Partition solvent effects

Table 11. Solvent Effects on Solvent-Water Partition Coefficients (P) [49]...

In this respect, the solvatochromic approach developed by Kamlet, Taft and coworkers38 which defines four parameters n. a, ji and <5 (with the addition of others when the need arose), to evaluate the different solvent effects, was highly successful in describing the solvent effects on the rates of reactions, as well as in NMR chemical shifts, IR, UV and fluorescence spectra, sol vent-water partition coefficients etc.38. In addition to the polarity/polarizability of the solvent, measured by the solvatochromic parameter ir, the aptitude to donate a hydrogen atom to form a hydrogen bond, measured by a, or its tendency to provide a pair of electrons to such a bond, /, and the cavity effect (or Hildebrand solubility parameter), S, are integrated in a multi-parametric equation to rationalize the solvent effects. 

Kumbar, S.G., Kulkarni, A.R., Dave, A.M., and Aminabhavi, T.M. An assessment of solubility profiles of structurally similar hazardous pesticide in water + methanol mixture and co-solvent effect on partition coefficient, J. Haz. Mater., 89 (2-3) 233-239, 2002. 

In spite of the preceding observation that eluite retention in RPC with hydrocarbonaceous bonded phases may not occur by partitio ng of the eluite between two liquid phases, theoretical considerations based on the solvophobic treatment of solvent effects shows that it might be possible to relate the observed retention factors to partition coefficients between water and an organic solverit. Such a relationship would be quite useful in light of the scale developed by Hansch and his co-workers (2/12, 283) to characterize hydrophobic properties of drugs and other biologically active... 

Table 1.10 Solvent effects on solvent-water partition ...

To illustrate this a model transesterification reaction catalyzed by subtilisin Carls-berg suspended in carbon dioxide, propane, and mixtures of these solvents under pressure has been studied (Decarvalho et al., 1996). To account for solvent effects due to differences in water partitioning between the enzyme and the bulk solvents. Water sorption isotherms were measured for the enzyme in each solvent. Catalytic activity as a function of enzyme hydration was measured, and bell-shaped curves with maxima at the same enzyme hydration (12%) in all the solvents were obtained. The activity maxima were different in all media, being much higher in propane than in either CO2 or the mixtures with 50 and 10% CO2. Considerations based on the solvation ability of the solvents did not offer an explanation for the differences in catalytic activity observed. The results suggest that CO2 has a direct adverse effect on the catalytic activity of subtilisin. 

Partitioning between water and water-immiscible organic solvents is thus a straightforward way to get quantitative data for predicting solvent effects on the conversion of a certain substrate. However, the method is not applicable to water-miscible solvents. An alternative way to quantify solvation is to carry out theoretical calculation of interactions between the various components in the reaction mixture. 

In view of the predictive properties of the octanol-water partition coefficient, logP, in the description of enzymatic activity [79], this parameter has received much attention. However, as argued in an early but still authoritative review compiled by Carrea and coworkers [80], its usefulness in the correlation of solvent effects on enantioselectivity appears to be limited. The problem is exemplified by the entries in Figure... 

In our discussion the usual Born-Oppenheimer (BO) approximation will be employed. This means that we assume a standard partition of the effective Hamiltonian into an electronic and a nuclear part, as well as the factorization of the solute wavefunction into an electronic and a nuclear component. As will be clear soon, the corresponding electronic problem is the main source of specificities of QM continuum models, due to the nonlinearity of the effective electronic Hamiltonian of the solute. The QM nuclear problem, whose solution gives information on solvent effects on the nuclear structure (geometry) and properties, has less specific aspects, with respect the case of the isolated molecules. In fact, once the proper potential energy surfaces are obtained from the solution of the electronic problem, such a problem can be solved using the standard methods and approximations (mechanical harmonicity, and anharmonicity of various order) used for isolated molecules. The QM nuclear problem is mainly connected with the vibrational properties of the nuclei and the corresponding spectroscopic observables, and it will be considered in more detail in the contributions in the book dedicated to the vibrational spectroscopies (IR/Raman). This contribution will be focused on the QM electronic problem. 

At a more detailed level, we note that the solvent effects on the optical rotation have the same origins as solvent effects on the energy itself, as described in detail in other contributions to this book. Most other studies of solvent effects on natural optical activity have focused on the electrostatic contributions. These contributions can be partitioned into direct effects arising from the influence of the dielectric environment on the electronic density of the solute, and into indirect effects arising from the relaxation of the nuclear structure in the solvent. For conformationally flexible molecules, we may also consider a third possible solvent effect due to the changes in the conformational equilibria when going from the gas phase to solution. 

The advantage of having a reference arm that is almost identical in chemical composition allows for the cancellation of other interfering effects. The effect of humidity has no bearing on the interferometer unless the humidity drops below 20% and the reaction stopped (making it apparent that water is necessary). In this case, the ammonium ion and the citrate ion may also be appreciably separated, adding to the dipole effect. As an added bonus, the similarity between the two arms also eliminates any solvent effects since they partitioned equally in the two arms at the levels measured. 

These results can be interpreted as true "solvent effects".on the partition of some intermediate or, more specifically, as evidence for reversible formation of an oxacarbene, and its potential participation in decar-bonylation. In any case, some revealing information might be given by experiments in which the yields for all products and quantum yields for cyclobutanone disappearance are measured in an "inert" solvent as a function of added methanol. 

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