Aqueous solution | EPFL Graph Search

An aqueous solution is a solution in which the solvent is water. It is mostly shown in chemical equations by appending (aq) to the relevant chemical formula. For example, a solution of table salt, or sodium chloride (NaCl), in water would be represented as . The word aqueous (which comes from aqua) means pertaining to, related to, similar to, or dissolved in, water. As water is an excellent solvent and is also naturally abundant, it is a ubiquitous solvent in chemistry. Since water is frequently used as the solvent in experiments, the word solution refers to an aqueous solution, unless the solvent is specified. A non-aqueous solution is a solution in which the solvent is a liquid, but is not water. (See also Solvent and Inorganic nonaqueous solvent.) Characteristics Substances that are hydrophobic ('water-fearing') do not dissolve well in water, whereas those that are hydrophilic ('water-friendly') do. An example of a hydrophilic substance is sodium chloride. In an aqueo

Spectroscopy and dynamics at liquid water interfaces

Bruno Credidio

This thesis is a detailed description of three experimental investigations on aqueous interfaces. All projects made use of the microjet technology or the more recently developed flat-jet technique which enables the implementation of liquid water in vacuum chambers. In the first study presented here we show that a flat-jet created from the impingement of two liquid microjets generates a laminar turbulence-free water-water interface. By colliding a Luminol solution microjet with another microjet of hydrogen peroxide solution, the chemiluminescence of Luminol reveals where the liquids mix in the flat-jet. The liquids readily mix in the rims of the flat-jet, while in the middle part the different liquids only meet via diffusion. Flat-jets are stationary systems such that the longitudinal flow direction translates into a time dimension, providing access to the interface in different total interaction times ranging from 10 to 200 µs. This timescale is difficult to access by current techniques. The water-vacuum interface is the next topic, in which we have studied aqueous solutions using microjets and photoelectron spectroscopy (MJ-PES). For the first time, we have experimentally demonstrated the implementation of an absolute photoelectron energy reference in MJ-PES. We could show that there is a concentration-dependent shift of valence bands which were previously (without this absolute energy reference) undetectable. Even though this study was done using a tabletop He plasma light source, it creates the foundation of absolute energy referencing for MJ-PES works done in, e.g., synchrotron laboratories. Lastly, we have built an experimental apparatus to investigate the water-gas interface. Such interfaces are ubiquitous in nature but lack direct experimental works on the molecular scale, namely scattering studies. This is largely due to the technical difficulty imposed by the high vapour pressure of water. The dense layer of vapour shields the liquid surface in such a way that conventional molecular beams cannot travel to and from the liquid surface without interacting with the vapour phase, destroying the initial and final states required to understand the surface scattering event at the quantum level (transmission probability of ~e^(-100)). We propose an alternative method to this: by approaching the molecular beam source and the water flat-jet to a distance of 200 µm or less, the probability of scattering solely at the liquid surface becomes realistic. We have performed preliminary experiments using the developed apparatus.

EPFL2022

Solution behavior of peptide and peptide-hybrid materials

Harald Nuhn

Peptide based and peptide hybrid materials represent two interesting and challenging classes of biomaterials. Both classes consist of and contain, respectively, one or more polypeptide blocks, endowing the resulting polymers with enhanced self-assembly properties, biocompatibility or novel characteristics. Peptide based materials, solely comprised of amino acids, benefit from their advanced self-assembly properties. In the case of peptide hybrid materials, being conjugates of peptides and synthetic polymers, either the polypeptide or the synthetic polymer block can drive the self-assembly process. Furthermore, the latter class benefits from combining the advantages of peptides and synthetic polymers, thus overcoming limitations related to the use of the individual components. The application of these materials is still challenging because it is not possible to predict their final self-assembly behavior based on their design. In order to facilitate a target-oriented design of novel materials for application such as drug delivery, tissue engineering, or self-healing materials, a detailed understanding of the complex interactions within and between these molecules is essential. The work presented in this thesis addresses these fundamental questions. Over the last decades, a plethora of peptide and peptide hybrid materials has been reported. Chapter 1 gives an overview of selected articles describing different synthesis routes for peptide as well as peptide hybrid materials, showing examples of molecules and their self-assembly into superstructures, and highlighting recent applications. Chapter 2 describes the synthesis and characterization of different peptide hybrid diblock oligomers composed of two classes of peptide sequences covalently attached to a poly(ethylene glycol) (PEG) block. The first class of peptide sequences contains the intrinsic propensity to form coiled coils, whereas the second class is composed of "switch" peptides and is able to adopt both amphiphilic α-helical and β-strand conformations. Upon dissolution, the first class yielded superstructures comprised of dimeric and tetrameric coiled coil aggregates, whereas the second class formed fibrillar assemblies. In both cases, the self-assembly properties were driven by the peptide block, and the final superstructure consisted of a peptidic core wrapped by the synthetic polymer block. Chapter 3 presents a detailed study on the aqueous solution self-assembly of two poly(styrene)n-b-poly(L-lysine)m peptide hybrid oligomers. The aim was to clarify whether the observed rod-like micelles, obtained by direct dissolution of the diblock oligomers in aqueous solution, reflect intrinsic self-assembly properties of the hybrid diblock oligomers or whether they present structures that are energetically trapped due to the glassy nature of the polystyrene block. To address this question, the influence of a variety of sample preparation techniques, including the use of organic solvents, dialysis from an organic solvent and several thermal treatments, was investigated. All treatments resulted in solution aggregates that differed in size and shape from samples prepared by direct dissolution in aqueous solution. Thus, it seems likely that direct dissolution of polystyrene-b-poly(L-lysine) diblock oligomers in aqueous solution results in kinetically trapped, rod-like aggregates, which can be transformed into non-spherical micelles by the appropriate treatment. Chapter 4 contains a comprehensive study on peptide-based materials, investigating four different series of short elastin-like peptides (ELPs) based on the GVGVP motif. The objective was to test whether and how defined changes in the primary structure of short ELPs affect the secondary structure and the lower critical solution temperature (LCST) behavior. Therefore, the number of repeats was altered, and within one peptide of constant length, all valines were successively substituted by the more hydrophobic amino acids isoleucine, leucine and phenylalanine, respectively. In parallel, a theoretical approach based on the partition coefficient log P was used to predict the shift of the LCST as function of chain length and composition. For short ELPs, the LCST is strongly affected by changes in the primary structure. This has also been predicted by calculating log P. An increase in the hydrophobicity resulted in a shift of the LCST towards lower temperatures. Furthermore, it was shown for the first time that the sensitivity of short ELPs towards external factors, such as salt concentration, is determined by the intrinsic propensity of the incorporated amino acids to form either α-helices or β-strands. In summary, the obtained results on peptide based and peptide-hybrid materials provides deeper insights into their self-assembly characteristics and highlights the potential of these materials to be used for technical and medical applications.

EPFL2008

Supercritical water gasification of effluents from composted human excreta and recycling of the aqueous phases for microalgae cultivation

Dorian Tosi Robinson

Effluents from composted human excreta were sampled and characterized. Results show a constancy in the characteristics and nutrient content of these effluents. Then, these effluents were treated with supercritical water gasification, producing hydrogen rich gas (67-69%). Carbon efficiencies of 41-43% were achieved. Microalgae Chlorella vulgaris (CV) and Phaeodactylum tricornutum (Ph.t) cultivation were studied in the gasification aqueous phase (AP). No growth was observed in the raw AP even with adjusted pH. CV could grow in the activated carbon treated AP with similar results for cell concentration and pigment content, but with higher biomass production than in its control medium. Ph.t was unable to grow even in the treated AP. These results show promising development in recuperating energy and nutrients from effluents from composted human excreta, combining energy production, microalgae valorization and contributing to close the nutrient loop.