Spin-orbit torques for current parallel and perpendicular to a domain wall

We report field- and current-induced domain wall (DW) depinning experiments in Ta/Co20Fe60B20/MgO nanowires through a Hall cross geometry. While purely field-induced depinning shows no angular dependence on in-plane fields, the effect of the current depends crucially on the internal DW structure, wh...

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Veröffentlicht in:	arXiv.org 2015-07
Hauptverfasser:	Schulz, Tomek, Alejos, Oscar, Martinez, Eduardo, Hals, Kjetil M D, Garcia, Karin, Lee, Kyujoon, Roberto Lo Conte, Karnad, Gurucharan V, Moretti, Simone, Ocker, Berthold, Ravelosona, Dafiné, Brataas, Arne, Kläui, Mathias
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Schlagworte:	Damping Dependence Domain walls Efficiency Nanowires Physics - Mesoscale and Nanoscale Physics Pinning Torque
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creator	Schulz, Tomek Alejos, Oscar Martinez, Eduardo Hals, Kjetil M D Garcia, Karin Lee, Kyujoon Roberto Lo Conte Karnad, Gurucharan V Moretti, Simone Ocker, Berthold Ravelosona, Dafiné Brataas, Arne Kläui, Mathias
description	We report field- and current-induced domain wall (DW) depinning experiments in Ta/Co20Fe60B20/MgO nanowires through a Hall cross geometry. While purely field-induced depinning shows no angular dependence on in-plane fields, the effect of the current depends crucially on the internal DW structure, which we manipulate by an external magnetic in-plane field. We show for the first time depinning measurements for a current sent parallel to the DW and compare its depinning efficiency with the conventional case of current flowing perpendicularly to the DW. We find that the maximum efficiency is similar for both current directions within the error bars, which is in line with a dominating damping-like spin-orbit torque (SOT) and indicates that no large additional torques arise for currents parallel to the DW. Finally, we find a varying dependence of the maximum depinning efficiency angle for different DWs and pinning levels. This emphasizes the importance of our full angular scans compared to previously used measurements for just two field directions (parallel and perpendicular to the DW) and shows the sensitivity of the spin-orbit torque to the precise DW structure and pinning sites.
doi_str_mv	10.48550/arxiv.1507.02435
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While purely field-induced depinning shows no angular dependence on in-plane fields, the effect of the current depends crucially on the internal DW structure, which we manipulate by an external magnetic in-plane field. We show for the first time depinning measurements for a current sent parallel to the DW and compare its depinning efficiency with the conventional case of current flowing perpendicularly to the DW. We find that the maximum efficiency is similar for both current directions within the error bars, which is in line with a dominating damping-like spin-orbit torque (SOT) and indicates that no large additional torques arise for currents parallel to the DW. Finally, we find a varying dependence of the maximum depinning efficiency angle for different DWs and pinning levels. 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subjects	Damping Dependence Domain walls Efficiency Nanowires Physics - Mesoscale and Nanoscale Physics Pinning Torque
title	Spin-orbit torques for current parallel and perpendicular to a domain wall
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