Intruding gravity currents and re-circulation in a rotating frame: Laboratory experiments

We study the propagation of viscous gravity currents over a thin porous substrate with finite capillary entry pressure. Near the origin, where the current is deep, propagation of the current coincides with leakage through the substrate. Near the nose of the current, where the current is thin and the fluid pressure is below the capillary entry pressure, drainage is absent. Consequently the flow can be characterised by the evolution of drainage and fluid fronts. We analyse this flow using numerical and analytical techniques combined with laboratory-scale experiments. At early times, we find that the position of both fronts evolve as $t^{1/2}$, similar to an axisymmetric gravity current on an impermeable substrate. At later times, the growing effect of drainage inhibits spreading, causing the drainage front to logarithmically approach a steady position. In contrast, the asymptotic propagation of the fluid front is quasi-self-similar, having identical structure to the solution of gravity currents on an impermeable substrate, only with slowly varying fluid flux. We benchmark these theoretical results with laboratory experiments that are consistent with our modelling assumption, but that also highlight the detailed dynamics of drainage inhibited by finite capillary pressure.

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Tailwater gravity currents and their connection to perfectly subcritical flow: laboratory experiments and shallow-water and direct numerical solutions

Environmental Fluid Mechanics ◽

10.1007/s10652-020-09745-7 ◽

2020 ◽

Vol 20 (4) ◽

pp. 1141-1171

Author(s):

M. S. Baker ◽

M. Ungarish ◽

M. R. Flynn

Keyword(s):

Shallow Water ◽

Laboratory Experiments ◽

Numerical Solutions ◽

Gravity Currents ◽

Subcritical Flow

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Density- and viscosity-stratified gravity currents: Insight from laboratory experiments and implications for submarine flow deposits

Sedimentary Geology ◽

10.1016/j.sedgeo.2005.04.009 ◽

2005 ◽

Vol 179 (1-2) ◽

pp. 5-29 ◽

Cited By ~ 27

Author(s):

L.A. Amy ◽

J. Peakall ◽

P.J. Talling

Keyword(s):

Laboratory Experiments ◽

Gravity Currents

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The effects of drag on turbulent gravity currents

Journal of Fluid Mechanics ◽

10.1017/s002211200000896x ◽

2000 ◽

Vol 416 ◽

pp. 297-314 ◽

Cited By ~ 28

Author(s):

LYNNE HATCHER ◽

ANDREW J. HOGG ◽

ANDREW W. WOODS

Keyword(s):

Analytical Solution ◽

Laboratory Experiments ◽

Gravity Current ◽

Gravity Currents ◽

Similarity Solutions ◽

Flow Speed ◽

Series Solutions ◽

Accurate Approximation ◽

New Class ◽

Power Series Solutions

We model the propagation of turbulent gravity currents through an array of obstacles which exert a drag force on the flow proportional to the square of the flow speed. A new class of similarity solutions is constructed to describe the flows that develop from a source of strength q0tγ. An analytical solution exists for a finite release, γ = 0, while power series solutions are developed for sources with γ > 0. These are shown to provide an accurate approximation to the numerically calculated similarity solutions. The model is successfully tested against a series of new laboratory experiments which investigate the motion of a turbulent gravity current through a large flume containing an array of obstacles. The model is extended to account for the effects of a sloping boundary. Finally, a series of geophysical and environmental applications of the model are discussed.

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Intrusive gravity currents from finite-length locks in a uniformly stratified fluid

Journal of Fluid Mechanics ◽

10.1017/s0022112009007563 ◽

2009 ◽

Vol 635 ◽

pp. 245-273 ◽

Cited By ~ 23

Author(s):

J. R. MUNROE ◽

C. VOEGELI ◽

B. R. SUTHERLAND ◽

V. BIRMAN ◽

E. H. MEIBURG

Keyword(s):

Numerical Simulations ◽

Internal Waves ◽

Laboratory Experiments ◽

Wave Speed ◽

Gravity Currents ◽

Fluid Density ◽

Ambient Fluid ◽

Experimental Conditions ◽

Mode 2 ◽

The Waves

Gravity currents intruding into a uniformly stratified ambient are examined in a series of finite-volume full-depth lock-release laboratory experiments and in numerical simulations. Previous studies have focused on gravity currents which are denser than fluid at the bottom of the ambient or on symmetric cases in which the intrusion is the average of the ambient density. Here, we vary the density of the intrusion between these two extremes. After an initial adjustment, the intrusions and the internal waves they generate travel at a constant speed. For small departures from symmetry, the intrusion speed depends weakly upon density relative to the ambient fluid density. However, the internal wave speed approximately doubles as the waves change from having a mode-2 structure when generated by symmetric intrusions to having a mode-1 structure when generated by intrusions propagating near the bottom. In the latter circumstance, the interactions between the intrusion and internal waves reflected from the lock-end of the tank are sufficiently strong and so the intrusion stops propagating before reaching the end of the tank. These observations are corroborated by the analysis of two-dimensional numerical simulations of the experimental conditions. These reveal a significant transfer of available potential energy to the ambient in asymmetric circumstances.

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Gravity current propagation up a valley

Journal of Fluid Mechanics ◽

10.1017/jfm.2014.627 ◽

2014 ◽

Vol 762 ◽

pp. 417-434 ◽

Cited By ~ 13

Author(s):

Catherine S. Jones ◽

Claudia Cenedese ◽

Eric P. Chassignet ◽

P. F. Linden ◽

Bruce R. Sutherland

Keyword(s):

Numerical Simulations ◽

Laboratory Experiments ◽

Rectangular Channel ◽

Gravity Current ◽

Gravity Currents ◽

Momentum Transport ◽

Front Speed

AbstractThe advance of the front of a dense gravity current propagating in a rectangular channel and V-shaped valley both horizontally and up a shallow slope is examined through theory, full-depth lock–release laboratory experiments and hydrostatic numerical simulations. Consistent with theory, experiments and simulations show that the front speed is relatively faster in the valley than in the channel. The front speed measured shortly after release from the lock is 5–22 % smaller than theory, with greater discrepancy found in upsloping V-shaped valleys. By contrast, the simulated speed is approximately 6 % larger than theory, showing no dependence on slope for rise angles up to ${\it\theta}=8^{\circ }$. Unlike gravity currents in a channel, the current head is observed in experiments to be more turbulent when propagating in a V-shaped valley. The turbulence is presumably enhanced due to the lateral flows down the sloping sides of the valley. As a consequence, lateral momentum transport contributes to the observed lower initial speeds. A Wentzel–Kramers–Brillouin like theory predicting the deceleration of the current as it runs upslope agrees remarkably well with simulations and with most experiments, within errors.

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Erratum: “Gravity currents flowing upslope: Laboratory experiments and shallow-water simulations” [Phys. Fluids 27, 016602 (2015)]

Physics of Fluids ◽

10.1063/1.4928549 ◽

2015 ◽

Vol 27 (8) ◽

pp. 089902

Author(s):

V. Lombardi ◽

C. Adduce ◽

G. Sciortino ◽

M. La Rocca

Keyword(s):

Shallow Water ◽

Laboratory Experiments ◽

Gravity Currents

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On the application of box models to particle-driven gravity currents

Journal of Fluid Mechanics ◽

10.1017/s0022112000008879 ◽

2000 ◽

Vol 416 ◽

pp. 187-195 ◽

Cited By ~ 23

Author(s):

CHARLOTTE GLADSTONE ◽

ANDREW W. WOODS

Keyword(s):

Experimental Data ◽

Froude Number ◽

Laboratory Experiments ◽

Interstitial Fluid ◽

Gravity Currents ◽

Box Model ◽

Monodisperse Particle ◽

Box Models ◽

Exchange Particle ◽

Different Types

New laboratory experiments on different types of lock-exchange particle-driven gravity currents advancing into a flume of fresh water are presented. These include purely saline currents, monodisperse particle-laden gravity currents with both fresh and saline interstitial fluid, and bidisperse particle-laden currents. For each case a simple box model is developed. These agree well with the experimental data. We find that particulate gravity currents with saline interstitial fluid flowing into ambient fresh fluid are best described using a Froude number of 0.52 in the box model (cf. Huppert & Simpson 1980). However, particulate gravity currents with fresh interstitial fluid are best described using a higher Froude number of 0.67. The change in Froude number reflects the different shape and structure associated with the different density of interstitial fluid. For all experiments, box models provide accurate predictions for up to twenty lock-lengths.

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