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MAP IOP 10 South Foehn Event in the Wipp Valley: Verification of High-Resolution Numerical Simulations with Observations A. Gohm*, G. Zängl**, G. J. Mayr* * University of Innsbruck, Austria ** University of Munich, Germany ICAM/MAP 2003 Brig, Switzerland, May 19 to 23, 2003 Gohm, A., G. Zängl, G. J. Mayr, 2003, submitted to Mon. Wea. Rev.
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The scientific objective: To assess to what extent the temporal evolution and spatial structure of small-scale orographic flows can be simulated with a state-of-the-art mesoscale model run in a very high- resolution mode. The phenomenon: Deep south foehn in the Wipp Valley on 24-25 October 1999 The scientific tools: Penn State/NCAR mesoscale model MM5 NOAA/ETL ground-based scanning Doppler lidar (TEACO2) NCAR airborne aerosol backscatter lidar (SABL) ZAMG Doppler sodar radiosoundings and weather stations
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MM5 basic setup: 6 domains with x = 64.8 – 0.267 km 39 full-sigma levels initialized with operational ECMWF analysis at 23 Oct 18 UTC and 24 Oct 00 UTC Wipp Valley Innsbruck Brenner Pass
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Backscatter intensity versus potential temperature, 15 UTC 24 Oct 1999: P1 P2 MM5 00 UTC run AML top heights & isentropes indicate regions of flow descent and jump-like features indications for underestimation of flow descent SABL lidar on NCAR Electra InnsbruckBrenner flow
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Wind profile at Brenner Pass, 24 Oct 1999: ZAMG PA2 sodar MM5 00 UTC run, D6 simulated wind speed 15 % too high lower gap area 30% too large in D6 simulated mass flux 50% too high 00 (18) UTC run: RMSE = 5.6 (6.2) m/s ME = +1.5 (+1.6) m/s Alpine crest line lower gap upper gap
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Wind speed, 24 Oct 1999: too strong winds
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Potential temperature, 24 Oct 1999: -2 K bias
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Radial wind velocity, 24 Oct 1999: lidar Doppler lidar 09 UTC MM5 (00 UTC run) -1.6-3.1ME 5.36.9RMSE 15Z09ZTime abs(radial velocity) 00 UTC run – lidar 15 UTC Doppler lidar MM5 (00 UTC run)
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Inversion upstream of the pass, 09 UTC 24 Oct 1999: upstream inversion 1 km too low early in the event (~09 UTC) southerly flow too shallow MM5 (00 UTC run): domain 4
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Conclusions: The model captured several striking features: foehn break-through in the Inn Valley magnitude of surface wind speed at several weather stations regions of strong descent jump-like features related to deep amplified gravity waves Discrepancies were found between simulations and observations: overestimation of the mass flux through lower Brenner gap (+50%) underestimation of the descent of potentially warm air through upper gap bias of surface pot. temperature in the northern Wipp Valley (-2 K) wrong inversion height upstream of the pass early in the event
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ECMWF analysis 12 UTC 24 Oct 1999: 500 hPa geopot. height: Sea level pressure: L H
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MM5 flow structure, 15 UTC 24 Oct 1999, 00 UTC run: surface wind speed: wind speed & pot. temperature: BrennerInnsbruck
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Pressure gradient, 24 Oct 1999: as function of time as function of wind speed
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Doppler lidar rad. vel. 09 UTC Radial wind velocity, 24 Oct 1999: 15 UTC lidar MM5 (00 UTC run) rad.vel. MM5 (00 UTC run) + wspd -1.6-3.1ME 5.36.9RMSE 15Z09ZTime abs(radial velocity) 00 UTC run – lidar
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