Effects of shear and sharp gradients in static stability on two-dimensional flow over an isolated mountain ridge |
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Authors: | Ting-An Wang Yuh-Lang Lin |
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Institution: | (1) Air Traffic Services Division, Civil Aeronautics Administration, Taipei, Taiwan, TW;(2) North Carolina State University, Raleigh, NC, US |
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Abstract: | Summary ?We have investigated the effects of shear and sharp gradients in static stability and demonstrated how a mountain wave and
its associated surface winds can be strongly influenced. Linear theory for two-dimensional, nonrotating stratified flow over
an isolated mountain ridge with positive shear and constant static stability shows that the horizontal wind speeds on both
the lee and upslope surfaces are suppressed by positive shear. The critical F(=U/Nh where U is the basic wind speed, N the Brunt-Vaisala frequency, and h the mountain height) for the occurrence of wave breaking decreases when the strength of the positive shear increases, while
the location for the wave-induced critical level is higher in cases with larger positive shear. The linear theory is then
verified by a series of systematic nonlinear numerical experiments. Four different flow regimes are found for positive shear
flow over a two-dimensional mountain. The values of critical F which separate the flow regimes are lower when the strength of the positive shear is larger. The location of stagnation aloft
from numerical simulations is found to be quite consistent with those predicted by linear theory.
We calculate the strongest horizontal wind speed on the lee surface (U
max), the smallest horizontal wind speed on the upslope surface (U
min), the reflection (Ref), and the transmission (Tran) coefficients for different combinations of the stability ratio between
the upper and lower layers (i.e. and z
1 (interface height) in a two-layer atmosphere from linear analytical solutions. Both Ref and Tran are found to be functions
of log() but not the interface height (z
1). Ref is larger when is much different from 1, no matter whether it is larger or smaller than 1. However, Tran decreases when log() increases and approaches 0 when log() is large. The magnitude of the largest U
max (smallest U
min) increases (decreases) as the absolute value of log() increases. It is found that the largest U
max occurs when the nondimensional z
1 is near for cases with a less stable upper layer or when z
1 is near for cases with a more stable upper layer. These results are confirmed by nonlinear numerical simulations. We find that linear
theory is very useful in qualitative analysis of the possibility of high-drag state for different stability profiles. The
location of stagnation aloft in a two-layer atmosphere from numerical simulations agrees very well with those predicted by
linear theory.
The above findings are applied to investigate the Boulder severe downslope windstorm of 11 January 1972. We find that the
windstorm cannot develop if the near mountain-top inversion is located at a higher altitude (e.g., km). However, if there exists a less stable layer right below the tropopause, the windstorm can develop in the absence of
a low-level inversion. These results indicate the importance of partial reflection due to the structured atmosphere in influencing
the possibility of severe downslope windstorms, although partial reflection may not be the responsible mechanism for the generation
of windstorms.
Received September 25, 1999/Revised February 9, 2000 |
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