Paper detail

A partitioned scheme for fluid-composite structure interaction problems

We present a loosely-coupled partitioned scheme for a benchmark problem in fluid-composite structure interaction. The benchmark problem proposed here consists of an incompressible, viscous fluid interacting with a composite structure that consists of two layers: a thin elastic layer which is in contact with the fluid, and a thick elastic layer which sits on top of the thin layer. The motivation comes from fluid-structure interaction (FSI) in hemodyam- ics. The equations of linear elasticity are used to model the thick structural layer, while the Koiter member/shell equations are used to model the thin structural layer which serves as fluid-structure interface with mass. An effi- cient, modular, operator-splitting scheme is proposed to simulate solutions to the coupled, nonlinear FSI problem. The operator splitting scheme sepa- rates the elastodynamics structure problem, from a fluid problem in which the thin structure inertia is included as a Robin-type boundary condition to achieve unconditional stability, without requiring any sub-iterations within time-steps. An energy estimate associated with unconditional stability is derived for the fully nonlinear FSI problem defined on moving domains. Two instructive numerical examples are presented to test the performance of the scheme, where it is shown numerically, that the scheme is at least first-order accurate in time. The second example reveals a new phenomenon in FSI problems: the presence of a thin fluid-structure interface with mass regularizes solutions to the full FSI problem.