dorsal/arxiv
View SchemaInner Shell Definition and Absolute Hydration Free Energy of K+(aq) on the Basis of Quasi-chemical Theory and Ab Initio Molecular Dynamics
| Authors | Susan B. Rempe, D. Asthagiri, Lawrence R. Pratt |
|---|---|
| Categories | |
| ArXiv ID | physics/0310158 |
| URL | https://arxiv.org/abs/physics/0310158 |
Abstract
K+(aq) ion is an integral component of many cellular processes, amongst which the most important, perhaps, is its role in transmitting electrical impulses along the nerve. Understanding its hydration structure and thermodynamics is crucial in dissecting its role in such processes. Her we address these questions using both the statistical mechanical quasi-chemical theory of solutions and ab initio molecular dynamics simulations. Simulations predict an interesting hydration structure for K+(aq): the population of about six (6) water molecules within the initial minimum of the observed g_{KO}(r) at infinite dilution involves four (4) inner-most molecules that the quasi-chemical theory suggests should be taken as the theoretical inner shell. The contribution of the 5th and 6th closest water molecules is observable as a distinct shoulder on the principal maximum of the g_{KO}(r). The quasi-chemical estimate of solvation free energy for the neutral pair KOH is also in good agreement with experiments.
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"abstract": "K+(aq) ion is an integral component of many cellular processes, amongst which\nthe most important, perhaps, is its role in transmitting electrical impulses\nalong the nerve. Understanding its hydration structure and thermodynamics is\ncrucial in dissecting its role in such processes. Her we address these\nquestions using both the statistical mechanical quasi-chemical theory of\nsolutions and ab initio molecular dynamics simulations. Simulations predict an\ninteresting hydration structure for K+(aq): the population of about six (6)\nwater molecules within the initial minimum of the observed g_{KO}(r) at\ninfinite dilution involves four (4) inner-most molecules that the\nquasi-chemical theory suggests should be taken as the theoretical inner shell.\nThe contribution of the 5th and 6th closest water molecules is observable as a\ndistinct shoulder on the principal maximum of the g_{KO}(r). The quasi-chemical\nestimate of solvation free energy for the neutral pair KOH is also in good\nagreement with experiments.",
"arxiv_id": "physics/0310158",
"authors": [
"Susan B. Rempe",
"D. Asthagiri",
"Lawrence R. Pratt"
],
"categories": [
"physics.chem-ph",
"physics.bio-ph"
],
"title": "Inner Shell Definition and Absolute Hydration Free Energy of K+(aq) on the Basis of Quasi-chemical Theory and Ab Initio Molecular Dynamics",
"url": "https://arxiv.org/abs/physics/0310158"
},
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