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Toward 100% Spin–Orbit Torque Efficiency with High Spin–Orbital Hall Conductivity Pt–Cr Alloys

Chenyu Hu, Yu-Fang Chiu, Chia-Chin Tsai, Chao-Chung Huang, Kuan‐Hao Chen, Cheng-Wei Peng, Chien-Min Lee, Ming-Yuan Song, Yen‐Lin Huang, Shy-Jay Lin, Chi‐Feng Pai

2022ACS Applied Electronic Materials50 citationsDOIOpen Access PDF

Abstract

5d transition metal Pt is the canonical spin Hall material for efficient generation of spin–orbit torques (SOTs) in Pt/ferromagnetic layer (FM) heterostructures. However, for a long while with tremendous engineering endeavors, the damping-like SOT efficiencies (ξDL) of Pt and Pt alloys have still been limited to ξDL < 0.5. Here we present that with proper alloying elements, particularly 3d transition metals V and Cr, a high spin–orbital Hall conductivity (σSH ≈ 6.5 × 105 (ℏ/2e) Ω–1 m–1) can be developed. Especially for the Cr-doped case, an extremely high ξDL ≈ 0.9 in a Pt0.69Cr0.31/Co device can be achieved with a moderate Pt0.69Cr0.31 resistivity of ρxx ≈ 133 μΩ cm. A low critical SOT-driven switching current density of Jc ≈ 3.2 × 106 A cm–2 is also demonstrated. The damping constant (α) of the Pt0.69Cr0.31/FM structure is also found to be reduced to 0.052 from the pure Pt/FM case of 0.078. The overall high σSH, giant ξDL, moderate ρxx, and reduced α of such a Pt–Cr/FM heterostructure makes it promising for versatile extremely low power consumption SOT memory applications.

Topics & Concepts

Condensed matter physicsHeterojunctionFerromagnetismSpin (aerodynamics)Transition metalMaterials scienceSpin Hall effectHall conductivityElectrical resistivity and conductivityHall effectConductivityElectronPhysicsChemistrySpin polarizationThermodynamicsQuantum mechanicsCatalysisBiochemistryMagnetic properties of thin filmsAdvanced Memory and Neural ComputingMagnetic and transport properties of perovskites and related materials