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Main Authors: Jennings, Asher, Grytsenko, Ivan, Giovansili, Thomas, Barabash, Itay Josef, Rybalko, Oleksiy, Tian, Yiran, Wang, Jun, Ikegami, Hiroki, Kawakami, Erika
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.22552
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author Jennings, Asher
Grytsenko, Ivan
Giovansili, Thomas
Barabash, Itay Josef
Rybalko, Oleksiy
Tian, Yiran
Wang, Jun
Ikegami, Hiroki
Kawakami, Erika
author_facet Jennings, Asher
Grytsenko, Ivan
Giovansili, Thomas
Barabash, Itay Josef
Rybalko, Oleksiy
Tian, Yiran
Wang, Jun
Ikegami, Hiroki
Kawakami, Erika
contents Plasmons, arising from the collective motion of electrons, can interact strongly with electromagnetic fields or photons; this capability has been exploited across a broad range of applications, from chemical reactivity to biosensing. Recently, there has been growing interest in plasmons for applications in quantum information processing. Electrons floating on liquid helium provide an exceptionally clean, disorder-free system and have emerged as a promising platform for this purpose. In this work, we establish this system as a tunable plasmon-photon hybrid platform. We demonstrate strong coupling between floating-electron plasmons and radio-frequency (RF) photons confined in an LC resonator. Time-resolved measurements reveal coherent oscillatory energy exchange between the plasmonic and photonic modes, providing direct evidence of their coherent coupling. These results represent a step towards cavity quantum electrodynamics with a floating-electron plasmon coupled to a resonator. Furthermore, the LC resonator serves as a sensitive probe of electron-on-helium physics, enabling the observation of the Wigner crystal transition and a quantitative study of the temperature-dependent plasmon decay arising from ripplon-induced scattering.
format Preprint
id arxiv_https___arxiv_org_abs_2601_22552
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Strong Coupling Between RF Photons and Plasmons of Electrons on Liquid Helium
Jennings, Asher
Grytsenko, Ivan
Giovansili, Thomas
Barabash, Itay Josef
Rybalko, Oleksiy
Tian, Yiran
Wang, Jun
Ikegami, Hiroki
Kawakami, Erika
Optics
Strongly Correlated Electrons
Plasmons, arising from the collective motion of electrons, can interact strongly with electromagnetic fields or photons; this capability has been exploited across a broad range of applications, from chemical reactivity to biosensing. Recently, there has been growing interest in plasmons for applications in quantum information processing. Electrons floating on liquid helium provide an exceptionally clean, disorder-free system and have emerged as a promising platform for this purpose. In this work, we establish this system as a tunable plasmon-photon hybrid platform. We demonstrate strong coupling between floating-electron plasmons and radio-frequency (RF) photons confined in an LC resonator. Time-resolved measurements reveal coherent oscillatory energy exchange between the plasmonic and photonic modes, providing direct evidence of their coherent coupling. These results represent a step towards cavity quantum electrodynamics with a floating-electron plasmon coupled to a resonator. Furthermore, the LC resonator serves as a sensitive probe of electron-on-helium physics, enabling the observation of the Wigner crystal transition and a quantitative study of the temperature-dependent plasmon decay arising from ripplon-induced scattering.
title Strong Coupling Between RF Photons and Plasmons of Electrons on Liquid Helium
topic Optics
Strongly Correlated Electrons
url https://arxiv.org/abs/2601.22552