Collective multimode strong coupling in plasmonic nanocavities

Angus Crookes; Ben Yuen; Angela Demetriadou

doi:10.1515/nanoph-2024-0618

Collective multimode strong coupling in plasmonic nanocavities

Angus Crookes, Ben Yuen, Angela Demetriadou^*

^*Corresponding author for this work

Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

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Abstract

Plasmonic nanocavities enable access to the quantum properties of matter, but are often simplified to single mode models despite their complex multimode structure. Here, we show that off-resonant plasmonic modes in fact play a crucial role in strong coupling, and determine the onset of a novel collective interaction. Our analysis reveals that 𝑛 strongly coupled plasmonic modes, introduce up to 𝑛(𝑛 + 1)/2 oscillation frequencies that depend on their coupling strengths and detuning’s from the quantum emitter. Furthermore, we identify three distinct regions as the coupling strength increases: (1) single mode, (2) multimode, and (3) collective multimode strong coupling. Our findings enhance the understanding of quantum dynamics in realistic plasmonic environments and demonstrate their potential to achieve ultra-fast energy transfer in light-driven quantum technologies.

Original language	English
Pages (from-to)	2065-2073
Number of pages	11
Journal	Nanophotonics
Volume	14
Issue number	11
DOIs	https://doi.org/10.1515/nanoph-2024-0618
Publication status	Published - 21 Mar 2025

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2 Finished
3 Active

Mid-IR vibration-assisted luminescence & spectroscopies (MIRVALS)
Chikkaraddy, R. (Co-Investigator) & Demetriadou, A. (Principal Investigator)
Engineering & Physical Science Research Council
1/04/24 → 28/02/27
Project: Research Councils
Nanoplasmonics for quantum technologies
Demetriadou, A. (Principal Investigator)
The Royal Society
17/02/24 → 13/08/27
Project: Research Councils
Chip-scale Atomic Systems for a Quantum Navigator
Holynski, M. (Principal Investigator), Demetriadou, A. (Co-Investigator) & Bongs, K. (Co-Investigator)
Engineering & Physical Science Research Council
16/11/23 → 15/11/28
Project: Research Councils
Extreme Photonic Crystals for Quantum Processes
Demetriadou, A. (Principal Investigator)
The Royal Society
31/03/21 → 30/03/22
Project: Research Councils
Plasmons and Molecules: Photochemistry in the Light-Matter Strong Coupling Regime (Dr Angela Demetriadou)
Demetriadou, A. (Principal Investigator)
The Royal Society
1/10/18 → 16/02/24
Project: Research Councils

Cite this

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title = "Collective multimode strong coupling in plasmonic nanocavities",

abstract = "Plasmonic nanocavities enable access to the quantum properties of matter, but are often simplified to single mode models despite their complex multimode structure. Here, we show that off-resonant plasmonic modes in fact play a crucial role in strong coupling, and determine the onset of a novel collective interaction. Our analysis reveals that 𝑛 strongly coupled plasmonic modes, introduce up to 𝑛(𝑛 + 1)/2 oscillation frequencies that depend on their coupling strengths and detuning{\textquoteright}s from the quantum emitter. Furthermore, we identify three distinct regions as the coupling strength increases: (1) single mode, (2) multimode, and (3) collective multimode strong coupling. Our findings enhance the understanding of quantum dynamics in realistic plasmonic environments and demonstrate their potential to achieve ultra-fast energy transfer in light-driven quantum technologies.",

author = "Angus Crookes and Ben Yuen and Angela Demetriadou",

year = "2025",

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language = "English",

volume = "14",

pages = "2065--2073",

journal = "Nanophotonics",

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T1 - Collective multimode strong coupling in plasmonic nanocavities

AU - Crookes, Angus

AU - Yuen, Ben

AU - Demetriadou, Angela

PY - 2025/3/21

Y1 - 2025/3/21

N2 - Plasmonic nanocavities enable access to the quantum properties of matter, but are often simplified to single mode models despite their complex multimode structure. Here, we show that off-resonant plasmonic modes in fact play a crucial role in strong coupling, and determine the onset of a novel collective interaction. Our analysis reveals that 𝑛 strongly coupled plasmonic modes, introduce up to 𝑛(𝑛 + 1)/2 oscillation frequencies that depend on their coupling strengths and detuning’s from the quantum emitter. Furthermore, we identify three distinct regions as the coupling strength increases: (1) single mode, (2) multimode, and (3) collective multimode strong coupling. Our findings enhance the understanding of quantum dynamics in realistic plasmonic environments and demonstrate their potential to achieve ultra-fast energy transfer in light-driven quantum technologies.

AB - Plasmonic nanocavities enable access to the quantum properties of matter, but are often simplified to single mode models despite their complex multimode structure. Here, we show that off-resonant plasmonic modes in fact play a crucial role in strong coupling, and determine the onset of a novel collective interaction. Our analysis reveals that 𝑛 strongly coupled plasmonic modes, introduce up to 𝑛(𝑛 + 1)/2 oscillation frequencies that depend on their coupling strengths and detuning’s from the quantum emitter. Furthermore, we identify three distinct regions as the coupling strength increases: (1) single mode, (2) multimode, and (3) collective multimode strong coupling. Our findings enhance the understanding of quantum dynamics in realistic plasmonic environments and demonstrate their potential to achieve ultra-fast energy transfer in light-driven quantum technologies.

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DO - 10.1515/nanoph-2024-0618

M3 - Article

SN - 2192-8606

VL - 14

SP - 2065

EP - 2073

JO - Nanophotonics

JF - Nanophotonics

IS - 11

ER -

Collective multimode strong coupling in plasmonic nanocavities

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Projects

Mid-IR vibration-assisted luminescence & spectroscopies (MIRVALS)

Nanoplasmonics for quantum technologies

Chip-scale Atomic Systems for a Quantum Navigator

Extreme Photonic Crystals for Quantum Processes

Plasmons and Molecules: Photochemistry in the Light-Matter Strong Coupling Regime (Dr Angela Demetriadou)

Cite this