Self-organised dynamics and emergent shape spaces of active isotropic fluid surfaces

Da Gao, Huayang Sun, Rui Ma, Alexander Mietke

Published 2025-01-29Version 1

Theories of self-organised active fluid surfaces have emerged as an important class of minimal models for the shape dynamics of biological membranes, cells and tissues. Here, we develop and apply a variational approach for active fluid surfaces to systematically study the nonlinear dynamics and emergent shape spaces such theories give rise to. To represent dynamic surfaces, we design an arbitrary Lagrangian-Eulerian parameterizations for deforming surfaces. Exploiting the symmetries imposed by Onsager relations, we construct a variational formulation that is based on the entropy production in active surfaces. The resulting dissipation functional is complemented by Lagrange multipliers to relax nonlinear geometric constraints, which allows for a direct computation of steady state solutions of surface shapes and flows. We apply this framework to study the dynamics of open fluid membranes and closed active fluid surfaces, and characterize the space of stationary solutions that corresponding surfaces and flows occupy. Our analysis rationalizes the interplay of first-order shape transitions of internally and externally forced fluid membranes, reveals degenerate regions in stationary shape spaces of mechanochemically active surfaces and identifies a mechanism by which hydrodynamic screening controls the geometry of active surfaces undergoing cell division-like shape transformations.