Hail

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Hail is a form of precipitation which consists of balls or irregular lumps of ice (hailstones). Hailstones on Earth usually consist mostly of water ice and measure between 5 and 150 millimeters in diameter, with the larger stones coming from severe thunderstorms.[1] Hail is only produced by cumulonimbi (thunderclouds), usually at the front of the storm system, and is composed of transparent ice or alternating layers of transparent and translucent ice at least 1 mm thick. The METAR code for hail 5 mm or greater in diameter is GR, while smaller hailstones and graupel are coded GS. Unlike ice pellets, they are layered and can be irregular and clumped together.

pARIS HILTON IS HOT

Contents

Ideal conditions for hail formation

The largest hailstone ever measured, 17.8 centimetres (7.0 in) in diameter with a 47.6 centimetres (19 in) circumference.

Hail forms in strong thunderstorm clouds, particularly those with intense updrafts, high liquid water content, great vertical extent, large water droplets, and where a good portion of the cloud layer is below freezing 0 °C (32 °F). The growth rate is maximized at about −13 °C (9 °F), and becomes vanishingly small much below −30 °C (−22 °F) as supercooled water droplets become rare. For this reason, hail is most common in mid-latitudes during early summer where surface temperatures are warm enough to promote the instability associated with strong thunderstorms, but the upper atmosphere is still cool enough to support ice. Accordingly, hail is actually less common in the tropics despite a much higher frequency of thunderstorms than in the mid-latitudes because the atmosphere over the tropics tends to be warmer over a much greater depth. Also, entrainment of dry air into strong thunderstorms over continents can increase the frequency of hail by promoting evaporational cooling which lowers the freezing level of thunderstorm clouds giving hail a larger volume to grow in.

Hail is also much more common along mountain ranges because mountains force horizontal winds upwards (known as orographic lifting), thereby intensifying the updrafts within thunderstorms and making hail more likely. One of the most notorious regions for large hail is the mountainous northern India and Bangladesh, which have reported more hail-related deaths than anywhere else in the world and also some of the largest hailstones ever measured. Mainland China is also notorious for killer hailstorms. In North America, hail is most common in the area where Colorado, Nebraska, and Wyoming meet, known as "Hail Alley." [2] Cheyenne, Wyoming is North America's most hail-prone city with an average of nine to ten hailstorms per season. [3]

Hailstones, while most commonly only a few millimetres in diameter, can sometimes grow to 15 centimetres (6 in) and weigh more than .5 kilograms (1.1 lb)[4]. Pea or golf ball-sized hailstones are not uncommon in severe storms. Hail can do serious damage, notably to automobiles, skylights, glass-roofed structures, and most commonly, farmers' crops. Rarely, massive hailstones have been known to cause concussions or fatal head trauma. Sometimes, hail-producing clouds are identifiable by their green colouration.[5][6]

Short term detection

In the United States, to issue proper warnings and forecasts, National Weather Service uses a network of NEXRAD doppler radars to detect hail. Hail size and probability can be determined from radar data by a computer by different algorithms. This, in combination with an analysis of the radar display is an accurate way of detecting hail. An analysis of the radar data would include viewing reflectivity data at multiple angles above ground level to check for hail development in the upper levels of the storm, and checking the Vertically Integrated Liquid (VIL). VIL and hail do have a relationship, although it varies with atmospheric conditions and therefore is not highly accurate. Radar data can also be complimented by a knowledge of current atmospheric conditions which can allow one to determine if the current atmosphere is conducive to hail development.

Size scale

Hailstone size is often reported as compared to known objects rather than by reporting the actual diameter. Below is a table of commonly used objects for this purpose.[7] The UK organisation, TORRO, also scales for both hailstones and hailstorms.[8]

Object Diameter
Pea 6.4 millimetres (0.25 in)
Dime 17.9 millimetres (0.70 in)
Penny 19 millimetres (0.75 in)
Nickel 21.2 millimetres (0.83 in)
Quarter 24.26 millimetres (0.955 in)
Half dollar 30.6 millimetres (1.20 in)
Walnut 38 millimetres (1.5 in)
Golfball 44 millimetres (1.7 in)
Tennis Ball 64 millimetres (2.5 in)
Baseball 70 millimetres (2.8 in)
Grapefruit 108 millimetres (4.3 in)
Softball 114 millimetres (4.5 in)

Costly or deadly hailstorms

Hail clouds often exhibit a characteristic green coloration.

Gallery

See also

References

  1. "Weather Glossary" (html). Weatherzone.
  2. UCAR fact sheet on hail
  3. Hail Alley
  4. Video accompanying entry for "hail" in Britannica Online, Academic Edition
  5. Hail storms rock southern Qld - Toowoomba News
  6. Severe Thunderstorm Images of the Month Archives - 1997 - Australian Severe Weather
  7. PDF from NOAA, Page 5
  8. TORRO: Severe Weather: Hailstorm Intensity Scale
  9. Telegraph News
  10. Colorado hail statistics - Rocky Mountain Insurance Information Association
  11. atlas.nrcan.gc.ca
  12. Urban hailstorms: a view from Alberta
  13. National Weather Service Forecast Office - WFO, Ft. Worth, Texas
  14. weather.com - Storm Encyclopedia
  15. Ask the Expert - The Weather Guys - USATODAY.com
  16. The Sydney Hailstorm - 14 April 1999
  17. Sydney Hailstorm 14th April 1999 - Australian Severe Weather
  18. Fort Worth surveys tornado damage, counts the cost - March 30, 2000 - CNN.com
  19. Medill Reports: Chicago
  20. findarticles.com
  21. Storm Data and Unusual Weather Phenomena - National Weather Service
  22. NOAA's National Weather Service Weather Forecast Office - St Louis, MO
  23. April 2006 Weather Review - National Weather Service Forecast Office - WFO, Austin/San Antonio, Texas
  24. Preliminary Local Storm Report - National Weather Service
  25. Central Texas Hailstorms were Costly - The Insurance Council of Texas
  26. 2006 Year in Review - San Marcos Police Department
  27. Losses from April Hailstorms in Central Texas Reach $160M - Insurance Journal
  28. News from the Planning and Development Services Department - City of San Marcos, Texas
  29. Storms strike again - News 8 Austin
  30. It was raining great balls of ice - Sydney Morning Herald

Further reading

External links