High-Throughput Techniques for Measuring the Spin Hall Effect

Markus Meinert, Björn Gliniors, Oliver Gueckstock, Tom S. Seifert, Lukas Liensberger, Mathias Weiler, Sebastian Wimmer, Hubert Ebert, and Tobias Kampfrath

Phys. Rev. Applied 14, 064011 – Published 3 December 2020

Abstract

The spin Hall effect in heavy-metal thin films is routinely used to convert charge currents into transverse spin currents and can be used to exert torque on adjacent ferromagnets. Conversely, the inverse spin Hall effect is frequently used to detect spin currents by charge currents in spintronic devices up to the terahertz frequency range. Numerous techniques to measure the spin Hall effect or its inverse have been introduced, most of which require extensive sample preparation by multistep lithography. To enable rapid screening of materials in terms of charge-to-spin conversion, suitable high-throughput methods for measuring the spin Hall angle are required. Here we compare two lithography-free techniques, terahertz emission spectroscopy and broadband ferromagnetic resonance, with standard harmonic Hall measurements and theoretical predictions using the binary-alloy series ${Au}_{x} {Pt}_{1 - x}$ as a benchmark system. Despite their being highly complementary, we find that all three techniques yield a spin Hall angle with approximately the same $x$ dependence, which is also consistent with first-principles calculations. Quantitative discrepancies are discussed in terms of magnetization orientation and interfacial spin-memory loss.

Received 8 October 2020
Accepted 11 November 2020

DOI:https://doi.org/10.1103/PhysRevApplied.14.064011

Physics Subject Headings (PhySH)

Metrology Spin Hall effect Spin generation Spin torque Spin-orbit coupling

Ferromagnetic resonance Hall bar Terahertz spectroscopy

Condensed Matter, Materials & Applied Physics

Authors & Affiliations

Markus Meinert ^1,*, Björn Gliniors², Oliver Gueckstock ^3,4, Tom S. Seifert^3,4, Lukas Liensberger^5,6, Mathias Weiler ^5,6,7, Sebastian Wimmer ⁸, Hubert Ebert⁸, and Tobias Kampfrath^3,4

¹Department of Electrical Engineering and Information Technology, Technical University of Darmstadt, Merckstraße 25, 64283 Darmstadt, Germany
²Center for Spinelectronic Materials and Devices, Department of Physics, Bielefeld University, 33501 Bielefeld, Germany
³Department of Physics, Freie Universität Berlin, 14195 Berlin, Germany
⁴Fritz Haber Institute of the Max Planck Society, 14195 Berlin, Germany
⁵Walther-Meißner-Institut, Bayerische Akademie der Wissenschaften, 85748 Garching, Germany
⁶Physik-Department, Technische Universität München, 85748 Garching, Germany
⁷Fachbereich Physik and Landesforschungszentrum OPTIMAS, Technische Universität Kaiserslautern, 67663 Kaiserslautern, Germany
⁸Department Chemie, Ludwig-Maximilians-Universität München, 81377 Munich, Germany

^*markus.meinert@tu-darmstadt.de

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Vol. 14, Iss. 6 — December 2020

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Images

Figure 1
Overview of three different techniques to determine the spin Hall angle of a material as described in the main text. The top row shows schematics of the techniques (not to scale), while the bottom row shows typical raw data. (a),(d) Terahertz emission spectroscopy: an optical laser pulse generates an ultrafast heat pulse in the films. Because of the spin-dependent Seebeck effect, a spin current flows from the FM layer into the HM layer. The inverse spin Hall effect converts the spin current into a charge pulse, which emits terahertz radiation. (b),(e) VNA FMR: a gigahertz current in the coplanar waveguide excites the ferromagnetic resonance in the FM layer. Spin pumping drives a spin current into the HM layer, where it is converted into an oscillating charge current. Its magnetic field couples into the waveguide and can be detected in the complex-valued waveguide transmission signal $S_{21}$ . (c),(f) Harmonic Hall measurements: a kilohertz charge current drives an oscillating spin current from the HM layer into the FM layer. The associated spin-orbit torque drives an oscillating deflection of the magnetization out of the film plane. The associated oscillating anomalous Hall voltage is detected as a second-harmonic transverse voltage in the Hall cross.
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Figure 2
(a) Electrical conductivities of the ${Au}_{x} {Pt}_{1 - x}$ alloy films determined by four-point dc-conductivity measurements and by terahertz transmission measurements. In both cases, a parallel-conductor model is applied to subtract the conductance of the ${Co}_{40} {Fe}_{40} B_{20}$ layer. (b) Relative terahertz emission (right axis) and relative spin Hall angle (left axis) as obtained from Eq. (1). (c) Odd component of the spin-orbit-torque conductivity (right axis) obtained in the VNA-FMR measurements and extracted lower-bound spin Hall angle $θ_{SH} = σ_{o}^{SOT} / σ_{x x}$ (left axis). (d) Spin Hall angles as determined with the harmonic-Hall-response method via Eq. (6).
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Figure 3
(a) Experimental spin Hall angles scaled to the spin Hall angle of the pure- $Pt$ sample obtained with the harmonic-Hall-response method. Green lines represent results from spr-kkr calculations including or ignoring thin-film corrections of the conductivity via the MS model. (b) Scaled spin Hall conductivities as in (a). The green line represents the spr-kkr calculation. (c) Electrical conductivity as measured electrically (dots), as calculated (green line), and as calculated including corrections from the MS model (dashed line).
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