We study the performance and limitations of a coherent interface between collective atomic states and single photons. A quantized spin-wave excitation of an atomic sample inside an optical resonator is prepared probabilistically, stored, and adiabatically converted on demand into a sub-Poissonian photonic excitation of the resonator mode. The measured peak single-quantum conversion efficiency of χ=0.84(11) and its dependence on various parameters are well described by a simple model of the mode geometry and multilevel atomic structure, pointing the way towards implementing highperformance stationary single-photon sources.PACS numbers: 42.50. Dv, 03.67.Hk, 42.50.Fx, 32.80.Pj A quantum-coherent interface between light and a material structure that can store quantum states is a pivotal part of a system for processing quantum information [1]. In particular, a quantum memory that can be mapped onto photon number states in a single spatio-temporal mode could pave the way towards extended quantum networks [2,3] and all-optical quantum computing [4]. While light with sub-Poissonian fluctuations can be generated by a variety of single-quantum systems [5,6,7], a point emitter in free space is only weakly, and thus irreversibly, coupled to an electromagnetic continuum.To achieve reversible coupling, the strength of the emitter-light interaction can be enhanced by means of an optical resonator, as demonstrated for quantum dots in the weak- [8,9], trapped ions in the intermediate- [10], and neutral atoms in the strong-coupling regime [11,12]. By controlling the position of a single atom trapped inside a very-high-finesse resonator, McKeever et al. have realized a high-quality deterministic single-photon source [12]. This source operates in principle in the reversiblecoupling regime, although finite mirror losses presently make it difficult to obtain full reversibility in practice.Alternatively, superradiant states of an atomic ensemble [13] exhibit enhanced coupling to a single electromagnetic mode. For three-level atoms with two stable ground states these collective states can be viewed as quantized spin waves, where a spin-wave quantum (magnon) can be converted into a photon by the application of a phasematched laser beam [3]. Such systems have been used to generate [14,16], store and retrieve single photons [18,19], to generate simultaneous-photon pairs [17,25], and to increase the single-photon production rate by feedback [21,22,23]. The strong-coupling regime between magnons and photons can be reached if the sample's optical depth OD exceeds unity. However, since the failure rate for magnon-photon conversion in these free-space [14,15,16,17,18,19,20,21,22,23] or moderate-finessecavity [24,25] systems has been around 50% or higher, which can be realized with OD ≤ 1, none of the ensemble systems so far has reached the strong, reversible-coupling regime. In this Letter, we demonstrate for the first time the strong-coupling regime between collective spin-wave excitations and a single electromagnetic mode. This is evidenc...
