Spin-wave nonreciprocity and magnonic band structure in a thin permalloy film induced by dynamical coupling with an array of Ni stripes

Mruczkiewicz, M.; Graczyk, Piotr; Lupo, Pierpaolo; Adeyeye, A. O.; Gubbiotti, G.; Krawczyk, Maciej

doi:10.1103/physrevb.96.104411

Cited by 52 publications

(40 citation statements)

References 48 publications

(46 reference statements)

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“…Such a change of sign has also been predicted for films where breaking of the top-bottom magnetic symmetry is not obtained through a blockwise variation of M S , like here, but rather by a grading of saturation magnetization across the thickness [22]. In contrast, it has not been observed for bilayers where the two magnetic materials, being separated by a nonmagnetic spacer, are coupled only through longrange dipole interactions [41,42]. This further demonstrates the essential role played by short-range out-of-plane exchange coupling in this phenomenon.…”

Section: B Nonreciprocal Dispersion Relationssupporting

confidence: 72%

Slow-Wave-Based Nanomagnonic Diode

et al. 2020

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Spin waves, the collective excitations of the magnetic order parameter, and magnons, the associated quasiparticles, are envisioned as possible data carriers in future wave-based computing architectures. On the road toward spin-wave computing, the development of a diodelike device capable of transmitting spin waves in only one direction, thus allowing controlled signal routing, is an essential step. Here we report on the design and experimental realization of a microstructured magnonic diode in a ferromagnetic bilayer system. Effective unidirectional propagation of spin waves is achieved by taking advantage of nonreciprocities produced by dynamic dipolar interactions in transversally magnetized media, which lack symmetry about their horizontal midplane. More specifically, dipolar-induced nonreciprocities are used to engineer the spin-wave dispersion relation of the bilayer system so that the group velocity is reduced to very low values for one direction of propagation and not for the other, thus producing unidirectional slow spin waves. Brillouin light scattering and propagating-spin-wave spectroscopy are used to demonstrate the diodelike behavior of the device, the composition of which is first optimized through micromagnetic simulations.

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Section: B Nonreciprocal Dispersion Relationssupporting

confidence: 72%

Slow-Wave-Based Nanomagnonic Diode

et al. 2020

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“…It is manifested both, by a difference in the frequency of the waves at +k and −k, as well as the differences in the coupling strength on both sides of the Brillouin zone center. Clearly, hybridization at crossings for the −k are stronger than for the positive values of k. These effects are due to nonreciprocity of the Damon-Eshbach mode and the asymmetry of the structure [27,39].…”

Section: Resultsmentioning

confidence: 99%

“…Most of these studies deal with the in-plane SW propagation, but control of SW propagation in out of-plane direction is also promising for applications, although an area of 3D magnonics still remain unexplored [24]. Multilayer structures have already been studied for controlling SW spectra in thin films with using periodic gratings [25][26][27], periodic gratings were also used to excite and detect SWs propagating in homogeneous film beneath it. However, the way of transferring of the SW energy in the vertical direction has not yet been established.…”

Section: Introductionmentioning

confidence: 99%

Co- and contra-directional vertical coupling between ferromagnetic layers with grating for short-wavelength spin wave generation

2018

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The possibility to generate short spin waves (SWs) is of great interest in the field of magnonics nowadays. We present an effective and technically affordable way of conversion of long SWs, which may be generated by conventional microwave antenna, to the short, sub-micrometer waves. It is achieved by grating-assisted resonant dynamic dipolar interaction between two ferromagnetic layers separated by some distance. We analyze criteria for the optimal conversion giving a semi-analytical approach for the coupling coefficient. We show by the numerical calculations the efficient energy transfer between layers which may be either of co-directional or contra-directional type. Such a system may operate either as a short spin wave generator or a frequency filter, moving forward possible application of magnonics. permalloy (Py)-CoFeB bilayer separated by a nonmagnetic spacer, with Py layer decorated with a grating. We show, that it is possible to achieve complete SW power exchange between the layers, if the structure is optimized for resonant, phase-matched interaction of a proper magnitude. We tested influence of damping on the SW energy exchange between layers, and show that the effect can be optimized by increasing grating thickness. We propose such a system to be a simple and efficient transducer for generation of short SWs in Py from long SWs in CoFeB, which allows to transfer the SW signals in the vertical direction, and also to exploit it as a narrow band filters for future magnonic devices.

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“…Magnonic crystals are produced using different types of magnetic materials: metals such as Ni and Co 28,29 , alloys such as Permalloy (Ni 80 Fe 20 ) 28,[30][31][32][33] and CoFeB 34,35 , Heusler compounds such as Co 2 ðFe 0:4 Mn 0:6 ÞSi 36,37 , and dielectrics like yttrium iron garnet (YIG, Y 3 Fe 5 O 12 ) 11,16,18,[20][21][22][23][24][25][26][27]38,39 . The main advantages in choosing μm-thick single-crystal YIG films over nm-thick metallic materials such as Permalloy or CoFeB is the small magnetic damping 40 and higher group velocity of dipolar SWs.…”

mentioning

confidence: 99%

Reflection-less width-modulated magnonic crystal

et al. 2020

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The interest in artificial magnetic media such as magnonic crystals increased substantially in recent years due to their potential applications in information processing at microwave frequencies. The main features of these crystals are the presence of band gaps in the spin-wave spectra, usually formed due to Bragg reflections of spin-waves on the artificially created periodic structures. Here, we study spin-wave propagation in longitudinally magnetized width-and thickness-modulated yttrium iron garnet waveguides by means of Brillouin light scattering and microwave spectroscopy techniques. It is found that the width modulated crystal does not manifest noticeable Bragg reflections, but still demonstrates a pronounced band gap in its transmission characteristic. The phenomenon can be explained by the destructive interference between different frequency-degenerated spin-wave modes excited by the crystal. Such a reflection-less crystal is promising for future design of multi-element magnonic devices.

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Spin-wave nonreciprocity and magnonic band structure in a thin permalloy film induced by dynamical coupling with an array of Ni stripes

Cited by 52 publications

References 48 publications

Slow-Wave-Based Nanomagnonic Diode

Slow-Wave-Based Nanomagnonic Diode

Co- and contra-directional vertical coupling between ferromagnetic layers with grating for short-wavelength spin wave generation

Reflection-less width-modulated magnonic crystal

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