Internal bores: an improved model via a detailed analysis of the energy budget

Internal bores: an improved model via a detailed analysis of the energy budget

Internal bores, or internal hydraulic jumps, arise in many atmospheric and oceanographic phenomena. The classic single-layer hydraulic jump model accurately predicts the bore height and propagation velocity when the difference between the densities of the expanding and contracting layers is large (i...

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Veröffentlicht in:Journal of fluid mechanics 2012-07, Vol.703, p.279-314
Hauptverfasser: Borden, Zachary, Meiburg, Eckart, Constantinescu, George
Format: Artikel
Sprache:eng
Schlagworte:
Atmospheric circulation
Bores
Boring tools
Boussinesq equations
Earth, ocean, space
Energy loss
Energy transfer
Energy use
Exact sciences and technology
External geophysics
Fluid flow
Fluid mechanics
Geophysics
Geophysics. Techniques, methods, instrumentation and models
Gravity
Hydraulic jump
Mathematical models
Turbulence
Turbulent flow
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Meiburg, Eckart
Constantinescu, George
description Internal bores, or internal hydraulic jumps, arise in many atmospheric and oceanographic phenomena. The classic single-layer hydraulic jump model accurately predicts the bore height and propagation velocity when the difference between the densities of the expanding and contracting layers is large (i.e. water and air), but fails in the Boussinesq limit. A two-layer model, which conserves mass separately in each layer and momentum globally is more accurate in the Boussinesq limit, but it requires for closure an assumption about the loss of energy across a bore. It is widely believed that bounds on the bore speed can be found by restricting the energy loss entirely to one of the two layers, but under some circumstances, both bounds overpredict the propagation speed. A front velocity slower than both bounds implies that, somehow, the expanding layer is gaining energy. We directly examine the flux of energy within internal bores using two- and three-dimensional direct numerical simulations and find that although there is a global loss of energy across a bore, a transfer of energy from the contracting to the expanding layer causes a net energy gain in the expanding layer. The energy transfer is largely the result of turbulent mixing at the interface. Within the parameter regime investigated, the effect of mixing is much larger than non-hydrostatic and viscous effects, both of which are neglected in the two-layer analytical models. Based on our results, we propose an improved two-layer model that provides an accurate propagation velocity as a function of the geometrical parameters, the Reynolds number, and the Schmidt number.
doi_str_mv 10.1017/jfm.2012.213
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Based on our results, we propose an improved two-layer model that provides an accurate propagation velocity as a function of the geometrical parameters, the Reynolds number, and the Schmidt number.</abstract><cop>Cambridge, UK</cop><pub>Cambridge University Press</pub><doi>10.1017/jfm.2012.213</doi><tpages>36</tpages></addata></record>
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source Cambridge University Press Journals Complete
subjects Atmospheric circulation
Bores
Boring tools
Boussinesq equations
Earth, ocean, space
Energy loss
Energy transfer
Energy use
Exact sciences and technology
External geophysics
Fluid flow
Fluid mechanics
Geophysics
Geophysics. Techniques, methods, instrumentation and models
Gravity
Hydraulic jump
Mathematical models
Turbulence
Turbulent flow
title Internal bores: an improved model via a detailed analysis of the energy budget
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