160 research outputs found
Ab initio quantum mechanical simulations confirm the formation of all postulated species in ionic dissociation
A single sodium chloride molecule in aqueous solution was simulated by the ab initio quantum mechanical charge field-molecular dynamics (QMCF-MD) approach. During a series of simulations the solvated molecule (CIP), dissociated solvated ions and - most noticeably - a solvent separated ion pair (SSIP) were observed and the structural and dynamical characteristics of these systems were investigated. In addition to a detailed structural analysis of the observed species, vibrational spectra and charge distributions were calculated to elucidate the mechanism of the NaCl dissociation
Is the Hexacyanoferrate(II) Anion Stable in Aqueous Solution? A Combined Theoretical and Experimental Study
A combined theoretical and experimental study was performed to elucidate the structural and dynamical properties of the isolated aqueous hexacyanoferrate(II) ion as well as in the presence of potassium counterions. It is shown that in absence of counterions, the highly negatively charged hexacyanoferrate(II) complex is not stable in aqueous solution. However, if the high negative charge is compensated by potassium counterions, a stable complex is observed, which is proven by theoretical simulations as well as by extended X-ray absorption fine structure (EXAFS) experiments. From the simulation it is found that potassium ions surrounding the complex are highly mobile and thus cannot be observed via EXAFS experiments. The structure of aqueous hexacyanoferrate(II) in the presence of potassium ions is identical to that of the solid-state structure, but the mobility of potassium ions is significantly increased in the liquid. These highly mobile potassium ions circulating the complex are the reason for the very short lifetime of hydrogen bonds between solvent water molecules and cyanide ligands being on the femtosecond scale
Selective Adsorption and Chiral Amplification of Amino Acids in Vermiculite Clay -Implications for the origin of biochirality
Smectite clays are hydrated layer silicates that, like micas, occur naturally
in abundance. Importantly, they have readily modifiable interlayer spaces that
provide excellent sites for nanochemistry. Vermiculite is one such smectite
clay and in the presence of small chain-length alkyl-NH3Cl ions, forms
sensitive, 1-D ordered model clay systems with expandable nano-pore inter-layer
regions. These inter-layers readily adsorb organic molecules. N-propyl NH3Cl
vermiculite clay gels were used to determine the adsorption of alanine, lysine
and histidine by chiral HPLC. The results show that during reaction with fresh
vermiculite interlayers, significant chiral enrichment of either L- and
D-enantiomers occurs depending on the amino acid. Chiral enrichment of the
supernatant solutions is up to about 1% per pass. In contrast, addition to clay
interlayers already reacted with amino acid solutions resulted in little or no
change in D/L ratio during the time of the experiment. Adsorption of small
amounts of amphiphilic organic molecules in clay inter-layers is known to
produce Layer-by-Layer or Langmuir-Blodgett films. Moreover atomistic
simulations show that self-organization of organic species in clay interlayers
is important. These non-centrosymmetric, chirally active nanofilms may cause
clays to act subsequently as chiral amplifiers, concentrating organic material
from dilute solution and having different adsorption energetics for D- and
L-enantiomers. The additional role of clays in RNA oligimerization already
postulated by Ferris and others, together with the need for the organization of
amphiphilic molecules and lipids noted by Szostak and others, suggests that
such chiral separation by clays in lagoonal environments at normal biological
temperatures might also have played a significant role in the origin of
biochirality.Comment: 17 Pages, 2 Figures, 4 Table
Effect of metal Ions (Ni2+, Cu2+ and Zn2+) and water coordination on the structure of L-phenylalanine, L-tyrosine, L-tryptophan and their zwitterionic forms
Methods of quantum chemistry have been applied to double-charged complexes involving the transition metals Ni2+, Cu2+ and Zn2+ with the aromatic amino acids (AAA) phenylalanine, tyrosine and tryptophan. The effect of hydration on the relative stability and geometry of the individual species studied has been evaluated within the supermolecule approach. The interaction enthalpies, entropies and Gibbs energies of nine complexes Phe•M, Tyr•M, Trp•M, (M = Ni2+, Cu2+ and Zn2+) were determined at the Becke3LYP density functional level of theory. Of the transition metals studied the bivalent copper cation forms the strongest complexes with AAAs. For Ni2+and Cu2+ the most stable species are the NO coordinated cations in the AAA metal complexes, Zn2+cation prefers a binding to the aromatic part of the AAA (complex II). Some complexes energetically unfavored in the gas-phase are stabilized upon microsolvation
Structure and dynamics of hydrated ions-new insights throuth quantum mechanical simulations
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