English

On a Model for Mass Aggregation with Maximal Size

Analysis of PDEs 2012-05-22 v2 Mathematical Physics math.MP

Abstract

We study a kinetic mean-field equation for a system of particles with different sizes, in which particles are allowed to coagulate only if their sizes sum up to a prescribed time-dependent value. We prove well-posedness of this model, study the existence of self-similar solutions, and analyze the large-time behavior mostly by numerical simulations. Depending on the parameter \Dconst\Dconst, which controls the probability of coagulation, we observe two different scenarios: For \Dconst>2\Dconst>2 there exist two self-similar solutions to the mean field equation, of which one is unstable. In numerical simulations we observe that for all initial data the rescaled solutions converge to the stable self-similar solution. For \Dconst<2\Dconst<2, however, no self-similar behavior occurs as the solutions converge in the original variables to a limit that depends strongly on the initial data. We prove rigorously a corresponding statement for \Dconst(0,1/3)\Dconst\in (0,1/3). Simulations for the cross-over case \Dconst=2\Dconst=2 are not completely conclusive, but indicate that, depending on the initial data, part of the mass evolves in a self-similar fashion whereas another part of the mass remains in the small particles.

Keywords

Cite

@article{arxiv.0912.1797,
  title  = {On a Model for Mass Aggregation with Maximal Size},
  author = {Ondrej Budáč and Michael Herrmann and Barbara Niethammer and Andrej Spielmann},
  journal= {arXiv preprint arXiv:0912.1797},
  year   = {2012}
}

Comments

new version with revised proofs; 13 pages, several figures

R2 v1 2026-06-21T14:21:47.454Z