Abstract
Charge-current-induced torque effects on the magnetization dynamics of ferromagnetic/metal bilayer is interesting from the aspect of fundamental physics as well as the applications in spintronic devices. The torque-induced variation of damping constant of magnetization can be foreseen from the change of the linewidth of ferromagnetic resonance spectrum. The Oersted torque (τOe) and current-induced torque (τC) are induced by charge current; while the spin-orbit torque (τSO) and field-like torque (τFL) are induced by spin current. However, the torque effects often were hindered due to the heating-induced artifacts. In this work, we particularly pay attention to minimize the Joule heating effects in order to investigate the intrinsic torque effects in cobalt (Co)/platinum (Pt) bilayer with an applied charge current ranging from −60 to 60 mA. In this range, the Oersted field is estimated as 0.25 Oe which is much smaller than the experimental result of ΔHr (∼0.7 Oe), implying some contribution from the spin-current induced field like torque. The current-polarization-induced asymmetry of linewidth ΔW, ΔW≡W+Jc−W−Jc, increases from 0 to 0.15 with Jc changing from 0 to 60 mA, which is attributed to the spin-orbit torque.
Highlights
Ferromagnetic resonance (FMR) is a powerful tool to analyze the torque effects on magnetic materials
The underlying physics is that the torque changes the magnetization relaxation time, which is reflected from the variation of FMR linewidth (W) and resonance field (Hr)
The τSO drives the magnetization toward or away from the equilibrium position depending on the direction of the injected charge current, which can be detected from the variation of W with injecting different direction of Jc
Summary
Ferromagnetic resonance (FMR) is a powerful tool to analyze the torque effects on magnetic materials. Injecting a charge current into the structure of ferromagnetic material (FM)/nonmagnetic material (NM) bilayer might induce various kinds of torque on the magnetization and modify the Landau-Lifshitz-Gilbert equation. The three torques (τFL, τOe and τC) enhance the precession angle of magnetization and are analogous to the effect of magnetic field, which can be detected from the variation of Hr. On the other hand, the τSO drives the magnetization toward or away from the equilibrium position depending on the direction of the injected charge current, which can be detected from the variation of W with injecting different direction of Jc. The related subject of electric-current-driven torque effects has been studied on Py/Pt, YIG/Pt and Pb/Pt bilayer structures using. The temperature of sample is measured with a K-type thermocouple
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