Solvent contribution to the stability of a physical gel characterized by quasi-elastic neutron scattering

The dynamics of a physical gel, namely the Low Molecular Mass Organic Gelator {\textit Methyl-4,6-O-benzylidene-$\alpha$ -D-mannopyranoside ($\alpha$-manno)} in water and toluene are probed by neutron scattering. Using high gelator concentrations, we were able to determine, on a timescale from a few ps to 1 ns, the number of solvent molecules that are immobilised by the rigid network formed by the gelators. We found that only few toluene molecules per gelator participate to the network which is formed by hydrogen bonding between the gelators' sugar moieties. In water, however, the interactions leading to the gel formations are weaker, involving dipolar, hydrophobic or $\pi-\pi$ interactions and hydrogen bonds are formed between the gelators and the surrounding water. Therefore, around 10 to 14 water molecules per gelator are immobilised by the presence of the network. This study shows that neutron scattering can give valuable information about the behaviour of solvent confined in a molecular gel.Comment: Langmuir (2015

Drying affects the fiber network in low molecular weight hydrogels

Low molecular weight gels are formed by the self-assembly of a suitable small molecule gelator into a three-dimensional network of fibrous structures. The gel properties are determined by the fiber structures, the number and type of cross-links and the distribution of the fibers and cross-links in space. Probing these structures and cross-links is difficult. Many reports rely on microscopy of dried gels (xerogels), where the solvent is removed prior to imaging. The assumption is made that this has little effect on the structures, but it is not clear that this assumption is always (or ever) valid. Here, we use small angle neutron scattering (SANS) to probe low molecular weight hydrogels formed by the self-assembly of dipeptides. We compare scattering data for wet and dried gels, as well as following the drying process. We show that the assumption that drying does not affect the network is not always correct

Unravelling the secret of seedbased gels in water: the nanoscale 3D network formation

Chia (Salvia hispanica) and basil (Ocimum basilicum) seeds have the intrinsic ability to form a hydrogel concomitant with moisture-retention, slow releasing capability and proposed health benefits such as curbing diabetes and obesity by delaying digestion process. However, the underlying mode of gelation at nanoscopic level is not clearly explained or explored. The present study elucidates and corroborates the hypothesis that the gelling behavior of such seeds is due to their nanoscale 3D-network formation. The preliminary study revealed the influence of several conditions like polarity, pH and hydrophilicity/ hydrophobicity on fiber extrusion from the seeds which leads to gelation. Optical microscopic analysis clearly demonstrated bundles of fibers emanating from the seed coat while in contact with water, and live growth of fibers to form 3D network. Scanning electron microscope (SEM) and transmission electron microscope (TEM) studies confirmed 3D network formation with fiber diameters ranging from 20 to 50 nm

Enantioselective component selection in multicomponent supramolecular gels

We investigate a two-component acid-amine gelation system in which chirality plays a vital role. A carboxylic acid based on a second generation l-lysine dendron interacts with chiral amines and subsequently assembles into supramolecular gel fibers. The chirality of the amine controls the assembly of the resulting diastereomeric complexes, even if this chirality is relatively "poor quality". Importantly, the selective incorporation of one enantiomer of an amine over the other into the gel network has been demonstrated, with the R amine that forms complexes which assemble into the most stable gel being primarily selected for incorporation. Thermodynamic control has been proven by forming a gel exclusively with an S amine, allowing the R enantiomer to diffuse through the gel network, and displacing it from the "solidlike" fibers, demonstrating that these gels adapt and evolve in response to chemical stimuli to which they are exposed. Excess amine, which remains unincorporated within the solidlike gel fiber network, can diffuse out and be reacted with an isocyanate, allowing us to quantify the enantioselectivity of component selection but also demonstrating how gels can act as selective reservoirs of potential reagents, releasing them on demand to undergo further reactions; hence, component-selective gel assembly can be coupled with controlled reactivity

Surfactant Aggregation in Organic Solvents: Structural Features of some Physical Gel Networks Probed by Small Angle Neutron Scattering

We have studied viscoelastic gel-like systems constituted by surfactants in organic solvents. SANS appears to be efficient technique for investigating both the local and long-range structures of the related 3d networks. The basic equations are given for the scattering from the rod-like aggregates encountered in these phases. The aggregation reactions involve mechanisms specific of the surfactant used. A large variety of structural situations has been found. In each case, the polar heads of the surfactants form a polar inner core surrounded by hydrophobic shell constituted by the hydrocarbon chains. The typical mechanical properties of the samples are partly defined by the structure of the junctions in the network: transient entanglements and crystalline microdomains are the extreme cases found in these physical supermolecular organizations

Surfactant Aggregation in Organic Solvents: Structural Features of some Physical Gel Networks Probed by Small Angle Neutron Scattering

We have studied viscoelastic gel-like systems constituted by surfactants in organic solvents. SANS appears to be efficient technique for investigating both the local and long-range structures of the related 3d networks. The basic equations are given for the scattering from the rod-like aggregates encountered in these phases. The aggregation reactions involve mechanisms specific of the surfactant used. A large variety of structural situations has been found. In each case, the polar heads of the surfactants form a polar inner core surrounded by hydrophobic shell constituted by the hydrocarbon chains. The typical mechanical properties of the samples are partly defined by the structure of the junctions in the network: transient entanglements and crystalline microdomains are the extreme cases found in these physical supermolecular organizations

Scattering Techniques As Structural Investigation Tools of Colloidal Aggregates in Organic Media Techniques de diffusion / diffraction pour l'étude d'agrégats coloïdaux en milieu organique

International audienc