Add to ORKGThis work introduces a model, solvation model 6 with temperature dependence (SM6T), to predict the temperature dependence of aqueous free energies of solvation for compounds containing H, C, and O in the range 273-373 K. In particular, we extend solvation model 6 (SM6), which was previously developed (Kelly, C. P.; Cramer, C. J.; Truhlar, D. G. J. Chem. Theory Comput. 2005, 1, 1133) for predicting aqueous free energies of solvation at 298 K, to predict the variation of the free energy of solvation relative to 298 K. Also, we describe the database of experimental aqueous free energies of solvation for compounds containing H, C, and O that was used to parametrize and test the new model. SM6T partitions the temperature dependence of the free e...
We derive a consistent approach for predicting the solvation free energies of charged solutes in the...
The Gibbs free energy of solvation and dissociation of hydrogen chloride in water is calculated thro...
Local ordering of water in the first hydration shell around a solute is different from isotropic bul...
Most methods for predicting free energies of solvation have been developed or validated exclusively ...
584-588A simple method is proposed to predict the solvation free energy of electrolytes in the aqu...
A method based on molecular dynamics simulations which employ two distinct levels of theory is propo...
We present a new strategy to estimate the temperature‐dependent vapor–liquid equilibria and solvatio...
Solvation free energies can now be calculated precisely from molecular simulations, providing a valu...
1 Introduction Chapter 1 contains a basic introduction to solvation models. Special attention is ...
We have developed a fast procedure to predict solvation free energies for both organic and biologica...
Gas to aqueous phase standard state (1 atm to 1 mol/L; 298.15 K) free energies of solvation ([DELTA]...
The solvation of nonpolar molecules in water and that in simple liquids are compared and contrasted....
ABSTRACT: Accurate prediction of hydration free energies is a key objective of any free energy metho...
Many approaches have been used to improve the accuracy of implicit solvent models including solute c...
The Henry\u27s law constant of a chemical solute in water exhibits a maximum value at a temperature ...
We derive a consistent approach for predicting the solvation free energies of charged solutes in the...
The Gibbs free energy of solvation and dissociation of hydrogen chloride in water is calculated thro...
Local ordering of water in the first hydration shell around a solute is different from isotropic bul...
Most methods for predicting free energies of solvation have been developed or validated exclusively ...
584-588A simple method is proposed to predict the solvation free energy of electrolytes in the aqu...
A method based on molecular dynamics simulations which employ two distinct levels of theory is propo...
We present a new strategy to estimate the temperature‐dependent vapor–liquid equilibria and solvatio...
Solvation free energies can now be calculated precisely from molecular simulations, providing a valu...
1 Introduction Chapter 1 contains a basic introduction to solvation models. Special attention is ...
We have developed a fast procedure to predict solvation free energies for both organic and biologica...
Gas to aqueous phase standard state (1 atm to 1 mol/L; 298.15 K) free energies of solvation ([DELTA]...
The solvation of nonpolar molecules in water and that in simple liquids are compared and contrasted....
ABSTRACT: Accurate prediction of hydration free energies is a key objective of any free energy metho...
Many approaches have been used to improve the accuracy of implicit solvent models including solute c...
The Henry\u27s law constant of a chemical solute in water exhibits a maximum value at a temperature ...
We derive a consistent approach for predicting the solvation free energies of charged solutes in the...
The Gibbs free energy of solvation and dissociation of hydrogen chloride in water is calculated thro...
Local ordering of water in the first hydration shell around a solute is different from isotropic bul...