Strongly nonlinear antiferromagnetic dynamics in high magnetic fields

Pavel Stremoukhov; Ansar Safin; Casper F. Schippers; Reinoud Lavrijsen; Maurice Bal; Uli Zeitler; Alexandr Sadovnikov; Elizaveta Kozlova; Kamyar Saeedi Ilkhchy; Sergey Nikitov; Andrei Kirilyuk

doi:10.1016/j.rinp.2024.107377

Strongly nonlinear antiferromagnetic dynamics in high magnetic fields

Pavel Stremoukhov, Ansar Safin, Casper F. Schippers, Reinoud Lavrijsen, Maurice Bal, Uli Zeitler, Alexandr Sadovnikov, Elizaveta Kozlova, Kamyar Saeedi Ilkhchy, Sergey Nikitov, Andrei Kirilyuk (Corresponding author)

Onderzoeksoutput: Bijdrage aan tijdschrift › Tijdschriftartikel › Academic › peer review

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Antiferromagnetic (AFM) materials possess a well-recognized potential for ultrafast data processing thanks to their intrinsic ultrafast spin dynamics, absence of stray fields, and large spin transport effects. The very same properties, however, make their manipulation difficult, requiring frequencies in THz range and magnetic fields of tens of Teslas. Switching of AFM order implies going into the nonlinear regime, a largely unexplored territory. Here we use THz light from a free electron laser to drive antiferromagnetic NiO into a highly nonlinear regime and steer it out of nonlinearity with magnetic field from a 33-Tesla Bitter magnet. This demonstration of large-amplitude dynamics represents a crucial step towards ultrafast resonant switching of AFM order.

Originele taal-2	Engels
Artikelnummer	107377
Aantal pagina's	7
Tijdschrift	Results in Physics
Volume	57
DOI's	https://doi.org/10.1016/j.rinp.2024.107377
Status	Gepubliceerd - feb. 2024

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© 2024 The Authors

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title = "Strongly nonlinear antiferromagnetic dynamics in high magnetic fields",

abstract = "Antiferromagnetic (AFM) materials possess a well-recognized potential for ultrafast data processing thanks to their intrinsic ultrafast spin dynamics, absence of stray fields, and large spin transport effects. The very same properties, however, make their manipulation difficult, requiring frequencies in THz range and magnetic fields of tens of Teslas. Switching of AFM order implies going into the nonlinear regime, a largely unexplored territory. Here we use THz light from a free electron laser to drive antiferromagnetic NiO into a highly nonlinear regime and steer it out of nonlinearity with magnetic field from a 33-Tesla Bitter magnet. This demonstration of large-amplitude dynamics represents a crucial step towards ultrafast resonant switching of AFM order.",

keywords = "High magnetic field, Nonlinear resonance, Spin pumping, Spin-hall effect",

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AU - Stremoukhov, Pavel

AU - Safin, Ansar

AU - Schippers, Casper F.

AU - Lavrijsen, Reinoud

AU - Bal, Maurice

AU - Zeitler, Uli

AU - Sadovnikov, Alexandr

AU - Kozlova, Elizaveta

AU - Ilkhchy, Kamyar Saeedi

AU - Nikitov, Sergey

AU - Kirilyuk, Andrei

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N2 - Antiferromagnetic (AFM) materials possess a well-recognized potential for ultrafast data processing thanks to their intrinsic ultrafast spin dynamics, absence of stray fields, and large spin transport effects. The very same properties, however, make their manipulation difficult, requiring frequencies in THz range and magnetic fields of tens of Teslas. Switching of AFM order implies going into the nonlinear regime, a largely unexplored territory. Here we use THz light from a free electron laser to drive antiferromagnetic NiO into a highly nonlinear regime and steer it out of nonlinearity with magnetic field from a 33-Tesla Bitter magnet. This demonstration of large-amplitude dynamics represents a crucial step towards ultrafast resonant switching of AFM order.

AB - Antiferromagnetic (AFM) materials possess a well-recognized potential for ultrafast data processing thanks to their intrinsic ultrafast spin dynamics, absence of stray fields, and large spin transport effects. The very same properties, however, make their manipulation difficult, requiring frequencies in THz range and magnetic fields of tens of Teslas. Switching of AFM order implies going into the nonlinear regime, a largely unexplored territory. Here we use THz light from a free electron laser to drive antiferromagnetic NiO into a highly nonlinear regime and steer it out of nonlinearity with magnetic field from a 33-Tesla Bitter magnet. This demonstration of large-amplitude dynamics represents a crucial step towards ultrafast resonant switching of AFM order.

KW - High magnetic field

KW - Nonlinear resonance

KW - Spin pumping

KW - Spin-hall effect

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Strongly nonlinear antiferromagnetic dynamics in high magnetic fields

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