English

Data-driven discovery of active nematic hydrodynamics

Soft Condensed Matter 2022-12-28 v1 Statistical Mechanics

Abstract

Two-dimensional active nematics are often modeled using phenomenological continuum theories that describe the dynamics of the nematic director and fluid velocity through partial differential equations (PDEs). While these models provide a statistically accurate description of the experiments, the identification of the relevant terms in the PDEs and their parameters is usually indirect. Here, we adapt a recently developed method to automatically identify optimal continuum models for active nematics directly from the spatio-temporal director and velocity data, via sparse fitting of the coarse-grained fields onto generic low order PDEs. We test the method extensively on computational models, and then apply it to data from experiments on microtubule-based active nematics. Thereby, we identify the optimal models for microtubule-based active nematics, along with the relevant phenomenological parameters. We find that the dynamics of the orientation field are largely governed by its coupling to the underlying flow, with free-energy gradients playing a negligible role. Furthermore, by fitting the flow equation to experimental data, we estimate a key parameter quantifying the `activity' of the nematic.

Keywords

Cite

@article{arxiv.2202.12854,
  title  = {Data-driven discovery of active nematic hydrodynamics},
  author = {Chaitanya Joshi and Sattvic Ray and Linnea Lemma and Minu Varghese and Graham Sharp and Zvonimir Dogic and Aparna Baskaran and Michael F. Hagan},
  journal= {arXiv preprint arXiv:2202.12854},
  year   = {2022}
}
R2 v1 2026-06-24T09:54:14.145Z