Surface tension: Difference between revisions
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The surface tension | The '''surface tension''', | ||
<math> \gamma </math> is a measure of the work required to | <math> \gamma </math>, is a measure of the [[work]] required to create an [[interface]] between | ||
two bulk phases. | |||
Canonical | == Thermodynamics == | ||
In the [[Canonical ensemble]] the surface tension is formally given as: | |||
<math> \gamma = \frac{ \partial | :<math> \gamma = \frac{ \partial A (N,V,T, {\mathcal A} )}{\partial {\mathcal A} } </math>; | ||
where | where | ||
*<math>A</math> is the [[Helmholtz energy function]] | |||
* <math> N </math> is the number of particles | * <math> N </math> is the number of particles | ||
*<math> V </math> is the volume | |||
*<math> T </math> is the [[temperature]] | |||
*<math> {\mathcal A} </math> is the surface area | |||
==Computer Simulation== | |||
Different techniques may be used to compute this quantity, such as the traditional [[stress | stress tensor]] route. More recently, several methods have been proposed which avoid the some times difficult calculation of the stress tensor, e.g., the [[test area method]] and [[wandering interface method]]. A review can be found in the paper by Gloor ''et al.'' <ref name="Gloor">[http://dx.doi.org/10.1063/1.2038827 Guy J. Gloor, George Jackson, Felipe J. Blas and Enrique de Miguel "Test-area simulation method for the direct determination of the interfacial tension of systems with continuous or discontinuous potentials", Journal of Chemical Physics '''123''' 134703 (2005)]</ref>. | |||
==Liquid-Vapour Interfaces of one component systems == | |||
=== Binder procedure=== | |||
Here, only an outline of the procedure is presented, more details can be found in <ref>[http://dx.doi.org/10.1103/PhysRevA.25.1699 K. Binder "Monte Carlo calculation of the surface tension for two- and three-dimensional lattice-gas models", Physical Review A '''25''' pp. 1699 - 1709 (1982)]</ref>. | |||
For given conditions of volume and temperature, the [[Helmholtz energy function]] is computed as a function of the number of molecules, <math> A(N;V,T)</math>. The calculation is usually carried out using [[Monte Carlo]] simulation using [[periodic boundary conditions]] | |||
If liquid-vapour equilibrium occurs, a plot of the [[chemical potential]], <math> \mu \equiv (\partial A/\partial N)_{V,T} </math>, | |||
as a function of <math> N </math> shows a loop. | |||
Using basic thermodynamic procedures ([[Maxwell's equal area construction]]) it is possible | |||
to compute the densities of the two phases; <math> \rho_v, \rho_l </math> at liquid-vapour equilibrium. | |||
Considering the thermodynamic limit for densities <math> \rho </math> with <math> \rho_v < \rho < \rho_l </math> the | |||
[[Helmholtz energy function]] will be: | |||
... | :<math> A(N) = - p_{eq} V + \mu_{eq} N + \gamma {\mathcal A}(N) </math> | ||
where the quantities with the subindex "eq" are those corresponding to the fluid-phase equilibrium situation. | |||
From the previous equation one can write | |||
:<math> \Omega (N) \equiv A(N) - \mu_{eq} N = - p_{eq} V + \gamma {\mathcal A}(N) </math>. | |||
For appropriate values of <math> N </math> one can estimate the value of the surface area, <math> {\mathcal A} </math> (See MacDowell ''et al.'' <ref>[http://dx.doi.org/10.1063/1.2218845 L. G. MacDowell, V. K. Shen, and J. R. Errington "Nucleation and cavitation of spherical, cylindrical, and slablike droplets and bubbles in small systems", Journal of Chemical Physics '''125''' 034705 (2006)]</ref>), and compute <math> \gamma </math> directly as: | |||
:<math> \gamma = \frac{ \Omega(N) + p_{eq} V } { {\mathcal A}(N) } = \frac{ \Omega(N) - \frac{1}{2}(\Omega(N_l)+\Omega(N_v)) }{{\mathcal A}(N)} </math> | |||
where <math> N_l </math> and <math> N_v </math> are given by: <math> N_l = V \cdot \rho_l </math> and <math> N_v = V \cdot \rho_v </math> | |||
=== Explicit interfaces === | |||
In these methods one performs a direct simulation of the two-phase system. [[Periodic boundary conditions]] are usually employed. | |||
Simulation boxes are elongated in one direction, and the interfaces are built (and expected to stay) perpendicular to | |||
such a direction. | |||
Taking into account the [[canonical ensemble]] definition (see above), one computes the change in the [[Helmholtz energy function]] when a small (differential) | |||
change of the surface area is performed at constant <math> V, T, </math> and <math> N </math>. | |||
The explicit equations can be written in terms of the diagonal components of the [[pressure]] tensor of the system. | |||
Mechanical arguments can also be invoked to arrive at equivalent conclusions (see Ref <ref name="Gloor"></ref> for a detailed discussion of these issues). | |||
=== System-size analysis === | |||
The [[Finite size effects |system-size dependence]] of the results for <math> \gamma </math> have to be taken into account in order to obtain accurate results for [[Models |model systems]]. | |||
Spurious effects that occur due to small system sizes can appear in the ''explicit interface'' methods. (See P.Orea ''et al.'' <ref>[http://dx.doi.org/10.1063/1.2018640 Pedro Orea, Jorge López-Lemus, and José Alejandre, "Oscillatory surface tension due to finite-size effects", Journal of Chemical Physics '''123''' 114702 (6 pages) (2005)]</ref>). | |||
== Mixtures == | |||
Different ensembles can be used to compute the surface tension between two phases in the case of mixtures (See for example see Y. Zhang ''et al.'' <ref>[http://dx.doi.org/10.1063/1.469927 Yuhong Zhang, Scott E. Feller, Bernard R. Brooks, and Richard W. Pastor, "Computer simulation of liquid/liquid interfaces. I. Theory and application to octane/water", Journal of Chemical Physics, '''103''', pp. 10252-10266 (1995)]</ref>). | |||
The simulation techniques are essentially the same as those for one-component systems, but different ensembles can be more adequate. | |||
For instance, for binary mixtures (with components 1 and 2), the [[isothermal-isobaric ensemble]], <math> N_1,N_2,p.T </math> is a ''more natural'' ensemble to compute | |||
<math> \gamma </math> using explicit interface techniques (See Ref. <ref>[http://dx.doi.org/10.1063/1.2751153 E. de Miguel, N. G. Almarza, and G. Jackson, "Surface tension of the Widom-Rowlinson model", Journal of Chemical Physics, '''127''', 034707 (10 pages) (2007)]</ref> as an example). | |||
In the case of the Binder technique | |||
the analysis can be carried out by fixing the total number of particles: <math> N \equiv N_1 + N_2 </math>, the [[pressure]], <math> p </math>, and the [[temperature]] <math> T </math>. Then | |||
one will have to compute the variation of the adequate thermodynamic potential as a function of the composition, e.g. <math> x_1 = N_1/N </math>. | |||
==See also== | |||
*[[Line tension]] | |||
*[[Boundary tension]] | |||
*[[Droplets]] | |||
==References== | |||
<references/> | |||
;Related reading | |||
*[http://dx.doi.org/10.1063/1.1747248 John G. Kirkwood and Frank P. Buff "The Statistical Mechanical Theory of Surface Tension", Journal of Chemical Physics '''17''' pp. 338-343 (1949)] | |||
*[http://dx.doi.org/10.1016/0021-9991(76)90078-4 Charles H. Bennett "Efficient estimation of free energy differences from Monte Carlo data", Journal of Computational Physics '''22''' pp. 245-268 (1976)] | |||
*[http://dx.doi.org/10.1063/1.432627 J. Miyazaki, J. A. Barker and G. M. Pound "A new Monte Carlo method for calculating surface tension", Journal of Chemical Physics '''64''' pp. 3364-3369 (1976)] | |||
*[https://doi.org/10.1016/j.molliq.2016.11.103 A. Maslechko, K. Glavatskiy, V.L. Kulinskii "Surface tension of molecular liquids: Lattice gas approach", Journal of Molecular Liquids '''235''' pp. 119-125 (2017)] | |||
*[https://doi.org/10.1016/j.molliq.2016.12.062 Stephan Werth, Martin Horsch and Hans Hasse "Molecular simulation of the surface tension of 33 multi-site models for real fluids", Journal of Molecular Liquids '''235''' pp. 126-134 (2017)] | |||
*[https://doi.org/10.1063/1.5008473 T. Dreher, C. Lemarchand, L. Soulard, E. Bourasseau, P. Malfreyt, and N. Pineau "Calculation of a solid/liquid surface tension: A methodological study", Journal of Chemical Physics '''148''' 034702 (2018)] | |||
==External links== | |||
*[http://dx.doi.org/10.4249/scholarpedia.9218 Charles Pfister "Interface free energy", Scholarpedia, 5(2):9218 (2010)] | |||
[[category: statistical mechanics]] |
Latest revision as of 12:26, 30 January 2018
The surface tension, , is a measure of the work required to create an interface between two bulk phases.
Thermodynamics[edit]
In the Canonical ensemble the surface tension is formally given as:
- ;
where
- is the Helmholtz energy function
- is the number of particles
- is the volume
- is the temperature
- is the surface area
Computer Simulation[edit]
Different techniques may be used to compute this quantity, such as the traditional stress tensor route. More recently, several methods have been proposed which avoid the some times difficult calculation of the stress tensor, e.g., the test area method and wandering interface method. A review can be found in the paper by Gloor et al. [1].
Liquid-Vapour Interfaces of one component systems[edit]
Binder procedure[edit]
Here, only an outline of the procedure is presented, more details can be found in [2]. For given conditions of volume and temperature, the Helmholtz energy function is computed as a function of the number of molecules, . The calculation is usually carried out using Monte Carlo simulation using periodic boundary conditions If liquid-vapour equilibrium occurs, a plot of the chemical potential, , as a function of shows a loop. Using basic thermodynamic procedures (Maxwell's equal area construction) it is possible to compute the densities of the two phases; at liquid-vapour equilibrium. Considering the thermodynamic limit for densities with the Helmholtz energy function will be:
where the quantities with the subindex "eq" are those corresponding to the fluid-phase equilibrium situation. From the previous equation one can write
- .
For appropriate values of one can estimate the value of the surface area, (See MacDowell et al. [3]), and compute directly as:
where and are given by: and
Explicit interfaces[edit]
In these methods one performs a direct simulation of the two-phase system. Periodic boundary conditions are usually employed. Simulation boxes are elongated in one direction, and the interfaces are built (and expected to stay) perpendicular to such a direction. Taking into account the canonical ensemble definition (see above), one computes the change in the Helmholtz energy function when a small (differential) change of the surface area is performed at constant and . The explicit equations can be written in terms of the diagonal components of the pressure tensor of the system. Mechanical arguments can also be invoked to arrive at equivalent conclusions (see Ref [1] for a detailed discussion of these issues).
System-size analysis[edit]
The system-size dependence of the results for have to be taken into account in order to obtain accurate results for model systems. Spurious effects that occur due to small system sizes can appear in the explicit interface methods. (See P.Orea et al. [4]).
Mixtures[edit]
Different ensembles can be used to compute the surface tension between two phases in the case of mixtures (See for example see Y. Zhang et al. [5]). The simulation techniques are essentially the same as those for one-component systems, but different ensembles can be more adequate. For instance, for binary mixtures (with components 1 and 2), the isothermal-isobaric ensemble, is a more natural ensemble to compute using explicit interface techniques (See Ref. [6] as an example). In the case of the Binder technique the analysis can be carried out by fixing the total number of particles: , the pressure, , and the temperature . Then one will have to compute the variation of the adequate thermodynamic potential as a function of the composition, e.g. .
See also[edit]
References[edit]
- ↑ 1.0 1.1 Guy J. Gloor, George Jackson, Felipe J. Blas and Enrique de Miguel "Test-area simulation method for the direct determination of the interfacial tension of systems with continuous or discontinuous potentials", Journal of Chemical Physics 123 134703 (2005)
- ↑ K. Binder "Monte Carlo calculation of the surface tension for two- and three-dimensional lattice-gas models", Physical Review A 25 pp. 1699 - 1709 (1982)
- ↑ L. G. MacDowell, V. K. Shen, and J. R. Errington "Nucleation and cavitation of spherical, cylindrical, and slablike droplets and bubbles in small systems", Journal of Chemical Physics 125 034705 (2006)
- ↑ Pedro Orea, Jorge López-Lemus, and José Alejandre, "Oscillatory surface tension due to finite-size effects", Journal of Chemical Physics 123 114702 (6 pages) (2005)
- ↑ Yuhong Zhang, Scott E. Feller, Bernard R. Brooks, and Richard W. Pastor, "Computer simulation of liquid/liquid interfaces. I. Theory and application to octane/water", Journal of Chemical Physics, 103, pp. 10252-10266 (1995)
- ↑ E. de Miguel, N. G. Almarza, and G. Jackson, "Surface tension of the Widom-Rowlinson model", Journal of Chemical Physics, 127, 034707 (10 pages) (2007)
- Related reading
- John G. Kirkwood and Frank P. Buff "The Statistical Mechanical Theory of Surface Tension", Journal of Chemical Physics 17 pp. 338-343 (1949)
- Charles H. Bennett "Efficient estimation of free energy differences from Monte Carlo data", Journal of Computational Physics 22 pp. 245-268 (1976)
- J. Miyazaki, J. A. Barker and G. M. Pound "A new Monte Carlo method for calculating surface tension", Journal of Chemical Physics 64 pp. 3364-3369 (1976)
- A. Maslechko, K. Glavatskiy, V.L. Kulinskii "Surface tension of molecular liquids: Lattice gas approach", Journal of Molecular Liquids 235 pp. 119-125 (2017)
- Stephan Werth, Martin Horsch and Hans Hasse "Molecular simulation of the surface tension of 33 multi-site models for real fluids", Journal of Molecular Liquids 235 pp. 126-134 (2017)
- T. Dreher, C. Lemarchand, L. Soulard, E. Bourasseau, P. Malfreyt, and N. Pineau "Calculation of a solid/liquid surface tension: A methodological study", Journal of Chemical Physics 148 034702 (2018)