Litcius/Paper detail

Pathway selectivity in time-resolved spectroscopy using two-photon coincidence counting with quantum entangled photons

Yuta Fujihashi, Akihito Ishizaki, Ryōsuke Shimizu

2024The Journal of Chemical Physics13 citationsDOI

Abstract

Ultrafast optical spectroscopy is a powerful technique for studying the dynamic processes of molecular systems in condensed phases. However, in molecular systems containing many dye molecules, the spectra can become crowded and difficult to interpret owing to the presence of multiple nonlinear optical contributions. In this work, we theoretically propose time-resolved spectroscopy based on the coincidence counting of two entangled photons generated via parametric down-conversion with a monochromatic laser. We demonstrate that the use of two-photon counting detection of entangled photon pairs enables the selective elimination of the excited-state absorption signal. This selective elimination cannot be realized with classical coherent light. We anticipate that the proposed spectroscopy will help simplify the spectral interpretation of complex molecular and material systems comprising multiple molecules.

Topics & Concepts

SpectroscopyPhotonCoincidencePhoton countingUltrashort pulseCoherent spectroscopyPhysicsPhoton entanglementCoincidence countingTime-resolved spectroscopyExcited stateQuantum opticsOpticsQuantumLaserAtomic physicsQuantum mechanicsQuantum entanglementCoherent anti-Stokes Raman spectroscopyRaman scatteringMedicineAlternative medicineRaman spectroscopyPathologySpectroscopy and Quantum Chemical StudiesLaser-Matter Interactions and ApplicationsSpectroscopy and Laser Applications