中文

Interface tracking with Microscale Topological Surgery for two-dimensional filament breakup

流体动力学 2026-06-26 v1 数值分析 计算物理

摘要

We design and implement a Microscale Topological Surgery (MTS) algorithm to detect and enforce topological transitions in two-dimensional tracked interfaces. The method combines classical Lagrangian tracking with an intermittent topological processor that: (i) constructs Eulerian snapshots from which an interface family with microscale-resolved topology is extracted, (ii) infers adjacency topology between dual Lagrangian and Eulerian interface families, and (iii) performs interface surgery to stitch the two families together across microscale defect regions. A novel long-time nonlinear alternating-shear flow is introduced, in which repeated stretching and folding generate rich multiscale interface dynamics with filamentation at microscales. Using the MTS algorithm and a posteriori geometric and material diagnostics, we compute and visualize microscale filament-breakup dynamics. Error analysis and scaling studies demonstrate second-order geometric convergence and optimal computational scaling of the MTS algorithm, with topology-processing costs comparable to those of the underlying Lagrangian evolution. Ensemble simulations generated by pseudo-random perturbations of the flow further reveal coherent droplet size distributions and statistically robust filament-breakup dynamics.

引用

@article{arxiv.2606.27615,
  title  = {Interface tracking with Microscale Topological Surgery for two-dimensional filament breakup},
  author = {Raaghav Ramani},
  journal= {arXiv preprint arXiv:2606.27615},
  year   = {2026}
}

备注

45 pages, 23 figures