Deformable bodies in a 3-dimensional viscous flow: Vorticity-Stream vector formulation

TL;DR

This paper introduces a simplified vorticity-stream vector numerical method for simulating 3D viscous flows with deformable interfaces, effectively modeling vesicle and droplet dynamics in low Reynolds number conditions.

Contribution

A novel vorticity-stream vector formulation that simplifies 3D flow simulations with deformable bodies using standard finite-difference techniques.

Findings

Successfully simulates vesicle and droplet shapes in flow.

Recovers canonical axisymmetric shapes and stress profiles.

Framework adaptable to more complex fluid models.

Abstract

When simulating three-dimensional flows interacting with deformable and elastic obstacles, current methods often encounter complexities in the governing equations and challenges in numerical implementation. In this work, we introduce a novel numerical formulation for simulating incompressible viscous flows at low Reynolds numbers in the presence of deformable interfaces. Our method employs a vorticity-stream vector formulation that significantly simplifies the fluid solver, transforming it into a set of coupled Poisson problems. The body-fluid interface is modeled using a phase field, allowing for the incorporation of various free-energy models to account for membrane bending and surface tension. In contrast to existing three-dimensional approaches, such as Lattice Boltzmann Methods or boundary-integral techniques, our formulation is lightweight and grounded in classical fluid mechanics principles, making it implementable with standard finite-difference techniques. We demonstrate the capabilities of our method by simulating the evolution of a single vesicle or droplet in Newtonian Poiseuille and Couette flows under different free-energy models, successfully recovering canonical axisymmetric shapes and stress profiles. Although this work primarily focuses on single-body dynamics in Newtonian suspending fluids, the framework can be extended to include body forces, inertial effects, and viscoelastic media.