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Main Authors: Höfinger, Andreas, Voronov, Andrey A., Schmoll, David, Koraltan, Sabri, Bruckner, Florian, Abert, Claas, Suess, Dieter, Lindner, Morris, Reimann, Timmy, Dubs, Carsten, Chumak, Andrii V., Knauer, Sebastian
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.10346
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author Höfinger, Andreas
Voronov, Andrey A.
Schmoll, David
Koraltan, Sabri
Bruckner, Florian
Abert, Claas
Suess, Dieter
Lindner, Morris
Reimann, Timmy
Dubs, Carsten
Chumak, Andrii V.
Knauer, Sebastian
author_facet Höfinger, Andreas
Voronov, Andrey A.
Schmoll, David
Koraltan, Sabri
Bruckner, Florian
Abert, Claas
Suess, Dieter
Lindner, Morris
Reimann, Timmy
Dubs, Carsten
Chumak, Andrii V.
Knauer, Sebastian
contents The excitation and detection of propagating spin waves with lithographed nanoantennas underpin both classical magnonic circuits and emerging quantum technologies. Here, we establish a framework for all-electrical propagating spin-wave spectroscopy (AEPSWS) that links realistic electromagnetic drive fields to micromagnetic dynamics. Using finite-element (FE) simulations, we compute the full vector near-field of electrical impedance-matched, tapered coplanar and stripline antennas and import this distribution into finite-difference (FD) micromagnetic solvers. This approach captures the antenna-limited wave-vector spectrum and the component-selective driving fields (perpendicular to the static magnetisation) that simplified uniform-field models cannot. From this coupling, we derive how realistic current return paths and tapering shapes, k-weighting functions, for Damon-Eshbach surface spin waves in yttrium-iron-garnet (YIG) films are, for millimetre-scale matched CPWs and linear tapers down to nanometre-scale antennas. Validation against experimental AEPSWS on a $48\,nm$ YIG film shows quantitative agreement in dispersion ridges, group velocities, and spectral peak positions, establishing that the antenna acts as a tunable k-space filter. These results provide actionable design rules for on-chip magnonic transducers, with immediate relevance for low-power operation regimes and prospective applications in quantum magnonics.
format Preprint
id arxiv_https___arxiv_org_abs_2511_10346
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle k-Selective Electrical-to-Magnon Transduction with Realistic Field-distributed Nanoantennas
Höfinger, Andreas
Voronov, Andrey A.
Schmoll, David
Koraltan, Sabri
Bruckner, Florian
Abert, Claas
Suess, Dieter
Lindner, Morris
Reimann, Timmy
Dubs, Carsten
Chumak, Andrii V.
Knauer, Sebastian
Mesoscale and Nanoscale Physics
Applied Physics
The excitation and detection of propagating spin waves with lithographed nanoantennas underpin both classical magnonic circuits and emerging quantum technologies. Here, we establish a framework for all-electrical propagating spin-wave spectroscopy (AEPSWS) that links realistic electromagnetic drive fields to micromagnetic dynamics. Using finite-element (FE) simulations, we compute the full vector near-field of electrical impedance-matched, tapered coplanar and stripline antennas and import this distribution into finite-difference (FD) micromagnetic solvers. This approach captures the antenna-limited wave-vector spectrum and the component-selective driving fields (perpendicular to the static magnetisation) that simplified uniform-field models cannot. From this coupling, we derive how realistic current return paths and tapering shapes, k-weighting functions, for Damon-Eshbach surface spin waves in yttrium-iron-garnet (YIG) films are, for millimetre-scale matched CPWs and linear tapers down to nanometre-scale antennas. Validation against experimental AEPSWS on a $48\,nm$ YIG film shows quantitative agreement in dispersion ridges, group velocities, and spectral peak positions, establishing that the antenna acts as a tunable k-space filter. These results provide actionable design rules for on-chip magnonic transducers, with immediate relevance for low-power operation regimes and prospective applications in quantum magnonics.
title k-Selective Electrical-to-Magnon Transduction with Realistic Field-distributed Nanoantennas
topic Mesoscale and Nanoscale Physics
Applied Physics
url https://arxiv.org/abs/2511.10346