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MPM-Flow project -- References

[WB10] Van Balen W., Uijttewaal W.S.J., K. Blanckaert (2010). Large-eddy simulation of a curved open-channel flow over topography Physics of Fluids 22(7).

[LB11] Beuth L., Wieckowski Z., Vermeer P.A. (2011). Solution of quasi-static large-strain problems by the material point method, International Journal for Numerical and Analytical Methods in Geomechanics 35, 1451-1465.

[MC14] Cartigny M.J.B., Eggenhuisen J.T., Hansen E.W.M., Postma, G. (in review) Concentration-dependent flow stratifi-cation in experimental high-denisty turbidity currents and their relevance to turbidites facies models. J. Sed. Res.

[JE12a] Eggenhuisen J.T., McCaffrey W.D. (2012). The vertical turbulence structure of experimental turbidity currents en-countering basal obstructions: implications for vertical suspended sediment distribution in non-equilibrium currents. Sedimentology 59, 1101-1120.

[JE12b] Eggenhuisen J.T., McCaffrey W.D. (2012). Dynamic deviation of fluid pressure from hydrostatic pressure in turbidity currents. Geology 40, 295-298.

[IJ13] Jassim I., Stolle D., Vermeer P.A. (2013). Two-phase dynamic analysis by material point method. International Journal for Numerical and Analytical Methods in Geomechanics 37(15), 2502-2522.

[SJ08] Jonkman S.N., Vrijling J.K., Kok M. (2008). Flood risk assessment in the Netherlands: A case study for dike ring South Holland. Risk Analysis 28(5), 1357-1373.

[SJ03] Jonkman S.N., Van Gelder P.H.A.J.M., Vrijling J.K. (2003). An overview of quantitative risk measures for loss of life and economic damage, Journal of Hazardous Materials A 99, 1-30.

[SJ13] Jonkman S.N. (2013). Advanced flood risk analysis required. Nature Climate Change 3.

[GK11] Kruse G.A.M. (2011). Deriving scenarios for stochastic characterisation of the subsurface. In: Van M.A., Den Haan E.J., Van Deen J.K. (Eds.) A feeling for soil and water. A tribute to Prof. Barends. Deltares Select Series 7, Deltares Delft, 19-28.

[RL07] Labeur R.J., Wells G. N. (2007). A Galerkin interface stabilization method for the advection-diffusion and incompressible Navier-Stokes equations. Computer Methods in Applied Mechanics and Engineering 196, 4985-5000.

[AN99] Niedoroda A., Reed C., Breza J., Parsons B., Badalini M., Kruse G.A.M., Mullee G., Parker G., Forristal G. (1999). Developing engineering design criteria for deep water turbidity currents. In: Proc. ASME and OMAE Conference, New Orleans.

[SP05] Van der Pijl S.P., Segal A., Vuik C., Wesseling P. (2005). A mass-conserving Level-Set method for modelling of multi-phase flows. International Journal for Numerical Methods in Fluids 47, 339-361.

[SP08] Van Pijl S.P., Segal A., Vuik C., Wesseling P. (2008). Computing three-dimensional two-phase flows with a mass-conserving level-set method Comput. Visual Sciences 11, 221-235.

[JT14] Teunissen J.A.M., Kruse G.A.M. (2014). Simulation of liquefaction in layered loose and dense sand. In: Proc. 8th European Conference on Numerical Methods in Geotechnical Engineering, Delft, 18-20 June 2014.

[WU03] Uijttewaal W.S.J., Jirka G.H. (2003). Grid turbulence in shallow flows, Journal of Fluid Mechanics 489, 325-344.

[PC93] Cowell P.J., Stive M.J.F., Niedoroda A.W., Swift D.J.P., De Vriend H.J., Buijsman M.C., Nicholls R.J., Roy P.S., Kaminsky G.M., Cleveringa J., Reed C.W., De Boer P.L. (1993) The coastal-tract (part 2): Applications of aggregated modeling of lower-order coastal change. Journal of Coastal Research, 828-848.

[PB88] De Boer P.L., Nio S.D., Van Gelder A. (1988) Tide-influenced sedimentary environments and facies. Reidel Publishing Co.

[PB89] De Boer P.L., Oost A.P., Visser M.J. (1989) The diurnal inequality of the tide as a parameter for recognizing tidal influences. Journal of Sedimentary Research 59, 912-921.

[PB98] De Boer P.L. (1998) Intertidal sediments: Composition and structures. Chapter 7 in: Eisma, D. (Ed.) Intertidal Deposits: River Mouths, Tidal Flats, and Coastal Lagoons.Boca Raton, Fla. CRC Press, 345-361.

[PB12] De Boer P.L. and Trabucho-Alexandre, J. (2012) Orbitally forced sedimentary rhythms in the stratigraphic record: Is there room for tidal forcing? Sedimentology, 59, 379-392.

[AO94] Oost A.P., De Boer P.L. (1994) Sedimentology and development of barrier islands, ebb-tidal deltas, inlets and backbarrier areas of the Dutch Wadden Sea. Senckenbergiana Maritima 24, 65-115.

[AO93] Oost A.P., De Haas H., IJnsen F., Van den Boogert J.M., De Boer P.L. (1993) The 18.6 yr nodal cycle and its impact on tidal sedimentation. Sedimentary Geology 87, 1-11

[RR05] Rieu R., Van Heteren S., Van der Spek A.J.F., De Boer P.L. (2005) Development and preservation of a mid-Holocene tidal-channel network offshore the western Netherlands. Journal of Sedimentary Research 75, 409-419

[LS91] Sha L.P., De Boer, P.L. (1991) Ebb-tidal delta deposits along the West Frisian Islands (The Netherlands): processes, facies architecture and preservation. In: Smith, D.G., Reinson, G.E. Zaitlin, B.A. & Rahmani, R.A. (Eds.) Clastic tidal sedimentology Canadian Soc. Petrol. Geol. Mem. 16, 199-218.

[OS95] Sztanó O., De Boer, P.L. (1995) Amplification of tidal motions in the Early Miocene North Hungarian bay. Sedimentology, 42, 665-682.

[KA07] Abe K., Johansson J., Konagai K. (2007). A new method for the run-out analysis and motion prediction of rapid and long-traveling landslides with MPM. JSCE Journal of Geotechnical and Geoenvironmental Engineering 63, 93-109. (In Japanese).

[SA10] Andersen S.M., Andersen L. (2010). Modeling of landslides with the material point method. Computational Geosciences 14, 137-147.

[JB04] Baas J.H., Van Kesteren W., Postma G. (2004). Deposits of depletive high-density turbidity currents: a flume analogue of bed geometry, structure and texture. Sedimentology 51(5), 1053-1088.

[JB02] Van den Berg J.H., Van Gelder A., Mastbergen D.R. (2002). The importance of breaching as a mechanism of sub-aqueous slope failure in fine sand, Sedimentology 49, 81-95.

[HB07] Bui, H.H., Sako, K., Fukagawa, R. (2007). Numerical simulation of soil-water interaction using smoothed particle hydrodynamics (SPH) method. Journal of Terramechanics 44, 339-346.

[CC05] Cassar C., Nicolas M., Pouliquen O. (2005). Submarine granular flows down inclined planes. Physics of Fluids 17(10), 103301.

[GC69] Castro G., (1969). Liquefaction of sands, Harvard Soil Mechanical Series No.81, Harvard University, Cambridge Mass., United States.

[MG95] De Groot M.B., Den Adel H., Stoutjesdijk T.P., Van Westenbrugge C.J. (1995). Risk of dike failure due to flow slides, Coastal Engineering 26, 241-299.

[MG06] De Groot M.B., Bolton M.D., Foray P., Meijers P., Palmer A.C., Sandven R., Sawicki A., The T.C. (2006). Physics of liquefaction phenomena around marine structures, Journal of Waterway, Port, Coastal and Ocean Engineering 132, 227-243.

[RH07] Hack R., Alkema D., Kruse G.A.M., Leenders N., Luzi L. (2007). Influence of earthquakes on the stability of slopes. Engineering Geology 91(1), 4-15.

[HH04] Haflidason H., Sejrup H.P., Nygård A., Mienert J., Bryn P., Lien R., Forsberg C.F., Berg K., Masson D. (2004). The Storegga Slide: Architecture, geometry and slide development. Marine Geology 213(1-4), 201-234.

[WH03] Hundsdorfer W., Verwer J.G. (2003). Numerical Solution of Time-Dependent Advection-Diffusion-Reaction Equations Springer, Berlin.

[MJ93] Jefferies M.G. (1993). Nor-Sand: A simple critical state model for sand, Géotechnique 43, 91-103.

[SK11] Kraft S., Wang Y., Oberlack M. (2011). Large eddy simulation of sediment deformation in a turbulent flow by means of level-set method. Journal of Hydraulic Engingeering 137(11), 1394-1405.

[GK07] Kruse G.A.M., Dijkstra T.A., Schokking F. (2007). Soil structure and effects on soil behaviour: Illustrated with loess, glacially loaded clay and simulated flaser bedding examples. Engineering Geology 91(1), 34-45.

[RL12] Labeur R.J., Wells G.N. (2012). Energy stable and momentum conserving hybrid finite element method for the incompressible Navier-Stokes equations, SIAM Journal of Scientific Computing 34(2).

[DM03] Mastbergen D.R., Van den Berg J. (2003). Breaching in fine sands and the generation of sustained turbidity currents in submarine canyons, Sedimentology 50, 625-637.

[KM76] Meijer K.L., Van Os A.G. (1976). Pore pressures near moving underwater slope.Journal of the Geotechnical Engineering Division 102(4), :361-372.

[FM91] Molenkamp F (1991). Liquefaction Analysis of slopes. Delft Geotechnics SE-703454/1.

[FM98] Molenkamp F., Choobbasti A.J., Heshmati A. (1998). Modelling of liquefaction and flow of water saturated soil. In: Proc. of the Sec. Roy. Soc. UK Forum in Material Science and Engineering on Dynamics of Complex Fluids, Imperial College Press, 446-468.

[FM99] Molenkamp F. (1999). Collapse due to static liquefaction analysed using large deformation elasto-visco-plastic dynamics. In: Proc. NUMOG 7, Numerical Models in Geomechanics, Graz, Balkema, 527-533.

[DM10] Muir Wood, D., Maeda, K., Nukudani, E. (2010). Modelling mechanical consequences of erosion. Géotechnique 60(6), 447-457.

[EO08] Onate E., Idelsohn S.R., Celigueta M.A., Rossi, R. (2008). Advances in the particle finite element method for the analysis of fluid-multibody interaction and bed erosion in free surface flows. Computer Methods in Applied Mechanics and Engineering 197, 1777-1800.

[EO06] Onate E., Celigueta M.A., Idelsohn, S.R. (2006). Modeling bed erosion in free surface flows by the particle finite element method. Acta Geotechnica 1, 237-252.

[WO13] Ottevanger W., Blanckaert K., Uijttewaal W.S.J., Vriend H.J. de (2013). Meander dynamics: A reduced-order nonlinear model without curvature restrictions for flow and bed morphology, Journal of Geophysical Research: Earth Surface 118(2), 1118-1131.

[MP09] Pailha M., Pouliquen O. (2009). A two-phase flow description of the initiation of underwater granular avalanches. Journal of Fluid Mechanics 633,115-135.

[GP86] Parker G., Fukushima Y., Pantin H.M. (1986). Self-accelerating turbidity currents. Journal of Fluid Mechanics 171, 145-81.

[CR98] Van Rhee C., Bezuijen A. (1998). The breaching of sand investigated in large-scale model tests. In: Proc. Int. Coastal Eng. Conf. 3, 2509-2519.

[CR10a] Van Rhee C. (2010). Sediment entrainment at high flow velocity. Journal of Hydraulic Engineering 136(9), 572-582.

[CR10b] Van Rhee C., Talmon A.M. (2010). Sedimentation and erosion of sediment at high solids concentration. In: Hydrotransport 18, Rio de Janeiro, Brazil.

[RW13] Rijkswaterstaat Zee en Delta / Witteveen+Bos (2013). MIRT Verkenning Zandhonger Oosterschelde.

[WR93] Rodi, W. (1993). Turbulence models and their application in hydraulics: A state of the art review. IAHR, Third Edition.

[GK02] Schoofs C.A., Kruse G.A.M. (2002). Investigation of a tensor renormalization method to determine the effective conductivity of heterogeneous subsoils. In: Proc. 14th Int. Conf. of Computational Methods in Water Resources, Delft, Amsterdam, Elsevier, 1235-1242.

[WS09] Shin W. (2009). Numerical simulation of landslides and debris flows using an enhanced material point method. Ph.D. Dissertation, University of Washington.

[FS95] Silvis F., De Groot M.B. (1995). Flow slides in the Netherlands: experience and engineering practice, Canadian Geotechnical Journal 32, 1086-1092.

[DS04] Smith, D.E., Shi S., Cullingford R.A., Dawson A.G., Dawson S., Firth C.R., Foster I.D.L., Fretwell P.T., Haggart B.A., Holloway L.K., Long D. (2004). The Holocene Storegga Slide tsunami in the United Kingdom, Quaternary Science Reviews 23(23-24), 2291-2321.

[DT01] Tappin, D.R., Watts P., McMurtry G.M., Lafoy Y., Matsumoto T. (2001). The Sissano, Papua New Guinea tsunami of July 1998 - offshore evidence on the source mechanism, Marine Geology 175(1-4), 1-23.

[HV06] De Vriend, H.J., Barends, F.B.J. (2006). Scour and erosion: common ground between hydraulics and geotechnics. In: Proc. 3rd International Conference on Scour and Erosion, Amsterdam, 45-51.

[PW08] Wallstedt P.C., Guilkey J.E. (2008). An evaluation of explicit time integration schemes for use with the generalized interpolation material point method. Journal of Computational Physics 227, 9628- 9642.

[WH14] Waterschap Hollandsche Delta (2014). Extern Evaluatierapport Zettingsvloeiing. Kwink Groep, Den Haag.

[ZW04] Wieckowski, Z. (2004). The material point method in large strain engineering problems., Computer Methods in Applied Mechanics and Engineering 193, 4417-4438.

[MW79] Wilderom, M.H. (1979). Resultaten van het vooroeveronderzoek langs de Zeeuwse stromen. Rijkswaterstaat, Nota 75.2 (in Dutch).