Publications

 Damien Pham Van Bang

• Boujia N, Schmidt F, Chevalier C, Siegert D et Pham van Bang D (2020).Distributed optical fiber-based approach for soil-structure interaction. Sensor, 20 (1): Art. 321.   DOI : 10.3390/s20010321
• Orseau S, Huybrechts N, Tassi P, Pham van Bang D et Klein F (2020). Two-dimensional modeling of fine sediment transport with mixed sediment and consolidation: Application to the Gironde Estuary, France . Int. J. Sediment Res.,  EN LIGNE. DOI : 10.1016/j.ijsrc.2019.12.005
• Boujia, Nissrine; Schmidt, Franziska; Chevalier, Christophe; Siegert, Dominique et Pham van Bang, Damien (2019). Effect of scour on the natural frequency responses of bridge piers: development of a scour depth sensor. Infrastructures, 4 (2) : Art. 21.
  DOI : 10.3390/infrastructures4020021
• Cordier, F.; Tassi, Pablo; Claude, N.; Rodrigues, S.; Crosato, A. et Pham van Bang, Damien (2019). Numerical study of alternate bars in alluvial channels with non-uniform sediment. Water Resour. Res., 55 (4) : 2976-3003.
  DOI : 10.1029/2017WR022420
• Santoro, Pablo; Fossati, Monica; Tassi, Pablo; Huybrechts, Nicolas; Pham van Bang, Damien et Piedra-Cueva, Ismael (2019). Effect of self-weight consolidation on a hydro-sedimentological model for the Río de la Plata estuary. Int. J. Sediment Res., 34 (5) : 444-454.
  DOI : 10.1016/j.ijsrc.2018.12.004
• Uh Zapata, Niguel; Zhang, Wei; Pham van Bang, Damien et Nguyen, Dan Kim (2019). A parallel second-order unstructured finite volume method for 3D free-surface flows using a ó coordinate. Comput. Fluids, 190 (Août) : 15-29.
  DOI : 10.1016/j.compfluid.2019.06.001
• Zhang, Wei; Uh Zapata, Niguel; Bai, Xin; Pham van Bang, Damien et Nguyen, Kim Dan (2019). Tree-dimensional simulation of horseshoe vortex and local scour around a vertical cylinder using an unstructured finite-volume technique. Int. J. Sediment Res., EN LIGNE.
  DOI : 10.1016/j.ijsrc.2019.09.001
• Zapata MU, Pham Van Bang D & NguyenKD (2018) Parallel simulations for a 2D x/z two-phase flow fluid-solid particle model. Computers and fluids, 173: 103-110. DOI: 10.1016/j.compfluid.2018.03.019
• Boujia N, Schmidt F, Siegert D, Pham Van Bang D, Chevalier C (2017). Modelling of a bridge pier subjected to scour. Procedia Engineering, 199: 925-2930. DOI: 10.1016/j.proeng.2017.09.343
• Santoro P, Fossati M, Tassi P, Huybrechts N, Pham Van Bang D & Piedra-Cueva JCI (2017) A coupled wave–current–sediment transport model for an estuarine system: Application to the Río de la Plata and Montevideo Bay. Applied Mathematical Modelling, 52:107-130.  DOI: 10.1016/j.apm.2017.07.0040
• Zapata MU, Pham Van Bang D & Nguyen KD (2016). Parallel SOR methods with a parabolic-diffusion acceleration technique for solving an unstructured-grid Poisson equation on 3D arbitrary geometries. International Journal for Computational Fluid Dynamics, 30(5):370-385. DOI: 10.1080/10618562.2016.1234045
• Zapata MU, Pham Van Bang D & Nguyen KD (2014) An unstructured finite volume technique for the 3D Poisson equation on arbitrary geometry using a σ‐coordinate system. International Journal for Numerical Methods in Fluids, 76(10):611-631. DOI: 10.1002/fld.3945
• Van LA & Pham Van Bang D (2013) Hindered settling of sand-mud flocs mixtures: From model formulation to numerical validation. Advances in Water Resources, 53:1-11.  DOI: 10.1016/j.advwatres.2012.09.009
• Chauchat J, Guillou S, Pham Van Bang D & Dan Nguyen K (2013) Modelling sedimentation–consolidation in the framework of a one-dimensional two-phase flow model. Journal of Hydraulic Research, 51(3):293-305.
  DOI: 10.1080/00221686.2013.76879
• Nguyen DH, Levy F, Pham Van Bang D, Guillou S, Nguyen KD & Chauchat J (2012) Simulation of dredged sediment releases into homogeneous water using a two-phase model. Advances in Water Resources, 48:102-112.
  DOI: 10.1016/j.advwatres.2012.03.009
• Camenen B & Pham Van Bang D (2011) Modelling the settling of suspended sediments for concentrations close to the gelling concentration. Continental Shelf Research, 31(10):S106-S116.  DOI: 10.1016/j.csr.2010.07.003
• Villaret C, Van LA, Huybrechts N, Pham Van Bang D & Boucher O (2010) Effets de la consolidation sur la modélisation morphodynamique : application à l’estuaire de la Gironde. La Houille Blanche, (6):15-24.  DOI: 10.1051/lhb/2010062
• Pham Van Bang D, Ouahsine A, Sergent P, Long B, Montreuil S, Debaillon P & Hissel F (2009) Vagues et érosion des sédiments générées par le passage des bateaux de navigation intérieure, mesures in situ et analyses. Revue Technique Maritime et Fluviale, 2:18-24.
• Pham Van Bang D, Lefrancois E, Sergent P & Bertrand F (2008) Expérimentation par IRM et modélisation par éléments finis de la sédimentation-consolidation des vases. La Houille Blanche, (3):39-44.  DOI: 10.1051/lhb:2008025
• Pham Van Bang D, Ovarlez G & Tocquer L (2007) Density and structural effects on the rheological characteristics of mud. La Houille Blanche, (2):85-93.  DOI: 10.1051/lhb:2007023
• Pham Van Bang D, Di Benedetto H, Duttine A & Ezaoui A (2007) Viscous behaviour of dry sand. International Journal for Numerical and Analytical Methods in Geomechanics, 31(15):1631-1658.
  DOI: 10.1002/nag.606
• Duttine A, Di Benedetto H, Pham Van Bang D & Ezaoui A (2007) Anisotropic small strain elastic properties of sands and mixture of sand-clay measured by dynamic and static methods. Soils and Foundations, 47(3):457-472.  DOI: 10.3208/sandf.47.457
• Pham Van Bang D(2004) Comportement instantané et différé des sables des petites aux moyennes déformations : expérimentation et modélisation. Doctorat en Génie civil (PhD) (INSA, Lyon). 275 p.
• Unstructured Finite-Volume Model of Sediment Scouring Due to Wave Impact on Vertical Seawalls Miguel Uh Zapata 1,*,† , Damien Pham Van Bang 2,† and Kim Dan Nguyen 3,†, Miguel Uh Zapata 1,*,† , Damien Pham Van Bang 2,† and Kim Dan Nguyen 3,† Mar. Sci. Eng. 2021, 9, 1440. https://doi.org/10.3390/jmse9121440
• Three-Dimensional Hydrostatic Curved Channel Flow Simulations Using Non-Staggered Triangular Grids, Wei Zhang 1,* , Miguel Uh Zapata 2 , Damien Pham Van Bang 3 and Kim Dan Nguyen 4, Water 2022, 14, 174. https://doi.org/10.3390/w14020174
• Two-phase experimental and numerical studies on scouring at the toe of vertical seawall, M. Uh Zapata a,∗, W. Zhang b, L. Marois c, A. Hammouti c, D. Pham Van Bang c, K.D. Nguyen d : Eur. J. Mech /B Fluids. 2022,https://doi.org/10.1016/j.euromechflu.2021.12.008

Jacob Stolle

• Stolle, J., Goseberg, N., Nistor, I., and Petriu, E. (2020). Development of a Probabilistic Framework for Debris Transport and Hazard Assessment in Tsunami-Like Flow Conditions. Journal of Waterway, Port, Coastal, and Ocean Engineering. ASCE. Under Review.
• Mauti, G., Stolle, J., Takabatake, T., Nistor, I., Goseberg, N., and Mohammadian, M. (2020). Experimental Investigation of Idealized Debris Dams in Steady Flow Conditions. Journal of Hydraulic Engineering. ASCE. In-Press.
• Stolle, J., Krautwald, C., Robertson, I., Achiari, H., Nakamura, R., Takabatake, T., Nishida, Y., Shibayama, T., Esteban, M., Nistor, I., and Goseberg, N. (2019). Engineering Lessons from the 28 September 2018 Tsunami: Debris Loading. Canadian Journal of Civil Engineering. 47, pp. 1 – 12.
• Ghodoosipour, B., Stolle, J., Nistor, I., Mohammadian, M., and Goseberg, N. (2019). Experimental Study on Extreme Hydrodynamic Loading on Pipelines. Part 1: Flow Hydrodynamics. Journal of Marine Science and Engineering. MDPI. 7, 251.
• Ghodoosipour, B., Stolle, J., Nistor, I., Mohammadian, M., and Goseberg, N. (2019). Experimental Study on Extreme Hydrodynamic Loading on Pipelines. Part 2: Induced Force Analysis. Journal of Marine Science and Engineering. MDPI. 7, 262.
• Stolle, J., Nistor, I., Goseberg, N., and Petriu, E. (2018). Multiple Debris Impact Loads in Extreme Hydrodynamic Conditions. Journal of Waterway, Port, Coastal and Ocean Engineering. ASCE. 146, 04019038.
• Takabatake, T., St-Germain, P., Nistor, I., Stolle, J., and Shibayama, T. (2018). Numerical Modelling of Coastal Inundation from Cascadia Subduction Zone Tsunamis and Implications for Coastal Communities on Western Vancouver Island, Canada. Natural Hazards, Springer. 98, pp. 267 – 291.
• Stolle, J., Takabatake, T., Hamano, G., Ishii, H., Iimura, K., Shibayama, T., Nistor, I., Goseberg, N., and Petriu, E. (2018). Debris Transport over a Sloped Surface. Coastal Engineering Journal. Taylor & Francis. 61, pp. 241 – 255.
• Stolle, J., Goseberg, N., Nistor, I., and Petriu, E. (2018). Debris Impact Forces on Flexible Structures in Extreme Hydrodynamic Conditions. Journal of Fluids and Structures. Elsevier. 84, pp. 391 – 407.
• Stolle, J., Derschum, C., Goseberg, N., Nistor, I., and Petriu, E. (2018). Debris Impact under Extreme Hydrodynamic Conditions Part 2: Impact Force Responses for Non-Rigid Debris Collisions. Coastal Engineering. Elsevier. 141, pp. 107 – 118.
• Von Häfen, H., Goseberg, N., Stolle, J., and Nistor, I. (2018). Gate-Opening Criteria for Generating Dam-break Waves using Smoothed Particle Hydrodynamics. Journal of Hydraulic Engineering. ASCE. 04019002.
• Derschum, C., Nistor, I., Stolle, J., and Goseberg, N. (2018). Debris Impact under Extreme Hydrodynamic Conditions Part 1: Hydrodynamics, Wave-Structure Interactions and Impact Geometry. Coastal Engineering. Elsevier. 141, pp. 24 – 35.
• Stolle, J., Takabatake, T., Nistor, I., Mikami, T., Nishizaki, S., Hamano, G., Ishii, H., Shibayama, T., Goseberg, N., and Petriu, E. (2018). Experimental Investigation of Debris Damming Loads under Transient Supercritical Flow Conditions. Coastal Engineering. Elsevier. 139, pp. 16 – 31.
• Stolle, J., Ghodoosipour, B., Derschum, C., Nistor, I., Petriu, E., and Goseberg, N. (2018). Swing Gate Generated Dam-break Waves. Journal of Hydraulic Research, IAHR, Taylor & Francis. 57, pp. 657 – 687.
• Esteban, M., Glasbergen, T., Takabatake, T., Hofland, B., Nishizaki, S., Nishida, Y., Stolle, J., Nistor, I., Bricker, J., Takagi, H., and Shibayama, T. (2017). Overtopping of Coastal Structures by Tsunami Waves. Geosciences. MDPI. 7, 121.
• Stolle, J., Takabatake, T., Mikami, T., Shibayama, T., Goseberg, N., Nistor, I., and Petriu, E. (2017). Experimental Investigation of Debris-Induced Loading in Tsunami-Like Flood Events. Geosciences. MDPI. 7, 74.
• Stolle, J., Goseberg, N., Nistor, I., and Petriu, E. (2018). Probabilistic Investigation and Risk Assessment of Debris Transport in Extreme Hydrodynamic Conditions. Journal of Waterways, Port, Ocean, and Coastal Engineering. ASCE. 144(1), 04017039.
• Stolle, J., Nistor, I., Goseberg, N., Mikami, T. and Shibayama, T. (2017). Entrainment and Transport Dynamics of Shipping Containers in Extreme Hydrodynamic Conditions. Coastal Engineering Journal, JSCE, 1750011.
• Nistor, I., Goseberg, N., & Stolle, J. (2017). Tsunami-Driven Debris Motion and Loads: A Critical Review. Frontiers in Built Environment, 3, 2.
• Goseberg, N., Stolle, J., Nistor, I., and Shibayama, T. (2016). Experimental Analysis of Debris Motion due the Obstruction from Fixed Obstacles. Coastal Engineering, Elsevier, 18, pp. 35 – 49.
• Stolle, J., Nistor, I., & Goseberg, N. (2016). Optical Tracking of Floating Shipping Containers in a High-Velocity Flow. Coastal Engineering Journal, JSCE, 1650005.
• Nistor, I., Goseberg, N., Mikami, T., Shibayama, T., Stolle, J., Nakamura, R., and Matsuba, S. (2016). Hydraulic Experiments on Debris Dynamics over a Horizontal Plane. Journal of Waterway, Port, Coastal and Ocean Engineering, ASCE, 04016022.
• Goseberg, N., Nistor, I., Mikami, T., Shibayama, T., & Stolle, J. (2016). Nonintrusive Spatiotemporal Smart Debris Tracking in Turbulent Flows with Application to Debris-Laden Tsunami Inundation. Journal of Hydraulic Engineering, IAHR, 04016058.