Phase engineering in waveguide QED enables unidirectional remote charging of quantum batteries with independent control of nonreciprocity and storage efficiency across four emitter-waveguide configurations.
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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.
Giant atoms with engineered multi-point couplings to waveguides enable deterministic passive quantum state transfer, with optimized fidelities of 87% for two points and over 99% for ten or more.
A stochastic Schrödinger equation approach models giant atoms in waveguides under continuous coupling, showing weakened interference and naturally handling multiple excitations.
Dark states are derived for two-to-four atom cases and the single-excitation subspace of general N-atom cavity-Rydberg systems, with a characterization method via state populations.
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