roll or arcus cloud supercell thunderstorms
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Roll or Arcus Cloud
Supercell Thunderstorms
Storm split 1
Storm split 3
Storm Split 2
Squall Lines
Bow Echoes and Derechos
DC Derecho: June 10, 2013
Often Associated with Strong Straight Line Winds Known as
“Derechos”• These straight-line winds may exceed 100
miles per hour, reaching 130 miles per hour in past eventshttp://www.youtube.com/watch?v=EGJmOeDEBtw
• Great Derecho Website:
http://www.spc.noaa.gov/misc/AbtDerechos/derechofacts.htm
Climatology (Events over 1980-2001
Major Derecho on June 2012
June 2012 Derecho
• Wind gusts increased substantially, peaking as high as 91 mph (147 km/h) in Fort Wayne, Indiana
• Extremely hot and highly unstable atmosphere with CAPE values in excess of 5,000 J/kg. Temperatures on the south side of a stationary front were in excess of 100F.
Derecho Prediction
• Warm season derechos in the Northern Hemisphere form in west to northwesterly flow at mid levels with moderate to high levels of instability (CAPE).
• Derechos form within environments of low-level warm air advection and significant low-level moisture
Numerical Simulation of Convection
• High resolution simulates cable of explicitly resolving convection have been run in research mode.
• It appears that such numerical model can provide great insights into the conditions necessary for convection and how varying environments influence convective evolution.
METED Convective Storm Matrix
• http://www.meted.ucar.edu/convectn/csmatrix/
• Allows you to experiment with instability and shear and view how the storms evolve.
High Resolution Numerical Prediction of Convection
Explicit Convective Prediction
• Requires high resolution (4km or less grid spacing)
• Requires high-resolution analysis of current situation, using radar, surface observations and all other assets.
• NCAR (WRF model) and CAPS (Oklahoma, ARPS model) are two leading efforts.
Bow Echo and Mesoscale Convective Vortex Experiment (BAMEX)Using the WRF Model
Goal: Study the lifecycles of mesoscale convective vortices and bow echoes in and around the St. Louis MO area
10 km WRF forecast domain4 km WRF forecast domain
Field program conducted 20 May – 6 July 2003
Real-time WRF 4 km BAMEX Forecast
Composite NEXRAD RadarReflectivity forecast
Initialized 00 UTC 9 June 03
Real-time WRF 4 km BAMEX Forecast
Composite NEXRAD Radar
4 km BAMEX forecast 36 h Reflectivity
4 km BAMEX forecast 12 h Reflectivity
Valid 6/10/03 12Z
Real-time WRF 4 km BAMEX Forecast
Initialized 00 UTC 10 June 03
Reflectivity forecast Composite NEXRAD Radar
Real-time 12 h WRF Reflectivity Forecast
Composite NEXRAD Radar
4 km BAMEX forecast
Valid 6/10/03 12Z
10 km BAMEX forecast
22 km CONUS forecast
Composite NEXRAD RadarReflectivity forecast
Real-time WRF 4 km BAMEX Forecast
Initialized 00 UTC 30 May 03
Real-time WRF 4 km BAMEX Forecast
Composite NEXRAD Radar23 h Reflectivity Forecast
Line ofSupercells
Valid 5/30/03 23Z
Realtime WRF 4 km BAMEX Forecast
Composite NEXRAD Radar30 h Reflectivity Forecast
Squall line
6” hail 00Z
Valid 6/23/03 06Z
Realtime WRF 4 km BAMEX Forecast
Composite NEXRAD RadarReflectivity Forecast
12 h
24 h
Squall line
Persists Dissipates
Initialized 5/24/03 00Z
Preliminary BAMEX Forecast Verification
(Done, Davis, and Weisman)
Mode for corresponding convective systems
For Convective Mode 2 or 3
Cases Observed
Yes No
CasesPredicted
61 25
16 21
Yes
No
Probability of detection (POD) = 79%
False alarm rate (FAR) = 29%
A High-Resolution Modeling Study of the 24 May 2002 Dryline Case during IHOP
(Xue and Martin 2006a,b MWR)
Goal: Understand exactly
WHEN, WHERE, HOW convection is initiated
Time and Location of Initiation(Loop time: 17UTC – 22 UTC)
Surface analysis
+ satellite images
From Wakimoto et al.(2006 MWR).
1900 2000
22002100
18 UTC May 24, 2002 I.C.3 km / 1km grid
Model Configurations
• ARPS model with full physics, including ice microphysics + soil model + PBL and TKE-SGS turbulence
1200 UTC 1800 UTC 0006 UTC
1km3km
CI ~ 2000UTC
0000 UTC
ADAS ADAS
t=3h, 2100 UTC
sfc. winds, qv, and composite reflectivity
t=4h, 2200 UTC
t=5h, 2300 UTC
t=3h, 2100 UTC
t=2h t=2h 15min t=2h 30min t=2h 45min
A A A
B BB
C C
C
B
A
2000 UTC 2015 UTC 2030 UTC 2045 UTC
Bottom Line• High resolution NWP can often predict the mode of
the convection correctly, even a day ahead (supercell, bow echo, scattered convection).
• Skill in predicting the magnitude and location of convection fades out quickly after only a few hours.
• Predictability is lengthened when there is strong, large scale forcing (e.g,. front or dry line)
The Future of Convective Forecasting
• Clearly, there is substantial uncertainty that must be considered.
• A major requirement is for there to be large convection-resolving ensembles run operationally (25-100 members), with varying initializations and physics.
• Need for better initializations to describe the detailed 3D configuration of the lower atmosphere (using all assets: commuter aircraft, mesosnets, satellite data, etc.)
• http://www.spc.noaa.gov/exper/sseo/
Storm Prediction Center Ensemble of Opportunity
• Based on 7 high-resolution deterministic forecasts run by a variety of groups.
Another Major Advancing Tool: High Resolution Rapid Refresh: Particularly for Next Few Hours.
The U.S Storm Prediction Center
Storm Prediction Center
• Main U.S. entity responsible for severe weather forecasting.
• Coordinates between NWS forecast offices, who also important players for their areas.
Forecasting of Convection Summary
• The big challenge is to predict the environment in which convection will develop.
• Parameters such as vertical instability (CAPE), wind shear and helicity, low-level thermal and moisture structures, CIN, etc.
• These can change rapidly with large mesoscale variations.
Major Ingredients for General Convection• Convective or conditional instability
– Lifting turns convectively unstable sounding to a conditionally unstable sounding
– Negative LI
– High CAPE
– Low LFC
– CAPE is more useful than LI
• Moist layer near the surface
– Generally Td > 53F needed.
• An initiator
– Source of upward motion (front, dry line, sea breeze front)
• Low or moderate CIN