1. Weather systems & mountains Chapter 8 Cold Air Damming in Lackmann (2011) Chapter 8.2 Orographic effects in Wallace and Hobbs (2006) see Elsevier companion site for additional materialElsevier companion site This MODIS image shows smoke from forest fires in Southern California stoked by Santa Anna winds on 10/14/2008

2. Orographic effects: topics lee cyclogenesis Rossby wave propagation along sloping terrain cold air damming terrain-induced wind storms orographic precipitation Want to learn more? Visit the COMET-MetEd moduleCOMET-MetEd module

3. Lee cyclogenesis Alberta low Colorado low regions of frequent lee cyclogenesis

4. Explanation: conservation of potential vorticity (PV) slow spin fast spin Fig. 7.8 fast spin  =290 K  =330 K  z large  z small  z large ET cyclones decay upwind of mountain barrier ET cyclones re-emerge downwind of barrier PV is generally conserved.

5. trof ridge

6. L trof ridge

7. L trof ridge

8. L trof ridge

9. L

10. Lows and highs tend to propagate equatorward east of topographic barriers, and poleward west of the barriers example: examine trof-ridge movement in the Colorado low example, a few slides back reason: PV conservation warm cold

11. Barrier jet dynamics H L H L cold-airmass boundary retardation deflection  along-barrier jet

12. Barrier jet due to terrain blocking –  air accelerates down the pressure gradient (Parish 1982) west east x Sierra Nevada Rocky Mtns & Plains

13. Cold-air damming & barrier jet east of the Rockies mesoscale barrier jet in Colorado 20 March 2002: COMET caseCOMET case radial velocity dual-Doppler velocity L

14. Want to learn more? Visit the COMET-MetEd moduleCOMET-MetEd module Barrier jet

15. Barrier jet: cold-air damming east of the Appalachians surface temperatures (F) 17-20 Z

16. Barrier jet: cold-air damming east of the Appalachians H H H H

17. barrier jet scatterometer data Alaska

18. scatterometer data Gap flows

19. Gap winds Want to learn more? Visit the COMET-MetEd moduleCOMET-MetEd module acceleration through the gap  strong winds downwind of the gap Tehuantepec gap

20. gap flow: Tehuantepecer

21. gap flow: Tehuantepecer: synoptic-scale cold surge into Mexico 1993/3/13 12Z (storm of the century) Schultz et al 1997 isthmus of Tehuantepec

22. Santa Ana winds and wildfires in California cold high down-gradient, subsident flow channeled through the gaps

23. Average wind speed at 50 m AGL in 2012 in winter (DJF) (9 km WRF) source: David Siuta 10 14 18 2 6 Wind speed (m/s)

24. lee convergence zone lee convergence zone: behind the mountain, where gap currents meet

25. Mountain waves and downslope wind storms Want to learn more? Visit the COMET-MetEd moduleCOMET-MetEd module

26. Orographic precipitation Want to learn more? Visit the COMET-MetEd moduleCOMET-MetEd module Clearly mountains have a profound impact on precipitation. The mechanism is basic: the moisture-laden marine boundary- layer is lifted over coastal ridges. These ridges are rather low. Further downwind towards the continental divide the ascent is higher, but the remaining water vapor less.

27. Summary: orographic effects Cyclogenesis occurs in the lee of a major mountain range when strong deep- tropospheric flow crosses that range. The lee cyclone finds itself in warm air due to subsidence, and often evolves into a classic frontal disturbance. Low-level warm or cold anomalies tend to propagate to the left along sloping terrain, when looking towards the higher terrain. An example of this is cold-air damming, most prominent east of the Rockies and the Appalachians. The cold pool tends to propagate to the left (equatorward) and becomes more shallow, trapped by the terrain. Terrain-induced wind storms (downslope plunging flow) may occur when the upstream flow is blocked (stable) below the mountain crest, and strong cross- barrier flow is present aloft. This plunging flow may produce a hydraulic jump. Mountains tend to capture much water vapor crossing the barrier, as orographic precip, by forced ascent, convection, and BL turbulence.