Realizing strong light-matter interactions between single nanoparticle plasmons and molecular excitons at ambient conditions

Realizing strong light-matter interactions between individual 2-level systems and resonating cavities in atomic and solid state systems opens up possibilities to study optical nonlinearities on a single photon level, which can be useful for future quantum information processing networks. However, th...

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Bibliographic Details
Published in:arXiv.org 2015-03
Main Authors: Zengin, Gülis, Wersäll, Martin, Nilsson, Sara, Antosiewicz, Tomasz J, Käll, Mikael, Shegai, Timur
Format: Article
Language:English
Subjects:
Coupling (molecular)
Cryogenic temperature
Data processing
Excitons
Holes
Nanoparticles
Photonic crystals
Plasmons
Quantum optics
Quantum phenomena
Quantum theory
Ultrahigh vacuum
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Summary:Realizing strong light-matter interactions between individual 2-level systems and resonating cavities in atomic and solid state systems opens up possibilities to study optical nonlinearities on a single photon level, which can be useful for future quantum information processing networks. However, these efforts have been hampered by the unfavorable experimental conditions, such as cryogenic temperatures and ultrahigh vacuum, required to study such systems and phenomena. Although several attempts to realize strong light-matter interactions at room-temperature using so-called plasmon resonances have been made, successful realizations on the single nanoparticle level are still lacking. Here, we demonstrate strong coupling between plasmons confined within a single silver nanoprism and excitons in molecular J-aggregates at ambient conditions. Our findings show that the deep subwavelength mode volumes, \(V\), together with high quality factors, \(Q\), associated with plasmons in the nanoprisms result in strong coupling figure-of-merit -- \(Q/\sqrt{V}\) as high as \(\sim6\times10^{3}\)~\(\mu\)m\(^{-3/2}\) -- a value comparable to state-of-art photonic crystal and microring resonator cavities, thereby suggesting that plasmonic nanocavities and specifically silver nanoprisms can be used for room-temperature quantum optics.
ISSN:2331-8422
DOI:10.48550/arxiv.1501.02123