Sediment-entraining suspension clouds: a model of powder-snow avalanches

M. RASTELLO; E. J. HOPFINGER

doi:10.1017/S0022112004009322

Abstract

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A dense cloud model of avalanches is presented which includes large density difference effects as well as sediment entrainment along the path of the cloud. This model demonstrates the importance of sediment entrainment in the evolution of the front velocity. Without sediment entrainment the cloud first accelerates and then decelerates, a behaviour known from previous studies of cloud or thermal motions. With sediment entrainment the cloud is mostly in an accelerating state. The closure coefficients in the model concerning the cloud shape and air entrainment are obtained from laboratory experiments. These coefficients can be considered generic in the Boussinesq limit. A correction for inertial effects which need to be taken into account when applied to large density difference clouds such as avalanches, is proposed. An expression for the sediment entrainment coefficient is derived, taking into account the flow parameters and the sediment layer properties. The model predictions are in good agreement with recent measurement of the front velocity of a powder-snow avalanche. A presentation, in terms of dimensionless variables, of avalanche and laboratory Boussinesq cloud velocities shows clearly the similarities and differences between the two.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Étienne, Jocelyn Saramito, Pierre and Hopfinger, Emil J. 2004. Numerical simulations of dense clouds on steep slopes: application to powder-snow avalanches. Annals of Glaciology, Vol. 38, Issue. , p. 379.

Étienne, Jocelyn Rastello, Marie and Hopfinger, Emil J. 2006. Modelling and simulation of powder-snow avalanches . Comptes Rendus. Mécanique, Vol. 334, Issue. 8-9, p. 545.

MAXWORTHY, T. and NOKES, R. I. 2007. Experiments on gravity currents propagating down slopes. Part 1. The release of a fixed volume of heavy fluid from an enclosed lock into an open channel. Journal of Fluid Mechanics, Vol. 584, Issue. , p. 433.

Dai, Albert 2010. Note on the generalized thermal theory for gravity currents in the deceleration phase. Dynamics of Atmospheres and Oceans, Vol. 50, Issue. 3, p. 424.

MAXWORTHY, T. 2010. Experiments on gravity currents propagating down slopes. Part 2. The evolution of a fixed volume of fluid released from closed locks into a long, open channel. Journal of Fluid Mechanics, Vol. 647, Issue. , p. 27.

Dai, Albert and García, Marcelo H. 2010. Gravity currents down a slope in deceleration phase. Dynamics of Atmospheres and Oceans, Vol. 49, Issue. 1, p. 75.

Roche, O. Montserrat, S. Niño, Y. and Tamburrino, A. 2010. Pore fluid pressure and internal kinematics of gravitational laboratory air‐particle flows: Insights into the emplacement dynamics of pyroclastic flows. Journal of Geophysical Research: Solid Earth, Vol. 115, Issue. B9,

Meyapin, Yannick Dutykh, Denys and Gisclon, Marguerite 2011. Computational Science and High Performance Computing IV. Vol. 115, Issue. , p. 219.

Rastello, Marie Rastello, Fabrice Bellot, Hervé Ousset, Frédéric Dufour, François and Meier, Lorenz 2011. Size of snow particles in a powder-snow avalanche. Journal of Glaciology, Vol. 57, Issue. 201, p. 151.

Dutykh, Denys Acary‐Robert, Céline and Bresch, Didier 2011. Mathematical Modeling of Powder‐Snow Avalanche Flows. Studies in Applied Mathematics, Vol. 127, Issue. 1, p. 38.

Dai, A. Ozdemir, C. E. Cantero, M. I. and Balachandar, S. 2012. Gravity Currents from Instantaneous Sources Down a Slope. Journal of Hydraulic Engineering, Vol. 138, Issue. 3, p. 237.

Dai, Albert 2013. Experiments on gravity currents propagating on different bottom slopes. Journal of Fluid Mechanics, Vol. 731, Issue. , p. 117.

Dai, Albert 2013. Power-law for gravity currents on slopes in the deceleration phase. Dynamics of Atmospheres and Oceans, Vol. 63, Issue. , p. 94.

Dai, Albert 2013. Gravity Currents Propagating on Sloping Boundaries. Journal of Hydraulic Engineering, Vol. 139, Issue. 6, p. 593.

Carroll, C. S. Louge, M. Y. and Turnbull, B. 2013. Frontal dynamics of powder snow avalanches. Journal of Geophysical Research: Earth Surface, Vol. 118, Issue. 2, p. 913.

Dai, Albert 2014. Non-Boussinesq gravity currents propagating on different bottom slopes. Journal of Fluid Mechanics, Vol. 741, Issue. , p. 658.

Dai, Albert 2015. Thermal Theory for Non-Boussinesq Gravity Currents Propagating on Inclined Boundaries. Journal of Hydraulic Engineering, Vol. 141, Issue. 1,

Dai, Albert 2015. On the instability of a buoyancy-driven downflow. Dynamics of Atmospheres and Oceans, Vol. 71, Issue. , p. 98.

Calgaro, Caterina Creusé, Emmanuel and Goudon, Thierry 2015. Modeling and simulation of mixture flows: Application to powder–snow avalanches. Computers & Fluids, Vol. 107, Issue. , p. 100.

Steinkogler, Walter Gaume, Johan Löwe, Henning Sovilla, Betty and Lehning, Michael 2015. Granulation of snow: From tumbler experiments to discrete element simulations. Journal of Geophysical Research: Earth Surface, Vol. 120, Issue. 6, p. 1107.

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Sediment-entraining suspension clouds: a model of powder-snow avalanches

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