Computational methods to study jammed systems

doi:10.1017/CBO9780511760549.002

2 - Computational methods to study jammed systems

Published online by Cambridge University Press: 05 July 2014

Carl F. Schreck and

Corey S. O'hern

Edited by

Jeffrey Olafsen

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Carl F. Schreck: Affiliation:
Yale University
Corey S. O'hern: Affiliation:
Yale University
Jeffrey Olafsen: Affiliation:
Baylor University, Texas

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Summary

Introduction

Jammed materials are ubiquitous in nature and share several defining characteristics. They are disordered, yet solid-like with a nonzero static shear modulus. Jammed systems typically exist in metastable states with structural and mechanical properties that depend on the procedure used to create them. There are a number of different routes to the jammed state, including compressing systems to densities near random close packing [1], lowering the applied shear stress below the yield stress [2], and quenching temperature below the glass transition for the material [3]. Examples of jammed and glassy particulate systems include dense colloidal suspensions [4], attractive glasses and gels [5], static packings of granular materials [6], and quiescent foams [7] and emulsions [8]. Due to space constraints, we will limit our discussion to athermal jammed systems in which thermal energy at room temperature is unable to induce local rearrangements of particles. We note though that there are deep connections [9] between athermal jammed systems and thermal, glassy systems [10]. An important open problem in the field of jammed materials is identifying universal features that are not sensitive to the particular path in parameter space taken to create them.

In this contribution, we will review the computational techniques used to generate athermal jammed systems and characterize their structural and mechanical properties. We will focus on frictionless model systems that interact via soft, pairwise, and purely repulsive potentials. (Computational studies of frictional granular materials will be the focus of Chapter 5.) The methods for generating jammed particle packings discussed here are quite general and can be employed to study both two- and three-dimensional systems; both monodisperse and polydisperse systems; a spectrum of particle shapes, including spheres, ellipsoids, and rods; and a variety of boundary conditions and applied stress.

Type: Chapter
Information: Experimental and Computational Techniques in Soft Condensed Matter Physics , pp. 25 - 61

DOI: https://doi.org/10.1017/CBO9780511760549.002 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2010

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References

[1] S., Torquato, T. M., Truskett, and P. G., Debenedetti, “Is random close packing of spheres well defined?” Phys. Rev. Lett. 84, 2064 (2000).Google Scholar

[2] N., Xu and C. S., O'Hern, “Measurements of the yield stress in frictionless granular systems,” Phys. Rev. E 73, 061303 (2006).Google Scholar

[3] W., Kob and H. C., Andersen, “Testing mode-coupling theory for a supercooled binary Lennard-Jones mixture I: the van Hove correlation function,” Phys. Rev. E 51, 4626 (1995).Google Scholar

[4] P. N., Pusey and W., van Megan, “Observation of a glass transition in suspensions of spherical colloidal particles,” Phys. Rev. Lett. 59, 2083 (1987).Google Scholar

[5] K. N., Pham, A. M., Puertas, J., Bergenholtz, S. U., Egelhaaf, A., Mousai'd, P. N., Pusey, A. B., Schofield, M. E., Cates, M., Fuchs, and W. C. K., Poon, “Multiple glassy states in a simple model system,” Science 296, 104 (2002).Google Scholar

[6] L. E., Silbert, D., Ertas, G. S., Grest, T. C., Halsey, and D., Levine, “Geometry of frictionless and frictional sphere packings,” Phys. Rev. E 65, 031304 (2002).Google Scholar

[7] D. J., Durian and D. A., Weitz, “Foams,” in J. I., Kroschwitz (ed.), Kirk-Othmer Encyclopedia of Chemical Technology, Vol. 11, p. 783, 4th edition (Wiley, New York, 1994).Google Scholar

[8] T. G., Mason, J., Bibette, and D. A., Weitz, “Elasticity of compressed emulsions,” Phys. Rev. Lett. 75, 2051 (1995).Google Scholar

[9] Z., Zhang, N., Xu, D. D. N., Chen, P., Yunker, A. M., Alsayed, K. B., Aptowicz, P., Habdas, A. J., Liu, S. R., Nagel, and A. G., Yodh, “Thermal vestige of the zero-temperature jamming transition,” Nature 459, 230 (2009).Google Scholar

[10] P. G., Debenedetti and F. H., Stillinger, “Supercooled liquids and the glass transition,” Nature 410, 259 (2001).Google Scholar

[11] A., Tanguy, J. P., Wittmer, F., Leonforte, and J.-L., Barrat, “Continuum limit of amorphous elastic bodies: a finite-size study of low frequency harmonic vibrations,” Phys. Rev. B 66, 174205 (2002).Google Scholar

[12] B. D., Lubachevsky, F. H., Stillinger, and E. N., Pinson, “Disks vs. spheres: contrasting properties of random packings,” J. Stat. Phys. 64, 501 (1991).Google Scholar

[13] C. O., O'Hern, L. E., Silbert, A.J, Liu, and S. R., Nagel, “Jamming at zero temperature and zero applied stress: the epitome of disorder,” Phys. Rev. Lett. 68, 011306 (2003).Google Scholar

[14] N., Xu, J., Blawzdziewicz, and C. S., O'Hern, “Reexamination of random close packing: ways to pack frictionless disks,” Phys. Rev. E 71, 061306 (2005).Google Scholar

[15] G.-J., Gao, J., Blawzdziewicz, and C. S., O'Hern, “Studies of the frequency distribution of mechanically stable disk packings,” Phys. Rev. E 74, 061304 (2006).Google Scholar

[16] A., Donev, R., Connelly, F. H., Stillinger, and S., Torquato, “Underconstrained jammed packings of hard ellipsoids,” Phys. Rev. E 75, 051304 (2007).Google Scholar

[17] W. S., Jodrey and E. M., Tory, “Computer simulation of close random packing of equal spheres,” Phys. Rev. A 32, 2347 (1985).Google Scholar

[18] R. J., Speedy, “Random jammed packings of hard discs and spheres,” J. Phys.: Condens. Matter 10, 4185 (1998).Google Scholar

[19] A., Zinchenko, “Algorithm for random close packing of spheres with periodic boundary conditions,” J. Comput. Phys. 114, 298 (1994).Google Scholar

[20] W. H., Press, B. P., Flannery, S. A., Teukolsky, and W. T., Vetterling, Numerical Recipes in Fortran 77 (Cambridge University Press, New York, 1986).Google Scholar

[21] T., Majmudar and R. P., Behringer, “Contact force measurements and stress-induced anisotropy in granular materials,” Nature 435, 1079 (2005).Google Scholar

[22] S., Henkes, C. S., O'Hern, and B., Chakraborty, “Entropy and temperature of a static granular assembly: an ab initio approach,” Phys. Rev. Lett. 99, 038002 (2007).Google Scholar

[23] G., Lois, J., Xie, T., Majmudar, S., Henkes, B., Chakraborty, C. S., O'Hern, and R., Behringer, “Stress correlations in granular materials: An entropic formulation,” Phys. Rev. E 80, 060303(R) (2009).Google Scholar

[24] S., Henkes and B., Chakraborty, “Statistical mechanics framework for static granular matter,” Phys. Rev. E 79, 061301 (2009).Google Scholar

[25] M., Lundberg, K., Krishan, N., Xu, C. S., O'Hern, and M., Dennin, “Comparison of low amplitude oscillatory shear in experimental and computational studies of model foams,” Phys. Rev. E 79, 041505 (2009).Google Scholar

[26] B., Miller, C., O'Hern, and R. P., Behringer, “Stress fluctuations for continuously sheared granular materials,” Phys. Rev. Lett. 77, 3100 (1996).Google Scholar

[27] M. P., Allen and D. J., Tildesley, Computer Simulation of Liquids (Oxford University Press, New York, 1987).Google Scholar

[28] G.-J., Gao, J., Blawzdziewicz, and C. S., O'Hern, “Geometric families of mechanically stable granular packings,” Phys. Rev. E 80, 061303 (2009).Google Scholar

[29] D. J., Lacks and M. J., Osborne, “Energy landscape picture of overaging and rejuvenation in a sheared glass,” Phys. Rev. Lett. 93, 255501 (2004).Google Scholar

[30] B. A., Isner and D. J., Lacks, “Generic rugged landscapes under strain and the possibility of rejuvenation in glasses,” Phys. Rev. Lett. 96, 025506 (2006).Google Scholar

[31] G., Parisi and F., Zamponi, “Mean field theory of hard sphere glasses and jamming,” to appear in Rev. Mod. Phys. 82, 789 (2010).Google Scholar

[32] L., Santen and W., Krauth, “Absence of thermodynamic phase transition in a model glass former,” Nature 405, 550 (2000).Google Scholar

[33] M., Mailman, C. F., Schreck, C. S., O'Hern, and B., Chakraborty, “Jamming in systems of ellipse-shapes particles,” Phys. Rev. Lett. 102, 255501 (2009).Google Scholar

[34] C., Schreck, J.-K., Yang, H., Noh, H., Cao, and C. S., O'Hern, “Pseudo band gaps in two-dimensional amorphous materials,” unpublished 2010.

[35] D., Brown and J. H. R., Clarke, “Constant-stress nonequilibrium molecular dynamics: shearing of the soft-sphere crystal and fluid,” Phys. Rev. A 34, 2093 (1986).Google Scholar

[36] G.-J., Gao, J., Blawzdziewicz, C. S., O'Hern, and M., Shattuck, “Experimental demonstration of nonuniform frequency distributions of granular packings,” Phys. Rev. E 80, 061304 (2009).Google Scholar

[37] Z., Zeravcic, N., Xu, A., Liu, S., Nagel, and W., van Saarloos, “Excitations of ellipsoid packings near jamming,” Europhys. Lett. 87, 26001 (2009).Google Scholar

[38] B. J., Berne and P., Pechukas, “Gaussian model potentials for molecular interactions,” J. Chem. Phys. 56, 4213 (1972).Google Scholar

[39] J. G., Gay and B. J., Berne, “Modification of the overlap potential to mimic a linear site-site potential,” J. Comp. Phys. 74, 3316 (1981).Google Scholar

[40] D. J., Cleaver, C. M., Care, M. P., Allen, and M. P, Neal, “Extension and generalization of the Gay-Berne potential,” Phys. Rev. E 54, 559 (1996).Google Scholar

[41] J. W., Perram and M. S., Wertheim, “Statistical mechanics of hard ellipsoids I: overlap algorithm and the contact function,” J. Comp. Phys. 58, 409 (1985).Google Scholar

[42] J. W., Perram, J., Rasmussen, and E., Prœtgaard, “Ellipsoid contact potential: theory and relation to overlap potentials,” Phys. Rev. E. 54, 6565 (1996).Google Scholar

[43] C., Schreck and C. S., O'Hern, “A new jamming critical point controls the glassy dynamics of ellipsoidal particles,” unpublished 2010.Google Scholar

[44] S., Torquato and F. H., Stillinger, “Multiplicity of generation, selection, and classification procedures for jammed hard-particle packings”, J. Phys. Chem. B 105, 11849 (2001).Google Scholar

[45] C. F., Moukarzel, “Isostatic phase transition and instability in stiff granular materials,” Phys. Rev. Lett. 81, 1634 (1998).Google Scholar

[46] R., Blumenfeld, “Stresses in isostatic granular systems and emergence of force chains,” Phys. Rev. Lett. 93, 108301 (2004).Google Scholar

[47] H. A., Makse, D. L., Johnson, and L. M., Schwartz, “Packing of compressible granular materials,” Phys. Rev. Lett. 84, 4160 (2000).Google Scholar

[48] C. S., O'Hern, S. A., Langer, A. J., Liu, and S. R., Nagel, “Random packing of frictionless particles,” Phys. Rev. Lett. 88, 075507 (2002).Google Scholar

[49] W., Kob, C., Donati, S. J., Plimpton, P. H., Poole, and S. C., Glotzer, “Dynamical heterogeneities in a supercooled Lennard-Jones liquid,” Phys. Rev. Lett. 79, 2827 (1997).Google Scholar

[50] L. E., Silbert, A. J., Liu, and S. R., Nagel, “Structural signatures of the unjamming transition at zero temperature,” Phys. Rev. E 73, 041304 (2006).Google Scholar

[51] A., Donev, F. H., Stillinger, and S., Torquato, “Unexpected density fluctuations in jammed disordered sphere packings,” Phys. Rev. Lett. 95, 090604 (2005).Google Scholar

[52] K. E., Daniels and R. P., Behringer, “Hysteresis and competition between disorder and crystallization in sheared and vibrated granular flow,” Phys. Rev. Lett. 94, 168001 (2005).Google Scholar

[53] N., Duff and D. J., Lacks, “Shear-induced crystallization in jammed systems,” Phys. Rev. E 75, 031501 (2007).Google Scholar

[54] T. M., Truskett, S., Torquato, and P. G., Debenedetti, “Towards a quantification of disorder in materials: distinguishing equilibrium and glassy sphere packings,” Phys. Rev. E 62, 993 (2000).Google Scholar

[55] H.-J., Lee, T., Cagin, W. L., Johnson, and W. A., Goddard, “Criteria for formation of metallic glasses: the role of atomic size ratio,” J. Chem. Phys. 119, 9858 (2003).Google Scholar

[56] C., De Michele, R., Schilling, and F., Sciortino, “Dynamics of unixial hard ellipsoids,” Phys. Rev. Lett. 98, 265702 (2007).Google Scholar

[57] P. J., Steinhardt, D. R., Nelson, and M., Ronchetti, “Bond-orientational order in liquids and glasses,” Phys. Rev. B 28, 784 (1983).Google Scholar

[58] L. E., Silbert, A. J., Liu, and S. R., Nagel, “Vibrations and diverging length scales near the unjamming transition,” Phys. Rev. Lett. 95, 098301 (2005).Google Scholar

[59] W. G., Ellenbroek, E., Somfai, and M., van Hecke, W., van Saarloos, “Critical scaling in linear response of frictionless granular packings near jamming,” Phys. Rev. Lett. 97, 258001 (2006).Google Scholar

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