Recent studies of the hydration of micro- and nanoscale solutes have demonstrated a strong {\it coupling} between hydrophobic, dispersion and electrostatic contributions, a fact not accounted for in current implicit solvent models. We present a theoretical formalism which accounts for coupling by minimizing the Gibbs free energy with respect to a solvent volume exclusion function. The solvent accessible surface is output of our theory. Our method is illustrated with the hydration of alkane-assembled solutes on different length scales, and captures the strong sensitivity to the particular form of the solute-solvent interactions in agreement with recent computer simulations
Molecular statistical thermodynamic models of hydration for chemistry and biophysics have advanced a...
Hydration effects in colloidal interactions or problems involving electrolytes are usually taken car...
Continuum models to handle solvent and electrolyte effects in an effective way have a long tradition...
An implicit solvent model is presented that couples hydrophobic, dispersion, and electrostatic solva...
Recent studies on the solvation of atomistic and nanoscale solutes indicate that a strong coupling e...
In our previous work, we introduced a solvation model based on discrete solvent representation and d...
AbstractWe consider whether the continuum model of hydration optimized to reproduce vacuum-to-water ...
We have studied the effect of weak solute-solvent attractions on the solvation of nonpolar molecules...
The unique solvent properties of water arise from its capacity to structurally respond to solutes wi...
Understanding hydrophobic interactions requires a molecular-level picture of how water molecules adj...
Hydrophobic effects play an essential role for a variety of chemical processes. These effects fall i...
Local ordering of water in the first hydration shell around a solute is different from isotropic bul...
The CMIRS1.0 (composite method for implicit representation of solvent, Version 1.0) model is introdu...
The dispersion energy is an important contribution to the total solvation energies of ions and neutr...
A computational method for the evaluation of dispersion and repulsion contributions to the solvation...
Molecular statistical thermodynamic models of hydration for chemistry and biophysics have advanced a...
Hydration effects in colloidal interactions or problems involving electrolytes are usually taken car...
Continuum models to handle solvent and electrolyte effects in an effective way have a long tradition...
An implicit solvent model is presented that couples hydrophobic, dispersion, and electrostatic solva...
Recent studies on the solvation of atomistic and nanoscale solutes indicate that a strong coupling e...
In our previous work, we introduced a solvation model based on discrete solvent representation and d...
AbstractWe consider whether the continuum model of hydration optimized to reproduce vacuum-to-water ...
We have studied the effect of weak solute-solvent attractions on the solvation of nonpolar molecules...
The unique solvent properties of water arise from its capacity to structurally respond to solutes wi...
Understanding hydrophobic interactions requires a molecular-level picture of how water molecules adj...
Hydrophobic effects play an essential role for a variety of chemical processes. These effects fall i...
Local ordering of water in the first hydration shell around a solute is different from isotropic bul...
The CMIRS1.0 (composite method for implicit representation of solvent, Version 1.0) model is introdu...
The dispersion energy is an important contribution to the total solvation energies of ions and neutr...
A computational method for the evaluation of dispersion and repulsion contributions to the solvation...
Molecular statistical thermodynamic models of hydration for chemistry and biophysics have advanced a...
Hydration effects in colloidal interactions or problems involving electrolytes are usually taken car...
Continuum models to handle solvent and electrolyte effects in an effective way have a long tradition...