Quantum Optical Induced-Coherence Tomography by a Hybrid Interferometer
Abstract
Quantum interferometry based on induced-coherence phenomena has demonstrated the possibility of undetected-photon measurements. Perturbation in the optical path of probe photons can be detected by interference signals generated by quantum mechanically correlated twin photons propagating through a different path, possibly at a different wavelength. To the best of our knowledge, this work demonstrates for the first time a hybrid-type induced-coherence interferometer that incorporates a Mach-Zehnder-type interferometer for visible photons and a Michelson-type interferometer for infrared photons, based on double-pass pumped spontaneous parametric down-conversion. This configuration enables infrared optical measurements via the detection of near-visible photons and provides methods for characterizing the quality of measurements by identifying photon pairs of different origins. The results verify that the induced-coherence interference visibility is approximately the same as the heralding efficiencies between twin photons along the relevant spatial modes. Applications to both time-domain and frequency-domain quantum-optical induced-coherence tomography for three-dimensional test structures are demonstrated. The results prove the feasibility of practical undetected-photon sensing and imaging techniques based on the presented structure.
Cite
@article{arxiv.2309.06777,
title = {Quantum Optical Induced-Coherence Tomography by a Hybrid Interferometer},
author = {Eun Mi Kim and Sun Kyung Lee and Sang Min Lee and Myeong Soo Kang and Hee Su Park},
journal= {arXiv preprint arXiv:2309.06777},
year = {2023}
}