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Total Lightning Activity as Diagnostic for Severe Weather

Total Lightning Activity as Diagnostic for Severe Weather. Earle R. Williams INPE Rio de Janerio, Brazil July 25-28, 2005. Outline. Experience with Thunderstorm Microbursts (Alabama, Florida; 1980s) Experience with Severe Weather (Florida; 1990s)

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Total Lightning Activity as Diagnostic for Severe Weather

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  1. Total Lightning Activity as Diagnostic for Severe Weather Earle R. Williams INPE Rio de Janerio, Brazil July 25-28, 2005

  2. Outline • Experience with Thunderstorm Microbursts (Alabama, Florida; 1980s) • Experience with Severe Weather(Florida; 1990s) • Lightning and Severe Weather over the Continental U.S.(2000+)

  3. Intracloud and Cloud-to-Ground Lightning:A Key Distinction Intracloud Lightning Cloud-to-Ground Lightning

  4. 100 10 1.0 0.1 10 100 1000 10000 Behavior of Intracloud and Cloud-to-Ground Lightning IC/CG Ratio 105 Flashes/km2/15 min(Ground Flash Rate)

  5. Illustration of Microburst Hazardto Aircraft

  6. Microburst Accidents

  7. National Response to Microburst Accidents • Regional field experiments to study the problemDoppler radar measurements Surface Mesonet arrays Corona point sensors Lightning interferometer system • Development and deployment of Terminal Doppler Weather Radars (TDWR)

  8. Microburst Field ExperimentsMIT Lincoln Laboratory

  9. Total Lightning Rate Precedes Microburst Outflow & Cloud-to-Ground Rate Does Not

  10. Distribution of Orlando Microburst Strength

  11. The LISDAD Project (1996 – 1999) • Integration of multiple observations into one real-time system: • Lincoln Laboratory ITWS • Melbourne NEXRAD radar • Orlando TDWR radar • National Lightning Detection Network • Lightning Detection and Ranging System (NASA KSC)

  12. Pilots TDWR NEXRAD ASR-9 Microburst Prediction ITWS Real-time Processor Gust Front Prediction Storm Location & Motion Storm Cell Information Controllers Terminal Winds Tornado AWOS/ASOS Supervisors Traffic Managers – TRACON Airlines – ARTCC TMU LLWAS – Dispatch CWSU Aircraft Lightning – Ramp Tower Integrated TerminalWeather System (ITWS)

  13. What is ‘Severe’ Weather? • Formal thresholds in the U.S. • Hail diameter > ¾ inch • or, Wind speed > 50 knots • or, Tornado on the ground

  14. 100 50 20 10 Particle Fall Speed (m/sec) 5 2 Non-Severe Severe 1 1 2 5 10 20 50 100 Particle Diameter (mm) Fallspeed of Hail vs. Size

  15. Updraft Strength is the Key Quality • Supplier of super-cooled water • Driver of cloud electrification and lightning • Origin of hail growth and the thunderstorm ice factory • Source of vortex stretching and tornado genesis

  16. Schematic Evolution of Total Lightning and Severe Weather

  17. Processes Aloft Naturally Precede Events at the Surface • Accretion of supercooled water in updraft precedes arrival of large hail at the surface • Active intracloud lightning aloft precedes cloud-to-ground lightning at the surface • Mesocyclonic rotation aloft precedes the tornado at the surface

  18. Total Lightning Precursor to 1” Hailand Strong Outflow 350 300 250 200 Lightning (LDAR) Flash Rate (min-1) 150 100 50 0 1-inch Diameter Hail on Ground 70 22 May 1997 Isolated Severe Storm 1-inch Hail Orlando, Florida 60 50 40 30 Differential Velocity (knots) 20 10 0 1930 1810 1830 1850 1910 Time (UT)

  19. Histogram of Total LDAR flash rate

  20. Severe Storm Cases in LISDAD

  21. From Mesocyclone to Tornado

  22. Total Lightning Precursor to a Tornado Goodman (2004)

  23. Global Lightning Based on the NASA LIS

  24. Low Cloud Base High Cloud Base W W Effect of cloud-base height on updraft width Less dilution by mixing Dynamic Effect of Cloud Base Height on Updraft Intensity and Lightning Activity

  25. Updraft Widths in Cumulonimbi

  26. Flash Rate / Thermodynamic Comparison

  27. Storm Flash Rate vs. Cloud Base Height

  28. Clustered Positive Ground Flashes in Severe Weather Curran and Rust (1992) Branick and Doswell (1992) Seimon (1993) Stolzenburg (1994) MacGorman and Burgess (1994) Knapp (1994) Later work in STEPS (2000) provided strong evidence that such storms were inverted in polarity relative to ordinary thunderclouds.

  29. Important Advances in Steps in 2000 • Development and implementation of VHF lightning mapping techniques for identifying the polarity of the lightning ‘tree’ (New Mexico Tech) • Inverted polarity storms characterized by large dew point depressions / low relative humidity • Rust and MacGorman (2002) • Wiens et. al. (2003) • Lang et. al. (2004)

  30. Takahashi (1978) Pereyra et al (2000) Saunders et al (1991) Laboratory Simulations Temperature / Cloud Water Diagrams

  31. Microphysical Effect of Cloud Base Height onLiquid Water Content Aloft Low Cloud Base High Cloud Base W W 0° C Cloud water loss by coalescence Superadiabatic loading in warm rain region

  32. Extreme Weather in the Conus

  33. 4” and Larger Hail Events(1955 – 1994) (Polston, 1996)

  34. Climatology of Wet Bulb Potential Temperature (Noontime – July)

  35. Climatology of Cloud Base Height(Noontime – July)

  36. Inverted Polarity CloudsIs it Aerosol, or is it Hot, Dry Conditions? May, 1998 (Lyons et al, 1998) (Smith et al, 2003)

  37. Conclusions • Total lightning activity (dominated by intracloud lightning) is a natural precursor to microbursts and severe weather at the surface • Cloud to ground lightning has relatively little benefit to this endeavor • Recipe for inverted polarity and extraordinary total lightning activity: High cloud base height AND appreciable instability

  38. Slide left intentionally blank.

  39. Pre-Squall Line Soundings in Great Plains: CAPE vs. θw

  40. Storm Flash Rate vs. Dry Bulb Temperature

  41. 1500 m 1000 m 500 m Ocean RH = 80% Rondonia Wet Season RH = 70% Rondonia Premonsoon RH = 60% Thermal Width/Updraft Width Scaling with Boundary Layer Depth?

  42. W Cape 0° C Large Cape Strong Updraft Bounded Weak Echo Region VHF Radiation “Holes” The Role of Strong Instability in Promoting High Liquid Water Content

  43. Cross-section of Dryline Ziegler and Rasmussen, (1998)

  44. Delay of First NLDN Ground Flashfrom First LDAR Lightning in Storm Mean Delay = 11 minutes 20 15 10 Number of Observations 5 0 0 10 20 30 40 50 60 Delay (min)

  45. Microburst Accidents Prompting Attention • New Orleans, Louisiana – July 9, 1982 • Dallas / Ft. Worth, Texas – August 2, 1985

  46. Classic Microburst Image

  47. Lightning Flash Rate vs Thermodynamics (Tropical Afternoon Storms Over Land)

  48. FAA Wind Shear Detection Systems

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