A dissipation gradient plus detuning ramp selects a resonant pinned density front in 2D driven-dissipative Bose-Hubbard lattice simulations, producing tunable depinning, pattern locking, and chaos.
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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.
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.
A modified input-output approach with an added low-Q cavity channel models giant-atom electromagnetic scattering beyond the dipole approximation, explaining generic Fano-type spectra and extracting dissipation and coupling parameters.
A giant atom coupled to a detuned honeycomb photonic lattice emits valley-polarized photons that propagate chirally along domain walls.
A stochastic Schrödinger equation approach models giant atoms in waveguides under continuous coupling, showing weakened interference and naturally handling multiple excitations.
io-HEOM accurately captures non-Markovian waveguide QED arising from spatially non-local coupling and non-linear dispersion in different spectral densities.
citing papers explorer
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Dissipation-Selected Resonant Fronts in a Driven-Dissipative Bose-Hubbard Lattice
A dissipation gradient plus detuning ramp selects a resonant pinned density front in 2D driven-dissipative Bose-Hubbard lattice simulations, producing tunable depinning, pattern locking, and chaos.
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Phase-tunable remote nonreciprocal charging in waveguide QED
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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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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An input-output approach for giant atom scatterings beyond the dipole approximation
A modified input-output approach with an added low-Q cavity channel models giant-atom electromagnetic scattering beyond the dipole approximation, explaining generic Fano-type spectra and extracting dissipation and coupling parameters.
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Giant-atom-enabled quantum optics with valley-polarized photons
A giant atom coupled to a detuned honeycomb photonic lattice emits valley-polarized photons that propagate chirally along domain walls.
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Giant atoms coupled to waveguide: Continuous coupling and multiple excitations
A stochastic Schrödinger equation approach models giant atoms in waveguides under continuous coupling, showing weakened interference and naturally handling multiple excitations.
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Strongly-coupled non-Markovian waveguide QED with input-output HEOM
io-HEOM accurately captures non-Markovian waveguide QED arising from spatially non-local coupling and non-linear dispersion in different spectral densities.