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Readout of an antiferromagnetic spintronics system by strong exchange coupling of Mn2Au and Permalloy

Author

Listed:
  • S. P. Bommanaboyena

    (Johannes Gutenberg-Universität)

  • D. Backes

    (Diamond Light Source, Chilton)

  • L. S. I. Veiga

    (Diamond Light Source, Chilton)

  • S. S. Dhesi

    (Diamond Light Source, Chilton)

  • Y. R. Niu

    (MAX IV Laboratory)

  • B. Sarpi

    (MAX IV Laboratory)

  • T. Denneulin

    (Forschungszentrum Jülich)

  • A. Kovács

    (Forschungszentrum Jülich)

  • T. Mashoff

    (Johannes Gutenberg-Universität)

  • O. Gomonay

    (Johannes Gutenberg-Universität)

  • J. Sinova

    (Johannes Gutenberg-Universität)

  • K. Everschor-Sitte

    (Johannes Gutenberg-Universität)

  • D. Schönke

    (Johannes Gutenberg-Universität)

  • R. M. Reeve

    (Johannes Gutenberg-Universität)

  • M. Kläui

    (Johannes Gutenberg-Universität)

  • H.-J. Elmers

    (Johannes Gutenberg-Universität)

  • M. Jourdan

    (Johannes Gutenberg-Universität)

Abstract

In antiferromagnetic spintronics, the read-out of the staggered magnetization or Néel vector is the key obstacle to harnessing the ultra-fast dynamics and stability of antiferromagnets for novel devices. Here, we demonstrate strong exchange coupling of Mn2Au, a unique metallic antiferromagnet that exhibits Néel spin-orbit torques, with thin ferromagnetic Permalloy layers. This allows us to benefit from the well-established read-out methods of ferromagnets, while the essential advantages of antiferromagnetic spintronics are only slightly diminished. We show one-to-one imprinting of the antiferromagnetic on the ferromagnetic domain pattern. Conversely, alignment of the Permalloy magnetization reorients the Mn2Au Néel vector, an effect, which can be restricted to large magnetic fields by tuning the ferromagnetic layer thickness. To understand the origin of the strong coupling, we carry out high resolution electron microscopy imaging and we find that our growth yields an interface with a well-defined morphology that leads to the strong exchange coupling.

Suggested Citation

  • S. P. Bommanaboyena & D. Backes & L. S. I. Veiga & S. S. Dhesi & Y. R. Niu & B. Sarpi & T. Denneulin & A. Kovács & T. Mashoff & O. Gomonay & J. Sinova & K. Everschor-Sitte & D. Schönke & R. M. Reeve &, 2021. "Readout of an antiferromagnetic spintronics system by strong exchange coupling of Mn2Au and Permalloy," Nature Communications, Nature, vol. 12(1), pages 1-7, December.
    • Handle: RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-021-26892-7
    DOI: 10.1038/s41467-021-26892-7
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    1. F. Nolting & A. Scholl & J. Stöhr & J. W. Seo & J. Fompeyrine & H. Siegwart & J.-P. Locquet & S. Anders & J. Lüning & E. E. Fullerton & M. F. Toney & M. R. Scheinfein & H. A. Padmore, 2000. "Direct observation of the alignment of ferromagnetic spins by antiferromagnetic spins," Nature, Nature, vol. 405(6788), pages 767-769, June.
    2. V.M.T.S. Barthem & C.V. Colin & H. Mayaffre & M.-H. Julien & D. Givord, 2013. "Revealing the properties of Mn2Au for antiferromagnetic spintronics," Nature Communications, Nature, vol. 4(1), pages 1-7, December.
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    Cited by:

    1. S. Reimers & Y. Lytvynenko & Y. R. Niu & E. Golias & B. Sarpi & L. S. I. Veiga & T. Denneulin & A. Kovács & R. E. Dunin-Borkowski & J. Bläßer & M. Kläui & M. Jourdan, 2023. "Current-driven writing process in antiferromagnetic Mn2Au for memory applications," Nature Communications, Nature, vol. 14(1), pages 1-6, December.
    2. Y. Behovits & A. L. Chekhov & S. Yu. Bodnar & O. Gueckstock & S. Reimers & Y. Lytvynenko & Y. Skourski & M. Wolf & T. S. Seifert & O. Gomonay & M. Kläui & M. Jourdan & T. Kampfrath, 2023. "Terahertz Néel spin-orbit torques drive nonlinear magnon dynamics in antiferromagnetic Mn2Au," Nature Communications, Nature, vol. 14(1), pages 1-10, December.

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