Ion-implanted magnetostatic wave reflective array filters

Carter, R. L.; Owens, J.M.; Smith, Charles V.; Reed, K.W.

doi:10.1063/1.330928

Cited by 38 publications

(11 citation statements)

References 7 publications

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“…The concept of spin-wave guiding in in-plane magnetised films using magnetisation gradients can be extended to the nanoscale (using e.g. ionic implantation [37][38][39]) and is promising for the realisation of magnonic networks for novel computing concepts. Moreover, the proposed approach is applicable for the guiding of waves in strongly-anisotropic media independently on the nature of these waves.…”

Section: Discussionmentioning

confidence: 99%

Control of Spin-Wave Propagation using Magnetisation Gradients

Vogel¹,

Aßmann²,

Pirro³

et al. 2018

Sci Rep

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We report that in an in-plane magnetised magnetic film the in-plane direction of a propagating spin wave can be changed by up to 90 degrees using an externally induced magnetic gradient field. We have achieved this result using a reconfigurable, laser-induced magnetisation gradient created in a conversion area, in which the backward volume and surface spin-wave modes coexist at the same frequency. Shape and orientation of the gradient control the conversion efficiency. Experimental data and numerical calculations agree very well. Our findings open the way to magnonic circuits with in-plane steering of the spin-wave modes.

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Section: Discussionmentioning

confidence: 99%

Control of Spin-Wave Propagation using Magnetisation Gradients

Vogel¹,

Aßmann²,

Pirro³

et al. 2018

Sci Rep

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“…. При изготовлении МК из пленок железо-иттриевого граната (ЖИГ) формирование периодической структуры может осуществляться за счет изменения геометрических параметров -толщины пленки [3,4] или ширины вырезанного из пленки волновода [5], магнитных параметров [6], помещения пленки в периодически изменяющееся магнитное поле [7] или размещения на поверхности пленки периодической решетки из металлических [8][9][10][11] или полупроводниковых [12] элементов.…”

Section: Introductionunclassified

“…Отметим, что в случае формирования на поверхности пленок ЖИГ решеток из проводящих элементов их влияние в зависимости от проводимости σ и толщины t проводника на распространение ПМСВ может проявляться либо за счет модуляции дисперсии волны под металлом [3][4][5][6][7][8][9][10], либо за счет модуляции коэффициента затухания ПМСВ [12]. Так, например, в случае периодической решетки из металлических полосок при их толщине t > l s , где l s -глубина скин-слоя, магнонный кристалл формируется за счет изменения скорости МСВ на " металлизированных" участках пленки.…”

Section: Introductionunclassified

Поверхностные Магнитостатические Волны В Пленках Железо-Иттриевого Граната С Поверхностной Субволновой Метаструктурой Из Пленки Пермаллоя

Высоцкий¹,

Хивинцев²,

Сахаров³

et al. 2020

Физика Твердого Тела

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The frequency dependencies of the transmission coefficient of surface magnetostatic waves (SMSW) propagating in subwavelength magnonic structures obtained by depositing of 1D and 2D thin-film metastructures based on a permalloy film 40 nm thick onto the surface of yttrium iron garnet (YIG) film were experimentally studied. Such structures in the frequency range 1–10 GHz (typical for the study of SMSW in YIG films) lead to modulation of attenuation and the effective internal magnetic field in the YIG film. The possibility of controlling the parameters of the bandwidth of the SMSW by the choice of the direction of magnetization in the plane of the structures relative to their axis of symmetry is shown.

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“…[1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18] It has been shown that a single scatterer, for instance, a thin wire sitting on top of a ferromagnetic film that carries a DC current, creates a strongly localized magnetic field from which an incident plane backward volume magnetostatic spin wave (BVMSW) can efficiently scatter. 12,13 Two regimes were identified in this case; one is tunneling, when the area of field nonuniformity acts as an energy barrier for spin waves (magnons), and the only way for a wave to cross the nonuniformity is by tunneling. 13 The energy barrier is formed because the spin wave spectrum in an in-plane magnetized ferromagnetic film is characterized by an energy gap due to Zeeman and shape anisotropy contributions to spin wave dispersion.…”

Section: Introductionmentioning

confidence: 99%

“…Thus, there is no second boundary of the nonuniformity, contrary to the cases of localized inhomogeneities studied before. [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18] This allows us to produce quasianalytical expressions for the transmission and reflection coefficients for the step. We utilize a similar integration technique found in prior work that involves a Green's function of spin wave excitation.…”

Section: Introductionmentioning

confidence: 99%

Scattering of a magnetostatic surface spin wave from a one-dimensional step potential in a ferromagnetic film

Balaji

Kostylev

Bailleul

2019

Journal of Applied Physics

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As the research on magnetostatic surface spin waves (MSSWs) gains momentum, a concrete understanding of how these waves behave at interfaces is still undeveloped. In this work, we theoretically investigate how a MSSW traveling in a ferromagnetic film scatters across a sharp step of magnetic parameters in the film such as the applied field. An integral equation is derived, which describes the scattering process. We solve this equation both directly numerically and using a second Born approximation. We find that scattering produces partial reflection and partial transmission of the wave through the step. A nontrivial behavior of the amplitude of the transmitted wave as a function of the step size is observed in the calculation and analyzed.

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Ion-implanted magnetostatic wave reflective array filters

Cited by 38 publications

References 7 publications

Control of Spin-Wave Propagation using Magnetisation Gradients

Control of Spin-Wave Propagation using Magnetisation Gradients

Поверхностные Магнитостатические Волны В Пленках Железо-Иттриевого Граната С Поверхностной Субволновой Метаструктурой Из Пленки Пермаллоя

Scattering of a magnetostatic surface spin wave from a one-dimensional step potential in a ferromagnetic film

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