# Interaction of multiple particles with a solidification front : from   compacted particle layer to particle trapping

**Authors:** Brice Saint-Michel, Marc Georgelin, Sylvain Deville, Alain Pocheau

arXiv: 1702.04581 · 2017-02-16

## TL;DR

This study experimentally investigates how multiple particles interact with a solidification front, revealing the formation of a particle layer and quantifying forces affecting particle trapping, advancing understanding of complex solidification processes.

## Contribution

It extends single particle models to multiple particles, accounting for viscous forces and thermomolecular pressures, providing new insights into particle-front interactions during solidification.

## Key findings

- Formation of a particle layer at close-packing volume fraction
- Increase in thermomolecular pressure due to multiple particles
- Reduction of liquid film thickness with increased solidification velocity

## Abstract

The interaction of solidification fronts with objects such as particles, droplets, cells, or bubbles is a phenomenon with many natural and technological occurrences. For an object facing the front, it may yield various fates, from trapping to rejection, with large implications regarding the solidification pattern. However, whereas most situations involve multiple particles interacting with each other and the front, attention has focused almost exclusively on the interaction of a single, isolated object with the front. Here we address experimentally the interaction of multiple particles with a solidification front by performing solidification experiments of a monodisperse particle suspension in a Hele-Shaw cell, with precise control of growth conditions and real-time visualization. We evidence the growth of a particle layer ahead of the front at a close-packing volume fraction and we document its steady state value at various solidification velocities. We then extend single particle models to the situation of multiple particles by taking into account the additional force induced on an entering particle by viscous friction in the compacted particle layer. By a force balance model, this provides an indirect measure of the repelling mean thermomolecular pressure over a particle entering the front. The presence of multiple particles is found to increase it following a reduction of the thickness of the thin liquid film that separates particles and front. We anticipate the findings reported here to provide a relevant basis to understand many complex solidification situations in geophysics, engineering, biology, or food engineering, where multiple objects interact with the front and control the resulting solidification patterns.

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/1702.04581/full.md

## References

49 references — full list in the complete paper: https://tomesphere.com/paper/1702.04581/full.md

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Source: https://tomesphere.com/paper/1702.04581