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The thickness dependence of the field-like spin–orbit torque in heavy metal/CoFeB/MgO heterostructures

Bo Han, Bo Zhang, Shuling Sun, Bo Wang, Yonghai Guo, Jiangwei Cao

2021Journal of Applied Physics10 citationsDOI

Abstract

We investigated the ferromagnet (FM) and heavy metal (HM) thickness dependence of the electric current-induced spin orbit torque (SOT), especially the field-like (FL) torque component in HM/CoFeB/MgO heterostructures. For Pt/CoFeB/MgO and Ta/CoFeB/MgO structures, after subtracting the dead-layer thickness of CoFeB, the damping-like (DL) effective field follows 1/tFM dependence, while the FL effective field deviates from 1/tFM dependence at the ultra-thin FM thickness range, indicating that an extra origination of FL torque, i.e., spin backflow at the FM/MgO interface, is responsible for the large FL torque in HM/CoFeB/MgO structures with a ultra-thin CoFeB layer. For Ta/Pt(tPt)/CoFeB(1)/MgO structures, the FL-SOT exhibits a gradual change similar to the DL-SOT, suggesting that the spin Hall effect is the dominant origination of spin current, which enhances the FL-SOT in the HM/CoFeB/MgO structures by the spin backflow effect when tCoFeB is less than the spin dephasing length. We also demonstrated that the obvious dead-layer thickness at the Ta/CoFeB interface reduces the effective CoFeB thickness and enhances the spin backflow effect further.

Topics & Concepts

Materials scienceCondensed matter physicsBackflowHeterojunctionLayer (electronics)Spin (aerodynamics)Thin filmSpin Hall effectFerromagnetismJoule heatingSpin polarizationComposite materialNanotechnologyOptoelectronicsElectronEngineeringPhysicsAerospace engineeringMechanical engineeringQuantum mechanicsInletMagnetic properties of thin filmsZnO doping and propertiesHeusler alloys: electronic and magnetic properties
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