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Nanoscale continuous quantum light sources based on driven dipole emitter arrays

Raphael Holzinger, Maria Moreno-Cardoner, Helmut Ritsch

2021Applied Physics Letters27 citationsDOIOpen Access PDF

Abstract

Regular arrays of two-level emitters at distances smaller than that of the transition wavelength collectively scatter, absorb, and emit photons. The strong inter-particle dipole coupling creates large energy shifts of the collective delocalized excitations, which generates a highly nonlinear response at the single and few photon level. This should allow us to implement nanoscale non-classical light sources via weak coherent illumination. At the generic tailored examples of regular chains or polygons, we show that the fields emitted perpendicular to the illumination direction exhibit a strong directional confinement with genuine quantum properties as antibunching. For short interparticle distances, superradiant directional emission can enhance the radiated intensity by an order of magnitude compared to a single atom focused to a strongly confined solid angle but still keeping the anti-bunching parameter at the level of g(2)(0)≈10−2.

Topics & Concepts

PhysicsDelocalized electronDipolePhotonWavelengthQuantumOptoelectronicsCommon emitterNanoscopic scaleAtom (system on chip)Coupling (piping)PerpendicularOpticsAtomic physicsSpontaneous emissionNonlinear opticsSuperradianceMolecular physicsQuantum opticsQuantum dotCondensed matter physicsNanophotonicsDiscrete dipole approximationSuperatomNonlinear systemElectromagnetically induced transparencyAbsorption (acoustics)Light intensityRayCavity quantum electrodynamicsQuantum fluctuationPhotonicsStimulated emissionElectric dipole transitionElectromagnetic radiationPhoton energyStrong Light-Matter InteractionsPlasmonic and Surface Plasmon ResearchMechanical and Optical Resonators
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