High-Reynolds-number gravity currents over a porous boundary: shallow-water solutions and box-model approximations

MARIUS UNGARISH; HERBERT E. HUPPERT

doi:10.1017/S0022112000008302

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

The behaviour of an inviscid, lock-released gravity current which propagates over a horizontal porous boundary in either a rectangular or an axisymmetric geometry is analysed by both shallow-water theory and ‘box-model’ approximations. It is shown that the effect of the porous boundary can be incorporated by means of a parameter λ which represents the ratio of the characteristic time of porous drainage, τ, to that of horizontal spread, x0 =(g′h0)1/2, where x0 and h0 are the length and height of the fluid initially behind the lock and g′ is the reduced gravity. The value of τ is assumed to be known for the fluid–boundary combination under simulation. The interesting cases correspond to small values of λ; otherwise the current has drained before any significant propagation can occur. Typical solutions are presented for various values of the parameters, and differences to the classical current (over a non-porous boundary) are pointed out. The results are consistent with the experiments in a rectangular tank reported by Thomas, Marino & Linden (1998), but a detailed verification, in particular for the axisymmetric geometry case, requires additional experimental data.

Crossref Citations

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

Harris, Thomas C. Hogg, Andrew J. and Huppert, Herbert E. 2001. A mathematical framework for the analysis of particle–driven gravity currents. Proceedings of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences, Vol. 457, Issue. 2009, p. 1241.

Marino, B. M. and Thomas, L. P. 2002. Spreading of a Gravity Current over a Permeable Surface. Journal of Hydraulic Engineering, Vol. 128, Issue. 5, p. 527.

Meiburg, Eckart Blanchette, F. Strauss, M. Kneller, B. Glinsky, M. E. Necker, F. Ha¨rtel, C. and Kleiser, L. 2005. High Resolution Simulations of Particle-Driven Gravity Currents. p. 381.

2009. An Introduction to Gravity Currents and Intrusions. p. 477.

SPANNUTH, MELISSA J. NEUFELD, JEROME A. WETTLAUFER, J. S. and WORSTER, M. GRAE 2009. Axisymmetric viscous gravity currents flowing over a porous medium. Journal of Fluid Mechanics, Vol. 622, Issue. , p. 135.

Thomas, L. P. and Marino, B. M. 2012. Inertial Density Currents over Porous Media Limited by Different Lower Boundary Conditions. Journal of Hydraulic Engineering, Vol. 138, Issue. 2, p. 133.

Liu, X. and Jiang, Y. 2014. Direct numerical simulations of boundary condition effects on the propagation of density current in wall-bounded and open channels. Environmental Fluid Mechanics, Vol. 14, Issue. 2, p. 387.

Sayag, Roiy and Neufeld, Jerome A. 2016. Propagation of viscous currents on a porous substrate with finite capillary entry pressure. Journal of Fluid Mechanics, Vol. 801, Issue. , p. 65.

Momen, Mostafa Zheng, Zhong Bou-Zeid, Elie and Stone, Howard A. 2017. Inertial gravity currents produced by fluid drainage from an edge. Journal of Fluid Mechanics, Vol. 827, Issue. , p. 640.

Zhou, Jian Cenedese, Claudia Williams, Tim Ball, Megan Venayagamoorthy, Subhas K. and Nokes, Roger I. 2017. On the propagation of gravity currents over and through a submerged array of circular cylinders. Journal of Fluid Mechanics, Vol. 831, Issue. , p. 394.

Sahu, Chunendra K. and Flynn, M. R. 2017. The Effect of Sudden Permeability Changes in Porous Media Filling Box Flows. Transport in Porous Media, Vol. 119, Issue. 1, p. 95.

Liu, Ying Zheng, Zhong and Stone, Howard A. 2017. The influence of capillary effects on the drainage of a viscous gravity current into a deep porous medium. Journal of Fluid Mechanics, Vol. 817, Issue. , p. 514.

Jiang, Y. and Liu, X. 2018. Experimental and numerical investigation of density current over macro-roughness. Environmental Fluid Mechanics, Vol. 18, Issue. 1, p. 97.

Venuleo, Sara Pokrajac, Dubravka Schleiss, Anton J. and Franca, Mário J. 2019. Continuously-fed gravity currents propagating over a finite porous substrate. Physics of Fluids, Vol. 31, Issue. 12,

Ungarish, Marius Zhu, Lailai and Stone, Howard A. 2019. Inertial gravity current produced by the drainage of a cylindrical reservoir from an outer or inner edge. Journal of Fluid Mechanics, Vol. 874, Issue. , p. 185.

Zemach, T. 2020. Inertial gravity currents over a permeable bottom in trapezoidal type cross-section channels: shallow-water and box-model solutions. SN Applied Sciences, Vol. 2, Issue. 10,

Zhou, Jian and Venayagamoorthy, Subhas K. 2020. How does three-dimensional canopy geometry affect the front propagation of a gravity current?. Physics of Fluids, Vol. 32, Issue. 9,

Ikeda, Jin and Testik, Firat Y. 2021. Propagation, deposition, and suspension characteristics of constant-volume particle-driven gravity currents. Environmental Fluid Mechanics, Vol. 21, Issue. 1, p. 177.

Venuleo, Sara Pokrajac, Dubravka Tokyay, Talia Constantinescu, George Schleiss, Anton J. and Franca, Mário J. 2021. Parameterization and Results of SWE for Gravity Currents Are Sensitive to the Definition of Depth. Journal of Hydraulic Engineering, Vol. 147, Issue. 5,

Petrolo, D. Ungarish, M. Chiapponi, L. Ciriello, V. and Longo, S. 2021. Experimental verification of theoretical approaches for radial gravity currents draining from an edge. Acta Mechanica, Vol. 232, Issue. 11, p. 4461.

Download full list

Article contents

High-Reynolds-number gravity currents over a porous boundary: shallow-water solutions and box-model approximations

Abstract

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests