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Bibliographic Details
Main Authors: Kurfman, Seth W., Geyer, Philipp, Kamalasanan, Anoop, Heimrich, Karl, Hu, Kwangyul, Puel, Tharnier O., Heyroth, Frank, Flatté, Michael, Schmidt, Georg
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.28145
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author Kurfman, Seth W.
Geyer, Philipp
Kamalasanan, Anoop
Heimrich, Karl
Hu, Kwangyul
Puel, Tharnier O.
Heyroth, Frank
Flatté, Michael
Schmidt, Georg
author_facet Kurfman, Seth W.
Geyer, Philipp
Kamalasanan, Anoop
Heimrich, Karl
Hu, Kwangyul
Puel, Tharnier O.
Heyroth, Frank
Flatté, Michael
Schmidt, Georg
contents Strong-coupling experiments based on magnons enable the exploration into on-chip demonstrations involving numerous long-lived excitations. Yttrium iron garnet (YIG) has been considered for decades as a gold standard material for magnonics due to its low-loss magnonic properties. While YIG has successfully demonstrated strong-coupling in macroscopic device geometries, the strong coupling of magnons in truly sub-10 micron YIG structures to date has not yet been realized. This obstacle is due to the difficulty producing large enough effective magnonic mode volume necessary primarily due to thickness limitations of YIG deposition and device fabrication techniques. Here, we demonstrate the use of a microplatelet of YIG, manufactured from a single crystal of YIG via focused ion beam (FIB) techniques, placed on a constricted inductive line of an optimized superconducting lumped element LC resonator to achieve strong coupling between numerous magnon modes and the LC resonator photons. These experimental findings are qualitatively backed by micromagnetic simulations and quantitatively supported by analytical calculations to identify the magnon modes corresponding to the experimentally observed anti-crossings in the microwave transmission signal. Further, we show that these anti-crossings remain even at incredibly low device input powers ($\leq 10$ fW). The fabrication techniques and device geometry enable the deterministic use of numerous confined magnon modes in micron-scale YIG structures for various magnetic field strengths and orientations at substantially reduced device powers. The results here establish a foundational path forward to achieving efficient magnon-based strong-coupling experiments in micron-scale YIG magnetic elements for effective on-chip studies.
format Preprint
id arxiv_https___arxiv_org_abs_2604_28145
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Strong coupling between quantized magnon modes in a YIG microstucture and microwaves in a superconducting resonator
Kurfman, Seth W.
Geyer, Philipp
Kamalasanan, Anoop
Heimrich, Karl
Hu, Kwangyul
Puel, Tharnier O.
Heyroth, Frank
Flatté, Michael
Schmidt, Georg
Materials Science
Strong-coupling experiments based on magnons enable the exploration into on-chip demonstrations involving numerous long-lived excitations. Yttrium iron garnet (YIG) has been considered for decades as a gold standard material for magnonics due to its low-loss magnonic properties. While YIG has successfully demonstrated strong-coupling in macroscopic device geometries, the strong coupling of magnons in truly sub-10 micron YIG structures to date has not yet been realized. This obstacle is due to the difficulty producing large enough effective magnonic mode volume necessary primarily due to thickness limitations of YIG deposition and device fabrication techniques. Here, we demonstrate the use of a microplatelet of YIG, manufactured from a single crystal of YIG via focused ion beam (FIB) techniques, placed on a constricted inductive line of an optimized superconducting lumped element LC resonator to achieve strong coupling between numerous magnon modes and the LC resonator photons. These experimental findings are qualitatively backed by micromagnetic simulations and quantitatively supported by analytical calculations to identify the magnon modes corresponding to the experimentally observed anti-crossings in the microwave transmission signal. Further, we show that these anti-crossings remain even at incredibly low device input powers ($\leq 10$ fW). The fabrication techniques and device geometry enable the deterministic use of numerous confined magnon modes in micron-scale YIG structures for various magnetic field strengths and orientations at substantially reduced device powers. The results here establish a foundational path forward to achieving efficient magnon-based strong-coupling experiments in micron-scale YIG magnetic elements for effective on-chip studies.
title Strong coupling between quantized magnon modes in a YIG microstucture and microwaves in a superconducting resonator
topic Materials Science
url https://arxiv.org/abs/2604.28145