A full-wave Green's function framework for non-Markovian collective single-photon emission in open-system QED, including a counter-term scheme to compensate for finite-bandwidth dispersive interaction errors.
Medina , author F
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The Pauli principle and nuclear spin isomers of ammonia molecules significantly reshape collective light-matter coupling in infrared cavities, demonstrated via numerical simulations for two molecules and an analytical model for ensembles.
Derives CQED-DDI model separating free-space and dielectric effects, concluding direct intermolecular interactions are essential for multi-molecule exciton-polariton dynamics.
Compares Lindblad, stochastic Schrödinger, and non-Hermitian methods for dissipative Na2-cavity dynamics and shows rotational nonadiabatic effects.
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Full-Wave Green's-Function Modeling of Collective Single-Photon Emission in Non-Markovian Open-System QED with Finite-Bandwidth Compensation of Dispersive Interactions
A full-wave Green's function framework for non-Markovian collective single-photon emission in open-system QED, including a counter-term scheme to compensate for finite-bandwidth dispersive interaction errors.
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Light-induced nonadiabatic dissipative quantum dynamics of the Na2 molecule
Compares Lindblad, stochastic Schrödinger, and non-Hermitian methods for dissipative Na2-cavity dynamics and shows rotational nonadiabatic effects.