Entrainment and mixing in gravity currents using simultaneous velocity-density measurements

Abstract

Gravity currents modify their flow characteristics by entraining ambient fluid, which depends on a variety of governing parameters such as the initial density, , the total initial height of the fluid, H, and the slope of the terrain, α, from where it is released. Depending on these parameters, the gravity current may be designated as sub-critical, critical, or super-critical. It is imperative to study the entrainment dynamics of a gravity current in order to have a clear understanding of mixing transitions that govern the flow physics, the shear layer thickness, δu, and the mixing layer thickness, δ. Experiments were conducted in a lock-exchange facility in which the dense fluid was separated from the ambient lighter fluid using a gate. As the gate is released instantaneously, an energy conserving gravity current is formed, for which the only governing parameter is the Reynolds number defined as Re=Uh, where U is the front velocity of the gravity current, and h is the height of the current. In our study, the bulk Richardson number, Rib=g'HUb2=1, takes a constant value for all the experiments, with Ub being the bulk velocity of the layer defined as Ub=g'H. Simultaneous Particle Image Velocimetry (PIV) and Planar Laser Induced Fluorescence (PLIF) measurement techniques are employed to get the velocity and density statistics. A flux-based method is used to calculate the entrainment coefficient, EF, for a Reynolds number range of Re≈400-13000 used in our experiments. The result shows a mixing transition at Re≈2700 that is attributed to the flow transitioning from weak Holmboe waves to Kelvin-Helmholtz type instabilities.