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Originally published in Optica on 20 April 2015 (optica-2-4-343

Visualization 1.mp4

Visualizations of evaporating water drop over one hou

Visualization 1: White-light quantitative phase imaging unit

Supplementary Video 1 Originally published in Optics Express on 02 May 2016 (oe-24-9-9308

Media 2: Real-time visualization of 3-D dynamic microscopic objects using optical diffraction tomography

Originally published in Optics Express on 30 December 2013 (oe-21-26-32269

Supplementary document for Single-shot refractive index slice imaging using spectrally multiplexed optical transfer function reshaping - 6318598.pdf

Supplement Informatio

La Petite presse : journal quotidien... / [rédacteur en chef : Balathier Bragelonne]

05 janvier 18801880/01/05 (A14,N4990)

Media 1: Polarization holographic microscopy for extracting spatio-temporally resolved Jones matrix

Originally published in Optics Express on 23 April 2012 (oe-20-9-9948

Contribution a l'etude de la cristallisation orientee : application aux alliages Cu-Be riches en Cu

SIGLECNRS T Bordereau / INIST-CNRS - Institut de l'Information Scientifique et TechniqueFRFranc

Source Code: Beyond Born-Rytov limit for super-resolution optical diffraction tomography

<p>This is the source code for the joint sparsity deriven image reconstruction algorithm for optical diffraction tomography used in the article "Beyond Born-Rytov limit for super-resolution optical diffraction tomography"</p

High-precision and low-noise dielectric tensor tomography using a micro-electromechanical system mirror

Dielectric tensor tomography is an imaging technique for mapping three-dimensional distributions of dielectric properties in transparent materials. This work introduces an enhanced illumination strategy employing a micro-electromechanical system mirror to achieve high precision and reduced noise in imaging. This illumination approach allows for precise manipulation of light, significantly improving the accuracy of angle control and minimizing diffraction noise compared to traditional beam steering approaches. Our experiments have successfully reconstructed the dielectric properties of liquid crystal droplets, which are known for their anisotropic structures, while demonstrating a notable reduction in background noise of the imag-es. Additionally, the technique has been applied to more complex samples, revealing its capability to achieve a high signal-to-noise ratio. This development represents a significant step forward in the field of birefringence imaging, offering a powerful tool for detailed study of materials with anisotropic properties