10th Conference on Mesoscale Processes

P2.19

Wave—Mean-Flow Interaction for Time-Dependent Mountain Waves

Chih-Chieh Chen, University of Washington, Seattle, WA; and G. J. Hakim and D. R. Durran

Wave--mean-flow interaction is investigated through idealized modeling in which a barotropic synoptic-scale disturbance passes over an isolated three-dimensional mesoscale mountain. Atmospheres with constant static stability and cases with a jump in stability at the tropopause are considered. It is widely accepted that terrain-induced disturbances may have significant impact on the background flow, such as a global loss of momentum due to wave breaking. The simulations reveal that the stratosphere tends to induce wave breaking at the tropopause, which promotes wave--mean-flow interaction.

In addition to wave--mean-flow interaction induced by wave breaking, our results show that non-viscous processes may also have significant feedback to the large-scale flow. It is found that in the cases without wave breaking, the synoptic-scale flow undergoes a different time evolution due to the presence of the mountain. The influence of the mountain is assessed by performing a second simulation with the mountain removed, and examining the difference in dynamics between the two simulations. The differences reveal both global and local impacts, which are quantified by a domain-averaged momentum budget and the spatial distribution of the momentum difference fields, respectively.

Poster Session 2, Poster Session P2 with Coffee Break
Wednesday, 25 June 2003, 3:30 PM-5:00 PM

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