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Observation of second-order interference beyond the coherence time with true thermal photons

Gyu-Hyeok Lee, Dong-Gil Im, Yosep Kim, U-Shin Kim, Yoon-Ho Kim

2020Optics Letters12 citationsDOI

Abstract

It has recently been shown that counter-intuitive Franson-like second-order interference can be observed with a pair of classically correlated pseudo thermal light beams and two separate unbalanced interferometers (UIs): the second-order interference visibility remains fixed at 1/3 even though the path length difference in each UI is increased significantly beyond the coherence length of the pseudo thermal light [Phys. Rev. Lett.119, 223603 (2017)PRLTAO0031-900710.1103/PhysRevLett.119.223603]. However, as the pseudo thermal beam itself originated from a long-coherence laser (and by using a rotating ground disk), there exists the possibility of a classical theoretical model to account for second-order interference beyond the coherence time on the long coherence time of the original laser beam. In this work, we experimentally explore this counter-intuitive phenomenon with a true thermal photon source generated via quantum thermalization, i.e., obtaining a mixed state from a pure two-photon entangled state. This experiment not only demonstrates the unique second-order coherence properties of thermal light clearly but may also open up remote sensing applications based on such effects.

Topics & Concepts

Coherence (philosophical gambling strategy)PhysicsOpticsCoherence timePhotonCoherence lengthThermalCoherence theoryInterferometryAstronomical interferometerInterference (communication)Optical path lengthGhost imagingLaserQuantumLight beamQuantum mechanicsTelecommunicationsMeteorologyComputer scienceChannel (broadcasting)SuperconductivityRandom lasers and scattering mediaQuantum Information and CryptographyOrbital Angular Momentum in Optics
Observation of second-order interference beyond the coherence time with true thermal photons | Litcius