English

Entangled-photon time- and frequency-resolved optical spectroscopy

Quantum Physics 2025-05-07 v1 Optics

Abstract

Classical time-resolved optical spectroscopy experiments are performed using sequences of ultrashort light pulses, with photon fluxes incident on the sample which are many orders of magnitude higher than real-world conditions corresponding to sunlight illumination. Here we overcome this paradigm by exploiting quantum correlations to perform time-resolved spectroscopy with entangled photons. Starting from spontaneous parametric down-conversion driven by a continuous-wave laser, we exploit the temporal entanglement between randomly generated signal/idler pairs to obtain temporal resolution, and their spectral entanglement to select the excitation frequency. We also add spectral resolution in detection, using a Fourier transform approach which employs a common-path interferometer. We demonstrate the potential of our entangled-photon streak camera by resolving, at the single-photon level, excitation energy transfer cascades from LH2 to LH1 in the photosynthetic membrane and disentangling the lifetimes of two dyes in a mixture. We show that time-resolved spectroscopy with quantum light can be performed without compromising measurement time, recording a fluorescence time trace in less than a minute even for samples with low quantum yield, which can be reduced to sub-second times with acceptable signal-to-noise ratio. Our results provide a new approach to ultrafast optical spectroscopy, where experiments are performed under conditions comparable to real-world sunlight illumination.

Keywords

Cite

@article{arxiv.2505.02940,
  title  = {Entangled-photon time- and frequency-resolved optical spectroscopy},
  author = {Raul Alvarez-Mendoza and Lorenzo Uboldi and Ashley Lyons and Richard Cogdell and Giulio Cerullo and Daniele Faccio},
  journal= {arXiv preprint arXiv:2505.02940},
  year   = {2025}
}
R2 v1 2026-06-28T23:21:58.950Z