English

Jamming of Deformable Polygons

Soft Condensed Matter 2018-12-19 v3

Abstract

There are two main classes of physics-based models for two-dimensional cellular materials: packings of repulsive disks and the vertex model. These models have several disadvantages. For example, disk interactions are typically a function of particle overlap, yet the model assumes that the disks remain circular during overlap. The shapes of the cells can vary in the vertex model, however, the packing fraction is fixed at ϕ=1\phi=1. Here, we describe the deformable particle model (DPM), where each particle is a polygon composed of a large number of vertices. The total energy includes three terms: two quadratic terms to penalize deviations from the preferred particle area a0a_0 and perimeter p0p_0 and a repulsive interaction between DPM polygons that penalizes overlaps. We performed simulations to study the onset of jamming in packings of DPM polygons as a function of asphericity, A=p02/4πa0{\cal A} = p_0^2/4\pi a_0. We show that the packing fraction at jamming onset ϕJ(A)\phi_J({\cal A}) grows with increasing A{\cal A}, reaching confluence at A1.16{\cal A} \approx 1.16. A{\cal A}^* corresponds to the value at which DPM polygons completely fill the cells obtained from a surface-Voronoi tessellation. Further, we show that DPM polygons develop invaginations for A>A{\cal A} > {\cal A}^* with excess perimeter that grows linearly with AA{\cal A}-{\cal A}^*. We confirm that packings of DPM polygons are solid-like over the full range of A{\cal A} by showing that the shear modulus is nonzero.

Keywords

Cite

@article{arxiv.1801.06150,
  title  = {Jamming of Deformable Polygons},
  author = {Arman Boromand and Alexandra Signoriello and Fangfu Ye and Corey S. O'Hern and Mark D. Shattuck},
  journal= {arXiv preprint arXiv:1801.06150},
  year   = {2018}
}

Comments

6 pages, 5 figures

R2 v1 2026-06-22T23:49:06.565Z