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Dicke Superradiance in Ordered Arrays of Multilevel Atoms

Stuart J. Masson, Jacob P. Covey, Sebastian Will, Ana Asenjo-Garcı́a

2024PRX Quantum43 citationsDOIOpen Access PDF

Abstract

In inverted atomic ensembles, photon-mediated interactions give rise to Dicke superradiance, a form of many-body decay that results in a rapid release of energy as a photon burst. While originally studied in pointlike ensembles, this phenomenon persists in extended ordered systems if the interparticle distance is below a certain bound. Here, we investigate Dicke superradiance in a realistic experimental setting using ordered arrays of alkaline-earth(-like) atoms, such as strontium and ytterbium. Such atoms offer exciting new opportunities for light-matter interactions, as their internal structure allows for trapping at short interatomic distances compared to their long-wavelength transitions, providing the potential for collectively enhanced dissipative interactions. Despite their intricate electronic structure, we show that two-dimensional arrays of these atomic species should exhibit many-body superradiance for achievable lattice constants. Moreover, superradiance effectively “closes” transitions, such that multilevel atoms become more two-level like. This occurs because the avalanchelike decay funnels the emission of most photons into the dominant transition, overcoming the single-atom decay ratios dictated by their fine structure and Zeeman branching. Our work represents an important step in harnessing alkaline-earth atoms as quantum optical sources and as platforms to explore many-body dissipative dynamics. Published by the American Physical Society 2024

Topics & Concepts

SuperradiancePhysicsOptical latticeAtomic physicsPhotonAtom (system on chip)Dissipative systemVirtual particleQuantum mechanicsLaserComputer scienceEmbedded systemSuperfluidityCold Atom Physics and Bose-Einstein CondensatesQuantum optics and atomic interactionsSpectroscopy and Laser Applications
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