Reflection-less width-modulated magnonic crystal

Frey, Pascal; Никитин, А. А.; Bozhko, Dmytro A.; Bunyaev, S. A.; Kakazei, G. N.; Устинов, А. Б.; Kalinikos, B. A.; Ciubotaru, Florin; Chumak, A. V.; Wang, Qi; Tiberkevich, Vasyl S.; Hillebrands, B.; Serga, Alexander A.

doi:10.1038/s42005-020-0281-y

Cited by 42 publications

(28 citation statements)

References 53 publications

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“…4 a ). The first and the second waveguiding structures are discussed in detail [5–14, 34–38] while the third one was not investigated. The experimental and theoretical investigations of transmission characteristics of the third waveguiding structure validate the mechanism of the band structure formation when compared with other structures.…”

Section: Experimental and Theoretical Resultsmentioning

confidence: 99%

“…Among different types of the magnetic materials, the epitaxial yttrium‐iron garnet (YIG) films are widely used for MC fabrication due to certain essential advantages: (i) small out‐of‐band insertion losses; (ii) deep rejection bands; (iii) well‐developed techniques of MC fabrication ranging from metal deposition, chemical etching, ion implantation, or other methods to produce a periodical variation of any magnetic parameter. As a result, the MCs are successfully utilised for realisation of the various microwave devices such as power limiters [5], magnetic field sensors [6, 7], microwave oscillators [8, 9], spin‐wave logic gates [10], magnon transistors [11] and filters [12].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Electromagnonic crystals based on ferrite–ferroelectric–ferrite multilayers

Никитин

Mylnikov

et al. 2020

IET Microwaves, Antennas & Propagation

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Section: Experimental and Theoretical Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Electromagnonic crystals based on ferrite–ferroelectric–ferrite multilayers

Никитин

Mylnikov

et al. 2020

IET Microwaves, Antennas & Propagation

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“…Использование элементарных квантов магнитных возбуждений (магнонов) и спиновых волн (СВ) в диэлектрических магнитных пленках, поддерживают передачу сигнала без движения зарядов и, следовательно, без омических потерь, обеспечивают сверхнизкое энергопотребление и являются многообещающей альтернативой полупроводниковым приборам [1][2][3]. Одним из новых научных направлений в физике конденсированного состояния является магноника [4][5][6], ставящая перед собой задачи по исследованию методов и характеристик управления спиновыми волнами в волноведущих системах в микрои наномасштабах [7,8].…”

Section: Introductionunclassified

Управляемая Электрическим Полем Спин-Волновая Связь В Латеральных Ансамблях Магнитных Микроструктур

Грачев¹,

Бегинин²,

Шешукова³

et al. 2021

Физика Твердого Тела

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In this work, using numerical and experimental studies, we have demonstrated the possibility of controlling the dipole spin-wave coupling in a lateral array of ferromagnetic stripes using local deformations. As an experimental demonstration of the investigated physical processes, a configuration of a magnonic structure with a piezoelectric layer and structured electrodes on its surface is proposed, and the technique of laser ablation with spatial resolution is used to structure the piezoelectric layer. The mechanisms for controlling the dipole coupling of spin waves by creating elastic deformations localized in the region of the maximums of the electric field are revealed. From an applied point of view, the results obtained can be used to create a class of information processing devices, such as demultiplexing systems with frequency-space selectivity, controlled simultaneously by an electric and magnetic field.

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“…Realizing a geometry-driven energy band gap formation allows enabling several prominent features to emerge, such as guided information carrier by periodic arrays of nanostrips [7,8] and width-modulated nanogratings [9][10][11][12]. Besides that spatial periodic variation of saturation magnetization, alternating nanostrips, filters, and phase shifters were investigated with different material classes [8,[13][14][15][16], where Y 3 Fe 5 O 12 (YIG) and permalloy were the common types for MC. YIG provides lower damping and low loss propagation of spin-waves [1,17].…”

Section: Introductionmentioning

confidence: 99%

Engineered Magnetization Dynamics of Magnonic Nanograting Filters

2021

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Magnonic crystals and gratings could enable tunable spin-wave filters, logic, and frequency multiplier devices. Using micromagnetic models, we investigate the effect of nanowire damping, excitation frequency and geometry on the spin wave modes, spatial and temporal transmission profiles for a finite patterned nanograting under external direct current (DC) and radio frequency (RF) magnetic fields. Studying the effect of Gilbert damping constant on the temporal and spectral responses shows that low-damping leads to longer mode propagation lengths due to low-loss and high-frequency excitations are also transmitted with high intensity. When the nanowire is excited with stronger external RF fields, higher frequency spin wave modes are transmitted with higher intensities. Changing the nanowire grating width, pitch and its number of periods helps shift the transmitted frequencies over super high-frequency (SHF) range, spans S, C, X, Ku, and K bands (3–30 GHz). Our design could enable spin-wave frequency multipliers, selective filtering, excitation, and suppression in magnetic nanowires.

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Reflection-less width-modulated magnonic crystal

Cited by 42 publications

References 53 publications

Electromagnonic crystals based on ferrite–ferroelectric–ferrite multilayers

Electromagnonic crystals based on ferrite–ferroelectric–ferrite multilayers

Управляемая Электрическим Полем Спин-Волновая Связь В Латеральных Ансамблях Магнитных Микроструктур

Engineered Magnetization Dynamics of Magnonic Nanograting Filters

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