Achieving two-dimensional optical spectroscopy with temporal and spectral resolution using quantum entangled three photons

• Published in: The Journal of chemical physics Vol. 155; no. 4; pp. 044101 - 44113
• Main Authors: Fujihashi, Yuta, Ishizaki, Akihito
• Format: Journal Article
• Language: English
• Published: Melville American Institute of Physics 28.07.2021
• Subjects: Counting; Dispersion; Electron states; Excitation spectra; Frequency filters; Investigations; Phase matching; Photons; Quantum entanglement; Selectivity; Sensitivity enhancement; Spectral resolution; Spectroscopic analysis; Spectrum analysis; Time measurement
• ISSN: 0021-9606; 1089-7690; 1089-7690
• DOI: 10.1063/5.0056808

Recent advances in techniques for generating quantum light have stimulated research on novel spectroscopic measurements using quantum entangled photons. One such spectroscopy technique utilizes non-classical correlations among entangled photons to enable measurements with enhanced sensitivity and selectivity. Here, we investigate the spectroscopic measurement utilizing entangled three photons. In this measurement, time-resolved entangled photon spectroscopy with monochromatic pumping [A. Ishizaki, J. Chem. Phys. 153, 051102 (2020)] is integrated with the frequency-dispersed two-photon counting technique, which suppresses undesired accidental photon counts in the detector and thus allows one to separate the weak desired signal. This time-resolved frequency-dispersed two-photon counting signal, which is a function of two frequencies, is shown to provide the same information as that of coherent two-dimensional optical spectra. The spectral distribution of the phase-matching function works as a frequency filter to selectively resolve a specific region of the two-dimensional spectra, whereas the excited-state dynamics under investigation are temporally resolved in the time region longer than the entanglement time. The signal is not subject to Fourier limitations on the joint temporal and spectral resolution, and therefore, it is expected to be useful for investigating complex molecular systems in which multiple electronic states are present within a narrow energy range.