Magnetization dynamics in an exchange-coupled NiFe/CoFe bilayer studied by x-ray detected ferromagnetic resonance

Stenning, Gavin B. G.; Shelford, L. R.; Cavill, S. A.; Hoffmann, Frank; Haertinger, M.; Hesjedal, T.; Woltersdorf, Georg; Bowden, G. J.; Gregory, Simon; Back, Christian; Groot, P.A.J. de; Laan, G. van der

doi:10.1088/1367-2630/17/1/013019

Cited by 53 publications

(30 citation statements)

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“…On the other hand, the FMR response for two exchange‐coupled ferromagnetic thin films has been studied in Refs. . As was pointed out, ferromagnetic coupling between the two layers can lead to a modulation of the intensity ratio between the two modes depending on the coupling strength.…”

Section: Discussionmentioning

confidence: 90%

Ferromagnetic resonance of MBE-grown FeRh thin films through the metamagnetic phase transition

Heidarian

Stienen

Семисалова

et al. 2017

Phys. Status Solidi B

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An FeRh thin film of 33 nm thickness grown by molecular beam epitaxy (MBE) has been investigated with respect to its temperature dependent magnetic properties by means of ferromagnetic resonance (FMR). Within the ferromagnetic regime, that is at temperatures above the antiferromagnetic‐to‐ferromagnetic phase transition, the resonance field decreases with decreasing temperature reflecting an increasing magnetization. Within the temperature regime of the phase transition, the resonance field behaves non‐monotonically, that is it suddenly increases with decreasing temperature. The observed asymmetric shape of the FMR absorption line is discussed with respect to a possible small magnetic inhomogeneity of the film coupled to the main ferromagnetic volume of B2 ordered, equiatomic FeRh.

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Section: Discussionmentioning

confidence: 90%

Ferromagnetic resonance of MBE-grown FeRh thin films through the metamagnetic phase transition

Heidarian

Stienen

Семисалова

et al. 2017

Phys. Status Solidi B

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“…Major opportunities for fundamental studies [193] Other techniques Nuclear resonant scattering Detection Highest spatial resolution currently achievable [194] X-ray-detected ferromagnetic resonance (XFMR) Detection High spatial resolution, access to layer resolution [195][196][197] Electron-magnon scattering approach Detection Suitable for the detection of domain wall position [198,199] and temporal resolution. For spin-wave excitation techniques the efficiency of excitation, its coherency and the wavenumber range are of primary importance [155-157, 159, 160, 163-165, 168-172, 174, 177-189, 191-199].…”

Section: Detectionmentioning

confidence: 99%

Magnonic crystals for data processing

Chumak

Serga

Hillebrands

2017

J. Phys. D: Appl. Phys.

423

320

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IntroductionThis article focuses on a selection of results in the field of magnonic crystals obtained within the last decade in our group. Special attention is devoted to the application of magnonic crystals in data processing and information technologies. Because of the large number of achievements in the field, it is unavoidable that many important results are excluded from this article. Therefore, we would like to direct the reader's attention to excellent reviews devoted to different aspects of magnonic crystals: spin-wave dynamics in periodic structures for microwave applications [1, 2], Brillouin light scattering (BLS) studies of planar metallic magnonic crystals [3], micromagnetic computer simulations of width-modulated waveguides [4], photo-magnonic aspects of antidot lattices studies [5], theoretical studies of one-dimensional monomode waveguides [6], and reconfigurable magnonic crystals [7]. The results presented in the current review were already partially presented in our own reviews of yttrium iron garnet (YIG) magnonics [8] and magnon spintronics [9] as well as in book chapters on dynamic magnonic crystals [10] and magnon spintronics [11].The article is organized in the following way: In the introduction we describe the field of magnon spintronics and discuss the role of magnonic crystals in it. The next section 2 is devoted to the properties of spin waves in thin planar films and waveguides, to the magnetic materials commonly used in the field, and to the methods of spin-wave excitation and detection. Sections 3 and 4 are devoted to the study of physical phenomena taking place in static and dynamic magnonic crystals, respectively. The application of magnonic crystals for magnonbased processing of analog and digital data is discussed in section 5. Specifically, static magnonic crystals can be used as passive elements, like microwave filters, resonators or delay lines for microwave generation. Reconfigurable and dynamic magnonic crystals are promising as active devices performing, for example, tunable filtering, frequency conversion or time reversal. In the final section we briefly summarize the results. Magnon spintronics: from electron-to magnon-based computingA disturbance in the local magnetic order can propagate in a magnetic material in the form of a wave. This wave was first predicted by Bloch in 1929 and was named spin wave since AbstractMagnons (the quanta of spin waves) propagating in magnetic materials with wavelengths at the nanometer-scale and carrying information in the form of an angular momentum can be used as data carriers in next-generation, nano-sized low-loss information processing systems. In this respect, artificial magnetic materials with properties periodically varied in space, known as magnonic crystals, are especially promising for controlling and manipulating magnon currents. In this article, different approaches for the realization of static, reconfigurable, and dynamic magnonic crystals are presented along with a variety of novel wave phenomena discovered in these cryst...

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“…Similarly, a standard value of g i =0.01 is used for all layers. The cubic anisotropy of the NiFeCu is on the same order than that of the NiFe [50,70] and thus both are taken equal.…”

Section: Resultsmentioning

confidence: 99%

“…In some cases, these requirements can also be fulfilled by using structures composed of multiple materials. For example, in a bilayer with an effective ferromagnetic exchange coupling (which tends to align the magnetization of the layers parallel to each other), two resonance modes with distinguishable frequencies are observed: the low frequency acoustic (both layers are in phase) and the high frequency optical (both layers are in antiphase) modes [50,51]. The acoustic mode is of particular importance, as it has an enhanced intensity due to the additive contribution of each layer to the frequency signal.…”

Section: Introductionmentioning

confidence: 99%

Intensity enhancement of ferromagnetic resonance modes in exchange coupled magnetic multilayers

Franco

2020

New J. Phys.

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In this work, the ferromagnetic resonance characteristics of a NiFeCu/Non-magnetic(NM)/NiFe/ NM/CoFe/NM/Co multilayer is studied from a theoretical point of view, and comparisons with the ferromagnetic resonance of a NiFe/NM/CoFe magnetic bilayer are presented. It is found that the resonance modes of the multilayer tend to be more intense than those of the bilayer for several combinations of applied field and interlayer exchange coupling. Furthermore, rules governing the individual layer contributions to the resonance modes of a exchanged coupled magnetic multilayer are presented, which would apply to any number of layers. These results open the possibility to tailor the resonance frequencies of the multilayer structure by either engineering the interlayer exchange coupling or by applying a perpendicular magnetic field for multiband high frequency magnetic devices.

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Magnetization dynamics in an exchange-coupled NiFe/CoFe bilayer studied by x-ray detected ferromagnetic resonance

Cited by 53 publications

References 53 publications

Ferromagnetic resonance of MBE-grown FeRh thin films through the metamagnetic phase transition

Ferromagnetic resonance of MBE-grown FeRh thin films through the metamagnetic phase transition

Magnonic crystals for data processing

Intensity enhancement of ferromagnetic resonance modes in exchange coupled magnetic multilayers

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