Gravity currents under oscillatory forcing

We investigate the effect of external oscillatory forcing on evolving two-dimensional (2-D) gravity currents, resulting from the well-known lock-exchange set-up, by superimposing a horizontally uniform oscillating pressure gradient. This pressure gradient generates a 2-D horizontally uniform laminar...

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Bibliographic Details
Published in:Journal of fluid mechanics 2024-12, Vol.1002
Main Authors: Bingol, Cem, Duran-Matute, Matias, Zhu, Rui, Meiburg, Eckart, Clercx, Herman J.H.
Format: Article
Language:English
Subjects:
Advection
Boundary layers
Brackishwater environment
Density distribution
Dynamic structural analysis
Estuaries
External pressure
Fresh water
Gravity
JFM Papers
Laminar boundary layer
Laminar flow
Lifting
Oscillating flow
Oscillations
Pressure effects
Pressure gradients
Propagation velocity
Reynolds number
Rivers
Saline water
Salinity
Sediment transport
Simulation
Two dimensional boundary layer
Two dimensional flow
Velocity
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Summary:We investigate the effect of external oscillatory forcing on evolving two-dimensional (2-D) gravity currents, resulting from the well-known lock-exchange set-up, by superimposing a horizontally uniform oscillating pressure gradient. This pressure gradient generates a 2-D horizontally uniform laminar oscillating flow over the flat no-slip bottom that interacts with the evolving gravity current. We explore the effect of the velocity amplitude of the applied oscillating flow and its period of oscillations on the behaviour of the evolving gravity currents. A key element introduced by the external forcing is the Stokes boundary layer near the no-slip bottom wall generating differential advection near the bottom wall when the propagation direction of the gravity current and the oscillating externally imposed flow are in the same direction. This results in a phenomenon that we refer to as lifting of the gravity current, which clearly distinguishes the oscillatory forced gravity current from the freely evolving case. This phenomenon induces fine-scale density structures when the externally imposed flow is opposite to the propagation direction of the gravity current a semi-period later. We have explored the effect of lifting on the current propagation and the density structure of the gravity current front. Three separate regimes are distinguished for the evolution of the density structure in the front of the gravity current depending on the period of forcing, including a regime reminiscent of tidally forced estuarine flows. The present study shows the existence of significant effects of an oscillatory forcing on the dynamics, advection and density distribution of gravity currents.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2024.1170