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Supersolid light in a semiconductor microcavity (2509.09007v1)

Published 10 Sep 2025 in physics.optics

Abstract: Supersolidity - simultaneous superfluid flow and crystalline order - has been realized in quantum atomic systems but remains unexplored in purely photonic platforms operating at weak light-matter coupling. We predict a supersolid phase of light in a plasma-filled optical microcavity, where photons acquire effective mass and interact via nonlocal, plasma-mediated nonlinearities. By deriving a Gross-Pitaevskii equation with a tunable photon-photon interaction kernel, we show that under coherent driving the cavity light field can spontaneously crystallize into a supersolid lattice via modulational instability. Crucially, this supersolid arises from a weak photon-electron coupling enabled by virtual electronic transitions, and it does not require hybrid polariton formation. Using doped semiconductor microcavities, we identify feasible conditions (electron densities $\sim 10^{10}- 10^{{11}~\mathrm{cm}^{-2}$} and optical intensities $\sim 10^{{2}-10^{{4}~\mathrm{W/cm}^{2}$)}} for experimental realization. This work establishes plasmonic cavities as a platform for correlated photonic matter with emergent quantum order.