Crustwater: Modeling Hydrophobic Solvation

Ajeet Kumar Yadav; Pradipta Bandyopadhyay; Evangelos A. Coutsias; Ken A. Dill

doi:10.1021/acs.jpcb.2c02695

Crustwater: Modeling Hydrophobic Solvation

Ajeet Kumar Yadav
, Pradipta Bandyopadhyay
, Evangelos A. Coutsias
, Ken A. Dill

Jawaharlal Nehru University

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

We describe Crustwater, a statistical mechanical model of nonpolar solvation in water. It treats bulk water using the Cage Water model and introduces a crust, i.e., a solvation shell of coordinated partially structured waters. Crustwater is analytical and fast to compute. We compute here solvation vs temperature over the liquid range, and vs pressure and solute size. Its thermal predictions are as accurate as much more costly explicit models such as TIP4P/2005. This modeling gives new insights into the hydrophobic effect: (1) that oil-water insolubility in cold water is due to solute-water (SW) translational entropy and not water-water (WW) orientations, even while hot water is dominated by WW cage breaking, and (2) that a size transition at the Angstrom scale, not the nanometer scale, takes place as previously predicted.

Original language	English
Pages (from-to)	6052-6062
Number of pages	11
Journal	Journal of Physical Chemistry B
Volume	126
Issue number	32
DOIs	https://doi.org/10.1021/acs.jpcb.2c02695
State	Published - Aug 18 2022

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title = "Crustwater: Modeling Hydrophobic Solvation",

abstract = "We describe Crustwater, a statistical mechanical model of nonpolar solvation in water. It treats bulk water using the Cage Water model and introduces a crust, i.e., a solvation shell of coordinated partially structured waters. Crustwater is analytical and fast to compute. We compute here solvation vs temperature over the liquid range, and vs pressure and solute size. Its thermal predictions are as accurate as much more costly explicit models such as TIP4P/2005. This modeling gives new insights into the hydrophobic effect: (1) that oil-water insolubility in cold water is due to solute-water (SW) translational entropy and not water-water (WW) orientations, even while hot water is dominated by WW cage breaking, and (2) that a size transition at the Angstrom scale, not the nanometer scale, takes place as previously predicted.",

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T2 - Modeling Hydrophobic Solvation

AU - Yadav, Ajeet Kumar

AU - Bandyopadhyay, Pradipta

AU - Coutsias, Evangelos A.

AU - Dill, Ken A.

PY - 2022/8/18

Y1 - 2022/8/18

N2 - We describe Crustwater, a statistical mechanical model of nonpolar solvation in water. It treats bulk water using the Cage Water model and introduces a crust, i.e., a solvation shell of coordinated partially structured waters. Crustwater is analytical and fast to compute. We compute here solvation vs temperature over the liquid range, and vs pressure and solute size. Its thermal predictions are as accurate as much more costly explicit models such as TIP4P/2005. This modeling gives new insights into the hydrophobic effect: (1) that oil-water insolubility in cold water is due to solute-water (SW) translational entropy and not water-water (WW) orientations, even while hot water is dominated by WW cage breaking, and (2) that a size transition at the Angstrom scale, not the nanometer scale, takes place as previously predicted.

AB - We describe Crustwater, a statistical mechanical model of nonpolar solvation in water. It treats bulk water using the Cage Water model and introduces a crust, i.e., a solvation shell of coordinated partially structured waters. Crustwater is analytical and fast to compute. We compute here solvation vs temperature over the liquid range, and vs pressure and solute size. Its thermal predictions are as accurate as much more costly explicit models such as TIP4P/2005. This modeling gives new insights into the hydrophobic effect: (1) that oil-water insolubility in cold water is due to solute-water (SW) translational entropy and not water-water (WW) orientations, even while hot water is dominated by WW cage breaking, and (2) that a size transition at the Angstrom scale, not the nanometer scale, takes place as previously predicted.

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Crustwater: Modeling Hydrophobic Solvation

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