Soft lamellar solid foams from ice-templating of self-assembled lipid hydrogels: organization drives the mechanical properties
Ghazi Ben Messaoud (LIBio), Niki Baccile (LCMCP-SMiLES), Ghazi, Messaoud, Thomas Zinn (ESRF), Francisco Fernandes (LCMCP-MATBIO)

TL;DR
This study demonstrates that the internal organization of self-assembled lipid hydrogels critically influences the mechanical properties of ice-templated foams, with lamellar structures yielding soft, isotropic, sponge-like materials.
Contribution
It reveals that ice-templating can produce soft, mechanically resilient foams from physical gels, depending on their nanostructure, expanding applications of freeze-casting to soft matter.
Findings
Lamellar hydrogels produce soft, isotropic foams with Young's modulus of several kPa.
Fibrillar hydrogels result in brittle, anisotropic fibrous solids.
Structural organization determines the mechanical outcome after ice-templating.
Abstract
Ice-templating, also referred to as freeze-casting, is a process exploiting unidirectional crystallization of ice to structure macroporous materials from colloidal solutions. Commonly applied to inorganic and polymeric materials, we employ it here to cast soft self-assembled matter into spongy solid foams. Use of ice-templating to cast soft matter is generally confined to polymers. In the case of polymeric hydrogels, cross-linking ensures a good stability towards the harsh conditions (fast cooling at temperatures as low as-80{\textdegree}C) employed during ice-templating. However, freeze-casting of soft systems held together by weak interactions, like in physical gels, has not been explored, because the nonequilibrium conditions could easily disrupt the nano and macroscale organization of self-assembled matter, resulting in a cruel loss of mechanical properties. Whether this is a…
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