tsunami-models
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Basic Info
- Host: GitHub
- Owner: mandli
- License: cc-by-4.0
- Language: TeX
- Default Branch: master
- Size: 130 KB
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- Stars: 6
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- Forks: 6
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Metadata Files
README.md
Tsunami Models List
This list is meant to be a community effort to both list and categorize the available tsunami models currently maintained and publicly (openly) available. This list was started based on a review paper that is currently itself under review. Check back soon for a draft and how to contribute.
Citation: Marras, S.; Mandli, K.T. Modeling and Simulation of Tsunami Impact: A Short Review of Recent Advances and Future Challenges. Geosciences (2021) 11, 5.
| Model | SpaceDim. | Equations | Turbul. | Wavebreak. | FSI | MP | SD | |------------------------|---------------------|-----------|-------------|------------|-----|-----|-------| | GeoCLAW[1] | 1D/2D/2D(1/2) | SW | No | No | No | No | FV | | NUMA2D[2][3] | 1D/2D | SW | No | No | No | No | SE/DG | | MOST[4] | 1D/2D | SW | No | No | No | No | FD | | Cliffs[5] | 1D/2D | SW | No | No | No | No | FD | | Tsunami-HySEA[6a,b,c] | 1D/2D | SW/B | No | Yes | No | No | FV | | Multilayer-HySEA[7,8] | 1D/2D(1/2) | SW/B | No | Yes | No | Yes | FV | | TUNAMI[9,10] | 1D/2D | SW | No | No | No | No | FD | | NAMI-DANCE[11] | 1D/2D | SW | No | No | No | No | FD | | COMCOT[12] | 1D/2D | SW | No | No | No | No | FD | | SELFE[13] | 1D/2D | SW | No | No | No | No | FE | | TsunAWI[14] | 1D/2D | SW | No | No | No | No | FE | | TsunaFlash[15] | 1D/2D | SW | No | No | No | No | FE/DG | | VOLNA[16,17] | 1D/2D | SW | No | No | No | No | FV | | Delft3D[18] | 1D/2D | SW | No | No | No | Yes | FD | | Basilisk[19-21] | 2D/3D | SGN | No | Yes | No | Yes | FV | | BOSZ[22] | 1D/2D | B | No | No | No | No | FV/FD | | Celeris[23] | 1D/2D | B | No | No | No | No | FV | | FUNWAVE[24,25] | 1D/2D | B | No | No | No | No | FV/FD | | pCOULWAVE[26,27] | 2D/3D | B | Yes | No | No | No | FV | | NEOWAVE[28] | 2D | B | No | No | No | No | FD | | GPUSPH[29] | 3D | SPH | No | Yes | No | No | SPH | | SCHISM[30] | 1D/2D/3D | N-S | RANS | Yes | No | No | FE/FV | | COBRAS[31,32] | 2D/3D | N-S | RANS | Yes | No | No | FD | | TSUNAMI3D[33,34] | 2D/3D | N-S | RANS | Yes | No | No | FD | | waves2FOAM[35-37] | 2D(tsunami) | N-S | RANS | Yes | No | No | FV | | NHWAVE[38] | 2D/3D | N-S | LES | Yes | Yes | Yes | FV/FD | | Alya[39,40] | 2D/3D | N-S | LES/WM/RANS | Yes | Yes | Yes | FE | | FVCOM [41,42] | 3D | N-S | Yes | Yes | No | No | FV | | ANUGA [43] | 2D | SW | | | | | |
References
[1] Berger, M.; George, D.; LeVeque, R.; Mandli, K. The GeoClaw software for depth-averaged flows withadaptive refinement.Adv. Water Res. 2011,34, 1195–1206.
[2] Marras, S.; Kopera, M.; Giraldo, F.X. Simulation of Shallow Water Jets with a Unified Element-basedContinuous/Discontinuous Galerkin Model with Grid Flexibility on the Sphere.Q. J. Roy. Meteor. Soc. 2015,141, 1727–1739.
[3] Marras, S.; Kopera, M.; Constantinescu, E.; Suckale, J.; Giraldo, F. A Residual-based Shock CapturingScheme for the Continuous/Discontinuous Spectral Element Solution of the 2D Shallow Water Equations.Adv. Water Res. 2018,114, 45–63.
[4] Titov, V.V.; Gonzalez, F. Implementation and testing of the Method Of Splitting Tsunami (MOST) model.NOAA Technical Memorandum ERL PMEL-112 1927, NOAA, Seattle, WA,USA. Technical report, 1997.
[5] Tolkova, E. Land–water boundary treatment for a tsunami model with dimensional splitting.Pure Appl.Geophys. 2014,171, 2289–2314.
[6a] Macías, J.; Castro, M.; Ortega, S.; Escalante, C.; González-Vida, J. Performance Benchmarking of Tsunami-HySEA Model for NTHMP’s Inundation Mapping Activities. Pure Appl. Geophys. 2017, 174, 3147–3183.
[6b] Macías, J.; Castro, M.; Ortega, S.; González-Vida, J. Performance assessment of Tsunami-HySEA model for NTHMP tsunami currents benchmarking. Field cases. Ocean Modelling 2020, 152, 101645.
[6c] Macías, J.; Castro, M.; Escalante, C. Performance assessment of the Tsunami-HySEA model for NTHMP tsunami currents benchmarking. Laboratory data. Coastal Engineering 2020, 158, 103667.
[7] Macías, J.; Escalante, C.; Castro, M.J. Multilayer-HySEA model validation for landslide generated tsunamis.Part I Rigid slides.Natural Hazards and Earth System Sciences Discussions. 10.5194/nhess-2020-1712020, 2020, 1–33.
[8] Macías, J.; Escalante, C.; Castro, M.J. Multilayer-HySEA model validation for landslide generated tsunamis.Part II Granular slides.Natural Hazards and Earth System Sciences Discussions, 10.5194/nhess-2020-1722020, 2020, 1–34.
[9] Imamura, F. Tsunami numerical simulation with the staggered leap-frog scheme (numerical code ofTUNAMI-N1 and N2), 1989.
[10] Imamura, F.; Yalciner, A.; Ozyurt, G. Tsunami Modelling Manual. Technical report, 2006.
[11] Yalciner, A.; Pelinovsky, E.; Zaytsev, A.; Kurkin, A.; Ozer, C.; Karakus, H. NAMI DANCE Manual.Technical report, METU, Civil Engineering Department, Ocean Engineering Research Center, Ankara,Turkey, 2006.
[12] Wang, X. User manual for COMCOT version 1.7. Technical report, 2009.
[13] Zhang, Y.; Baptista, A. An efficient and robust tsunami model on unstructured grids. Part I: inundationbenchmarks.Pure Appl. Geophys. 2008,165, 2229–2248.
[14] Harig, S.; Chaeroni, X.; Pranowo, W.; Behrens, J. Tsunami simulations on several scales: comparison ofapproaches with unstructured meshes and nested grids.Ocean Dyn. 2008,58, 429–440.
[15] Pranowo, W.; Behrens, J.; Schlicht, J.; Ziemer, C.Adaptive mesh refinement applied to tsunamimodeling: TsunaFLASH. In Proc. Int. Conf. on Tsunami Warning (ICTW) (ed. H Adrianto). Jakarta,Indonesia: State Ministry of Research and Technology, Republic of Indonesia (RISTEK). Available at:http://hdl.handle.net/10013/epic.32425.d001, 2008.
[16] Dutykh, D.; Poncet, R.; Dias, F. The VOLNA code for the numerical modeling of tsunami waves: generation,propagation and inundation.Eur. J. Mech. B/Fluids 2011,30, 598–615.
[17] Reguly, I.Z.; Giles, D.; Gopinathan, D.; Quivy, L.; Beck, J.H.; Giles, M.B.; Guillas, S.; Dias, F. TheVOLNA-OP2 tsunami code (version 1.5).Geoscientific Model Development 2018, 11, 4621–4635.
[18] Roelvink, J.; Van Banning, G.Design and development of DELFT3D and application to coastalmorphodynamics.Oceanographic Lit. Review 1995,42, 925–
[19] Popinet, S. Basilisk: simple abstractions for octree-adaptive scheme.SIAM conference on ParallelProcessing for Scientific Computing. April 12-15; 2016.
[20] Popinet, S. A quadtree-adaptive multigrid solver for the Serre–Green–Naghdi equations.Journal ofComputational Physics 2015,302, 336 – 358. doi:https://doi.org/10.1016/j.jcp.2015.09.009
[21] Popinet, S. A vertically-Lagrangian, non-hydrostatic, multilayer model for multiscale free-surface flows.Journal of Computational Physics 2020,418, 109609. doi:https://doi.org/10.1016/j.jcp.2020.109609.
[22] Roeber, V.; Cheung, K. Boussinesq-type model for energetic breaking waves in fringing reef environment.Coast. Eng. 2012,70, 1–20.
[23] Tavakkol, S.; Lynett, P. Celeris: A GPU-accelerated open source software with a Boussinesq-type wavesolver for real-time interactive simulation and visualization.Computer Physics Communications 2017,217, 117 – 127.
[24] Kennedy, A.; Chen, Q.; Kirby, J.; Dalrymple, R. Boussinesq modeling of wave transformation, breakingand runup, part I: 1D.J. Waterw. Port Coast. Ocean Eng. 2000,126, 39–47.
[25] Shi, F.; Kirby, J.; Harris, J.; Geiman, J.; Grilli, S. A high-order adaptive time-stepping TVD solver forBoussinesq modeling of breaking waves and coastal inundation.Ocean Model. 2012,43-44, 36–51
[26] Lynett, P.; Wu, T.; P.L.F., L. Modeling wave runup with depth-integrated equations.Coast. Eng. 2002, 46:89–107.
[27] Kim, D.; Lynett, P. Turbulent mixing and passive scalar transport in shallow flows.Phys. Fluids 2011,23, 016603.
[28] Yamazaki, Y.; Kowalik, Z.; Cheung, K. Depth-integrated, non-hydrostatic model for wave breaking andrun-up.Int. J. Numer. Meth. Fluids 2009,61, 473–497.
[29] Wei, Z.; Dalrympl, R.; Hérault, A.; Bilotta, G.; Rustico, E.; Yeh, H. SPH modeling of dynamic impact oftsunami bore on bridge pier.Coast. Eng. 2015,104, 26–42.
[30] Zhang, Y.; Ye, F.; Stanev, E.; Grashorn, S. Seamless cross-scale modeling with SCHISM, Ocean Modelling.Ocean Model. 2016,102, 64–81.
[31] Lin, P.; Liu, P. A numerical study of breaking waves in the surf zone.J. Fluid Mech. 1998,358, 239–264.
[32] Lin, P.; Liu, P. Turbulence transport, vorticity dynamics, and solute mixing under plunging breaking wavesin surf zone.J. Geophys. Res. 1998,103 C8
[33] Horrillo, J.; Wood, A.; Kim, G.; Parambath, A. A simplified 3-D /Navier–Stokes numerical model forlandslide tsunami: Application to the Gulf of Mexico.J. Geophys. Res./Oceans 2013,118, 6934–6950.
[34] Horrillo, J.; Grilli, S.; Nicolsky, D.; Roeber, V.; Zhang, J. Performance benchmarking tsunami models forNTHMP’s inundation mapping activities.Pure Appl. Geophys. 2015,172, 869–884
[35] Jacobsen, N.; Fuhrman, D.; Fredsoe, J. A wave generation toolbox for the open-source CFD library:OpenFOAM (R).Int. J. Numer. Methods Fluids 2012,70, 1073–1088.
[36] Larsen, B.; Fuhrman, D. Full-scale CFD simulation of tsunamis. Part 1: Model validation and run-up.Coastal Engineering 2019,151
[37] Larsen, B.; Fuhrman, D. Full-scale CFD simulation of tsunamis. Part 2: Boundary layers and bed shearstresses.Coastal Engineering 2019,151.
[38] Ma, G.; Shi, F.; Kirby, J. Shock-capturing non-hydrostatic model for fully dispersive surface wave processes.Ocean Modeling 2012,43-44, 22–35
[39] Vázquez, M.; Houzeaux, G. Alya: Multiphysics Engineering Simulation Towards Exascale.J. Comput. Sci 2016.
[40] Mukherjee, A.; Cajas, J.; Houzeaux, G.; Lehmkuhl, O.; Vázquez, M.; Suckale, J.; Marras, S. Using fluid-structure interaction to evaluate the energy dissipation of a tsunami run-up through idealized flexible trees. sciencesconf.org:parcfd2020:3202002020.
[41] Chen, C.; Liu, H.; Beardsley, R. C. An unstructured grid, finite-volume, three dimensional, primitive equations ocean model: application to coastal ocean and estuarie. J. Atmos. Ocean Technol. 2003, 20 159-186
[42] Chen, C.; Lai, Z.; Beardsley, R. C.; Sasaki, J.; Lin, J.; Lin, H.; Ji, R.; Sun, Y. The March 11, 2011 Tohoku M9.0 Earthquake-induced Tsunami and Coastal Inundation along the Japanese Coast: A Model Assessment. Progress in Oceanography 2014, 123 84-104
[43] Roberts, S.; Davies, G.; Nielsen, O. ANUGA Github Repository https://github.com/anuga-community/anuga_core 2022
Owner
- Name: Kyle Mandli
- Login: mandli
- Kind: user
- Location: New York, NY
- Company: Columbia University
- Website: www.columbia.edu/~ktm2132
- Twitter: kylemandli
- Repositories: 40
- Profile: https://github.com/mandli
Citation (citations.bib)
@software{anuga,
author = {Roberts, Stephen and Davies, Gareth and Nielsen, Ole},
license = {Apache License, Version 2.0},
month = jun,
title = {{ANUGA Github Repository}},
url = {https://github.com/anuga-community/anuga_core},
version = {3.1.9},
year = {2022}
},
@article{berger2011geoclaw,
title={The GeoClaw software for depth-averaged flows with adaptive refinement},
author={Berger, M.J. and George, D.L. and LeVeque, R.J. and Mandli, K.T.},
journal={Adv. Water Res.},
volume={34},
number={9},
pages={1195--1206},
year={2011},
},
@article{giraldoRestelli2008b,
author = {{Giraldo},F.~X. and {Restelli},M.},
title = {A Conservative Discontinuous Galerkin Semi-Implicit Formulation for the Navier-Stokes Equations in Nonhydrostatic Mesoscale Modeling},
journal = {SIAM J. Sci. Comp.},
volume = {31},
pages = {2231-2257},
year = {2009},
},
@article{marrasEtAl2015,
author = {{Marras},S. and {Kopera},M. and {Giraldo},F~X.},
title = {Simulation of Shallow Water Jets with a Unified Element-based Continuous/Discontinuous {Galerkin} Model with Grid Flexibility on the Sphere},
journal = {Q. J. Roy. Meteor. Soc.},
year = {2015},
Volume = {141},
pages={1727-1739}
},
@ARTICLE{marrasEtAl2017residual,
author = {Marras, S. and Kopera, M.A. and Constantinescu, E.M. and
Suckale, J. and Giraldo, F.X.},
title = {A Residual-based Shock Capturing Scheme for the Continuous/Discontinuous
Spectral Element Solution of the 2D Shallow Water Equations},
journal = {Adv. Water Res.},
year = {2018},
volume = {114},
pages = {45-63},
},
@techreport{MOST,
author = {{Titov},V~V. and {Gonzalez}, F.},
title = {{Implementation and testing of the Method Of Splitting Tsunami(MOST) model. NOAA Technical Memorandum ERL PMEL-112 1927, NOAA, Seattle, WA,USA}},
year = {1997},
},
@article{tolkova2014,
author = {Tolkova, E.},
title = {Land–water boundary treatment for a tsunami model with dimensional splitting},
journal = {Pure Appl. Geophys.},
volume = {171},
pages = {2289--2314},
year = {2014},
},
@article{castroEtAl2005wetdry,
title = {The numerical treatment of wet/dry fronts in shallow flows: application to one-layer and two-layer systems},
journal = {Math. Comput. Model.},
volume = {42},
number = {3},
pages = {419 - 439},
year = {2005},
author = {M.J. Castro and A.M. {Ferreiro Ferreiro} and J.A. Garc\'ia-Rodr\'iguez and J.M. Gonz\'alez-Vida and J. Mac\'ias and C. Par\'es and M. {Elena V\'azquez-Cend\'on}},
},
@Article{maciasEtAl2020b,
AUTHOR = {Mac\'{\i}as, J. and Escalante, C. and Castro, M. J.},
TITLE = {{Multilayer-HySEA model validation for landslide generated tsunamis. Part II Granular slides}},
JOURNAL = {Natural Hazards and Earth System Sciences Discussions, 10.5194/nhess-2020-172},
VOLUME = {2020},
YEAR = {2020},
PAGES = {1--34},
},
@article{maciasEtAl2020a,
AUTHOR = {Mac\'{\i}as, J. and Escalante, C. and Castro, M. J.},
TITLE = {{Multilayer-HySEA model validation for landslide generated tsunamis. Part I Rigid slides}},
JOURNAL = {Natural Hazards and Earth System Sciences Discussions. 10.5194/nhess-2020-171},
VOLUME = {2020},
YEAR = {2020},
PAGES = {1--33},
},
@misc{imamura1989,
author = {Imamura, F.},
title={{Tsunami numerical simulation with the staggered leap-frog scheme (numerical code of TUNAMI-N1 and N2)}},
volume={},
institution={School of Civil Engineering, Asian institute of Technology and Disaster Control Research Center, Tohoku University},
year={1989},
},
@techreport{TUNAMI,
author = {Imamura, F. and Yalciner, A.C. and Ozyurt, G.},
title = {{Tsunami Modelling Manual}},
year = {2006},
},
@techreport{maniDance,
author = {Yalciner, A.C. and Pelinovsky, E. and Zaytsev, A. and Kurkin, A. and Ozer, C. and Karakus, H.},
title = {{NAMI DANCE Manual}},
institution = {METU, Civil Engineering Department, Ocean Engineering Research Center, Ankara, Turkey},
year = {2006},
},
@techreport{COMCOT,
author = {Wang, X.},
title = {{User manual for COMCOT version 1.7}},
year = {2009},
},
@article{gaillerEtAl2013,
author = {Gailler, A. and Hbert, H. and Loevenbruck, A. and Hernandez, B.},
title={Simulation systems for tsunami wave propagation forecasting within the French tsunami warning system},
volume={13},
journal={Nat. Hazards Earth Sys. Sci.},
year={2013},
pages={2465--2482},
},
@article{reymondEtAl2012,
author = {Reymond, D. and Okal, E.A. H\'ebert, H. and Bourdet, M.},
title={{Rapid forecast of tsunami wave heights from a database of pre-computed simulations, and application during the 2011 Tohoku tsunami in French Polynesia}},
volume={39},
journal={Geophys. Res. Lett.},
year={2012},
pages={39},
},
@article{zhangBaptista2008selfe,
author = {Zhang, Y.J. and Baptista A.M.},
title={{An efficient and robust tsunami model on unstructured grids. Part I: inundation benchmarks}},
volume={165},
journal={Pure Appl. Geophys. },
year={2008},
pages={2229--2248},
},
@article{harigEtAl2008tsunawi,
author = {Harig, S. and Chaeroni, X. and Pranowo, W.S. and Behrens, J. },
title={Tsunami simulations on several scales: comparison of approaches with unstructured meshes and nested grids},
volume={58},
journal={Ocean Dyn.},
year={2008},
pages={429--440},
},
@article{dutykhEtAl2011volna,
author = {Dutykh, D. and Poncet, R. and Dias, F. },
title={{The VOLNA code for the numerical modeling of tsunami waves: generation, propagation and inundation}},
volume={30},
journal={Eur. J. Mech. B/Fluids},
year={2011},
pages={598--615},
},
@Article{regulyVOLNAOP2,
AUTHOR = {Reguly, I. Z. and Giles, D. and Gopinathan, D. and Quivy, L. and Beck, J. H. and Giles, M. B. and Guillas, S. and Dias, F.},
TITLE = {The VOLNA-OP2 tsunami code (version 1.5)},
JOURNAL = {Geoscientific Model Development},
VOLUME = {11},
YEAR = {2018},
NUMBER = {11},
PAGES = {4621--4635},
},
@inproceedings{tsunaFLASH,
author = {Pranowo, W.S. and Behrens, J. and Schlicht, J. and Ziemer, C.},
title={Adaptive mesh refinement applied to tsunami modeling: TsunaFLASH},
journal={In Proc. Int. Conf. on Tsunami Warning (ICTW) (ed. H Adrianto). Jakarta, Indonesia: State Ministry of Research and Technology, Republic of Indonesia (RISTEK). Avaiable at: http://hdl.handle.net/10013/epic.32425.d001},
year={2008},
},
@article{delft3D,
author = {Roelvink, J.A. and Van Banning, G.K.G.M.},
title={{Design and development of DELFT3D and application to coastal morphodynamics}},
volume={42},
journal={Oceanographic Lit. Review},
year={1995},
pages={925--},
},
@inproceedings{basilisk1,
author = {Popinet, S.},
title={Basilisk: simple abstractions for octree-adaptive scheme.},
booktitle = {SIAM conference on Parallel Processing for Scientific Computing. April 12-15},
address = {Paris, France},
year={2016},
},
@article{basilisk2,
title = "A quadtree-adaptive multigrid solver for the Serre–Green–Naghdi equations",
journal = "J. Comput. Phys.",
volume = "302",
pages = "336 - 358",
year = "2015",
author = "Popinet, S.",
},
@article{basilisk3,
title = "A vertically-Lagrangian, non-hydrostatic, multilayer model for multiscale free-surface flows",
journal = "J. Comput. Phys.",
volume = "418",
pages = "109609",
year = "2020",
author = "Popinet, S.",
},
@article{kennedyEtAl2000funwave,
author = {Kennedy, A.B. and Chen, Q. and Kirby, J.T. and Dalrymple, R.A.},
title={{Boussinesq modeling of wave transformation, breaking and runup, part I: 1D}},
volume={126},
journal={J. Waterw. Port Coast. Ocean Eng.},
year={2000},
pages={39--47},
},
@article{shiEtAl2012funwave,
author = {Shi, F. and Kirby, J. and Harris, J. and Geiman, J. and Grilli, S.T.},
title={{A high-order adaptive time-stepping TVD solver for Boussinesq modeling of breaking waves and coastal inundation}},
volume={43-44},
journal={Ocean Model.},
year={2012},
pages={36--51},
},
@article{lynettEtAl2002COULWAVE,
author = {Lynett, P.J. and Wu, T.R. and Liu P.L.F.},
title={{Modeling wave runup with depth-integrated equations}},
volume={46},
journal={Coast. Eng.},
year={2002},
pages={89--107},
},
@article{kimLynett2011COULWAVE,
author = {Kim, D.H. and Lynett, P.J.},
title={{Turbulent mixing and passive scalar transport in shallow flows}},
volume={23},
journal={Phys. Fluids},
year={2011},
pages={016603},
},
@article{yamazakiEt2009AlNEOWAVE,
author = {Yamazaki, Y. and Kowalik, Z. and Cheung, K.F.},
title={{Depth-integrated, non-hydrostatic model for wave breaking and run-up}},
volume={61},
journal={Int. J. Numer. Meth. Fluids},
year={2009},
pages={473--497},
},
@article{weiEtAl2015SPHtsunamiGPUSPH,
author = {Wei, Z. and Dalrympl, R.A. and H\'erault, A. and Bilotta, G. and Rustico, E. and Yeh, H. },
title={{SPH modeling of dynamic impact of tsunami bore on bridge pier}},
volume={104},
journal={Coast. Eng.},
year={2015},
pages={26--42},
},
@article{zhangEtAl2016SCHISM,
author = {Zhang, Y. and Ye, F. and Stanev, E.V. and Grashorn, S.},
title={{Seamless cross-scale modeling with SCHISM, Ocean Modelling}},
volume={102},
journal={Ocean Model.},
year={2016},
pages={64--81},
},
@article{linLiu1998cobras,
author = {Lin, P. and Liu, P. },
title={{A numerical study of breaking waves in the surf zone}},
volume={358},
journal={J. Fluid Mech.},
year={1998},
pages={239--264},
},
@article{linLiu1998b,
author = {Lin, P. and Liu, P. },
title={{Turbulence transport, vorticity dynamics, and solute mixing under plunging breaking waves in surf zone}},
volume={103 C8},
journal={J. Geophys. Res.},
year={1998},
pages={},
},
@article{horrilloEtAl2013TSUNAMI3D,
author = {Horrillo, J. and Wood, A. and Kim, G.B. and Parambath, A.},
title={{A simplified 3-D /Navier–Stokes numerical model for landslide tsunami: Application to the Gulf of Mexico}},
volume={118},
journal={J. Geophys. Res./Oceans},
year={2013},
pages={6934--6950},
},
@article{horrilloEtAl2015,
author = {Horrillo, J. and Grilli, S.T. and Nicolsky, D. and Roeber, V. and Zhang, J.},
title={{Performance benchmarking tsunami models for NTHMP's inundation mapping activities}},
volume={172},
journal={Pure Appl. Geophys.},
year={2015},
pages={869--884},
},
@article{jacobsenEtAl2012,
author = {Jacobsen, N.G. and Fuhrman, D.R. and Fredsoe, J.},
title={{A wave generation toolbox for the open-source CFD library: OpenFOAM (R)}},
volume={70},
journal={Int. J. Numer. Methods Fluids},
year={2012},
pages={1073--1088},
},
@article{larsenFuhrman2019a,
author = {Larsen, B.E. and Fuhrman, D.R.},
title = {{Full-scale CFD simulation of tsunamis. Part 1: Model validation and run-up}},
journal = {Coastal Engineering},
volume = {151},
page = {22-41},
year = {2019},
},
@article{larsenFuhrman2019b,
author = {Larsen, B.E. and Fuhrman, D.R.},
title = {{Full-scale CFD simulation of tsunamis. Part 2: Boundary layers and bed shear stresses}},
journal = {Coastal Engineering},
volume = {151},
page = {42-57},
year = {2019},
},
@article{maEtAlNHWAVE2012,
author = {Ma, G. and Shi, F. and Kirby, J.T.},
title={{Shock-capturing non-hydrostatic model for fully dispersive surface wave processes}},
volume={43-44},
journal={Ocean Modeling},
year={2012},
pages={22--35},
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author = {V\'azquez, M. and Houzeaux,G.},
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