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Instantaneous, parameter-free methods to define a solute's hydration shell

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Instantaneous, parameter-free methods to define a solute's hydration shell. / Chatterjee, A.; Higham, J.; Henchman, R.H.
In: Journal of Chemical Physics, Vol. 143, No. 23, 234501, 21.12.2015.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Chatterjee, A, Higham, J & Henchman, RH 2015, 'Instantaneous, parameter-free methods to define a solute's hydration shell', Journal of Chemical Physics, vol. 143, no. 23, 234501. https://doi.org/10.1063/1.4937376

APA

Chatterjee, A., Higham, J., & Henchman, R. H. (2015). Instantaneous, parameter-free methods to define a solute's hydration shell. Journal of Chemical Physics, 143(23), Article 234501. https://doi.org/10.1063/1.4937376

Vancouver

Chatterjee A, Higham J, Henchman RH. Instantaneous, parameter-free methods to define a solute's hydration shell. Journal of Chemical Physics. 2015 Dec 21;143(23):234501. doi: 10.1063/1.4937376

Author

Chatterjee, A. ; Higham, J. ; Henchman, R.H. / Instantaneous, parameter-free methods to define a solute's hydration shell. In: Journal of Chemical Physics. 2015 ; Vol. 143, No. 23.

Bibtex

@article{68d753590c194f0d9ace2b2def5a9e0a,
title = "Instantaneous, parameter-free methods to define a solute's hydration shell",
abstract = "A range of methods are presented to calculate a solute{\textquoteright}s hydration shell from computer simulations of dilute solutions of monatomic ions and noble gas atoms. The methods are designed to be parameter-free and instantaneous so as to make them more general, accurate, and consequently applicable to disordered systems. One method is a modified nearest-neighbor method, another considers solute-water Lennard-Jones overlap followed by hydrogen-bond rearrangement, while three methods compare various combinations of water-solute and water-water forces. The methods are tested on a series of monatomic ions and solutes and compared with the values from cutoffs in the radial distribution function, the nearest-neighbor distribution functions, and the strongest-acceptor hydrogen bond definition for anions. The Lennard-Jones overlap method and one of the force-comparison methods are found to give a hydration shell for cations which is in reasonable agreement with that using a cutoff in the radial distribution function. Further modifications would be required, though, to make them capture the neighboring water molecules of noble-gas solutes if these weakly interacting molecules are considered to constitute the hydration shell.",
author = "A. Chatterjee and J. Higham and R.H. Henchman",
year = "2015",
month = dec,
day = "21",
doi = "10.1063/1.4937376",
language = "English",
volume = "143",
journal = "Journal of Chemical Physics",
issn = "0021-9606",
publisher = "AMER INST PHYSICS",
number = "23",

}

RIS

TY - JOUR

T1 - Instantaneous, parameter-free methods to define a solute's hydration shell

AU - Chatterjee, A.

AU - Higham, J.

AU - Henchman, R.H.

PY - 2015/12/21

Y1 - 2015/12/21

N2 - A range of methods are presented to calculate a solute’s hydration shell from computer simulations of dilute solutions of monatomic ions and noble gas atoms. The methods are designed to be parameter-free and instantaneous so as to make them more general, accurate, and consequently applicable to disordered systems. One method is a modified nearest-neighbor method, another considers solute-water Lennard-Jones overlap followed by hydrogen-bond rearrangement, while three methods compare various combinations of water-solute and water-water forces. The methods are tested on a series of monatomic ions and solutes and compared with the values from cutoffs in the radial distribution function, the nearest-neighbor distribution functions, and the strongest-acceptor hydrogen bond definition for anions. The Lennard-Jones overlap method and one of the force-comparison methods are found to give a hydration shell for cations which is in reasonable agreement with that using a cutoff in the radial distribution function. Further modifications would be required, though, to make them capture the neighboring water molecules of noble-gas solutes if these weakly interacting molecules are considered to constitute the hydration shell.

AB - A range of methods are presented to calculate a solute’s hydration shell from computer simulations of dilute solutions of monatomic ions and noble gas atoms. The methods are designed to be parameter-free and instantaneous so as to make them more general, accurate, and consequently applicable to disordered systems. One method is a modified nearest-neighbor method, another considers solute-water Lennard-Jones overlap followed by hydrogen-bond rearrangement, while three methods compare various combinations of water-solute and water-water forces. The methods are tested on a series of monatomic ions and solutes and compared with the values from cutoffs in the radial distribution function, the nearest-neighbor distribution functions, and the strongest-acceptor hydrogen bond definition for anions. The Lennard-Jones overlap method and one of the force-comparison methods are found to give a hydration shell for cations which is in reasonable agreement with that using a cutoff in the radial distribution function. Further modifications would be required, though, to make them capture the neighboring water molecules of noble-gas solutes if these weakly interacting molecules are considered to constitute the hydration shell.

U2 - 10.1063/1.4937376

DO - 10.1063/1.4937376

M3 - Journal article

VL - 143

JO - Journal of Chemical Physics

JF - Journal of Chemical Physics

SN - 0021-9606

IS - 23

M1 - 234501

ER -