This monograph is centered on mathematical modeling, innovative numerical algorithms
and adaptive concepts to deal with fracture phenomena in multiphysics. State-of-the-art …

This work focuses on fluid–structure interaction (FSI) between a curved (tortuous) coronary
artery with an implanted stent, pulsatile blood flow, and heart contractions. The goal is to …

We study a nonlinear, unsteady, moving boundary, fluid–structure interaction (FSI) problem
in which the structure is composed of two layers: a thick layer, and a thin layer which serves …

We consider a parabolic–parabolic interface problem and construct a loosely coupled
prediction-correction scheme based on the Robin–Robin splitting method analyzed in [J …

We present a loosely coupled scheme for the numerical simulation of the cardiac electro-
fluid-structure interaction problem, whose solution is typically computationally intensive due …

In this paper, we present a partitioned numerical scheme for solving fluid-structure
interaction (FSI) problems based on the adaptive time-step**. The viscous …

In this work, we consider the solution of fluid‐structure interaction (FSI) problems using a
monolithic approach for the coupling between fluid and solid subproblems. The coupling of …

Moving boundary problems are ubiquitous in nature, technology, and engineering.
Examples include the human heart and heart valves interacting with blood flow …

This paper presents a numerical study in which several partitioned solution procedures for
incompressible fluid‐structure interaction are compared and validated against the results of …

We consider a loosely coupled, non-iterative Robin-Robin coupling method proposed and
analyzed in Burman et al.(J. Numer. Math. 31 (1): 59–77,) for a parabolic-parabolic interface …