Sculpting ultrastrong light-matter coupling through spatial matter structuring
Sculpting ultrastrong light-matter coupling through spatial matter structuring
The central theme of cavity quantum electrodynamics is the coupling of a single optical mode with a single matter excitation, leading to a doublet of cavity polaritons which govern the optical properties of the coupled structure. Especially in the ultrastrong coupling regime, where the ratio of the vacuum Rabi frequency and the quasi-resonant carrier frequency of light, 𝛀𝐑/𝝎𝐜, approaches unity, the polariton doublet bridges a large spectral bandwidth 𝟐𝛀𝐑, and further interactions with off-resonant light and matter modes may occur. The resulting multi-mode coupling has recently attracted attention owing to the additional degrees of freedom for designing light-matter coupled resonances, despite added complexity. Here, we experimentally implement a novel strategy to sculpt ultrastrong multi-mode coupling by tailoring the spatial overlap of multiple modes of planar metallic THz resonators and the cyclotron resonances of Landau-quantized two-dimensional electrons, on subwavelength scales. We show that similarly to the selection rules of classical optics, this allows us to suppress or enhance certain coupling pathways and to control the number of light-matter coupled modes, their octave-spanning frequency spectra, and their response to magnetic tuning. This offers novel pathways for controlling dissipation, tailoring quantum light sources, nonlinearities, correlations as well as entanglement in quantum information processing.
Landau Polaritons, Ultrastrong Coupling, multi-mode interference
1-27
Mornhinweg, Joshua
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Diebel, Laura
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Halbhuber, Maike
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Riepl, Josef
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Cortese, Erika
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De Liberato, Simone
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Bougeard, Dominique
8ca73003-a043-4861-8449-81878bc3bc1a
Huber, Rupert
76716ee3-0c59-4ae9-a306-8f612124e45f
Lange, Christoph
a4d183c9-5b5f-464a-bfc6-49851929c0e1
Mornhinweg, Joshua
55d36143-9f61-46db-968b-59618808da0d
Diebel, Laura
8783acc9-51c8-4db6-8845-fe7e8fca306b
Halbhuber, Maike
e1e0260f-7eec-4c08-a087-7e08c79bdce2
Riepl, Josef
ce113df3-21c4-4bab-bd83-d0ecd079d67e
Cortese, Erika
3a7d67d1-3321-40b2-91fa-2471dbed7147
De Liberato, Simone
5942e45f-3115-4027-8653-a82667ed8473
Bougeard, Dominique
8ca73003-a043-4861-8449-81878bc3bc1a
Huber, Rupert
76716ee3-0c59-4ae9-a306-8f612124e45f
Lange, Christoph
a4d183c9-5b5f-464a-bfc6-49851929c0e1
Mornhinweg, Joshua, Diebel, Laura, Halbhuber, Maike, Riepl, Josef, Cortese, Erika, De Liberato, Simone, Bougeard, Dominique, Huber, Rupert and Lange, Christoph
(2023)
Sculpting ultrastrong light-matter coupling through spatial matter structuring.
Nanophotonics, .
(In Press)
Abstract
The central theme of cavity quantum electrodynamics is the coupling of a single optical mode with a single matter excitation, leading to a doublet of cavity polaritons which govern the optical properties of the coupled structure. Especially in the ultrastrong coupling regime, where the ratio of the vacuum Rabi frequency and the quasi-resonant carrier frequency of light, 𝛀𝐑/𝝎𝐜, approaches unity, the polariton doublet bridges a large spectral bandwidth 𝟐𝛀𝐑, and further interactions with off-resonant light and matter modes may occur. The resulting multi-mode coupling has recently attracted attention owing to the additional degrees of freedom for designing light-matter coupled resonances, despite added complexity. Here, we experimentally implement a novel strategy to sculpt ultrastrong multi-mode coupling by tailoring the spatial overlap of multiple modes of planar metallic THz resonators and the cyclotron resonances of Landau-quantized two-dimensional electrons, on subwavelength scales. We show that similarly to the selection rules of classical optics, this allows us to suppress or enhance certain coupling pathways and to control the number of light-matter coupled modes, their octave-spanning frequency spectra, and their response to magnetic tuning. This offers novel pathways for controlling dissipation, tailoring quantum light sources, nonlinearities, correlations as well as entanglement in quantum information processing.
Text
2311.18278
- Accepted Manuscript
More information
Accepted/In Press date: 8 December 2023
Additional Information:
We gratefully acknowledge support by the Deutsche Forschungsgemeinschaft (dx.doi.org/10.13039/501100001659) through Project IDs 422 31469 5032-SFB1277 (Subproject A01), grants no. BO 3140/3-2, LA 3307/1-2, and HU 1598/8, as well as by the European Research Council (ERC)(dx.doi.org/10.13039/100010663) through Future and Emerging Technologies (FET) grant no. 737017 (MIR-BOSE) and by the Leverhulme Trust thought the grant RPG-2022-037.
Keywords:
Landau Polaritons, Ultrastrong Coupling, multi-mode interference
Identifiers
Local EPrints ID: 485678
URI: http://eprints.soton.ac.uk/id/eprint/485678
PURE UUID: d1a92b83-2253-4515-a58f-df763900db28
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Date deposited: 14 Dec 2023 17:30
Last modified: 18 Mar 2024 05:02
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Contributors
Author:
Joshua Mornhinweg
Author:
Laura Diebel
Author:
Maike Halbhuber
Author:
Josef Riepl
Author:
Dominique Bougeard
Author:
Rupert Huber
Author:
Christoph Lange
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