2000
DOI: 10.1021/jp993076u
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Molecular Dynamics Simulations of the Interior of Aqueous Reverse Micelles

Abstract: Aqueous reverse micelles, which are surfactant aggregates in nonpolar solvents that enclose packets of aqueous solution, have been widely studied experimentally and theoretically, but much remains unknown about the properties of water in the interior. The few previous molecular dynamics simulations of reverse micelles have not examined how the micelle size affects these properties. We have modeled the interior of an aqueous reverse micelle as a rigid spherical cavity, treating only the surfactant headgroups an… Show more

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Cited by 411 publications
(738 citation statements)
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References 96 publications
(293 reference statements)
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“…Furthermore, simulations show that the Na ions are associated with the headgroups. 28 Consequently the ionic strength of the nanoscopic water is much lower than 5.6 M, and the influence of free ions in the water nanopools on the vibrational echo decay will be much less than that measured for the 6 M NaCl solution.…”
Section: B Vibrational Echo Experimentsmentioning
confidence: 92%
“…Furthermore, simulations show that the Na ions are associated with the headgroups. 28 Consequently the ionic strength of the nanoscopic water is much lower than 5.6 M, and the influence of free ions in the water nanopools on the vibrational echo decay will be much less than that measured for the 6 M NaCl solution.…”
Section: B Vibrational Echo Experimentsmentioning
confidence: 92%
“…30,31,35,36 The potential depends only on the radial distance of the Lennard-Jones site on the molecule from the center of the cavity. We consider a single solvent density, ρ = 0.7 g/cm 3 (the bulk density of CH 3 CN is 0.786 g/cm 3 ).…”
Section: Simulation Detailsmentioning
confidence: 99%
“…32,33 The interactions of the solute and solvent molecules with the cavity walls involve only Lennard-Jones interactions. 32,33 The potential depends only on the radial distance of the Lennard-Jones site on the molecule from the center of the cavity. We consider two solvent densities, ϭ1.4 g/cm 3 and 2.0 g/cm 3 ͑the bulk density of CH 3 I is 2.279 g/cm 3 ͒.…”
Section: Nanocavity Systemmentioning
confidence: 99%
“…Their hydrophobic cavity model, 33 developed by Linse and Halle, 32 is the same as that used here; the reverse micelle model consists of the same cavity framework with fixed anionic headgroups and mobile cationic counterions added. 33 The solvation dynamics were studied using an anionic diatomic probe molecule with symmetrically ͑ground state, ϭ0͒ or asymmetrically ͑excited state, ϭ7.76 D͒ distributed charge. They simulated the solvation dynamics for the first 2 ps after excitation and obtained results that were relatively independent of the size of the reverse micelle.…”
Section: Theoretical Workmentioning
confidence: 99%