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The Physics of Foams

The Physics of Foams. Image by M. Boran (Dublin). Simon Cox. Outline. Foam structure – rules and description Dynamics Prototypes for many other systems:

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The Physics of Foams

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  1. The Physics of Foams Image by M. Boran (Dublin) Simon Cox

  2. Outline • Foam structure – rules and description • Dynamics • Prototypes for many other systems: • metallic grain growth, biological organisms, crystal structure, emulsions,…

  3. Motivation • Many applications of industrial importance: • Oil recovery • Fire-fighting • Ore separation • Industrial cleaning • Vehicle manufacture • Food products

  4. Dynamic phenomena in Foams Must first understand the foam’s structure

  5. What is a foam? • Depends on the length-scale: • Depends on the liquid content: • hard-spheres, tiling of space, …

  6. How are foams made? from Weaire & Hutzler, The Physics of Foams (Oxford)

  7. Singlebubble Soap film minimizes its energy = surface area Least area way to enclose a given volume is a sphere. Isoperimetric problem (known to Greeks, proven in 19th century)

  8. Laplace-Young Law (200 years old) Mean curvature C of each film is balanced by the pressure difference across it: Coefficient of proportionality is the surface tension Soap films have constant mean curvature

  9. Plateau’s Rules • Minimization of area gives geometrical constraints (“observation” = Plateau, proof = Taylor): • Three (and only three) films meet, at 120°, in a Plateau border • Plateau borders always meet symmetrically in fours (Maraldi angle).

  10. Tetrahedral and Cubic Frames Plateau For each film, calculate shape that gives surface of zero mean curvature.

  11. Bubbles in wire frames D’Arcy Thompson

  12. Ken Brakke’s Surface Evolver “The Surface Evolver is software expressly designed for the modeling of soap bubbles, foams, and other liquid surfaces shaped by minimizing energy subject to various constraints …” http://www.susqu.edu/brakke/evolver/

  13. Easily observable “Two-dimensional” Foams Lawrence Bragg Cyril Stanley Smith (crystals) (grain growth) Plateau & Laplace-Young: in equilibrium, each film is a circular arc; they meet three-fold at 120°. Energy proportional to perimeter

  14. Topological changes • T1: neighbour swapping (reduces perimeter) • T2: bubble disappearance

  15. Describing 2D foam structure • Euler’s Law: • Second moment of number of edges per bubble:

  16. Describing foam structure Aboav-Weaire Law: where m(n) is the average number of sides of cells with n-sided neighbours. Applied (successfully) to many natural and artificial cellular structures. What is a?

  17. 2D space-filling structure Honeycomb conjecture Hales Fejes-Toth

  18. Finite 2D clusters Find minimal energy cluster for N bubbles. Proofs for N=2 and 3. Morgan et al. Wichiramala How many possibilities are there for each N?

  19. Work with Graner (Grenoble) and Vaz (Lisbon) Candidates for N=4 to 23, coloured by topological charge

  20. 200 bubbles Honeycomb structure in bulk; what shape should surface take?

  21. Lotus flowers Tarnai (Budapest) Seed heads represented by perimeter minima for bubbles inside a circular constraint? Also work on fly eyes (Carthew) and sea urchins (Raup, D’Arcy Thompson)

  22. Conformal Foams Drenckhan et al. (2004) , Eur. J. Phys. Bilinear maps preserve arcs of circles Conformal map f(z) preserves angles (120º) Equilibrium foam structure mapped onto equilibrium foam structure f(z) ~ ez Logarithmic spiral

  23. Gravity’s Rainbow Drenckhan et al. (2004) , Eur. J. Phys. Setup Theoretical prediction Experimental result rotational symmetry translational symmetry w = (ia)-1log(iaz) w ~ z1/(1-)

  24. ratio: bubble diameter / tube diameter gas - pressure; nozzle diameter Ordered Foams in 3D (Elias, Hutzler, Drenckhan)

  25. Description of 3D bulk structure • Topological changes similar, but more possibilities. • restricts possible regular structures. • Second moment: • Sauter mean radius: (polydisperse) • Aboav-Weaire Law (Euler, Coxeter, Kusner)

  26. 3D space-filling structure Polyhedral cells with curved faces packed together to fill space. What’s the best arrangement? (Kelvin problem) Euler & Plateau: need structure with average of 13.39 faces and 5.1 edges per face 14 “delicately curved”faces (6 squares, 8 hexagons) <E>=5.14 See Weaire (ed), The Kelvin Problem (1994) Kelvin’s Bedspring (tetrakaidecahedron)

  27. Weaire-Phelan structure Kelvin’s candidate structure reigned for 100 years WP is based on A15 TCP structure/ β-tungsten clathrate <F>=13.5, <E>=5.111 0.3% lower in surface area 2 pentagonal dodecahedra 6 Goldberg 14-hedra Swimming pool for 2008 Beijing Olympics (ARUP) Surface Evolver

  28. 3D Monodisperse Foams nergy Matzke Quasi-crystals?

  29. Finite 3D clusters Find minimal energy cluster for N bubbles. Must eliminate strange possibilities: J.M.Sullivan (Berlin) Proof that “obvious” answer is the right one for N=2 bubbles in 3D, but for no greater N.

  30. Finite 3D clusters 27 bubbles surround one other DWT Central bubble from 123 bubble cluster

  31. Dynamics Coarsening Drainage Rheology Graner, Cloetens (Grenoble)

  32. Coarsening Gas diffuses across soap films due to pressure differences between bubbles. Von Neumann’s Law - rate of change of area due to gas diffusion depends only upon number of sides: T1 s and T2 s Only in 2D. Also applies to grain growth.

  33. Coarsening In 3D, Stationary bubble has 13.39 faces

  34. Foam Rheology • Elastic solids at low strain • Behave as plastic solids as strain increases • Liquid-like at very high strain • Exploit bubble-scale structure (Plateau’s laws) to predict and model the rheological response of foams. • Energy dissipated through topological changes (even in limit of zero shear-rate). • Properties scale with average bubble area.

  35. 2D contraction flow J.A. Glazier (Indiana)

  36. Couette Shear (Experiment) Much faster than real-time. Experiment by G. Debregeas (Paris), PRL ‘01 Shear banding? Localization? cf Lauridsen et al. PRL 2002

  37. Couette Shear Simulations Quasistatic: Include viscous drag on bounding plates:

  38. Outlook This apparently complex two-phase material has a well-defined local structure. This structure allows progress in predicting the dynamic properties of foams The Voronoi construction provides a useful starting condition (e.g. for simulations and special cases) but neglects the all-important curvature.

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