Wavelength and Polarization Multiplexed Nonlocal Metasurface for Quantitative Phase Microscopy

TL;DR

This paper introduces a wavelength and polarization multiplexed nonlocal metasurface that enables single-shot, low-noise quantitative phase imaging of transparent samples, offering a compact and efficient tool for biological and material analysis.

Contribution

The work demonstrates a novel metasurface design capable of capturing differential phase contrast images at multiple wavelengths and polarizations in a single shot, facilitating quantitative phase measurement.

Findings

Accurate phase recovery of optical fields matches specified values.

High-quality differential phase contrast images of unstained cells obtained.

Potential for compact, next-generation imaging systems demonstrated.

Abstract

Imaging transparent samples remains an ongoing challenge in the study of unstained biological cells and material samples. Widely used methods trade off system complexity, cost and bulk, computational efficiency and information content. Here we demonstrate the use of a nonlocal metasurface located in the object plane for obtaining single-shot, low-noise differential phase contrast images visualising phase gradients along orthogonal directions in a sample obtained at wavelengths of 613 nm and 656 nm. Furthermore, we show that these images are sufficient to calculate the quantitative phase introduced into the transmitted optical field by the sample. We find that the recovered phase of an optical field generated by a spatial light modulator is in good agreement with specified values. We also present information-rich differential phase contrast images of unstained HeLa cells with the recovered phase excursion values consistent with the literature. Our results demonstrate the potential for metasurfaces as a platform for extracting information from an optical field for use in next-generation compact imaging systems with applications in medical diagnostics, biotechnology, and materials science.