302 research outputs found
Profiles of electrostatic potential across the water-vapor, ice-vapor and ice-water interfaces
Ice-water, water-vapor interfaces and ice surface are studied by molecular
dynamics simulations with the SPC/E model of water molecules having the purpose
to estimate the profiles of electrostatic potential across the interfaces. We
have proposed a methodology for calculating the profiles of electrostatic
potential based on a trial particle, which showed good agreement for the case
of electrostatic potential profile of the water-vapor interface of TIP4P model
calculated in another way. The measured profile of electrostatic potential for
the pure ice-water interface decreases towards the liquid bulk region, which is
in agreement with simulations of preferential direction of motion of Li
and F solute ions at the liquid side of the ice-water interface. These
results are discussed in connection with the Workman-Reynolds effect.Comment: 7 pages, 5 figure
The effect of stirring on the heterogeneous nucleation of water and of clathrates of tetrahydrofuran/water mixtures
The statistics of liquid-to-crystal nucleation are measured for both water
and for clathrate-forming mixtures of tetrahydrofuran (THF) and water using an
automatic lag time apparatus (ALTA). We measure the nucleation temperature
using this apparatus in which a single sample is repeatedly cooled, nucleated
and thawed. The effect of stirring on nucleation has been evaluated numerically
and is discussed. We find that stirring of the solution makes no difference to
the nucleation temperature of a given solution in a given tube.Comment: 4 pages, 4 figure
How should a small country respond to climate change?
Responses to the global climate crisis often focus on the largest current
emitters of greenhouse gases. However, analysis shows that about a third of
emissions come from a collection of small emitters, each contributing one- to
two-percent of the total additional CO injected into the communal
atmosphere. Attempts to hold global warming to less than 1.5\textcelsius~
cannot succeed without also reducing emissions from these small countries.Comment: 4 pages, 3 figure
First Principles Derivation of Effective Ginzburg-Landau Free Energy models for Crystalline Systems
The expression of the free energy density of a classical crystalline system
as a gradient expansion in terms of a set of order parameters is developed
using classical density functional theory. The goal here is to extend and
complete an earlier derivation by L{\"o}wen et al (Europhys. Lett.9, 791,
1989). The limitations of the resulting expressions are also discussed
including the boundary conditions needed for finite systems and the fact that
the results cannot, at present, be used to take into account elastic
relaxation.Comment: 12 pages, no figures, sumitted to Physica
Calculation of the entropy from multiparticle correlation functions
This is the publisher's version, also available electronically from http://journals.aps.org/pra/abstract/10.1103/PhysRevA.45.5680.We consider three approximate expressions for the entropy of a single-particle fluid that require as input only the pair-correlation function g(r). By evaluating numerically these entropy estimates, for several model interparticle interactions of varying range, we examine the accuracy of these expressions compared to the ‘‘exact’’ entropy determined from computer simulation. With the exception of the one-component plasma at very low densities, the entropy of all systems studied can be approximated within 10% of the exact value for fluid densities up to 95% of the freezing density, with the agreement improving for the shorter-ranged potentials. For hard spheres, a preliminary extension to third-order terms is presented
Entropy of electrolytes
This is the publisher's version, also available electronically from http://scitation.aip.org/content/aip/journal/jcp/100/5/10.1063/1.466365The entropy of 1–1 and 2–2 model electrolytes is calculated from an expansion in terms of the multiparticle correlation functions. For electrolytes, a simple truncation of this expansion is never sufficient for the accurate calculation of the entropy,even in the limit of low concentration, in marked contrast to the behavior for short‐ranged potentials. However, a partial, but infinite‐order, summation of the expansion is shown to yield both the correct low‐concentration limit and excellent results over a wide range of concentrations for both 1–1 and 2–2 electrolytes. The consequences of this result for some earlier applications of the entropy expansion to electrolytes are discussed
The crystal–liquid interface of a body‐centered‐cubic‐forming substance: Computer simulations of the r − 6 potential
This is the publisher's version, also available electronically from http://scitation.aip.org/content/aip/journal/jcp/91/6/10.1063/1.456897.The interfaces between a bcc crystal and its melt are studied by molecular dynamics simulation. Three distinct crystal/melt interfaces, (100), (111), and (110) are studied. For all interfaces the variation with z, the coordinate perpendicular to the interfacial plane, of the single particle density (averaged over the directions perpendicular to z) and the diffusion constant are measured. Although the 10–90 widths of the density peak‐height profiles differ significantly among the three interfaces (6, 9, and 7 molecular diameters, respectively), the corresponding 10–90 widths of the diffusion constant profiles are nearly identical with a common value of about four molecular diameters. This leads to the conclusion that the differences in apparent structural width are due primarily to geometric considerations and not to differences in average local molecular environments
NATO Workshop on Ionic Soft Matter
On 14-17 April 2004 the NATO Advanced Research Workshop (ARW) on Ionic Soft Matter convened in the beautiful and historic city of Lviv. This was only the second NATO ARW to be held in Ukraine at that time
Consistent integral equations for two- and three-body-force models: Application to a model of silicon
This is the publisher's version, also available electronically from http://journals.aps.org/pre/abstract/10.1103/PhysRevE.47.2491.Functional differentiation of systematic expansions for the entropy, in the grand ensemble [B. B. Laird and A. D. J. Haymet, Phys. Rev. A 45, 5680 (1992)], leads directly to consistent integral equations for classical systems interacting via two-body, three-body, and even higher-order forces. This method is both a concise method for organizing existing published results and for deriving previously unpublished, higher-order integral equations. The equations are automatically consistent in the sense that all thermodynamic quantities may be derived from a minimum on an approximate free-energy surface, without the need to introduce weighting functions or numerically determined crossover functions. A number of existing approximate theories are recovered by making additional approximations to the equations. For example, the Kirkwood superposition approximation is shown to arise from a particular approximation to the entropy. The lowest-order theory is then used to obtain integral-equation predictions for the well-known Stillinger-Weber model for silicon, with encouraging results. Further connections are made with increasingly popular density-functional methods in classical statistical mechanics
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