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Detailed vertical structure of orographic precipitation development in cold clouds An illustration of high-resolution airborne mm-wave radar observations.

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Presentation on theme: "Detailed vertical structure of orographic precipitation development in cold clouds An illustration of high-resolution airborne mm-wave radar observations."— Presentation transcript:

1 Detailed vertical structure of orographic precipitation development in cold clouds An illustration of high-resolution airborne mm-wave radar observations and flight-level cloud data Bart Geerts, Heather McIntyre University of Wyoming

2 target mountain range Wyoming

3 Snowy Range Sierra Madre elevation range 2000-3500 m flight legs roughly parallel with wind 50 km

4 View from the south

5 Wyoming Cloud Radar 3 mm (95 GHz, W-band), dual-polarization pulse width: 250-500 ns max range: 3-10 km volume resolution @ 3 km range: < 40 m minimum detectable signal (@ 1 km): ~-30 dBZ Cloud droplets are much smaller than ice crystals, thus in a mixed-phase cloud, reflectivity is dominated by ice crystals.

6 PBL turbulence (~1 km deep) u rising motion sinking motion 215552-220402 UTC

7 Houze and Medina (2005)

8 generating cells? low-level echo intensification across the crest low-level snow outflow u 215552-220402 UTC

9 Synoptic situation at this time (20060118, 20 Z) prefrontal, SW flow aloft (UL trof evident to the NW)

10 flight level temperature: -16°C surface wind speed near crest: 11 ms -1 The increase in reflectivity sometimes coincides with a sudden drop in LWC. wedge of growing reflectivity in upslope PBL, disconnect from snow aloft

11 UpstreamDownstream LWC1000.20 g/m 3 0.06 g/m 3 PVMLWC0.27 g/m 3 0.10 g/m 3 Vertical Velocity0.93 m/s-0.33 m/s Relative Humidity88 %78 % WCR reflectivity (lowest 500m AGL) -4.6 dBZ+11.8 dbZ January 18,2006 213935-215050 UTC mean values within 10 km from the ridge flt level 4,400 m MSL, T=-15°C

12 flight level temperature: -17°C surface wind speed near crest: 13 ms -1 Is wind blowing over a snow-covered surface a possible nucleation source? We need to estimate snow particle trajectories to distinguish between fall- streaks and lofted surface snow t=0 t=14 min t=27 min t=40 min Barrett Ridge Med Bow peak

13 Battle Mountain Saratoga

14 Natural seeding by snow-covered surfaces “surface-induced snowfall” (SIS): snow seems to appear from the surface, and is mixed into the PBL Rogers and Vali (1987, “Ice Crystal Production by Mountain Surfaces”) found that the air sampled on Elk Mountain contained 10 - 1,000 more ice crystals than the free atmosphere upstream

15 (Rogers and Vali 1987)

16 Natural seeding by snow-covered surfaces Examination of data collected last winter suggests the following most-likely mechanisms –Lofting of snow from surface –Hallet-Mossop ice splintering when a supercooled drop hits an ice surface Conditions under which this appears to be most likely are: –Surface covered by fresh snow –Windy (>10 m/s ?) and cold (T<-5°C?) –Possibly: cloud present and tree surfaces are rimed

17 Post-frontal cumuliform orographic snowfall (2 Feb, 20 UTC) upwind (SRT) sounding GOES VIS GOES IR

18 20060202 1900-1912 UTC flight level temperature: -19°C surface wind near crest: 12 ms -1 from NW Post-frontal cumuliform orographic snowfall (2 Feb)

19

20 upstream views downstream view 21:38 UTC 21:24 UTC 20060202 21:25 UTC

21 Lee waves (5 Feb, 15 Z)

22 Lee waves (5 Feb) Kennaday Peak Med Bow Peak

23 conclusions High-resolution vertical-plane reflectivity and vertical velocity transects reveal a range of orographic precipitation structures. Pre-frontal: deep precipitation may be distinguished from shallow orographic component. Post-frontal orographic precip is far more cumuliform, with locally large LWC. Natural glaciation may be rapid, and can occur both upstream and just downstream of the crest. Natural seeding may occur by blowing snow or cloud contact with rimed surfaces (SIS).

24 Further work using winter 06 data objectives: 1.Describe snow growth relative to mountain ridge. 2.Gain clues about snow growth processes (deposition, riming, aggregation) 3.Examine differences between select cases, in terms of Fr and presence of upstream clouds methods: 1.Estimate snow crystal trajectories from VPDD and an assumed fall speed. 2.Examine LWC data and 2D particle imagery, in the context of WCR vertical velocity and echo structure 3.Plot upstream soundings (from WKA and model) and construct summary table

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