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.
Dissipative Channels Determine Open Electromagnetic Quantization
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abstract
We formulate a quantization scheme for open electromagnetic systems with arbitrary passive boundary conditions. Rather than specifying reservoirs phenomenologically, the method identifies them from the dissipation geometry of the Maxwell operator. Factoring the imaginary part of the Maxwell operator gives a bosonic realization of the field operator and separates the fluctuation channels into medium-assisted reservoirs from material absorption and boundary-assisted reservoirs from exchange through the open boundary. Depending on the boundary condition, the latter become free-space radiation modes, impedance-load channels, guided port modes, or more general boundary channels. Green-function input-output relations then follow as an application, yielding frequency-dependent scattering and noise kernels without Markov or single-mode assumptions. To illustrate the practical application, we consider a lossy structure with mixed impedance and outgoing boundaries, and photonic integrated circuit configurations with waveguide port boundaries.
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quant-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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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.