Abstract
The saponin escin, extracted from horse chestnut seeds, forms adsorption layers with high viscoelasticity and low gas permeability. Upon deformation, escin adsorption layers often feature surface wrinkles with characteristic wavelength. In previous studies, we investigated the origin of this behavior and found that the substantial surface elasticity of escin layers may be related to a specific combination of short-, medium-, and long-range attractive forces, leading to tight molecular packing in the layers. In the current study, we performed atomistic molecular dynamics simulations of 441 escin molecules in a dense adsorption layer with an area per molecule of 0.49 nm2. We found that the surfactant molecules are less submerged in water and adopt a more upright position when compared to the characteristics determined in our previous simulations with much smaller molecular models. The number of neighbouring molecules and their local orientation, however, remain similar in the different-size models. To maintain their preferred mutual orientation, the escin molecules segregate into well-ordered domains and spontaneously form wrinkled layers. The same specific interactions (H-bonds, dipole–dipole attraction, and intermediate strong attraction) define the complex internal structure and the undulations of the layers. The analysis of the layer properties reveals a characteristic wrinkle wavelength related to the surface lateral dimensions, in qualitative agreement with the phenomenological description of thin elastic sheets.
Highlights
It is known that certain classes of surface-active species may form highly viscoelastic adsorption layers [1,2]
The rheological properties of the adsorption layers formed from such substances have been extensively studied both at the air–water and oil–water interfaces
The results showed that the molecules in the dense adsorption layers are less submerged in water and adopt a more upright position, as compared to the dilute layers
Summary
It is known that certain classes of surface-active species may form highly viscoelastic adsorption layers [1,2]. The authors observed the formation of wrinkles on the water surface which reflect the unusual viscoelastic properties of such highly elastic layers. These wrinkles indicate very low surface tension upon surface compression, leading to spontaneous buckling of the adsorption layer. The high elasticity of the neutral escin layers was attributed to the combination of several complementary attractiveforces, including one rather specific interaction, intermediate in strength between the classical hydrogen bonds and the dipole–dipole interactions, acting between the hydroxyl groups in the sugar residues in the escin molecules The modelling in this first work, was made with dilute adsorption layers (low surface coverage). A relationship between the molecular behaviour and the experimentally determined rheological characteristics of the escin layers is proposed and discussed
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