Institute of Mathematics

Talk

Modul:   MAT675  PDE and Mathematical Physics

[Video] The shoreline problem for the Green-Naghdi equations

Dr. David Lannes talk

Speaker invited by: Prof. Dr. Thomas Kappeler

Date: 21.03.19  Time: 17.10 - 18.00  Room: Y27H12

Abstract: The Green-Naghdi equations are a nonlinear dispersive perturbation of the nonlinear shallow water equations, more precise by one order of approximation. These equations are commonly used for the simulation of coastal flows, and in particular in regions where the water depth vanishes (the shoreline). The local well-posedness of the Green-Naghdi equations (and their justification as an asymptotic model for the water waves equations) has been extensively studied, but always under the assumption that the water depth is bounded from below by a positive constant. In this talk we will see how to remove this assumption. The problem then becomes a free-boundary problem since the position of the shoreline is unknown and driven by the solution itself. For the (hyperbolic) nonlinear shallow water equation, this problem is very related to the vacuum problem for a compressible gas. The Green-Naghdi equation include additional nonlinear, dispersive and topography terms with a complex degenerate structure at the boundary. In particular, the degeneracy of the topography terms makes the problem loose its quasilinear structure and become fully nonlinear. Dispersive smoothing also degenerates and its behavior at the boundary can be described by an ODE with regular singularity. These issues require the development of new tools, some of which of independent interest such as the study of the mixed initial boundary value problem for dispersive perturbations of characteristic hyperbolic systems, elliptic regularization with respect to conormal derivatives, or general Hardy-type inequalities. This is joint work with G. Métivier. Ref: D. Lannes and G. Métivier. The shoreline problem for the one-dimensional shallow water and Green- Naghdi equations. J. Ec. polytech. Math., 5:455–518, 2018.

Slides