Quantum Imaging of Birefringent Samples using Hong-Ou-Mandel Interference

TL;DR

This paper presents a quantum imaging technique using Hong-Ou-Mandel interference with a narrowband photon source to quantitatively image birefringent samples, overcoming previous thickness sensitivity limitations.

Contribution

It introduces a polarization microscopy method leveraging a long-coherence photon source to enable thickness-insensitive, quantum-based birefringence imaging with high precision.

Findings

Validated the method with experimental results matching classical images

Achieved operation in a maximum-precision regime

Demonstrated insensitivity to layer thickness variations

Abstract

Two-photon interference in a Hong-Ou-Mandel (HOM) interferometer can be used as a quantum sensing mechanism due to the sensitivity of the interference dip to perturbations of the photon indistinguishability. In particular, recent works have generalized this concept to microscopy setups, but the sensitivity to optical path differences constrains its application to samples with thickness variation typically below a few micrometers if tracking changes in the coincidences at a fixed delay. Extending the concept to polarization microscopy and circumventing this limitation, this manuscript explores the use of a narrowband photon pair source with coherence length >1 mm to broaden the HOM dip. Thus, realistic sample-thickness variations introduce negligible temporal distinguishability, and changes in coincidence rate at the dip centre are then dominated by sample-induced polarization effects. To compute the polarization rotation, we develop a statistical model for the interferometer, derive the Fisher information, and establish a maximum-likelihood estimator for the local fast-axis angle. Recording dip and baseline frames at each sample position via raster scanning, the experimental results validate the framework, agreeing with classical polarized-intensity images while demonstrating operation at a maximum-precision regime and insensitiveness to layer thickness. Overall, the approach enclosed provides a quantum-based quantitative imaging of birefringent structures, which can motivate further advantageous applications, including enhanced signal-to-noise ratio and lower damage imaging of photosensitive samples.