📝 SummarXiv

Abstract

We present a neural-network--assisted Boltzmann framework that learns the binary-collision map of microswimmers from data and uses it to evaluate collision integrals efficiently. Using a representative model swimmer, the learned map provides quantitative predictions for rotational and translational diffusivities and allows a linear-stability analysis of the isotropic state against polar ordering in dilute suspensions. The resulting predictions closely match direct simulations in the dilute regime. The present approach is model agnostic: once two-body collision data are available -- either from simulations or experiments -- the same surrogate can be used to perform these evaluations across dilute conditions, as long as two-body collision processes dominate. Because the workflow relies only on pre- and post-collision statistics, it can be applied directly to a wide range of biological and synthetic colloidal swimmer systems.