Dressed states of a quantum emitter strongly coupled to a metal nanoparticle

Varguet, H.; Rousseaux, Benjamin; Dzsotjan, D.; Jauslin, H. R.; Guérin, S.; Francs, Gérard Colas des

doi:10.1364/ol.41.004480

Cited by 44 publications

(27 citation statements)

References 22 publications

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“…To understand the different coupling regimes, we use a quantum description and derive an effective Hamiltonian [57][58][59] whose structure is completely analogous to cavity QED Hamiltonians. The derivation is based on a first-principles method corresponding to the coupling of a single two-level system with a reservoir of harmonic oscillators: the Fano diagonalization [63,64].…”

Section: General Green's Tensor Approachmentioning

confidence: 99%

“…II, we derive a quantization procedure based on Refs. [57][58][59] and extend it to an arbitrary shaped nanoantenna by linking the Jaynes-Cummings coupling g with numerical solutions of the local density of states. The effective non-Hermitian Hamiltonian is then shown to be equivalent to a quantum master equation description of the QE-plasmon system where the plasmonic mode is described as a mixture of bright and dark modes.…”

Section: Introductionmentioning

confidence: 99%

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Quantum description and emergence of nonlinearities in strongly coupled single-emitter nanoantenna systems

et al. 2018

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Käll, M. et al (2018) Quantum description and emergence of nonlinearities in strongly coupled single-emitter nanoantenna systems PHYSICAL REVIEW B, 98(4) http://dx.Realizing strong coupling between a single quantum emitter (QE) and an optical cavity is of crucial importance in the context of various quantum optical applications. Although Rabi splitting of single quantum emitters coupled to high-Q classical cavities has been reported in numerous configurations, attaining single emitter Rabi splitting with a plasmonic nanostructure remains a challenge. In particular, strong coupling at the single QE regime would open the path for the realization of single-photon nonlinearities. In this paper, we derive a plasmon quantization procedure for systems consisting of a single QE located in the gap of a nanoantenna. This procedure leads to the description of the quantum dynamics by a master equation for the state of the QE and the quantized plasmonic modes, which is crucial to demonstrate the emergence of single-photon nonlinearities. We investigate numerically the optical response and the resulting Rabi splitting in metallic nanoantennas and find the optimal geometries for the emergence of the strong-coupling regime with single QEs. Finally, we demonstrate the saturation of hybridized modes for a chosen configuration. Our results will be useful for implementation of realistic quantum plasmonic nanosystems involving single QEs at room temperature.

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Section: General Green's Tensor Approachmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Quantum description and emergence of nonlinearities in strongly coupled single-emitter nanoantenna systems

et al. 2018

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“…and can be expanded in basis functions of the Green's function as in Refs. [49][50][51][52]. Inspired by this elegant approach [49], we use instead an expansion using few dominating (regularized) QNMs as in G QNM (r, r , ω), so that the source field expression of the electric field operator can be rewritten,…”

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confidence: 99%

Quantization of Quasinormal Modes for Open Cavities and Plasmonic Cavity Quantum Electrodynamics

et al. 2019

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We introduce a second quantization scheme based on quasinormal modes, which are the dissipative modes of leaky optical cavities and plasmonic resonators with complex eigenfrequencies. The theory enables the construction of multi-plasmon/photon Fock states for arbitrary three-dimensional dissipative resonators and gives a solid understanding to the limits of phenomenological dissipative Jaynes-Cummings models. In the general case, we show how different quasinormal modes interfere through an off-diagonal mode coupling and demonstrate how these results affect cavity-modified spontaneous emission. To illustrate the practical application of the theory, we show examples using a gold nanorod dimer and a hybrid dielectric-metal cavity structure. arXiv:1808.06392v3 [cond-mat.mes-hall]

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“…3). In the future, it could be interesting to test the validity of the weak-coupling approximation to quantify the Lamb shift in such a configuration, by employing an other formalism suitable for investigating the strong-coupling regime such as the one presented in [44]. A Drude-Lorentz model for the gold permittivity is used according to [28].…”

Section: B Gold Dimer Nanoantennamentioning

confidence: 99%