Microscopic nonlinear magnonic phase shifters based on ultrathin films of a magnetic insulator

Lake, S. R.; Divinskiy, B.; Schmidt, G.; Demokritov, S. O.; Demidov, V. E.

doi:10.1063/5.0100525

Cited by 3 publications

(1 citation statement)

References 47 publications

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“…Information can be transferred in diverse magnetic materials, including insulators, in the form of a spin wave [1][2][3]. Investigations of a wide variety of linear [4][5][6] and nonlinear [7][8][9] spin-wave phenomena address the field of science known as magnonics. The promising building blocks for magnonic devices are constituted by artificial spatially periodic magnetic media, known as magnonic crystals [10][11][12][13][14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Dynamic electromagnonic crystals based on ferrite-ferroelectric thin film multilayers

Nikitin,

Kuznetsov,

van Dijken

et al. 2024

Phys. Rev. B

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Magnons, the quanta of the oscillations of localized electron spins, are a powerful tool for information transport and processing of microwave signals. Owing to the challenge of energy efficient spin-wave control on small time-and space scales, dynamic magnonic crystals have been proposed. Their distinct feature is the possibility to toggle on and off the spatial periodicity of the magnetic waveguide that allows one to realize the unusual signal processing functions. The miniaturization of magnonic circuits, reduction in energy consumption, and fast operation are important possibilities of these artificial crystals. These can be achieved in ferrite-ferroelectric (multiferroic) heterostructures, where strong coupling of magnons and microwave photons constitutes quasiparticles called electromagnons. Using both a theoretical approach and microwave measurements, we report on successful dynamic control of electromagnonic band structures in artificial thin film crystals via application of a voltage to the grid electrode located on a ferroelectric film.A promising functionality of the proposed waveguiding structures arises from two major factors: (i) low energy consumptions due to the thin ferroelectric layer, and (ii) pronounced rejection bands caused by a gradual change of the dielectric permittivity.

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Section: Introductionmentioning

confidence: 99%

Dynamic electromagnonic crystals based on ferrite-ferroelectric thin film multilayers

Nikitin,

Kuznetsov,

van Dijken

et al. 2024

Phys. Rev. B

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Nonlinear chiral magnonic resonators: Toward magnonic neurons

Fripp

Shytov

et al. 2023

Applied Physics Letters

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We explore chiral magnonic resonators as building blocks of artificial neural networks. Via micromagnetic simulations and analytical modeling, we demonstrate that the spin-wave modes confined in the resonators exhibit a strongly nonlinear response owing to energy concentration when resonantly excited by incoming spin waves. This effect may be harnessed to implement an artificial neuron in a network. Therefore, the confined and propagating spin-wave modes can serve as neurons and interneural connections, respectively. For modest excitation levels, the effect can be described in terms of a nonlinear shift of the resonant frequency (“detuning”), which results in amplitude-dependent transmission of monochromatic spin waves, which may be harnessed to recreate a “sigmoid-like” activation function. At even stronger excitation levels, the nonlinearity leads to bistability and hysteresis, akin to those occurring in nonlinear oscillators when the excitation strength exceeds a threshold set by the decay rate of the mode. In magnonic resonators, the latter includes both the Gilbert damping and the radiative decay due to the coupling with the medium. The results of our simulations are well described by a phenomenological model in which the nonlinear detuning of the confined mode is quadratic in its amplitude, while the propagation in the medium is linear.

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Nonlinear phase shifts induced by pumping spin waves in magnonic crystals

Haponchyk

Устинов

2023

Applied Physics Letters

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A nonlinear phase shift of low-power spin waves (SWs) induced by a high-power pumping SW excited both inside and outside the magnonic band-gaps of a magnonic crystal has been studied. The magnonic crystal with spatially periodic thickness is fabricated from an yttrium iron garnet film by chemical etching. The results show that the phase shift of the low-power SWs can be effectively controlled by variation of power level of the pumping SW. This induced nonlinear phase shift is weakened if the pump frequency lies in the magnonic bandgap. The data obtained are well explained by contradirectional coupling of the high-power forward and reflected spin waves. A theoretical model for this effect is presented. Our findings are important for the further progress in SW computing.

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Microscopic nonlinear magnonic phase shifters based on ultrathin films of a magnetic insulator

Cited by 3 publications

References 47 publications

Dynamic electromagnonic crystals based on ferrite-ferroelectric thin film multilayers

Dynamic electromagnonic crystals based on ferrite-ferroelectric thin film multilayers

Nonlinear chiral magnonic resonators: Toward magnonic neurons

Nonlinear phase shifts induced by pumping spin waves in magnonic crystals

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