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

AbstractInternal 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.

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Two-layer Model for Electroabsorption and Built-in Potential Measurements on a-Si:H pin Solar Cells

MRS Proceedings ◽

10.1557/proc-420-203 ◽

1996 ◽

Vol 420 ◽

Cited By ~ 2

Author(s):

Lin Jiang ◽

E. A. Schiff

Keyword(s):

Solar Cells ◽

Amorphous Silicon ◽

Second Harmonic ◽

Semiconductor Devices ◽

Single Layer ◽

Experimental Results ◽

Layer Model ◽

Two Layer Model ◽

Organic Devices

AbstractModulated Electroabsorption (EA) measurements have been widely used to estimate built-in potentials (Vbi) in semiconductor devices. The method is particularly simple in devices for which the built-in potential is dropped in a single layer of the device. However, experimental results in amorphous silicon and organic devices can involve at least 2 layers. In the present paper we consider the information which can be obtained about 2-layer semiconductor devices from electroabsorption measurements. In particular we describe a 2-layer EA model appropriate to a-Si:H based pin solar cells, for which both the p+ and i layers contribute to the EA signal. We present an analysis of capacitance and second harmonic measurements which yields the EA coefficient for the p+ layer of the device, and we present measurements on a-Si:H pin devices which appear consistent with this analysis. Wavelength dependent EA then yields the built-in potential across the 2-layer device.

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Internal hydraulic jumps in two-layer systems

Journal of Fluid Mechanics ◽

10.1017/jfm.2015.662 ◽

2015 ◽

Vol 787 ◽

pp. 1-15 ◽

Cited By ~ 10

Author(s):

Peter G. Baines

Keyword(s):

Energy Loss ◽

Single Layer ◽

Boussinesq Approximation ◽

Maximum Speed ◽

Hydraulic Jumps ◽

Zero Energy ◽

Layer Model ◽

Two Fluids ◽

Conjugate State ◽

Two Layer Model

This paper describes a new model of internal hydraulic jumps in two-layer systems that places no restrictions (such as the Boussinesq approximation) on the densities of the two fluids. The model is based on that of Borden and Meiburg (J. Fluid Mech., vol. 276, 2013, R1) for Boussinesq jumps, and has the appropriate behaviour in various limits (single-layer, small amplitude, Boussinesq, infinite depth). The energy flux loss in each layer across the jump is positive for all realistic jumps, reaching a maximum for the jump with maximum speed. Larger-amplitude jumps are possible, with decreasing energy loss, down to the ‘conjugate state’ of zero energy loss. However, it is argued that such states may be difficult to realise in practice, and if formed, will tend to the jump with maximum speed. The energy loss is mostly in the contracting layer unless the density there is small. The two-layer model is extended to incorporate mixing between the layers within the jump, with mixing based on the Richardson number.

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A two-layer approach to modelling the transformation of dilute pyroclastic currents into dense pyroclastic flows

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rspa.2010.0402 ◽

2010 ◽

Vol 467 (2129) ◽

pp. 1348-1371 ◽

Cited By ~ 15

Author(s):

Emma E. Doyle ◽

Andrew J. Hogg ◽

Heidy M. Mader

Keyword(s):

Single Layer ◽

Pyroclastic Flows ◽

Constant Density ◽

Particle Collisions ◽

Layer Model ◽

Fluid Turbulence ◽

Naturally Occurring ◽

Dense Granular Flow ◽

Two Layer Model ◽

End Members

Most models of volcanic ash flows assume that the flow is either dilute or dense, with dynamics dominated by fluid turbulence or particle collisions, respectively. However, most naturally occurring flows feature both of these end members. To this end, a two-layer model for the formation of dense pyroclastic basal flows from dilute, collapsing volcanic eruption columns is presented. Depth-averaged, constant temperature, continuum conservation equations to describe the collapsing dilute current are derived. A dense basal flow is then considered to form at the base of this current owing to sedimentation of particles and is modelled as a granular avalanche of constant density. We present results which show that the two-layer model can predict much larger maximum runouts than would be expected from single-layer models, based on either dilute or dense conditions, as the dilute surge can outrun the dense granular flow, or vice versa, depending on conditions.

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The Stability Properties and Energy Transformations of the Two-layer Model of Variable Static Stability

Tellus B ◽

10.3402/tellusb.v13i4.13014 ◽

1961 ◽

Vol 13 (4) ◽

Author(s):

W. Lawrence Gates

Keyword(s):

Static Stability ◽

Layer Model ◽

Stability Properties ◽

Two Layer Model ◽

The Stability

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Effects of Varying Geometrical Parameters on Boiling From Microfabricated Enhanced Structures

Journal of Heat Transfer ◽

10.1115/1.1513575 ◽

2003 ◽

Vol 125 (1) ◽

pp. 103-109 ◽

Cited By ~ 52

Author(s):

C. Ramaswamy ◽

Y. Joshi ◽

W. Nakayama ◽

W. B. Johnson

Keyword(s):

Heat Dissipation ◽

Layer Structure ◽

Single Layer ◽

Nucleate Boiling ◽

Heat Fluxes ◽

Working Fluid ◽

Geometrical Parameters ◽

Small Range ◽

Two Phase ◽

Wall Superheat

The current study involves two-phase cooling from enhanced structures whose dimensions have been changed systematically using microfabrication techniques. The aim is to optimize the dimensions to maximize the heat transfer. The enhanced structure used in this study consists of a stacked network of interconnecting channels making it highly porous. The effect of varying the pore size, pitch and height on the boiling performance was studied, with fluorocarbon FC-72 as the working fluid. While most of the previous studies on the mechanism of enhanced nucleate boiling have focused on a small range of wall superheats (0–4 K), the present study covers a wider range (as high as 30 K). A larger pore and smaller pitch resulted in higher heat dissipation at all heat fluxes. The effect of stacking multiple layers showed a proportional increase in heat dissipation (with additional layers) in a certain range of wall superheat values only. In the wall superheat range 8–13 K, no appreciable difference was observed between a single layer structure and a three layer structure. A fin effect combined with change in the boiling phenomenon within the sub-surface layers is proposed to explain this effect.

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