Proposes realizing all-optical neural networks via phase-tunable interference, bad-cavity integration, and transient Rabi dynamics in waveguide QED, with simulations showing high accuracy on MNIST and object recognition.
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Two electrically tunable quantum dots coupled through a bidirectional waveguide form a radiatively coupled artificial molecule whose emission direction is switched by driving phase, yielding directional single photons and photon pairs.
Advanced Fourier modal method formulation for gratings with bi-anisotropic materials, providing explicit Fourier tensors of material parameters with and without generalized factorization rules that reduce to standard cases without magneto-electric coupling.
citing papers explorer
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Optical Neural Networks from Coherent Transient Dynamics in Waveguide QED
Proposes realizing all-optical neural networks via phase-tunable interference, bad-cavity integration, and transient Rabi dynamics in waveguide QED, with simulations showing high accuracy on MNIST and object recognition.
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Directional and correlated optical emission from a waveguide-engineered molecule with local control
Two electrically tunable quantum dots coupled through a bidirectional waveguide form a radiatively coupled artificial molecule whose emission direction is switched by driving phase, yielding directional single photons and photon pairs.
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The Fourier modal method for gratings with bi-anisotropic materials
Advanced Fourier modal method formulation for gratings with bi-anisotropic materials, providing explicit Fourier tensors of material parameters with and without generalized factorization rules that reduce to standard cases without magneto-electric coupling.