Magnetic antivortex-core reversal by circular-rotational spin currents

Thomas Kamionka; Michael Martens; Kang Wei Chou; Michael Curcic; André Drews; Gisela Schütz; Tolek Tyliszczak; Hermann Stoll; Bartel Van Waeyenberge; Guido Meier

doi:10.1103/PhysRevLett.105.137204

Magnetic antivortex-core reversal by circular-rotational spin currents

Thomas Kamionka, Michael Martens, Kang Wei Chou, Michael Curcic, André Drews, Gisela Schütz, Tolek Tyliszczak, Hermann Stoll, Bartel Van Waeyenberge, Guido Meier

Research output: Contribution to journal › Article › peer-review

44 Scopus citations

Abstract

Topological singularities occur as antivortices in ferromagnetic thin-film microstructures. Antivortices behave as two-dimensional oscillators with a gyrotropic eigenmode which can be excited resonantly by spin currents and magnetic fields. We show that the two excitation types couple in an opposing sense of rotation in the case of resonant antivortex excitation with circular-rotational currents. If the sense of rotation of the current coincides with the intrinsic sense of gyration of the antivortex, the coupling to the Oersted fields is suppressed and only the spin-torque contribution locks into the gyrotropic eigenmode. We report on the experimental observation of purely spin-torque induced antivortex-core reversal. The dynamic response of an isolated antivortex is imaged by time-resolved scanning transmission x-ray microscopy on its genuine time and length scale.

Original language	English
Article number	137204
Journal	Physical Review Letters
Volume	105
Issue number	13
DOIs	https://doi.org/10.1103/PhysRevLett.105.137204
State	Published - 21 Sep 2010
Externally published	Yes

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abstract = "Topological singularities occur as antivortices in ferromagnetic thin-film microstructures. Antivortices behave as two-dimensional oscillators with a gyrotropic eigenmode which can be excited resonantly by spin currents and magnetic fields. We show that the two excitation types couple in an opposing sense of rotation in the case of resonant antivortex excitation with circular-rotational currents. If the sense of rotation of the current coincides with the intrinsic sense of gyration of the antivortex, the coupling to the Oersted fields is suppressed and only the spin-torque contribution locks into the gyrotropic eigenmode. We report on the experimental observation of purely spin-torque induced antivortex-core reversal. The dynamic response of an isolated antivortex is imaged by time-resolved scanning transmission x-ray microscopy on its genuine time and length scale.",

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AU - Kamionka, Thomas

AU - Martens, Michael

AU - Chou, Kang Wei

AU - Curcic, Michael

AU - Drews, André

AU - Schütz, Gisela

AU - Tyliszczak, Tolek

AU - Stoll, Hermann

AU - Van Waeyenberge, Bartel

AU - Meier, Guido

PY - 2010/9/21

Y1 - 2010/9/21

N2 - Topological singularities occur as antivortices in ferromagnetic thin-film microstructures. Antivortices behave as two-dimensional oscillators with a gyrotropic eigenmode which can be excited resonantly by spin currents and magnetic fields. We show that the two excitation types couple in an opposing sense of rotation in the case of resonant antivortex excitation with circular-rotational currents. If the sense of rotation of the current coincides with the intrinsic sense of gyration of the antivortex, the coupling to the Oersted fields is suppressed and only the spin-torque contribution locks into the gyrotropic eigenmode. We report on the experimental observation of purely spin-torque induced antivortex-core reversal. The dynamic response of an isolated antivortex is imaged by time-resolved scanning transmission x-ray microscopy on its genuine time and length scale.

AB - Topological singularities occur as antivortices in ferromagnetic thin-film microstructures. Antivortices behave as two-dimensional oscillators with a gyrotropic eigenmode which can be excited resonantly by spin currents and magnetic fields. We show that the two excitation types couple in an opposing sense of rotation in the case of resonant antivortex excitation with circular-rotational currents. If the sense of rotation of the current coincides with the intrinsic sense of gyration of the antivortex, the coupling to the Oersted fields is suppressed and only the spin-torque contribution locks into the gyrotropic eigenmode. We report on the experimental observation of purely spin-torque induced antivortex-core reversal. The dynamic response of an isolated antivortex is imaged by time-resolved scanning transmission x-ray microscopy on its genuine time and length scale.

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Magnetic antivortex-core reversal by circular-rotational spin currents

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