Size distribution of migrating particles and droplets under gravity in concentrated dispersions measured with static multiple light scattering.

Hypothesis: Light scattering techniques can provide a non-intrusive measurement of particle and droplet size distribution but are limited to relatively diluted liquid dispersions. Measurement of particle velocity distributions (PVD) and particle/droplet size distributions (PSD) in diluted to highly concentrated solid suspensions and emulsions can be performed by coupling the static multiple light scattering technique (SMLS) to mathematical models describing the vertical motion under gravity of polydisperse particles and droplets.

Experiments: Measurement of the PSD using SMLS was performed on silica particles dispersed in water with monomodal, bimodal and trimodal PSDs ranging from 570 nm and 7.

Simultaneous screening of the stability and dosimetry of nanoparticles dispersions for in vitro toxicological studies with static multiple light scattering technique.

To evaluate the nanoparticle (NP) toxicity, much efforts have been devoted for developing methods to accurately disperse NPs into aqueous suspensions prior to in vitro toxicological studies. As NP toxicity is strongly dependent on their physicochemical properties, NP characterization is a key step for any in vitro toxicological study. This study demonstrates that the static multiple light scattering (SMLS) technique allows for the simultaneous screening of the NP size, agglomeration state, stability and dosimetry in biological media.

Bubbles, drops, and solid particles recognition from real or virtual photonic jets reconstructed by digital in-line holography.

The image of the photonic jet (also called caustic) formed by a large, transparent, and spherical particle, reconstructed by digital in-line holography, is shown to be similar to the Airy pattern observed at the focus of a diffraction-limited lens. The analysis of this image, real or virtual depending on whether the particle relative refractive index is above or below one, allows characterizing the particle composition via its refractive index. Experiments clearly demonstrate the value of this method for the simultaneous 3D characterization and differentiation of the dynamics, size, and composition of gas, liquid, and solid particles in multiphase flows.

Droplet sizing and mixture fraction measurement in liquid-liquid flows with rainbow-angle diffractometry.

The capabilities and resolution of the rainbow technique were extended to estimate the size distribution and composition of droplets in liquid-liquid systems. For these droplets, essentially characterized by a low relative refractive index (m≈1.001-1.

Photonic jet reconstruction for particle refractive index measurement by digital in-line holography.

A new and computationally efficient approach is proposed for determining the refractive index of spherical and transparent particles, in addition to their size and 3D position, using digital in-line holography. The method is based on the localization of the maximum intensity position of the photonic jet with respect to the particle center retrieved from the back propagation of recorded holograms. Rigorous electromagnetic calculations and experimental results demonstrate that for liquid-liquid systems and droplets with a radius > 30µm, a refractive index measurement with a resolution inferior to 4 × 10 is achievable, revealing a significant potential for the use of this method to investigate multiphase flows.