**Density Currents in Two-layer Shear Flows**

Ming
Xue

Center
for Analysis and Prediction of Storms

University of Oklahoma, Norman, Oklahoma 73019

(Submitted to the *Quarterly
Journal of Royal Meteorological Society* 1999)

Revised on September 18, 1999

Corresponding Author Address:

Dr. Ming Xue,

CAPS, University of Oklahoma, Sarkeys Energy Center,

100 East Boyd, Norman, OK 73019.

E-mail: mxue@ou.edu.

Summary

In this paper, a previous two-fluid model of idealized density current in low-level shear is extended to include variable upper-level shear. Far-field solutions are determined based on the conservation of mass, momentum and vorticity and the conservation of Bernoulli function (energy) along streamlines for inviscid flows. It is found that the upper-level shear plays a similar role as the low-level shear in controlling the depth of steady-state density currents. In most cases, large positive upper-level shear supports deeper density current and steeper front therefore stronger updraft. It is also found that when the low-level shear is weak and upper-level shear occupies about half of the domain depth, larger positive shear can result in a shallower rather than deeper density current. This behavior was not found for either constant shear flow or flows with only low-level shear. The behavior is understood by examining the flow structure and flow-force components as a function of the upper-level shear. Furthermore, by allowing the upper-level shear to vary, an overturning flow is permitted ahead of the density current. This is not possible in the earlier model in which the upper-level flow is assumed to be constant. This extension allows us to draw closer analogues between the current solutions with the circulation patterns found in typical squall lines in sheared environment.

Time-dependent numerical experiments are conducted for a range of upper and low-level shears. The depth and the propagation speed of simulated density currents are found to agree very well with predictions by the idealized theoretical model. This verifies the validity of the theoretical model. In addition, numerical experiments with identically zero low-level shear but differing upper-level shears suggest that the deeper shear is as important as the low-level shear in determining the uprightness of the upward branch of inflow. In fact, the presence of positive low-level inflow shear may not be essential. Such results are also supported by the theoretical model and may have important implications to our understanding of squall line dynamics.

Keywords: Density current, Squall line dynamics

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