Your search keyword '"Lara A. Patel"' showing total 6 results

1. Simulations of NaCl Aggregation from Solution: Solvent Determines Topography of Free Energy Landscape

Author

Lara A. Patel and James T. Kindt

Subjects

Supersaturation, Materials science, 010304 chemical physics, Nucleation, Thermodynamics, Energy landscape, General Chemistry, 010402 general chemistry, Kinetic energy, 01 natural sciences, 0104 chemical sciences, Amorphous solid, Solvent, Crystal, Computational Mathematics, 0103 physical sciences, Cluster (physics)

Abstract

The partition-enabled analysis of cluster histograms (PEACH) method is used to calculate the free energy surface of NaCl aggregation using cluster statistics from MD simulations of small systems (40-90 ions plus solvent) in four solvents. In all cases (pure methanol, pure water, and two methanol/water mixtures) NaCl clusters show a transition from amorphous to rocksalt structure with increasing cluster size. The crossover sizes, and the apparent kinetic barrier to ordering, increase with increasing water content. Implications for the proposed two-step mechanism of NaCl crystal nucleation (in which the ordered structure emerges from a large disordered cluster), and how this mechanism might depend on solvent and on degree of supersaturation, are discussed. In pure water, nonideal crowding effects that promote clustering are identified from systematic concentration-dependent deviations between simulation results and the PEACH model fit. In contrast, the ability of PEACH to fit aggregation statistics in mixed solvents is consistent with negligible interactions between ions in different clusters. © 2018 Wiley Periodicals, Inc.

Published

2018

2. Extracting Aggregation Free Energies of Mixed Clusters from Simulations of Small Systems: Application to Ionic Surfactant Micelles

Author

Olivia Beckwith, Robert Schneider, Xiaokun Zhang, Christopher J. Weeden, Lara A. Patel, and James T. Kindt

Subjects

chemistry.chemical_classification, 010304 chemical physics, Chemistry, Ionic bonding, Thermodynamics, Function (mathematics), 010402 general chemistry, 01 natural sciences, Micelle, 0104 chemical sciences, Computer Science Applications, Condensed Matter::Soft Condensed Matter, Reduction (complexity), Molecular dynamics, 0103 physical sciences, Cluster (physics), Molecule, Organic chemistry, Physics::Chemical Physics, Physical and Theoretical Chemistry, Counterion

Abstract

Micelle cluster distributions from molecular dynamics simulations of a solvent-free coarse-grained model of sodium octyl sulfate (SOS) were analyzed using an improved method to extract equilibrium association constants from small-system simulations containing one or two micelle clusters at equilibrium with free surfactants and counterions. The statistical-thermodynamic and mathematical foundations of this partition-enabled analysis of cluster histograms (PEACH) approach are presented. A dramatic reduction in computational time for analysis was achieved through a strategy similar to the selector variable method to circumvent the need for exhaustive enumeration of the possible partitions of surfactants and counterions into clusters. Using statistics from a set of small-system (up to 60 SOS molecules) simulations as input, equilibrium association constants for micelle clusters were obtained as a function of both number of surfactants and number of associated counterions through a global fitting procedure. The resulting free energies were able to accurately predict micelle size and charge distributions in a large (560 molecule) system. The evolution of micelle size and charge with SOS concentration as predicted by the PEACH-derived free energies and by a phenomenological four-parameter model fit, along with the sensitivity of these predictions to variations in cluster definitions, are analyzed and discussed.

Published

2017

3. Cluster Free Energies from Simple Simulations of Small Numbers of Aggregants: Nucleation of Liquid MTBE from Vapor and Aqueous Phases

Author

James T. Kindt and Lara A. Patel

Subjects

Aqueous solution, 010304 chemical physics, Chemistry, Nucleation, Aqueous two-phase system, Thermodynamics, 010402 general chemistry, 01 natural sciences, Measure (mathematics), 0104 chemical sciences, Computer Science Applications, Law of mass action, Molecular dynamics, Computational chemistry, 0103 physical sciences, Cluster (physics), Range (statistics), Physical and Theoretical Chemistry

Abstract

We introduce a global fitting analysis method to obtain free energies of association of noncovalent molecular clusters using equilibrated cluster size distributions from unbiased constant-temperature molecular dynamics (MD) simulations. Because the systems simulated are small enough that the law of mass action does not describe the aggregation statistics, the method relies on iteratively determining a set of cluster free energies that, using appropriately weighted sums over all possible partitions of N monomers into clusters, produces the best-fit size distribution. The quality of these fits can be used as an objective measure of self-consistency to optimize the cutoff distance that determines how clusters are defined. To showcase the method, we have simulated a united-atom model of methyl tert-butyl ether (MTBE) in the vapor phase and in explicit water solution over a range of system sizes (up to 95 MTBE in the vapor phase and 60 MTBE in the aqueous phase) and concentrations at 273 K. The resulting size-dependent cluster free energy functions follow a form derived from classical nucleation theory (CNT) quite well over the full range of cluster sizes, although deviations are more pronounced for small cluster sizes. The CNT fit to cluster free energies yielded surface tensions that were in both cases lower than those for the simulated planar interfaces. We use a simple model to derive a condition for minimizing non-ideal effects on cluster size distributions and show that the cutoff distance that yields the best global fit is consistent with this condition.

Published

2017

4. Electrical conductivity, ion pairing, and ion self-diffusion in aqueous NaCl solutions at elevated temperatures and pressures

Author

Lara A. Patel, Katie A. Maerzke, Robert P. Currier, Matthew J. Vigil, Alp T. Findikoglu, and Tae Jun Yoon

Subjects

Self-diffusion, Aqueous solution, Materials science, 010304 chemical physics, General Physics and Astronomy, Conductivity, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, Ion, Molecular dynamics, Solvation shell, Chemical physics, Electrical resistivity and conductivity, 0103 physical sciences, Isobar, Physical and Theoretical Chemistry

Abstract

We have performed classical molecular dynamics (MD) simulations of aqueous sodium chloride (NaCl) solutions from 298 to 674 K at 200 bars to understand the influence of ion pairing and ion self-diffusion on electrical conductivity in high-temperature/high-pressure salt solutions. Conductivity data obtained from the MD simulation highlight an apparent anomaly, namely, a conductivity maximum as temperature increases along an isobar, which has been also observed in experimental studies. By examining both velocity autocorrelation and cross-correlation terms of the Green-Kubo integral, we quantitatively demonstrate that the conductivity anomaly arises mainly from a competition between the single-ion self-diffusion and the contact ion pair formation. The velocity autocorrelation function in conjunction with structural analysis suggests that diffusive motion of ions is suppressed at high temperatures due to the persistence of an inner hydration shell. The contribution of velocity cross-correlation functions between oppositely charged ions becomes significant at the onset of the conductivity decrease. Structural analysis based on Voronoi tessellation and pair correlation functions indicates that the fraction of contact ion pairs increases as temperature increases. Spatial decomposition of the electrical conductivity also indicates that the formation of contact ion pairs significantly decreases the electrical conductivity compared to Nernst-Einstein conductivity, but the contribution of distant opposite charges cannot be ignored except at the highest temperature due to unscreened long-range interactions.

Published

2019

5. NaCl aggregation in water at elevated temperatures and pressures: Comparison of classical force fields

Author

Katie A. Maerzke, Lara A. Patel, Robert P. Currier, and Tae Jun Yoon

Subjects

Properties of water, Materials science, 010304 chemical physics, Force field (physics), General Physics and Astronomy, Thermodynamics, Dielectric, 010402 general chemistry, 01 natural sciences, Supercritical fluid, 0104 chemical sciences, Physical property, chemistry.chemical_compound, chemistry, Phase (matter), 0103 physical sciences, Water model, Physical and Theoretical Chemistry, Solubility

Abstract

The properties of water vary dramatically with temperature and density. This can be exploited to control its effectiveness as a solvent. Thus, supercritical water is of keen interest as solvent in many extraction processes. The low solubility of salts in lower density supercritical water has even been suggested as a means of desalination. The high temperatures and pressures required to reach supercritical conditions can present experimental challenges during collection of required physical property and phase equilibria data, especially in salt-containing systems. Molecular simulations have the potential to be a valuable tool for examining the behavior of solvated ions at these high temperatures and pressures. However, the accuracy of classical force fields under these conditions is unclear. We have, therefore, undertaken a parametric study of NaCl in water, comparing several salt and water models at 200 bar-600 bar and 450 K-750 K for a range of salt concentrations. We report a comparison of structural properties including ion aggregation, hydrogen bonding, density, and static dielectric constants. All of the force fields qualitatively reproduce the trends in the liquid phase density. An increase in ion aggregation with decreasing density holds true for all of the force fields. The propensity to aggregate is primarily determined by the salt force field rather than the water force field. This coincides with a decrease in the water static dielectric constant and reduced charge screening. While a decrease in the static dielectric constant with increasing NaCl concentration is consistent across all model combinations, the salt force fields that exhibit more ionic aggregation yield a slightly smaller dielectric decrement.

Published

2021

6. Coarse-grained molecular simulations of the melting kinetics of small unilamellar vesicles

Author

Lara A. Patel and James T. Kindt

Subjects

Physics::Biological Physics, 010304 chemical physics, Chemistry, Transition temperature, Vesicle, Bilayer, Partial melting, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Quantitative Biology::Subcellular Processes, Condensed Matter::Soft Condensed Matter, Crystallography, Chemical physics, Phase (matter), Temperature jump, 0103 physical sciences, Exponential decay, 0210 nano-technology, Lipid bilayer

Abstract

Simulations of small unilamellar lipid bilayer vesicles have been performed to model their response to an instantaneous rise in temperature, starting from an initial low-temperature structure, to temperatures near or above the main chain transition temperature. The MARTINI coarse-grained force-field was used to construct slabs of gel-phase DPPC bilayers, which were assembled into truncated icosahedral structures containing 13,165 or 31,021 lipids. Equilibration at 280 K produced structures with several (5-8) domains, characterized by facets of lipids packed in the gel phase connected by disordered ridges. Instantaneous heating to final temperatures ranging from 290 K to 310 K led to partial or total melting over 500 ns trajectories, accompanied by changes in vesicle shape and the sizes and arrangements of remaining gel-phase domains. At temperatures that produced partial melting, the gel-phase lipid content of the vesicles followed an exponential decay, similar in form and timescale to the sub-microsecond phase of melting kinetics observed in recent ultrafast IR temperature-jump experiments. The changing rate of melting appears to be the outcome of a number of competing contributions, but changes in curvature stress arising from the expansion of the bilayer area upon melting are a major factor. The simulations give a more detailed picture of the changes that occur in frozen vesicles following a temperature jump, which will be of use for the interpretation of temperature-jump experiments on vesicles.

Published

2016