Self‐Imaging Based Programmable Spin‐Wave Lookup Tables

Gołębiewski, Mateusz; Gruszecki, Paweł; Krawczyk, Maciej

doi:10.1002/aelm.202200373

Cited by 5 publications

(2 citation statements)

References 45 publications

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“…Thus, spin waves are not an ideal fit to directly replicate classical optical building blocks, instead, they are more suitable for the approaches used in nanophotonics [9,34] -we believe that our technique is also applicable to the realization of such structures, as the achievable resolution with FIB (≈10 nm) can easily serve that. The automatic design of magnonic devices combined with a flexible and versatile fabrication method has the potential to raise the bar for magnonic device concepts, enabling the realization of circuits, [35] and drive the field toward practical applications.…”

Section: Discussionmentioning

confidence: 99%

Spin‐Wave Optics in YIG Realized by Ion‐Beam Irradiation

Kiechle

Papp

Mendisch

et al. 2023

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Direct focused‐ion‐beam writing is presented as an enabling technology for realizing functional spin‐wave devices of high complexity, and demonstrate its potential by optically‐inspired designs. It is shown that ion‐beam irradiation changes the characteristics of yttrium iron garnet films on a submicron scale in a highly controlled way, allowing one to engineer the magnonic index of refraction adapted to desired applications. This technique does not physically remove material, and allows rapid fabrication of high‐quality architectures of modified magnetization in magnonic media with minimal edge damage (compared to more common removal techniques such as etching or milling). By experimentally showing magnonic versions of a number of optical devices (lenses, gratings, Fourier‐domain processors) this technology is envisioned as the gateway to building magnonic computing devices that rival their optical counterparts in their complexity and computational power.

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Section: Discussionmentioning

confidence: 99%

Spin‐Wave Optics in YIG Realized by Ion‐Beam Irradiation

Kiechle

Papp

Mendisch

et al. 2023

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“…An intriguing wave type is the spin wave (SW), that is, a collective precessional disturbance of magnetization in magnetic materials, which is believed to be a promising candidate for information carriers in beyond-CMOS devices. − SW optics is more complex than its electromagnetic counterpart and rich in optical phenomena. − Many effects from photonics have already been transferred to magnonics, for instance, negative refraction, anomalous refraction, graded refractive index effects, − and the Goos-Hänchen (GH) effect, i.e., the lateral shift of the waves’ reflection point at an interface. − While the GH effect has been predicted theoretically, it has not yet been experimentally observed for SW beams. Also, the BICs, LMs, Wood’s anomalies, and resonance effects widely explored in photonics remain poorly investigated in magnonics.…”

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confidence: 99%

Magnon-Optic Effects with Spin-Wave Leaky Modes: Tunable Goos-Hänchen Shift and Wood’s Anomaly

Sobucki,

Śmigaj,

Graczyk

et al. 2023

Nano Lett.

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We demonstrate numerically how a spin wave (SW) beam obliquely incident on the edge of a thin film placed below a ferromagnetic stripe can excite leaky SWs guided along the stripe. During propagation, leaky waves emit energy back into the layer in the form of plane waves and several laterally shifted parallel SW beams. This resonance excitation, combined with interference effects of the reflected and re-emitted waves, results in the magnonic Wood’s anomaly and a significant increase of the Goos-Hänchen shift magnitude. This yields a unique platform to control SW reflection and transdimensional magnonic router that can transfer SWs from a 2D platform into a 1D guided mode.

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