Mirror-mediated long-range coupling and robust phase locking of spatially separated exciton-polariton condensates (2506.20924v1)

Abstract: Lattice arrays have been shown to have great value as simulators for complicated mathematical problems. In all physical lattices so far, coupling is only between nearest neighbors or nearest plus next-nearest neighbors; the geometry of the lattice controls the couplings of the sites. Realizing independently tunable, long-range interactions between distant condensates is a prerequisite for scalable analogue spin machines but has so far been restricted to short-range geometric coupling. In this work we show that it is possible using two-dimensional lattices of polariton condensates to use the third dimension to arbitrarily select two sites to couple coherently. Light emitted in the vertical direction from a condensate at one site can be imaged and sent back into the system to impinge on a different condensate at an arbitrary distance. We demonstrate this for the case of two condensates, in which we first ensure that they have no coupling within the plane of the lattice, and then use external imaging to phase lock the two together. Phase-resolved interferometry confirms clearly visible interference fringes and deterministic phase locking even when direct, planar coupling is suppressed. Analytical modeling reveals complementary mechanisms underpinning the robust coherence. Because the mirror adds no cameras, modulators, or electronic processing, the condensate pair operates as a pure, high-bandwidth analog element. Extension to dense graphs via segmented micro-mirror arrays is therefore ultimately limited only by the field of view and numerical aperture of the imaging optics. Our scheme thus paves the way to reconfigurable, energy-efficient polaritonic hardware for optimization, classification, clustering, and other neuromorphic tasks at the speed of light.