src/references.bib

    [cano2016]

    José Carlos Cano-Lozano, Carlos Martínez-Bazán, Jacques Magnaudet, and Joël Tchoufag. Paths and wakes of deformable nearly spheroidal rising bubbles close to the transition to path instability. Phys. Rev. Fluids, 1:053604, Sep 2016. [ DOI | http ]
    [popinet2015]

    S. Popinet. A quadtree-adaptive multigrid solver for the serre–green–naghdi equations. Journal of Computational Physics, 302:336–358, 2015. [ http ]
    [bna2015]

    S. Bnà, S. Manservisi, R. Scardovelli, P. Yecko, and S. Zaleski. Vofi - a library to initialize the volume fraction scalar field. Computer Physics Communications, 2015. [ http ]
    [lannes2014]

    D. Lannes and F. Marche. A new class of fully nonlinear and weakly dispersive green-naghdi models for efficient 2d simulations. Technical report, INRIA, 2014. [ .pdf ]
    [hou2013]

    Jingming Hou, Qiuhua Liang, Franz Simons, and Reinhard Hinkelmann. A stable 2d unstructured shallow flow model for simulations of wetting and drying over rough terrains. Computers & Fluids, 82:132–147, 2013. [ http ]
    [popinet2012]

    S. Popinet. Adaptive modelling of long-distance wave propagation and fine-scale flooding during the tohoku tsunami. Natural Hazards and Earth System Sciences, 12(4):1213–1227, 2012. [ DOI | .pdf ]
    [kazolea2012]

    M Kazolea, AI Delis, IK Nikolos, and CE Synolakis. An unstructured finite volume numerical scheme for extended 2d boussinesq-type equations. Coastal Engineering, 69:42–66, 2012. [ http ]
    [an2012]

    Hyunuk An and Soonyoung Yu. Well-balanced shallow water flow simulation on quadtree cut cell grids. Advances in Water Resources, 39:60–70, 2012. [ http ]
    [popinet2011]

    S. Popinet. Quadtree-adaptive tsunami modelling. Ocean Dynamics, 61(9):1261–1285, 2011. [ .pdf ]
    [lopez-herrera2011]

    J. M. Lopez-Herrera, S. Popinet, and M. A. Herrada. A charge-conservative approach for simulating electrohydrodynamic two-phase flows using volume-of-fluid. Journal of Computational Physics, 230:1939–1955, 2011. [ .pdf ]
    [lagree2011]

    L. Staron P.-Y. Lagrée and S. Popinet. The granular column collapse as a continuum: validity of a navier-stokes model with a mu(i)-rheology. Journal of Fluid Mechanics, 686:378–408, 2011. [ .pdf ]
    [bonneton2011]

    P. Bonneton, F. Chazel, D. Lannes, F. Marche, and M. Tissier. A splitting approach for the fully nonlinear and weakly dispersive green-naghdi model. Journal of Computational Physics, 230:1479–1498, 2011. [ http ]
    [audusse2011b]

    E. Audusse, M.-O. Bristeau, M. Pelanti, and J. Sainte-Marie. Approximation of the hydrostatic navier–stokes system for density stratified flows by a multilayer model: Kinetic interpretation and numerical solution. Journal of Computational Physics, 230(9):3453 – 3478, 2011. [ DOI | http ]
    [audusse2011]

    Emmanuel Audusse, Marie-Odile Bristeau, Benoît Perthame, and Jacques Sainte-Marie. A multilayer saint-venant system with mass exchanges for shallow water flows. derivation and numerical validation. ESAIM: Mathematical Modelling and Numerical Analysis, 45:169–200, 1 2011. [ DOI | http ]
    [weymouth2010]

    G.D. Weymouth and D.K.P. Yue. Conservative volume-of-fluid method for free-surface simulations on cartesian-grids. Journal of Computational Physics, 229(8):2853–2865, 2010. [ http ]
    [lemetayer2010]

    O. Le Métayer, S. Gavrilyuk, and S. Hank. A numerical scheme for the green-naghdi model. Journal of Computational Physics, 229:2034–2045, 2010.
    [hsiao2010]

    S.-C. Hsiao and T.-C. Lin. Tsunami-like solitary waves impinging and overtopping an impermeable seawall: Experiment and rans modeling. Coastal Engineering, 57:1–18, 2010. [ http ]
    [delestre2010]

    Olivier Delestre, François James, et al. Simulation of rainfall events and overland flow. In X International Conference Zaragoza-Pau on Applied Mathematics and Statistics, volume 35, pages 125–135, 2010.
    [yamazaki2009]

    Y. Yamazaki, Z. Kowalik, and K. F. Cheung. Depth-integrated, non-hydrostatic model for wave breaking and run-up. Int. J. Numer. Meth. Fluids, 61:473–497, 2009. [ http ]
    [popinet2009]

    S. Popinet. An accurate adaptive solver for surface-tension-driven interfacial flows. Journal of Computational Physics, 228:5838–5866, 2009. [ .pdf ]
    [nikolos2009]

    IK Nikolos and AI Delis. An unstructured node-centered finite volume scheme for shallow water flows with wet/dry fronts over complex topography. Computer Methods in Applied Mechanics and Engineering, 198(47):3723–3750, 2009. [ http ]
    [kwatra2009]

    N. Kwatra, J. Su, J. T. Grétarsson, and R. Fedkiw. A method for avoiding the acoustic time step restriction in compressible flow. Journal of Computational Physics, 228:4146–4161, 2009.
    [hysing2009]

    S. Hysing, S. Turek, D. Kuzmin, N. Parolini, E. Burman, S. Ganesan, and L. Tobiska. Quantitative benchmark computations of two-dimensional bubble dynamics. International Journal for Numerical Methods in Fluids, 60:1259–1288, 2009. [ http ]
    [madsen2008]

    P. A. Madsen, D. R. Fuhrman, and H. A Schaffer. On the solitary wave paradigm for tsunamis. Journal of Geophysical Research: Oceans, 113(C12), 2008.
    [grilli2007]

    S.T. Grilli, M. Ioualalen, J. Asavanant, F. Shi, J.T. Kirby, and P. Watts. Source constraints and model simulation of the December 26, 2004, Indian Ocean Tsunami. Journal of Waterway, Port, Coastal, and Ocean Engineering, 133:414–428, 2007.
    [sampson2006]

    Joe Sampson, Alan Easton, and Manmohan Singh. Moving boundary shallow water flow above parabolic bottom topography. In Andrew Stacey, Bill Blyth, John Shepherd, and A. J. Roberts, editors, Proceedings of the 7th Biennial Engineering Mathematics and Applications Conference, EMAC-2005, volume 47 of ANZIAM J., pages C373–C387, oct 2006. [ http ]
    [madsen2006]

    P. A. Madsen, D. R. Fuhrman, and B. Wang. A boussinesq-type method for fully nonlinear waves interacting with a rapidly varying bathymetry. Coastal Engineering, 53(5-6):487–504, 2006. [ http ]
    [rosales2005]

    Carlos Rosales and Charles Meneveau. Linear forcing in numerical simulations of isotropic turbulence: Physical space implementations and convergence properties. Physics of Fluids, 17(9):095106, 2005. [ http ]
    [rossmanith2004]

    James A Rossmanith, Derek S Bale, and Randall J LeVeque. A wave propagation algorithm for hyperbolic systems on curved manifolds. Journal of Computational Physics, 199(2):631–662, 2004.
    [audusse2004]

    Emmanuel Audusse, Francois Bouchut, Marie-Odile Bristeau, Rupert Klein, and Benoit Perthame. A fast and stable well-balanced scheme with hydrostatic reconstruction for shallow water flows. SIAM Journal on Scientific Computing, 25(6):2050–2065, 2004.
    [popinet2003]

    S. Popinet. Gerris: a tree-based adaptive solver for the incompressible euler equations in complex geometries. J. Comput. Phys., 190(2):572–600, 2003. [ .pdf ]
    [kurganov2002]

    A. Kurganov and D. Levy. Central-upwind schemes for the Saint-Venant system. Mathematical Modelling and Numerical Analysis, 36(3):397–425, 2002.
    [pena2001]

    B Pena and C Perez-Garcia. Stability of turing patterns in the brusselator model. Physical Review E, 64(5):056213, 2001.
    [kurganov2000]

    A. Kurganov and E. Tadmor. New high-resolution central schemes for nonlinear conservation laws and convection–diffusion equations. Journal of Computational Physics, 160(1):241–282, 2000.
    [esteves2000]

    Michel Esteves, Xavier Faucher, Sylvie Galle, and Michel Vauclin. Overland flow and infiltration modelling for small plots during unsteady rain: numerical results versus observed values. Journal of hydrology, 228(3):265–282, 2000.
    [popinet1999]

    Stéphane Popinet and Stéphane Zaleski. A front-tracking algorithm for accurate representation of surface tension. International Journal for Numerical Methods in Fluids, 30(6):775–793, 1999.
    [jeong1995]

    Jinhee Jeong and Fazle Hussain. On the identification of a vortex. Journal of fluid mechanics, 285:69–94, 1995.
    [luth1994]

    H.R. Luth, G. Klopman, and N. Kitou. Project 13g: kinematics of waves breaking partially on an offshore bar. Technical report, Delfts hydraulics laboratory, 1994.
    [dingemans1994]

    M.W. Dingemans. Comparison of computations with boussinesq-like models and laboratory measurements. Technical report, Delft hydraulics laboratory, 1994. [ http ]
    [beji1993]

    S. Beji and J.A. Battjes. Experimental investigation of wave propagation over a bar. Coastal Engineering, 19:151–162, 1993.
    [bell89]

    J. B. Bell, P. Colella, and H. M. Glaz. A second-order projection method for the incompressible navier-stokes equations. J. Comput. Phys., 85:257–283, 1989.
    [synolakis1987]

    C.E. Synolakis. The runup of solitary waves. Journal of Fluid Mechanics, 185:523–545, 1987.
    [ghia82]

    C.T. Shin U. Ghia, K.N. Ghia. High-Re solution for incompressible flow using the Navier-Stokes equations and the multigrid method. J. Comput. Phys., 48:387–411, 1982.
    [berkhoff1982]

    JCW Berkhoff, N Booy, and AC Radder. Verification of numerical wave propagation models for simple harmonic linear water waves. Coastal Engineering, 6(3):255–279, 1982. [ http ]
    [harlow1965]

    F.H. Harlow and J.E. Welch. Numerical calculation of time-dependent viscous incompressible flow of fluid with free surface. Physics of fluids, 8:2182, 1965.