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Autores principales: Li, Yi, Kiehl, Carissa, Lim, Jinho, Abbott, Cliff, Pal, Pratap K., Szymczak, Alex J., Li, Juliang, Divan, Ralu, Chang, Clarence L., Phatak, Charudatta, Bozhko, Dmytro A., Hoffmann, Axel, Novosad, Valentine
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2602.13608
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author Li, Yi
Kiehl, Carissa
Lim, Jinho
Abbott, Cliff
Pal, Pratap K.
Szymczak, Alex J.
Li, Juliang
Divan, Ralu
Chang, Clarence L.
Phatak, Charudatta
Bozhko, Dmytro A.
Hoffmann, Axel
Novosad, Valentine
author_facet Li, Yi
Kiehl, Carissa
Lim, Jinho
Abbott, Cliff
Pal, Pratap K.
Szymczak, Alex J.
Li, Juliang
Divan, Ralu
Chang, Clarence L.
Phatak, Charudatta
Bozhko, Dmytro A.
Hoffmann, Axel
Novosad, Valentine
contents Spontaneous dynamic systems have attracted significant attention for their rich underlying physics such as phase-locking and synchronization. In this work, we report a new mechanism of generating magnetic spontaneous oscillation via parametric pumping. By applying a pump tone to excite propagating spin waves in a yttrium iron garnet delay line, four-wave mixing converts the pump mode into two phase-autonomous propagating magnon modes, i.e. a spontaneous mode with nearly twice the wavenumber of the pump mode and an idler mode with nearly zero wavenumber. This allows us to reliably generate ultrasharp spin wave dynamics with broad frequency tunability from the pump and magnetic field. We show that the spontaneous mode can be phase-locked to a probe tone, similar to an auto-oscillator. Furthermore, the spontaneous dynamics can be used to implement a high-gain magnonic parametric amplifier with a gain up to 40 dB. Our results open a new avenue for studying nonlinear magnonics and synchronization physics in propagating magnon geometry and for developing new magnonic devices.
format Preprint
id arxiv_https___arxiv_org_abs_2602_13608
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Magnonic spontaneous oscillation induced by parametric pumping
Li, Yi
Kiehl, Carissa
Lim, Jinho
Abbott, Cliff
Pal, Pratap K.
Szymczak, Alex J.
Li, Juliang
Divan, Ralu
Chang, Clarence L.
Phatak, Charudatta
Bozhko, Dmytro A.
Hoffmann, Axel
Novosad, Valentine
Mesoscale and Nanoscale Physics
Spontaneous dynamic systems have attracted significant attention for their rich underlying physics such as phase-locking and synchronization. In this work, we report a new mechanism of generating magnetic spontaneous oscillation via parametric pumping. By applying a pump tone to excite propagating spin waves in a yttrium iron garnet delay line, four-wave mixing converts the pump mode into two phase-autonomous propagating magnon modes, i.e. a spontaneous mode with nearly twice the wavenumber of the pump mode and an idler mode with nearly zero wavenumber. This allows us to reliably generate ultrasharp spin wave dynamics with broad frequency tunability from the pump and magnetic field. We show that the spontaneous mode can be phase-locked to a probe tone, similar to an auto-oscillator. Furthermore, the spontaneous dynamics can be used to implement a high-gain magnonic parametric amplifier with a gain up to 40 dB. Our results open a new avenue for studying nonlinear magnonics and synchronization physics in propagating magnon geometry and for developing new magnonic devices.
title Magnonic spontaneous oscillation induced by parametric pumping
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2602.13608