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Effects of Anisotropic Strain on Spin–Orbit Torque Produced by the Dirac Nodal Line Semimetal IrO<sub>2</sub>

Arnab Bose, Jocienne N. Nelson, Xiyue S. Zhang, Priyamvada Jadaun, Rakshit Jain, Darrell G. Schlom, Daniel C. Ralph, David A. Muller, Kyle Shen, R. A. Buhrman

2020ACS Applied Materials & Interfaces54 citationsDOIOpen Access PDF

Abstract

We report spin-torque ferromagnetic resonance studies of the efficiency of the damping-like (ξDL) spin–orbit torque exerted on an adjacent ferromagnet film by current flowing in epitaxial (001) and (110) IrO2 thin films. IrO2 possesses Dirac nodal lines (DNLs) in the band structure that are gapped by spin–orbit coupling, which could enable a very high spin Hall conductivity, σSH. We find that the (001) films do exhibit exceptionally high ξDL ranging from 0.45 at 293 K to 0.65 at 30 K, which sets the lower bounds of σSH to be 1.9 × 105 and 3.75 × 105 Ω–1 m–1, respectively, 10 times higher and of opposite sign than the theoretical prediction. Furthermore, ξDL and σSH are substantially reduced in anisotropically strained (110) films. We suggest that this high sensitivity to anisotropic strain is because of changes in contributions to σSH near the DNLs.

Topics & Concepts

SemimetalDirac (video compression format)Condensed matter physicsMaterials scienceAnisotropyStrain (injury)Line (geometry)TorqueSpin (aerodynamics)NODALOrbit (dynamics)Spin–orbit interactionPhysicsBand gapQuantum mechanicsGeometryAerospace engineeringAnatomyThermodynamicsEngineeringMathematicsMedicineNeutrinoInternal medicineTopological Materials and PhenomenaMagnetic properties of thin filmsAdvanced Condensed Matter Physics
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