Staggered field driven domain walls motion in antiferromagnetic heterojunctions

Staggered field driven domain walls motion in antiferromagnetic heterojunctions

In this work, we study the antiferromagnetic (AFM) spin dynamics in heterostructures which consist of two coupled AFM layers, i.e., AFM1 layers (describing CuMnAs or Mn2Au) with field-like Néel spin-orbit torque (NSOT) and AFM2 layers with easy-axis anisotropy orthogonal to that in AFM1 layers. Our...

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Bibliographic Details
Published in:Applied physics letters 2018-09, Vol.113 (11)
Main Authors: Zhang, Y. L., Chen, Z. Y., Yan, Z. R., Chen, D. Y., Fan, Z., Qin, M. H.
Format: Article
Language:eng
Subjects:
Anisotropy
Antiferromagnetism
Critical field (superconductivity)
Domain walls
Electric currents
Heterojunctions
Heterostructures
Spin dynamics
Spintronics
Torque
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Summary:In this work, we study the antiferromagnetic (AFM) spin dynamics in heterostructures which consist of two coupled AFM layers, i.e., AFM1 layers (describing CuMnAs or Mn2Au) with field-like Néel spin-orbit torque (NSOT) and AFM2 layers with easy-axis anisotropy orthogonal to that in AFM1 layers. Our micromagnetic simulations demonstrate that through the interface coupling, the AFM2 domain wall (DW) can be effectively driven by the AFM1 DW which is driven by the electrical current induced NSOT [Gomonay et al., Phys. Rev. Lett. 117, 017202 (2016)]. Furthermore, the two DWs detach from each other when the torque increases above a critical value. The critical field and the highest possible velocity of the AFM2 DW depend on several factors, which are investigated and discussed in detail. Based on the calculated results, we propose a method of efficiently modulating the multi DWs in antiferromagnets, which definitely provides useful information for future AFM spintronics device design.
ISSN:0003-6951
1077-3118