Collapse and cavitation during drying of water-saturated PDMS sponges with closed porosity

TL;DR

This study investigates how pore size influences collapse and cavitation during drying of water-saturated PDMS sponges with closed porosity, revealing size-dependent behaviors and cooperative effects.

Contribution

It provides the first experimental evidence of pore-size-dependent and cooperative drying responses in soft closed-porosity sponges.

Findings

Pores smaller than 30 μm mostly remain collapsed due to low cavitation probability.

Pores larger than 100 μm tend to reopen after cavitation.

Cavitation in large pores can induce reopening of neighboring small pores.

Abstract

In this paper, we study the drying of water-saturated porous polydimethylsiloxane (PDMS) elastomers with closed porosity in which the evaporation of water is possible only via the diffusion across the PDMS. Starting from water/PDMS emulsions, we fabricate soft macroporous samples with different pore diameter distributions and average diameters ranging from 10 to 300 $\mu$m. In these materials, the drying may lead either to a collapsed state with low porosity or to the cavitation and reopening of a fraction of the pores. Using optical microscopy and porosity measurements, we showed the importance of the pore diameters and interactions on the result of drying. At pore diameters lower than 30 $\mu$m, the majority of pores remain collapsed. We attribute the permanence of the collapse of most small pores to a low probability of cavitation and to the adhesion of the pore walls. Pores with diameters larger than 100 $\mu$m tend to reopen after the water they contain cavitates. The behavior of pores with diameters ranging from 30 to 100 $\mu$m depends on the porosity and drying temperature. We also visualize collective cavitation upon drying of sponges initially saturated with a sodium chloride solution. In this case, the cavitation in the largest pores leads to reopening of small pores in a neighboring zone of the sample. To our knowledge, our results present the first experimental proof of the pore-size-dependent and cooperative nature of the response of soft sponges with closed porosity to drying.