Exact factorization rule relates higher-order multitime correlations to products of lower-order ones in non-Markovian systems with finite memory, allowing reconstruction from O(τ_c^n) data volume.
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Non-Markovian quantum dynamics with complete positivity and non-signalling is characterized by an integro-differential equation augmenting the GKSL master equation with a memory integral, allowing description of systems with any integrable power spectral density and multi-time correlation evaluation
A self-consistent input-output approach eliminates cavity modes in non-adiabatic CQED to yield an effective two-level atom model with non-Markovian decoherence captured by an effective Lindblad equation having positive and negative rates.
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Factorization rule for multitime correlations in non-Markovian open quantum systems
Exact factorization rule relates higher-order multitime correlations to products of lower-order ones in non-Markovian systems with finite memory, allowing reconstruction from O(τ_c^n) data volume.
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Completely-positive non-signalling non-Markovian dynamics
Non-Markovian quantum dynamics with complete positivity and non-signalling is characterized by an integro-differential equation augmenting the GKSL master equation with a memory integral, allowing description of systems with any integrable power spectral density and multi-time correlation evaluation
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Cavity elimination in cavity-QED: a self-consistent input-output approach
A self-consistent input-output approach eliminates cavity modes in non-adiabatic CQED to yield an effective two-level atom model with non-Markovian decoherence captured by an effective Lindblad equation having positive and negative rates.