Genesis and Morphology of the Alberta Dryline

1. Genesis and Morphology of the Alberta Dryline Neil M. Taylor Hydrometeorology and Arctic Lab Meteorological Service of Canada

2. Outline • brief review of dryline ‘theory’ • mechanism responsible for dryline genesis in Alberta • dryline morphology • operational forecast issues • future work MOIP Simulator: Drylines

3. The Dryline • strong moisture gradient in the BL (obs at SFC) • dry air: hot -- deep, well mixed boundary layer • moist air: cooler & capped in BL -- dry and well mixed aloft => loaded gun sounding • literature: frontogenetic (wrt moisture) circulation driven mainly by differential heating (e.g., land breeze effect) • convergence at dryline => convective initiation MOIP Simulator: Drylines

4. Dryline Interpretation • circulation near dryline important for low-level mesocyclogenesis (tornadoes) • forms capping lid + convergence line a focus for convective initiation • simplest interpretation: storm - no storm boundary (e.g., too dry => no storms) IMPLICATIONS MOIP Simulator: Drylines

5. Severe Convection in Alberta • “breakdown of upper ridge” associated with upper trough or low advancing from BC 12Z 250mb and 500mb charts showing advancing upper trough / low MOIP Simulator: Drylines

6. Southwest Flow Over Mountains • subsidence in lee of Rockies -- 700mb flow • warmer & drier air mixes down to SFC 30kt Jet 25kt Jet MOIP Simulator: Drylines

7. Genesis of the Dryline Dryline • dry air mixes to SFC and converges with moist air over plains Moist, capped Dry, Well Mixed SW’ly 700mb flow MOIP Simulator: Drylines

8. 3 1 2 4 Schematic Dryline Cross-section capped Dry Air 10-20km Moist Air 1. SFC: dry air convergent with moist air over / near foothills 2. Aloft: dry air overruns moist air 3. Convergence at dryline breaks capping lid => deep convection 4. Secondary circulation generates horizontal vorticity MOIP Simulator: Drylines

9. Severe Weather Days from 2000 • Days from summer 2000 (AB and SK only) with... 3 or more reports of ≥ 20mm hail or 1 or more reports of ≥ 30mm hail or at least 1 report of a tornado • 33 days met criteria MOIP Simulator: Drylines

10. Dryline Days • Defined as a day where severe weather reports met criteria and either • The severe storm that produced the event was initiated in close proximity to the dryline, or • The severe storm developed from outflow boundary or storm split of a storm that initiated in close proximity to the dryline • 12 of 33 (36%) severe weather days met the ‘dryline day’ criteria MOIP Simulator: Drylines

11. 500mb TROF/Low Upper trof in BC leads to SW flow over Rocky mountains => subsidence necessary to form dryline 12Z 500mb 570dam on Dryline Days MOIP Simulator: Drylines

12. Dryline Day Severe Weather Events MOIP Simulator: Drylines

13. Dryline Locations Summer 2000 MOIP Simulator: Drylines

14. Dryline Associated Storm Tracks • Considered storms initiated near dryline that produced severe weather (or led to severe storm via outflow boundary cell generation / storm splitting) • Remote sensing used to define a storm track via radar (1.5km cappi – first echo to <40dBZ), VIS satellite + CLDN lightning flash data • 26 severe thunderstorms initiated near dryline (or led to severe storm development via outflow boundary / splitting) • All 26 storms initiated within 75km of dryline (61% within 50km and mean distance of 45km) MOIP Simulator: Drylines

15. Dryline Associated Storm Tracks MOIP Simulator: Drylines

16. Dryline Locations and Storm Tracks MOIP Simulator: Drylines

17. Dryline Morphology • develops rapidly (<6 hours) parallel to foothills • evolution strongly linked to flow over mountains (~700mb) Two Types: (depending on 700mb flow) I: general 15-20kt SW flow over Rockies => QS II: 20-30kt 700mb jet => bulges eastward • direction / extent of bulge function of location, angle, and speed of jet over mountain barrier MOIP Simulator: Drylines

18. QS Dryline • little “bulging” • Cu/TCu over foothills due differential heating • capping lid “breaks” at dryline -- obs convergence and moisture gradient 15-20kt MOIP Simulator: Drylines

19. 00Z 1 July 2000 35mm hail / tornado south of YQF 12Z 20kt YEG YQF YYC 00Z 15-20kt MOIP Simulator: Drylines

20. Bulging Dryline • eastward bulge in south -- jet momentum mixed to SFC 20-30kt 30kt RM storms may interact with bulging portion -- LL MESO MOIP Simulator: Drylines

21. 00Z 15 July 2000 Pine Lake Tornado YEG YQF 12Z 25-30kt YYC 00Z 30kt MOIP Simulator: Drylines

22. Storm Interaction with Dryline streamwise vorticity near dryline boundary cyclonic vorticity within storm -- LL mesocyclone E storm propagates eastward along dryline feeding on moist air streamwise vorticity tilted into vertical and ingested into storm updraft MOIP Simulator: Drylines

23. Forecast Issues • SW flow aloft (upper trough / low) • moisture gradient over foothills -- SFC isodrosotherms, mixing ratio, theta e/w • at least 15-20kt SW flow over mountains (700mb) • monitor SFC winds / moisture SW Alberta -- often develops by 18Z • mid-level jet over mtns -- monitor dryline for bulge ( bulging can trigger storms in SW/W SK) • beware RM storms near E-W portion of bulge MOIP Simulator: Drylines

24. Summary • a significant feature for summer severe weather in Alberta (13 of 22 days from 2000) • develops mainly in response to subsidence in lee of mountains • synoptic scale => mesoscale => microscale • anticipate dryline development from 12Z analysis (previous day?) -- i.e., forecastable • two types depending on 700mb flow • RM storms can interact with bulging dryline -- tornado MOIP Simulator: Drylines

25. Future Work • establish dryline climatology (threshold wind speeds, dewpoint gradients, time of convection, strength of cap…) • high-resolution mesoscale modeling of Alberta dryline • where’s the dryline? 100km SFC obs. • obtain in-situ measurements of BL moisture and winds (mesonet, instrumented vehicle, soundings, etc.) through UNSTABLE MOIP Simulator: Drylines