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Russian
Heading: 
Applied Problems of Nonlinear Oscillation and Wave Theory
Article type: 
Article
UDC: 
537.611.2
DOI: 
10.18500/0869-6632-003108
EDN: 
BKIICQ

Nonlinear regimes of spin wave propagation in a waveguide with a one-dimensional hole array

Autors: 
Martyshkin A. A. , Saratov State University
Sadovnikov Aleksandr Vladimirovich, Saratov State University
Abstract: 

Purpose. Investigation of spin-wave signal passage in a system of magnetic microwaves separated from each other by a one-dimensional array of holes. Using numerical and experimental methods to show controlled spatial-frequency selection of the signal in linear and nonlinear modes of operation.

Methods. Micromagnetic modeling of the spatial intensity distributions of spin waves. Obtaining S-parameters of spin waves propagating in a tangentially magnetized structure using a vector circuit analyzer.

Results. The spatially selective properties of the structure in linear and nonlinear modes are demonstrated using micromagnetic modeling. A mechanism for controlling the frequency range of the Bragg zone is revealed using a vector analyzer.

Conclusion. The proposed structure can be used as a functional element in planar topologies of magnon networks and parallel signal processing devices based on them.

Key words: 
Spin waves
magnonics
spintronics
nonlinearity
Lateral waveguides
Magnonic crystal
Acknowledgments: 
This work was supported by Russian Science Foundation (Project 20-79-10191)
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Received: 
11.07.2023
Accepted: 
19.02.2024
Available online: 
03.07.2024
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