We identify a new mechanism for cooperative emission of light by an ensemble of N dipoles near a metal nanostructure supporting a surface plasmon.The cross-talk between emitters due to virtual plasmon exchange leads to a formation of three plasmonic super-radiant modes whose radiative decay rates scales with N , while the total radiated energy is thrice that of a single emitter. Our numerical simulations indicate that the plasmonic Dicke effect survives non-radiative losses in the metal.Radiation of a dipole near a metal nanostructure supporting surface plasmon (SP) is attracting renewed interest due to possible biosensing applications [1]. While early studies mainly focused on fluorescence of molecules near rough metal films [2], recent advances in near-field optics and in chemical control of molecule-nanostructure complexes spurred a number of experiments on single metal nanoparticles (NP) linked to dye molecules [3,4,5,6,7,8] or semiconductor quantum dots [9]. Emission of a photon by a dipole-NP complex involves two competing processes: enhancement due to resonance energy transfer (RET) from an excited dipole to a SP [10], and quenching due to decay into optically-inactive excitations in the metal [11]. These decay channels are characterized by radiative, Γ r , and non-radiative, Γ nr , decay rates, respectively, and their balance is determined by the separation, d, of the emitter from the metal surface [12,13]. The emission is most enhanced at some optimal distance, and is quenched close to the NP surface due to the suppression of quantum efficiency, Q = Γ r / (Γ r + Γ nr ), by prevalent non-radiative processes. Both enhancement and quenching were widely observed in fluorescence experiments on Au and Ag nanoparticles [3,4,5,6,7,8]. In recent single-molecule measurements [6,7,8], the distance dependence was in a good agreement with single-dipole-NP models [12,13], prompting proposals for a NP-based nanoscopic ruler [8].In this Letter, we identify a novel mechanism in the emission of light by an ensemble of dipoles located near a nanostructure supporting a localized SP. A typical setup would involve, e.g., dye molecules [3,4,5] or quantum dots [9] attached to a metal NP via DNA linkers. Namely, we demonstrate that RET between individual dipoles and SP leads to a cross-talk between the emitters. As a result, the emission of a photon becomes a cooperative process involving all dipoles in the ensemble. This plasmonic mechanism of cooperative emission is analogous to the Dicke effect for N radiating dipoles in free space, confined within a volume with characteristic size smaller than the radiation wavelength λ [14,15,16]. In that case, the cooperative emission is due to photon exchange between the emitters that gives rise to super-radiant (SR) states with total angular momentun 1 and enhanced radiative decay rate ∼ N Γ r 0 , where Γ r 0 is the decay rate of an isolated dipole. In contrast, in plasmonic systems, the dominant coupling mechanism between dipoles is SP exchange, i.e., excitation of a virtual SP in a na...
