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Predicting Adsorption Coefficients at Air−Water Interfaces Using Universal Solvation and Surface Area Models

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Casey P. Kelly, Christopher J. Cramer,* and Donald G. Truhlar*

Department of Chemistry and Supercomputing Institute, 207 Pleasant Street SE, University of Minnesota, Minneapolis, Minnesota 55455-0431

J. Phys. Chem. B, 2004, 108 (34), pp 12882–12897

DOI: 10.1021/jp037210t

Publication Date (Web): July 29, 2004

Section:

Surface Chemistry and Colloids

Abstract

Vapor-phase molecules are adsorbed at air−water interfaces to a much greater extent than can be explained by air−water partition coefficients, indicating that interface adsorption can play an important role, and this can be very important for environmental phenomena. On the basis of a statistical thermodynamic analysis, we separate the observable free energy of adsorption into a dimensionality change and a coupling part so that the modeling effort is correctly focused on the coupling part. On the basis of this analysis, we present two kinds of models for predicting partitioning between the vapor phase and the macroscopic surface of liquid water. The first model, called SM5.0R-Surf, involves atomic surface tensions developed previously for bulk solvation in organic liquids and a set of four solvent descriptors that characterize the properties of the water layer at the air−water interface. The latter descriptors are treated as parameters that are determined empirically by optimization for a set of 85 solutes for which the air−water surface adsorption coefficients (K_i/a) are known experimentally. The resulting descriptors indicate that interfacial water has increased hydrogen-bond acidity and increased hydrogen-bond basicity as compared to bulk water. A second kind of model involves an empirical correlation of the interfacial-water partition coefficient K_i/w with the calculated van der Waals surface area, and this kind of model can be based either on experimental data, yielding the semiempirical surface area (SESA) model, or on theoretical data, yielding the semitheoretical surface area (STSA) model. The SM5.0R-Surf and STSA models should be especially useful for environmental modeling because neither model requires any experimental data about the solute, other than its molecular structure. As an example, we use the above models to calculate air−water adsorption coefficients for 24 different pesticides, chlorinated arenes, and polyaromatic hydrocarbons (PAHs). We also show that several models in the literature can be used successfully even if we substitute calculated instead of experimental data for the solute parameters that they originally required. In related work reported here, the SM5.0R parametrization for predicting free energies of solvation in organic solvents is extended to include solutes containing phosphorus. This extension is based on the experimental free energies of 13 solutes in 9 organic solvents (37 data points). The SM5.0R model extended in this way and the new SM5.0R-Surf model can therefore be used to predict the free energy of solvation at air−water interfaces and in bulk organic liquids for any solute composed of H, C, N, O, F, S, Cl, Br, I, and/or P, whereas the STSA model does not contain parameters that depend on atomic number and can, in principle, be used for any molecule.

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This article has been cited by 7 ACS Journal articles (5 most recent appear below).

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Predicting Adsorption of Organic Chemicals at the Air−Water Interface
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The Journal of Physical Chemistry A2009 113 (44), 12256-12259
- Predicting Adsorption of Organic Chemicals at the Air−Water Interface
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A Universal Approach to Solvation Modeling
Christopher J. Cramer and Donald G. Truhlar
Accounts of Chemical Research2008 41 (6), 760-768
- A Universal Approach to Solvation Modeling
  Christopher J. Cramer and Donald G. Truhlar
  Accounts of Chemical Research2008 41 (6), 760-768
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Self-Consistent Reaction Field Model for Aqueous and Nonaqueous Solutions Based on Accurate Polarized Partial Charges
Aleksandr V. Marenich, Ryan M. Olson, Casey P. Kelly, Christopher J. Cramer, and Donald G. Truhlar
Journal of Chemical Theory and Computation2007 3 (6), 2011-2033
- Self-Consistent Reaction Field Model for Aqueous and Nonaqueous Solutions Based on Accurate Polarized Partial Charges
  Aleksandr V. Marenich, Ryan M. Olson, Casey P. Kelly, Christopher J. Cramer, and Donald G. Truhlar
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  A new universal continuum solvation model (where “universal” denotes applicable to all solvents), called SM8, is presented. It is an implicit solvation model, also called a continuum solvation model, and it improves on earlier SMx universal solvation ...
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Comparison of Headspace and Gas-Stripping Techniques for Measuring the Air−Water Partititioning of Normal Alkanols (C4 to C10): Effect of Temperature, Chain Length, and Adsorption to the Water Surface
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Journal of Chemical & Engineering Data2007 52 (1), 168-179
- Comparison of Headspace and Gas-Stripping Techniques for Measuring the Air−Water Partititioning of Normal Alkanols (C4 to C10): Effect of Temperature, Chain Length, and Adsorption to the Water Surface
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  Journal of Chemical & Engineering Data2007 52 (1), 168-179
  The air−water partition coefficients of normal alkanols (C4 to C10) were determined as a function of temperature using both the phase ratio variation headspace (PRV−HS) method and the inert gas-stripping (IGS) method. Whereas the results of the PRV−HS ...
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