╨╧рб▒с>■  )+■   (                                                                                                                                                                                                                                                                                                                                                                                                                                                ье┴5@Ё┐ebjbj╧2╧2 .нXнXe       И.......B    BYь>>>>>>>>ОРРРРРР$ERЧ ╠┤!.>>>>>┤..>>╒<▐▐▐>(.>.>О▐>О▐(▐..>2 PLї╪ЩM╩ f(zHYc О.c BB....c .t>>▐>>>>>┤┤BBdжd╝"BBжThe effects of boundary layer on lee waves over double bell-shaped Ivana Stiperski1 and Vanda Grubiai2 1Meteorological and Hydrological Service, Zagreb, Croatia 2Desert Research Institute, Reno, NV, USA The Sierra Nevada White-Inyo system is an almost perfect two-dimensional double barrier well known for the generation of large-amplitude trapped lee waves and rotors, which were the focus of the recent Terrain-induced Rotor Experiment (T-REX in 2006) and its pilot Sierra Rotors Project (SRP in 2004). Observational evidence from T-REX as well as attendant numerical studies indicate that trapped lee waves and the process of wave-induced boundary-layer separation play an important role in the formation of rotors. From the observations it appears that the largest amplitude lee waves are those with the wavelength close to the ridge separation distance, suggesting a resonant wave response of the atmosphere to the surrounding terrain. Our earlier idealized free-slip simulations confirm that the presence of a second mountain exercises a profound influence on the wavelength as well as the amplitude of trapped lee waves over the double mountain barrier. The ridge separation distance was shown to be a key element that controls the trapped lee wave wavelength. Moreover, the oscillatory character of the quasi-state-state value of gravity-wave drag as a function of the ridge separation distance revealed the presence of constructive and destructive non-linear interferences and identifies separation distances for which these interferences occur. Here we report on further idealized high-resolution numerical simulations of the double-barrier problem using a no-slip lower boundary condition. Simulations, carried out using the NRL Coupled Ocean/Atmosphere Mesoscale Prediction System (COAMPS), are otherwise two-dimensional, irrotational and dry. In this study, we examine in more detail the effect of the frictional boundary layer on the previously established sensitivities of the double barrier flow to the valley geometry and upstream atmospheric structure. Our preliminary results indicate that surface friction significantly affects the lee wavelengths, reduces lee wave amplitudes and enhances trapping. The interference pattern changes and destructive (constructive) interference appears for different ridge separation distances than in the free slip simulation. Boundary layer separation is also observed together with regions of reversed flow. While these regions developed in the free slip simulations as well due to the strong pressure gradients induced by the large amplitude waves, in the no slip simulations they are enhanced. 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