Deep
eutectic solvents (DESs) are lately expanding their use to
more demanding applications upon aqueous dilution thanks to the preservation
of the most appealing properties of the original DESs while overcoming
some of their most important drawbacks limiting their performance,
like viscosity. Both experimental and theoretical works have studied
this dilution regime, the so-called “water-in-DES” system,
at near-to stoichiometric amounts to the original DES. Herein, we
rather studied the high-dilution range of the “water-in-DES”
system looking for enhanced performance because of the interesting
properties (a further drop of viscosity) and cost (water is cheap)
that it offers. In particular, we found that, in the “water-in-DES”
system of a ternary DES composed of resorcinol, urea and choline chloride
(e.g., RUChClnW, where n represents mol of water
per mole of ternary DES), the tetrahedral structure of water
was distorted as a consequence of its incorporation, as an additional
hydrogen bond donor or hydrogen bond acceptor, into the hydrogen bond
complexes formed among the original DES components . DSC confirmed
the formation of a new eutectic, with a melting point below that of
its respective components, the original ternary DES and water. This
depression in the melting point was also observed in the same regime
of reline and malicine aqueous dilutions, thus suggesting the universality
of this simple procedure (i.e., water addition to reach the high-dilution
range of the “water-in-DES” system) to obtain deeper
eutectics eventually providing enhanced performances and lower cost.
Efficient separation and storage of gas streams involving light hydrocarbons is essential for industrial applications. These hydrocarbons are widely used as energy resources and/or chemical raw materials in various chemical reactions. Here, we focus on the separation of acetylene from methane and carbon dioxide. The separation of acetylene from carbon dioxide is, in particular, challenging due to the similar kinetic diameters and boiling points of the molecules. In recent years, considerable progress has been made in adsorption-based separations using porous metal−organic frameworks (MOFs). Most reported studies are experimental. We present a computational study on these gas separations using a variety of MOFs. This allows investigation of the competitive gas adsorption, which is experimentally challenging, as well as understanding the adsorption mechanisms at the molecular level, which in turn allows further experimental MOF design for this application. MOFs with open metal sites, and particularly Fe-MOF-74, seem to be good for this separation, with a trade-off between physical adsorption capacity and selectivity. Based on experimental single-adsorption isotherms at various temperatures, we developed and validated a specific parameterization to account for the interactions of the olefin with the open metal sites. In addition to volumetric and calorimetric adsorption, we comprehensively investigate the characteristics of the interaction between the MOFs and the guest molecules in terms of binding sites and density profiles. The overall agreement of our simulated results with experimental data for pure components points to the reliability of the models and methods to successfully predict the separation of mixtures.
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