Free energy partitioning analysis of the driving forces that determine ion density profiles near the water liquid-vapor interface

Ayse Arslanargin, Thomas L. Beck

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43 Scopus citations

Abstract

Free energy partitioning analysis is employed to explore the driving forces for ions interacting with the water liquid-vapor interface using recently optimized point charge models for the ions and SPC/E water. The Na + and I - ions are examined as an example kosmotrope/chaotrope pair. The absolute hydration free energy is partitioned into cavity formation, attractive van der Waals, local electrostatic, and far-field electrostatic contributions. We first compute the bulk hydration free energy of the ions, followed by the free energy to insert the ions at the center of a water slab. Shifts of the ion free energies occur in the slab geometry consistent with the SPC/E surface potential of the water liquid-vapor interface. Then the free energy profiles are examined for ion passage from the slab center to the dividing surface. The profiles show that, for the large chaotropic I - ion, the relatively flat total free energy profile results from the near cancellation of several large contributions. The far-field electrostatic part of the free energy, largely due to the water liquid-vapor interface potential, has an important effect on ion distributions near the surface in the classical model. We conclude, however, that the individual forms of the local and far-field electrostatic contributions are expected to be model dependent when comparing classical and quantum results. The substantial attractive cavity free energy contribution for the larger I - ion suggests that there is a hydrophobic component important for chaotropic ion interactions with the interface.

Original languageEnglish
Article number104503
JournalJournal of Chemical Physics
Volume136
Issue number10
DOIs
StatePublished - Mar 14 2012
Externally publishedYes

Funding

We would like to thank David Rogers, Chris Mundy, Shawn Kathmann, Liem Dang, Kevin Leung, Benoit Roux, Kim Collins, Yan Levin, and Lawrence Pratt for helpful discussions. We also thank Collin Wick for performing an independent calculation of the surface potential of the SPC/E water liquid-vapor interface that yielded a value of −0.6 V, in agreement with our results. The research was supported by NSF Grants Nos. CHE-0709560 and CHE-1011746, and a grant of computer time at the Ohio Supercomputer Center. Nearing completion of this work, we received two preprints of related papers that analyze the effect of the water surface potential on ion free energy profiles near the liquid-vapor interface; those studies lead to conclusions similar to those presented here.

FundersFunder number
National Science FoundationCHE-1011746, CHE-0709560

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