Hard sphere model

The hard sphere model (sometimes known as the rigid sphere model) is defined as

\( \Phi_{12}\left( r \right) = \left\{ \begin{array}{lll} \infty & ; & r < \sigma \\ 0 & ; & r \ge \sigma \end{array} \right. \)

where \( \Phi_{12}\left(r \right) \) is the intermolecular pair potential between two spheres at a distance \(r := |\mathbf{r}_1 - \mathbf{r}_2|\), and \( \sigma \) is the diameter of the sphere. The hard sphere model can be considered to be a special case of the hard ellipsoid model, where each of the semi-axes has the same length, \(a=b=c\).

[edit] First simulations of hard spheres (1954-1957)

The hard sphere model, along with its two-dimensional manifestation hard disks, was one of the first ever systems studied using computer simulation techniques with a view to understanding the thermodynamics of the liquid and solid phases and their corresponding phase transition ^{[1] [2] [3]}, much of this work undertaken at the Los Alamos Scientific Laboratory on the world's first electronic digital computer ENIAC ^[4].

[edit] Liquid phase radial distribution function

The following are a series of plots of the hard sphere radial distribution function ^[5]. The horizontal axis is in units of \(\sigma\) where \(\sigma\) is set to be 1. Click on image of interest to see a larger view.

\(\rho=0.2\)	\(\rho=0.3\)	\(\rho=0.4\)
\(\rho=0.5\)	\(\rho=0.6\)	\(\rho=0.7\)
\(\rho=0.8\)	\(\rho=0.85\)	\(\rho=0.9\)

The value of the radial distribution at contact, \({\mathrm g}(\sigma^+)\), can be used to calculate the pressure via the equation of state (Eq. 1 in ^[6]) \[\frac{p}{\rho k_BT}= 1 + B_2 \rho {\mathrm g}(\sigma^+)\] where the second virial coefficient, \(B_2\), is given by \[B_2 = \frac{2\pi}{3}\sigma^3\]. Carnahan and Starling ^[7] provided the following expression for \({\mathrm g}(\sigma^+)\) (Eq. 3 in ^[6]) \[{\mathrm g}(\sigma^+)= \frac{1-\eta/2}{(1-\eta)^3}\] where \(\eta\) is the packing fraction.

Over the years many groups have studied the radial distribution function of the hard sphere model: ^{[8] [9] [10] [11] [12] [13] [14] [15] [16] [17] [18]}

[edit] Liquid-solid transition

The hard sphere system undergoes a liquid-solid first order transition ^[19], sometimes referred to as the Kirkwood-Alder transition ^[20]. The liquid-solid coexistence densities (\(\rho^* = \rho \sigma^3\)) are given by

\(\rho^*_{\mathrm {solid}}\)	\(\rho^*_{\mathrm {liquid}}\)	Reference
1.041	0.945	[19]
1.0376	0.9391	[21]
1.0367(10)	0.9387(10)	[22]
1.0372	0.9387	[23]
1.0369(33)	0.9375(14)	[24]
1.037	0.938	[25]
1.035(3)	0.936(2)	[26]

The coexistence pressure is given by

\(p (k_BT/\sigma^3) \)	Reference
11.567	[21]
11.57(10)	[22]
11.54(4)	[24]
11.50(9)	[27]
11.55(11)	[28]
11.48(11)	[26]
11.43(17)	[29]

The coexistence chemical potential is given by

\(\mu (k_BT) \)	Reference
15.980(11)	[26]

The Helmholtz energy function (in units of \(Nk_BT\)) is given by

\(A_{\mathrm {solid}}\)	\(A_{\mathrm {liquid}}\)	Reference
4.887(3)	3.719(8)	[26]

[edit] Helmholtz energy function

Values for the Helmholtz energy function (\(A\)) are given in the following Table:

\(\rho^*\)	\(A/(Nk_BT)\)	Reference
0.25	0.620 \(\pm\) 0.002	Table I [30]
0.50	1.541 \(\pm\) 0.002	Table I [30]
0.75	3.009 \(\pm\) 0.002	Table I [30]
1.04086	4.959	Table VI [23]
1.099975	5.631	Table VI [23]
1.150000	6.274	Table VI [23]

[edit] Interfacial Helmholtz energy function

The Helmholtz energy function of the solid–liquid interface has been calculated using the cleaving method giving (Ref. ^[31] Table I):

	work per unit area/\((k_BT/\sigma^2)\)
\(\gamma_{100}\)	0.5820(19)
\(\gamma_{110}\)	0.5590(20)
\(\gamma_{111}\)	0.5416(31)
\(\gamma_{120}\)	0.5669(20)

[edit] Solid structure

The Kepler conjecture states that the optimal packing for three dimensional spheres is either cubic or hexagonal close packing, both of which have maximum densities of \(\pi/(3 \sqrt{2}) \approx 74.048%\) ^{[32] [33]}. However, for hard spheres at close packing the face centred cubic phase is the more stable ^[34]

• See also: Equations of state for crystals of hard spheres

[edit] Direct correlation function

For the direct correlation function see: ^{[35] [36]}

[edit] Bridge function

Details of the bridge function for hard sphere can be found in the following publication ^[37]

[edit] Equations of state

Main article: Equations of state for hard spheres

[edit] Virial coefficients

Main article: Hard sphere: virial coefficients

[edit] Experimental results

Pusey and van Megen used a suspension of PMMA particles of radius 305 \(\pm\)10 nm, suspended in poly-12-hydroxystearic acid ^[38] For results obtained from the Colloidal Disorder - Order Transition (CDOT) experiments performed on-board the Space Shuttles Columbia and Discovery see Ref. ^[39]

[edit] Mixtures

• Binary hard-sphere mixtures
• Multicomponent hard-sphere mixtures

[edit] Related systems

• Quantum hard spheres
• Dipolar hard spheres
• Lattice hard spheres

Hard spheres in other dimensions:

• 1-dimensional case: hard rods.
• 2-dimensional case: hard disks.
• Hard hyperspheres

[edit] References

1. ↑ Marshall N. Rosenbluth and Arianna W. Rosenbluth "Further Results on Monte Carlo Equations of State", Journal of Chemical Physics 22 pp. 881-884 (1954)
2. ↑ W. W. Wood and J. D. Jacobson "Preliminary Results from a Recalculation of the Monte Carlo Equation of State of Hard Spheres", Journal of Chemical Physics 27 pp. 1207-1208 (1957)
3. ↑ B. J. Alder and T. E. Wainwright "Phase Transition for a Hard Sphere System", Journal of Chemical Physics 27 pp. 1208-1209 (1957)
4. ↑ The ENIAC Story
5. ↑ The total correlation function data was produced using the computer code written by Jiří Kolafa
6. ↑ ^{6.0 6.1} Fu-Ming Tao, Yuhua Song, and E. A. Mason "Derivative of the hard-sphere radial distribution function at contact", Physical Review A 46 pp. 8007-8008 (1992)
7. ↑ N. F.Carnahan and K. E.Starling,"Equation of State for Nonattracting Rigid Spheres" Journal of Chemical Physics 51 pp. 635-636 (1969)
8. ↑ John G. Kirkwood, Eugene K. Maun, and Berni J. Alder "Radial Distribution Functions and the Equation of State of a Fluid Composed of Rigid Spherical Molecules", Journal of Chemical Physics 18 pp. 1040- (1950)
9. ↑ B. R. A. Nijboer and L. Van Hove "Radial Distribution Function of a Gas of Hard Spheres and the Superposition Approximation", Physical Review 85 pp. 777 - 783 (1952)
10. ↑ B. J. Alder, S. P. Frankel, and V. A. Lewinson "Radial Distribution Function Calculated by the Monte-Carlo Method for a Hard Sphere Fluid", Journal of Chemical Physics 23 pp. 417- (1955)
11. ↑ Francis H. Ree, R. Norris Keeler, and Shaun L. McCarthy "Radial Distribution Function of Hard Spheres", Journal of Chemical Physics 44 pp. 3407- (1966)
12. ↑ W. R. Smith and D. Henderson "Analytical representation of the Percus-Yevick hard-sphere radial distribution function", Molecular Physics 19 pp. 411-415 (1970)
13. ↑ J. A. Barker and D. Henderson "Monte Carlo values for the radial distribution function of a system of fluid hard spheres", Molecular Physics 21 pp. 187-191 (1971)
14. ↑ J. M. Kincaid and J. J. Weis "Radial distribution function of a hard-sphere solid", Molecular Physics 34 pp. 931-938 (1977)
15. ↑ S. Bravo Yuste and A. Santos "Radial distribution function for hard spheres", Physical Review A 43 pp. 5418-5423 (1991)
16. ↑ Jaeeon Chang and Stanley I. Sandler "A real function representation for the structure of the hard-sphere fluid", Molecular Physics 81 pp. 735-744 (1994)
17. ↑ Andrij Trokhymchuk, Ivo Nezbeda and Jan Jirsák "Hard-sphere radial distribution function again", Journal of Chemical Physics 123 024501 (2005)
18. ↑ M. López de Haro, A. Santos and S. B. Yuste "On the radial distribution function of a hard-sphere fluid", Journal of Chemical Physics 124 236102 (2006)
19. ↑ ^{19.0 19.1} William G. Hoover and Francis H. Ree "Melting Transition and Communal Entropy for Hard Spheres", Journal of Chemical Physics 49 pp. 3609-3617 (1968)
20. ↑ Alice P. Gast and William B. Russel "Simple Ordering in Complex Fluids", Physics Today 51 (12) pp. 24-30 (1998)
21. ↑ ^{21.0 21.1} Daan Frenkel and Berend Smit "Understanding Molecular Simulation: From Algorithms to Applications", Second Edition (2002) (ISBN 0-12-267351-4) p. 261.
22. ↑ ^{22.0 22.1} Andrea Fortini and Marjolein Dijkstra "Phase behaviour of hard spheres confined between parallel hard plates: manipulation of colloidal crystal structures by confinement", Journal of Physics: Condensed Matter 18 pp. L371-L378 (2006)
23. ↑ ^{23.0 23.1 23.2 23.3} Carlos Vega and Eva G. Noya "Revisiting the Frenkel-Ladd method to compute the free energy of solids: The Einstein molecule approach", Journal of Chemical Physics 127 154113 (2007)
24. ↑ ^{24.0 24.1} Eva G. Noya, Carlos Vega, and Enrique de Miguel "Determination of the melting point of hard spheres from direct coexistence simulation methods", Journal of Chemical Physics 128 154507 (2008)
25. ↑ Ruslan L. Davidchack and Brian B. Laird "Simulation of the hard-sphere crystal–melt interface", Journal of Chemical Physics 108 pp. 9452-9462 (1998)
26. ↑ ^{26.0 26.1 26.2 26.3} Enrique de Miguel "Estimating errors in free energy calculations from thermodynamic integration using fitted data", Journal of Chemical Physics 129 214112 (2008)
27. ↑ N. B. Wilding and A. D. Bruce "Freezing by Monte Carlo Phase Switch", Physical Review Letters 85 pp. 5138-5141 (2000)
28. ↑ Robin J. Speedy "Pressure of the metastable hard-sphere fluid", Journal of Physics: Condensed Matter 9 pp. 8591-8599 (1997)
29. ↑ G. Odriozola "Replica exchange Monte Carlo applied to hard spheres", Journal of Chemical Physics 131 144107 (2009)
30. ↑ ^{30.0 30.1 30.2} T. Schilling and F. Schmid "Computing absolute free energies of disordered structures by molecular simulation", Journal of Chemical Physics 131 231102 (2009)
31. ↑ Ruslan L. Davidchack "Hard spheres revisited: Accurate calculation of the solid–liquid interfacial free energy", Journal of Chemical Physics 133 234701 (2010)
32. ↑ Neil J. A. Sloane "Kepler's conjecture confirmed", Nature 395 pp. 435-436 (1998)
33. ↑ C. F. Tejero, M. S. Ripoll, and A. Pérez "Pressure of the hard-sphere solid", Physical Review E 52 pp. 3632-3636 (1995)
34. ↑ Leslie V. Woodcock "Computation of the free energy for alternative crystal structures of hard spheres", Faraday Discussions 106 pp. 325 - 338 (1997)
35. ↑ C. F. Tejero and M. López De Haro "Direct correlation function of the hard-sphere fluid", Molecular Physics 105 pp. 2999-3004 (2007)
36. ↑ Matthew Dennison, Andrew J. Masters, David L. Cheung, and Michael P. Allen "Calculation of direct correlation function for hard particles using a virial expansion", Molecular Physics pp. 375-382 (2009)
37. ↑ Jiri Kolafa, Stanislav Labik and Anatol Malijevsky "The bridge function of hard spheres by direct inversion of computer simulation data", Molecular Physics 100 pp. 2629-2640 (2002)
38. ↑ P. N. Pusey and W. van Megen "Phase behaviour of concentrated suspensions of nearly hard colloidal spheres", Nature 320 pp. 340-342 (1986)
39. ↑ Z. Chenga, P. M. Chaikina, W. B. Russelb, W. V. Meyerc, J. Zhub, R. B. Rogersc and R. H. Ottewilld, "Phase diagram of hard spheres", Materials & Design 22 pp. 529-534 (2001)

Related reading

• "Theory and Simulation of Hard-Sphere Fluids and Related Systems", Lecture Notes in Physics 753/2008 Springer (2008)
• Laura Filion, Michiel Hermes, Ran Ni and Marjolein Dijkstra "Crystal nucleation of hard spheres using molecular dynamics, umbrella sampling, and forward flux sampling: A comparison of simulation techniques", Journal of Chemical Physics 133 244115 (2010)

[edit] External links

• Hard disks and spheres computer code on SMAC-wiki.