A vortex method for fluid-particle systems

A vortex particle method is developed for simulating two-dimensional, unsteady compressible flow. The method uses the Helmholtz decomposition of the velocity field to separately treat the irrotational and solenoidal portions of the flow, and the particles are allowed to change volume to conserve mas

It turns out that the precise form of the error produced by vortex methods, and not only their order of conver- The analysis of the truncation error produced by particle methods leads to artificial viscosity schemes. For vortex methods, they can be gence, can be precisely analyzed. This feature, wh

## Abstract Bio‐inspired mechanics of locomotion generally consist of the interaction of flexible structures with the surrounding fluid to generate propulsive forces. In this work, we extend, for the first time, the viscous vortex particle method (VVPM) to continuously deforming two‐dimensional bod

## Abstract We study an Hamiltonian system of __N__ particles in ℝ^3^ interacting by a short‐range repulsive and a long‐range attractive potential. It is shown that the empirical measures associated to the positions and velocity of the system converge to the solutions of Euler equations for a self‐

In order to understand the hydrodynamic interactions that can appear in a fluid particle motion, an original method based on the equations governing the motion of two immiscible fluids has been developed. These momentum equations are solved for both the fluid and solid phases. The solid phase is ass