34 research outputs found
Metal interchange of crown ether-alkali metal cation complexes in solution. 7Li nuclear magnetic resonance study of the exchange kinetics of lithium 15-crown-5 and lithium monobenzo-15-crown-5 in nitromethane
Peer reviewed: YesNRC publication: Ye
Adsorption of indole on kaolinite in nonaqueous media: Organoclay preparation and characterization, and 3D-RISM-KH molecular theory of solvation investigation
Current oil sand mining operations in the Athabasca basin are predominantly aqueous-based. Extracts containing large amounts of fines lead to the formation of stable organoclay suspensions in froths giving lower yields and greater tailing wastes and making the development of more efficient extraction methods desirable from both economical and environmental perspectives. We examine an indole-kaolinite system as a model for these oil fines and their resistance to washing in nonaqueous solvents. The prepared organoclays show indole loading exclusively on the external surface of the clay. Micron-scaled vermicular structures, similar to natural kaolinite, are observed. Their formation is believed to be driven by strong adsorbate-adsorbate interactions. Indole is the primary adsorbate, as solvent adsorption is shown to be minimal based on both experimental and computational results. Isotherms are constructed and parameters calculated from linear regression analysis fitted to the Brunauer-Emmett-Teller equation. Monolayer quantities calculated match well to the theoretical amount calculated from surface areas measurements. Washing the organoclays with both toluene and isopropanol results in a 50% decrease of loaded organic material, leaving a monolayer equivalent of organic matter. The statistical-mechanical 3D-RISM-KH molecular theory of solvation is employed to perform full sampling of solvent orientations around a kaolinite platelet and gain insights into the preferred orientation and adsorption thermodynamics of indole on kaolinite in toluene and heptane solvents. In its preferred orientation, indole is hydrogen-bonded to one or two O atoms at the aluminum hydroxide surface of kaolinite. The calculated solvation free energy and potential of mean force for adsorption of indole and solvents on kaolinite in solution yield the increasing adsorption strength order of heptane < toluene < indole on the aluminum hydroxide surface. Multilayer adsorption profiles are predicted based on the integrated three-dimensional distribution functions of indole, toluene, and heptane. \ua9 2013 American Chemical Society.Peer reviewed: YesNRC publication: Ye
Molecular Dynamics Simulation of Water-Based Fracturing Fluids in Kaolinite Slit Pores
The
adsorption behavior inside kaolinite mesopores of aqueous solutions
of various salts and additives is investigated using Molecular Dynamics
simulations. In particular, we examine the various combinations of
water + salt, water + additive, and water + salt + additive mixtures,
where the salts are NaCl, CsCl, SrCl<sub>2</sub>, and RaCl<sub>2</sub> and the additives are methanol and citric acid. Citric acid is modeled
in two forms, namely, fully protonated (H<sub>3</sub>A) and fully
deprotonated (A<sup>3–</sup>), the latter being prevalent in
neutral pH conditions, in accordance with the kaolinite structure
employed. The force fields used for the individual system components
include CLAYFF for the kaolinite mesopores, SPC/E for water, parameters
optimized for the SPC/E water model based on hydration free energies
(HFE) for ions, and general Amber force field (GAFF) for the additives.
The spatial distributions along the kaolinite pore are delineated
and reveal the preferential adsorption behavior of the various species
with respect to the gibbsite and siloxane surface, as well as the
effect on this behavior of the interactions between the various species.
Furthermore, we examine the hydrogen bonds formed between the kaolinite
surfaces and water molecules as well as the additives. For the case
of citric acid, which tends to aggregate, a cluster analysis is also
carried out, in order to examine the effect of the various ions on
the cluster formation. Finally, through the calculation of lateral
diffusion coefficients and mean residence times, we provide insights
on the mobility of the various species inside the kaolinite mesopores