📝 SummarXiv

Abstract

Coarsening, the process where larger structures grow at the expense of smaller ones, is a fundamental aspect of multiphase systems. The cell cytoplasm exemplifies an out-of-equilibrium multiphase system, where phase-separated condensates nucleate and expand within an active fluid made of biopolymers and energy-dependent enzymes. In this study, we explore how condensates grow in a self-stirring active fluid by examining the coarsening of biomimetic condensates embedded in a 3D reconstituted cytoskeleton composed of microtubules and molecular motors. The strong agreement among experiments, an active hydrodynamic model, and computer simulations offers a comprehensive framework that explains why self-similarity is absent in active coarsening and identifies the origins of the continuously changing coarsening exponents for both active and passive condensates. The dynamics of coarsening are primarily determined by the statistics of binary droplet collisions, which depend on their size-dependent motility, regardless of whether they are active or passive. These results reveal a unifying control parameter for the coarsening process and size distribution of active condensates, broadening our understanding of phase separation in out-of-equilibrium systems and potentially impacting materials science and biology.