Thundersnow

Thundersnow, also known as a winter thunderstorm or a thunder snowstorm, is an unusual[1][2] kind of thunderstorm with snow falling as the primary precipitation instead of rain. It typically falls in regions of strong upward motion within the cold sector of an extratropical cyclone. Thermodynamically, it is not different from any other type of thunderstorms, but the top of the cumulonimbus cloud is usually quite low. In addition to snow, graupel or hail falls.

Thundersnow formation with an occluded front.

Formation

There are usually three forms of thundersnow:

One unique aspect of thundersnow is that the snowfall acts as an acoustic suppressor of the thunder. The thunder from a typical thunderstorm can be heard many miles away, while the thunder from thundersnow can usually only be heard within a two to three mile radius from the lightning. In the United States, March is the peak month of formation; on average, only 6.3 events are reported per year.[3]

Thundersnow, while relatively rare anywhere, is more common with lake-effect snow in the Great Lakes area of the United States and Canada, the midwestern U.S., and the Great Salt Lake. Thundersnow also occurs in Halifax, Nova Scotia, sometimes several times per winter season. Bozeman, Montana also sees thundersnow more often than average with these storms typically occurring in April or May. The British Isles and other parts of northwestern Europe occasionally report thunder and lightning during sleet or (usually wet) snow showers during winter and spring. It is also common around Kanazawa and the Sea of Japan, and even around Mount Everest. Low pressure events in the eastern Mediterranean that originate from polar origin cause copious thundersnow occurrences during winter storms, especially over the elevated provinces of Israel and Jordan, including Amman and Jerusalem. When such storms happen at ski areas, these mountains are often evacuated for safety.

From lake effect precipitation

Lake effect thundersnow occurs after a cold front or shortwave aloft passes over a body of water. This steepens the lapse rates between the lake temperature and the temperatures aloft. A difference in temperature of 25 °C (45 °F) or more between the lake temperature and the temperature at about 1,500 m (4,900 ft) (the 850 hPa level) usually marks the onset of thundersnow if surface temperatures are expected to be below freezing. However, several factors, including other geographical elements, affect the development of thundersnow. The primary factor is convective depth. This is the vertical depth in the troposphere that a parcel of air will rise from the ground before it reaches the equilibrium (EQL) level and stops rising. A minimum depth of 1,500 m (4,900 ft) is necessary and an average depth of 3,000 m (9,800 ft) or more is generally accepted as sufficient. Wind shear is also a significant factor. Linear snow squall bands produce more thundersnow than clustered bands, thus a directional wind shear with a change of less than 12 °C (54 °F) between the ground and 2,000 m (6,600 ft) in height must be in place. However, any change in direction greater than 12 °C (54 °F) through that layer will tear the snow squall apart. A bare minimum fetch of 50 km/h (31 mph) is required so that the air passing over the lake or ocean water will become sufficiently saturated with moisture and will acquire thermal energy from the water. The last component is the echo top or storm top temperature. This must be at least −30 °C (−22 °F). It is generally accepted that at this temperature there is no longer any super cooled water vapor present in a cloud, but just ice crystals suspended in the air. This allows for the interaction of the ice cloud and graupel pellets within the storm to generate a charge and result in lightning and thunder.[4]

From synoptic forcing

Synoptic snow storms tend to be large and complex, with many possible factors affecting the development of thundersnow. The best location in a storm to find thundersnow is typically in its NorthWest quadrant (in the Northern Hemisphere, based on observations in the Midwestern United States), within what is known as the comma head of a mature extratropical cyclone.[5][6] Thundersnow can also be located underneath the TROWAL, a trough of warm air aloft which shows up in a surface weather analysis as an inverted trough extending backward into the cold sector from the main cyclone.[7] In extreme cases, thunderstorms along the cold front are transported towards the center of the low pressure system and will have their precipitation change to snow or ice once the cold front becomes a portion of the occluded front.[6] The 1991 Halloween blizzard, Superstorm of 1993 and White Juan are examples of such blizzards featuring thundersnow.

From upslope flow

Similar to the lake effect regime, thundersnow is usually witnessed in terrain in the cold sector of an extratropical cyclone when a shortwave aloft moves into the region. The shortwave will steepen the local lapse rates, allowing for a greater possibility of both heavy snow at elevations where it is near or below freezing, and occasionally thundersnow.[8]

Hazards

Thundersnow produces snowfall rates in the range of 5 to 10 cm (2 to 4 in) per hour. Snowfall of this intensity may limit visibilities severely, even during light wind conditions. However, thundersnow is often a part of a severe winter storm or blizzard. Winds of above tropical storm force are frequent with thundersnow. As a result, visibilities in thundersnow are frequently under 400 m (14 mi). Additionally, such wind creates extreme wind chills and may result in frostbite. Finally, there is a greater likelihood that thundersnow lightning will have a positive polarity which has greater destructive potential than negatively charged (typical) lightning.[9]

See also

References

  1. Dauna Coulter, NASA Retrieved on 12-20-2012.
  2. Christine Dell'Amore, National Geographic News
  3. Patrick S. Market, Chris E. Halcomb, and Rebecca L. Ebert. A Climatology of Thundersnow Events over the Contiguous United States. Retrieved on 01-11-2006.
  4. USA Today. Jack Williams. Warm water helps create Great Lakes snowstorms. Retrieved on 01-11-2006.
  5. Patrick S. Market, Angela M. Oravetz, David Gaede, Evan Bookbinder, Rebecca Ebert, and Christopher Melick. Upper Air Constant Pressure Composites of Midwestern Thundersnow Events. Retrieved on 01-11-2006.
  6. 1 2 Rauber, R.M.; et al. (2014). "Stability and Charging Characteristics of the Comma Head region of Continental Winter Cyclones". J. Atmos. Sci. 71 (5): 15591582. Bibcode:2014JAtS...71.1559R. doi:10.1175/JAS-D-13-0253.1.
  7. National Weather Service Office, St. Louis, Missouri. Thundersnow Proximity Soundings. Retrieved on 01-11-2006.
  8. National Weather Service Office, Sacramento, California. Alexander Tardy. Western Region Technical Attachment No. 02-13: Thundersnow in the Sierra Nevada. Retrieved on 01-11-2006.
  9. Christian, Hugh J. & McCook, Melanie A. "A Lightning Primer – Characteristics of a Storm". NASA.

External links

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