1Department of Applied Mathematics, University of Twente, Enschede, the Netherlands
2School of Mathematics, University of Leeds, Leeds, UK
Received: 10 Jan 2013 – Revised: 16 May 2013 – Accepted: 17 May 2013 – Published: 12 Jul 2013
Abstract. We are interested in the modelling of wave-current interactions around surf zones at beaches. Any model that aims to predict the onset of wave breaking at the breaker line needs to capture both the nonlinearity of the wave and its dispersion. We have therefore formulated the Hamiltonian dynamics of a new water wave model, incorporating both the shallow water and pure potential flow water wave models as limiting systems. It is based on a Hamiltonian reformulation of the variational principle derived by Cotter and Bokhove (2010) by using more convenient variables. Our new model has a three-dimensional velocity field consisting of the full three-dimensional potential velocity field plus extra horizontal velocity components. This implies that only the vertical vorticity component is nonzero. Variational Boussinesq models and Green–Naghdi equations, and extensions thereof, follow directly from the new Hamiltonian formulation after using simplifications of the vertical flow profile. Since the full water wave dispersion is retained in the new model, waves can break. We therefore explore a variational approach to derive jump conditions for the new model and its Boussinesq simplifications.
Gagarina, E., van der Vegt, J., and Bokhove, O.: Horizontal circulation and jumps in Hamiltonian wave models, Nonlin. Processes Geophys., 20, 483-500, doi:10.5194/npg-20-483-2013, 2013.