posted on 2015-07-28, 00:00authored byNadia Ziane, Jean-Baptiste Salmon
We investigate the dynamics of solidification
of a charged colloidal
dispersion using an original microfluidic technique referred to as
micropervaporation. This technique exploits pervaporation within a
microfluidic channel to extract the solvent of a dilute colloidal
dispersion. Pervaporation concentrates the colloids in a controlled
way up to the tip of the channel until a wet solid made of closely
packed colloids grows and invades the microfluidic channel. For the
charged dispersion under study, we however evidence a liquid to solid
transition (LST) preceding the formation of the solid, owing to the
presence of long-range electrostatic interactions. This LST is associated
with the nucleation and growth of domains confined in the channel.
These domains are then compacted anisotropically up to forming a wet
solid of closely packed colloids. This solid then invades the whole
channel as in directional drying with a growth rate which depends
on the microfluidic geometry. In the final steps of the solidification,
we observed the occurrence of cracks and shear bands, the delamination
of the wet solid from the channel walls, and its invasion by a receding
air front. Interestingly, this air front follows specific patterns
within the solid which reveal different microscopic colloidal organizations.