layer. The efficiency of the orbital torque in switching the magnetization from light metal Cr layers is proven, with the largest effective orbital torque efficiency around 2.6 Oe/(MA·cm(-2)).