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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Single-particle interference is governed by the relative phase between the prepared quantum state and the detector-defined measurement basis, with equivalent sinusoidal fringes produced by independent scans of pump, seed, or signal phases and visibility tuned by idler overlap.
Two-photon coincidence statistics in terahertz light from a cavity-embedded 2H-NbSe2 superconductor provide a diagnostic for ultrastrong Higgs-polariton coupling that is missing in total photon counts.
Photon counting readout detects weak postmerger gravitational wave signals at a rate of about 1 in 100 for SNR 0.2 and yields a twofold improvement in neutron star radius measurement after 20,000 events.
A Schwinger-Keldysh path integral formalism is developed for input-output theory, enabling computation of full output field coherence functions for nonlinear quantum systems.
A contextual cavity QED analogue of the Stern-Gerlach experiment is proposed in which continuous phase-sensitive detection of the cavity field drives spontaneous dressed-state polarization and persistent coherent-state superpositions.
Independent motionless two-level atoms emit thermal light statistics only when atom number and coherent-to-incoherent emission ratio meet specific conditions for each correlation order.
citing papers explorer
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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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Measurement-defined control of single-particle interference
Single-particle interference is governed by the relative phase between the prepared quantum state and the detector-defined measurement basis, with equivalent sinusoidal fringes produced by independent scans of pump, seed, or signal phases and visibility tuned by idler overlap.
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Ultrastrong Coupling Signatures in Photon Statistics from Terahertz Higgs-Polaritons
Two-photon coincidence statistics in terahertz light from a cavity-embedded 2H-NbSe2 superconductor provide a diagnostic for ultrastrong Higgs-polariton coupling that is missing in total photon counts.
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Photon counting readout for detection and inference of gravitational waves from neutron star merger remnants
Photon counting readout detects weak postmerger gravitational wave signals at a rate of about 1 in 100 for SNR 0.2 and yields a twofold improvement in neutron star radius measurement after 20,000 events.
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Path Integral Approach to Input-Output Theory
A Schwinger-Keldysh path integral formalism is developed for input-output theory, enabling computation of full output field coherence functions for nonlinear quantum systems.
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Operating a contextual Stern-Gerlach apparatus
A contextual cavity QED analogue of the Stern-Gerlach experiment is proposed in which continuous phase-sensitive detection of the cavity field drives spontaneous dressed-state polarization and persistent coherent-state superpositions.
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Deviations from thermal light statistics in ensembles of independent two-level emitters
Independent motionless two-level atoms emit thermal light statistics only when atom number and coherent-to-incoherent emission ratio meet specific conditions for each correlation order.
- Quantum Origin of Diffraction from Bright and Dark States