Crystal polaritons form via strong collective coupling of periodic emitter arrays to metasurface resonances, enabling orders-of-magnitude higher quantum light generation efficiency than conventional nonlinear metasurfaces.
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Moire superlattices naturally create tunable arrays of artificial atoms with uniform optical transition energies suitable for quantum optics applications across many wavelengths.
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Close encounters between periodic light and periodic arrays of quantum emitters
Crystal polaritons form via strong collective coupling of periodic emitter arrays to metasurface resonances, enabling orders-of-magnitude higher quantum light generation efficiency than conventional nonlinear metasurfaces.
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Artificial-atom arrays in moire superlattices for quantum optics
Moire superlattices naturally create tunable arrays of artificial atoms with uniform optical transition energies suitable for quantum optics applications across many wavelengths.