https://doi.org/10.1140/epjb/e2003-00185-4
Stratifications of cellular patterns: hysteresis and convergence
1
LPTM (CNRS & UCP UMR 8089) , Université de Cergy-Pontoise,
95031 Cergy-Pontoise, France
2
LDFC, Université Louis Pasteur, 67084 Strasbourg, France
3
Dep. of Applied Mathematics, RSPHYSSE, Australian National University,
ACT 0200 Canberra, Australia
Corresponding author: a oguey@ptm.u-cergy.fr
Received:
14
November
2002
Revised:
14
May
2003
Published online:
3
July
2003
A foam is a space-filling cellular pattern, that can be decomposed into successive layers or strata. Each layer contains all cells at the same topological distance to an origin (cell, cluster of cells, or basal layer). The disorder of the underlying structure imposes a characteristic roughening of the layers. In this paper, stratifications are described as the results a deterministic “invasion" process started from different origins in the same, given foam. We compare different stratifications of the same foam. Our main results are 1) hysteresis and 2) convergence in the sequence of layers. 1) If the progression direction is reversed, the layers in the up and down sequences differ (irreversibility of the invasion process); nevertheless, going back up, the layers return exactly to the top profile. This hysteresis phenomenon is established rigorously from elementary properties of graphs and processes. 2) Layer sequences based on different origins (e.g. different starting cells) converge, in cylindrical geometry. Jogs in layers may be represented as pairs of opposite dislocations, that move erratically because the underlying structure is disordered, and end up annihilating when colliding. Convergence is demonstrated and quantified by numerical simulations on a two dimensional columnar model.
PACS: 89.75.Fb – Structures and organization in complex systems / 82.70.Rr – Aerosols and foams / 05.90.+m – Other topics in statistical physics, thermodynamics, and nonlinear dynamical systems: “random graphs" / 87.18.Hf – Spatiotemporal pattern formation in cellular populations
© EDP Sciences, Società Italiana di Fisica, Springer-Verlag, 2003