English

Critical thresholds in flocking hydrodynamics\\with nonlocal alignment

Analysis of PDEs 2015-06-19 v1

Abstract

We study the large-time behavior of Eulerian systems augmented with non-local alignment. Such systems arise as hydrodynamic descriptions of agent-based models for self-organized dynamics, e.g., Cucker-Smale and Motsch-Tadmor models \cite{CS,MT}. We prove that in analogy with the agent-based models, the presence of non-local alignment enforces \emph{strong} solutions to self-organize into a macroscopic flock. This then raises the question of existence of such strong solutions. We address this question in one- and two-dimensional setups, proving global regularity for \emph{sub-critical} initial data. Indeed, we show that there exist \emph{critical thresholds} in the phase space of initial configuration which dictate the global regularity vs. a finite time blow-up. In particular, we explore the regularity of nonlocal alignment in the presence of vacuum.

Keywords

Cite

@article{arxiv.1403.0991,
  title  = {Critical thresholds in flocking hydrodynamics\\with nonlocal alignment},
  author = {Eitan Tadmor and Changhui Tan},
  journal= {arXiv preprint arXiv:1403.0991},
  year   = {2015}
}
R2 v1 2026-06-22T03:20:19.838Z