Taming plasmonic nanocavities for persistent entanglement

Angus Crookes; Ben Yuen; Angela Demetriadou

doi:10.1103/skc6-gnyr

Taming plasmonic nanocavities for persistent entanglement

Angus Crookes, Ben Yuen, Angela Demetriadou^*

^*Corresponding author for this work

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

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Abstract

Recent rapid advances in quantum nanoplasmonics offer the potential for accessing quantum phenomena at room temperature. Despite this, entangled states have not yet been realised, and remain an outstanding challenge. In this work, we demonstrate how entanglement emerges in plasmonic nanocavities, which are inherently multi-mode, and demonstrate the conditions necessary for entanglement to persist. We find that, in general, these conditions are broken due to coupling with multiple plasmonic modes of different parity. We address this challenge with a new nanocavity design that supports high selective coupling to a single mode, enabling the robust generation of persistent entanglement in nanoplasmonics. Our results open exciting prospects for leveraging simple plasmonic setups in ambient conditions for applications in quantum communication, sensing and rapid quantum memories.

Original language	English
Article number	085427
Number of pages	8
Journal	Physical Review B
Volume	112
Issue number	8
DOIs	https://doi.org/10.1103/skc6-gnyr
Publication status	Published - 28 Aug 2025

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3 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
Light-matter strong coupling for quantum nanoplasmonics
Demetriadou, A. (Principal Investigator)
The Royal Society
1/10/18 → 31/12/22
Project: Research Councils

Cite this

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title = "Taming plasmonic nanocavities for persistent entanglement",

abstract = "Recent rapid advances in quantum nanoplasmonics offer the potential for accessing quantum phenomena at room temperature. Despite this, entangled states have not yet been realised, and remain an outstanding challenge. In this work, we demonstrate how entanglement emerges in plasmonic nanocavities, which are inherently multi-mode, and demonstrate the conditions necessary for entanglement to persist. We find that, in general, these conditions are broken due to coupling with multiple plasmonic modes of different parity. We address this challenge with a new nanocavity design that supports high selective coupling to a single mode, enabling the robust generation of persistent entanglement in nanoplasmonics. Our results open exciting prospects for leveraging simple plasmonic setups in ambient conditions for applications in quantum communication, sensing and rapid quantum memories.",

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

year = "2025",

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day = "28",

doi = "10.1103/skc6-gnyr",

language = "English",

volume = "112",

journal = "Physical Review B",

issn = "2469-9950",

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T1 - Taming plasmonic nanocavities for persistent entanglement

AU - Crookes, Angus

AU - Yuen, Ben

AU - Demetriadou, Angela

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Y1 - 2025/8/28

N2 - Recent rapid advances in quantum nanoplasmonics offer the potential for accessing quantum phenomena at room temperature. Despite this, entangled states have not yet been realised, and remain an outstanding challenge. In this work, we demonstrate how entanglement emerges in plasmonic nanocavities, which are inherently multi-mode, and demonstrate the conditions necessary for entanglement to persist. We find that, in general, these conditions are broken due to coupling with multiple plasmonic modes of different parity. We address this challenge with a new nanocavity design that supports high selective coupling to a single mode, enabling the robust generation of persistent entanglement in nanoplasmonics. Our results open exciting prospects for leveraging simple plasmonic setups in ambient conditions for applications in quantum communication, sensing and rapid quantum memories.

AB - Recent rapid advances in quantum nanoplasmonics offer the potential for accessing quantum phenomena at room temperature. Despite this, entangled states have not yet been realised, and remain an outstanding challenge. In this work, we demonstrate how entanglement emerges in plasmonic nanocavities, which are inherently multi-mode, and demonstrate the conditions necessary for entanglement to persist. We find that, in general, these conditions are broken due to coupling with multiple plasmonic modes of different parity. We address this challenge with a new nanocavity design that supports high selective coupling to a single mode, enabling the robust generation of persistent entanglement in nanoplasmonics. Our results open exciting prospects for leveraging simple plasmonic setups in ambient conditions for applications in quantum communication, sensing and rapid quantum memories.

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DO - 10.1103/skc6-gnyr

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SN - 2469-9950

VL - 112

JO - Physical Review B

JF - Physical Review B

IS - 8

M1 - 085427

ER -

Taming plasmonic nanocavities for persistent entanglement

Abstract

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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)

Light-matter strong coupling for quantum nanoplasmonics

Cite this