Sprite (lightning) explained

Sprite (lightning) should not be confused with Sprite (computer graphics).

Sprites or red sprites are large-scale electric discharges that occur in the mesosphere, high above thunderstorm clouds, or cumulonimbus, giving rise to a varied range of visual shapes flickering in the night sky. They are usually triggered by the discharges of positive lightning between an underlying thundercloud and the ground.

Precis

Sprites appear as luminous red-orange flashes. They often occur in clusters above the troposphere at an altitude range of 50-. Sporadic visual reports of sprites go back at least to 1886.[1] They were first photographed on July 4, 1989,[2] by scientists from the University of Minnesota and have subsequently been captured in video recordings thousands of times.

Sprites are sometimes inaccurately called upper-atmospheric lightning. However, they are cold plasma phenomena that lack the hot channel temperatures of tropospheric lightning, so they are more akin to fluorescent tube discharges than to lightning discharges. Sprites are associated with various other upper-atmospheric optical phenomena including blue jets and ELVES.

History

The earliest known report is by Toynbee and Mackenzie in 1886.[3] Nobel laureate C. T. R. Wilson had suggested in 1925, on theoretical grounds, that electrical breakdown could occur in the upper atmosphere, and in 1956 he witnessed what possibly could have been a sprite. They were first documented photographically on July 6, 1989, when scientists from the University of Minnesota, using a low-light video camera, accidentally captured the first image of what would subsequently become known as a sprite.[4]

Several years after their discovery they were named sprites (air spirits) after their elusive nature.[5] Since the 1989 video capture, sprites have been imaged from the ground, from aircraft and from space, and have become the subject of intensive investigations. A featured high speed video that was captured by Thomas Ashcraft, Jacob L Harley, Matthew G McHarg, and Hans Nielsen in 2019 at about 100,000 frames per second is fast enough to provide better detailing of how sprites develop. However, according to NASA's APOD blog, despite being recorded in photographs and videos for the more than 30 years, the "root cause" of sprite lightning remains unknown, "apart from a general association with positive cloud-to-ground lightning." NASA also notes that not all storms exhibit sprite lightning.[6]

In 2016, sprites were observed during Hurricane Matthew's passage through the Caribbean.[7] The role of sprites in the tropical cyclones is presently unknown.[8]

Characteristics

Sprites have been observed over North America,[9] Central America, South America,[10] Europe,[11] Central Africa (Zaire), Australia, the Sea of Japan and Asia and are believed to occur during most large thunderstorm systems.

Rodger (1999) categorized three types of sprites based on their visual appearance.

Sprites are colored reddish-orange in their upper regions, with bluish hanging tendrils below, and can be preceded by a reddish halo. They last longer than normal lower stratospheric discharges, which last typically a few milliseconds, and are usually triggered by the discharges of positive lightning between the thundercloud and the ground,[12] although sprites generated by negative ground flashes have also been observed.[13] They often occur in clusters of two or more, and typically span the altitude range 50kmto90kmkm (30milesto60mileskm), with what appear to be tendrils hanging below, and branches reaching above.

Optical imaging using a 10,000 frame-per-second high speed camera showed that sprites are actually clusters of small, decameter scale, (10–) balls of ionization that are launched at an altitude of about 80sp=usNaNsp=us and then move downward at speeds of up to ten percent the speed of light, followed a few milliseconds later by a separate set of upward moving balls of ionization.[14] Sprites may be horizontally displaced by up to 50sp=usNaNsp=us from the location of the underlying lightning strike, with a time delay following the lightning that is typically a few milliseconds, but on rare occasions may be up to 100 milliseconds.

thumb|This footage from the ISS shows a red sprite over East Asia immediately before 0:07, directly above the large lightning flash towards the upper right of the frame.

In order to film sprites from Earth, special conditions must be present: 150- of clear view to a powerful thunderstorm with positive lightning between cloud and ground, red-sensitive recording equipment, and a black unlit sky.[15]

Mechanism

Sprites occur near the top of the mesosphere at about 80 km altitude in response to the electric field generated by lightning flashes in underlying thunderstorms. When a sufficiently large positive lightning strike carries charges to the ground, the cloud top is left with a strongly negative net charge. This can be modeled as a quasi-static electric dipole and for less than 10 milliseconds a strong electric field is generated in the region above the thunderstorm. In the low pressure of the upper mesosphere the breakdown voltage is drastically reduced, allowing for an electron avalanche to occur.[16] [17] Sprites get their characteristic red color from excitation of nitrogen in the low pressure environment of the upper mesosphere. At such low pressures quenching by atomic oxygen is much faster than that of nitrogen, allowing for nitrogen emissions to dominate despite no difference in composition.[18] [19]

Sprite halo

Sprites are sometimes preceded, by about 1 millisecond, by a sprite halo, a pancake-shaped region of weak, transient optical emissions approximately 50km (30miles) across and 10km (10miles) thick. The halo is centered at about 70km (40miles) altitude above the initiating lightning strike. These halos are thought to be produced by the same physical process that produces sprites, but for which the ionization is too weak to cross the threshold required for streamer formation. They are sometimes mistaken for ELVES, due to their visual similarity and short duration.[20] [21] [22]

Research carried out at Stanford University in 2000 indicates that, unlike sprites with bright vertical columnar structure, occurrence of sprite halos is not unusual in association with normal (negative) lightning discharges.Research in 2004 by scientists from Tohoku University found that very low frequency emissions occur at the same time as the sprite, indicating that a discharge within the cloud may generate the sprites.[23]

Related aircraft damage

Sprites have been blamed for otherwise unexplained accidents involving high altitude vehicular operations above thunderstorms. One example of this is the malfunction of a NASA stratospheric balloon launched on June 6, 1989, from Palestine, Texas. The balloon suffered an uncommanded payload release while flying at 120000feet over a thunderstorm near Graham, Texas. Months after the accident, an investigation concluded that a "bolt of lightning" traveling upward from the clouds provoked the incident.[24] The attribution of the accident to a sprite was made retroactively, since this term was not coined until late 1993.

See also

External links

Notes and References

  1. 10.1029/2001JA000283. Red sprites, upward lightning, and VLF perturbations. Reviews of Geophysics. 37. 1999. 3. 317–336. Rodger. C. J..
  2. Web site: NASA - Heliophysics Nugget: Seeing Sprites .
  3. Toynbee . Henry . Meteorological phenomena (letter) . Nature . 33 . 846 . 245 . 14 January 1886 . 10.1038/033245d0. 4128139 . free .
  4. 10.1126/science.249.4964.48 . Television Image of a Large Upward Electrical Discharge Above a Thunderstorm System . 1990 . R.C.. Franz . R.J.. Nemzek . J.R.. Winckler . Science. 249. 4964. 48–51. 17787625 . 1990Sci...249...48F . 9343018.
  5. 10.1029/95GL00583 . Sentman . D.D. . Wescott . E. M. . Osborne . D. L. . Hampton . D. L. . Heavner . M. J.. Preliminary results from the Sprites94 aircraft campaign: 1. Red Sprites . Geophys. Res. Lett. . 22 . 10 . 1205–1208. 1995 . 1995GeoRL..22.1205S.
  6. Web site: Sprite Lightning at 100,000 Frames Per Second . APOD.NASA.gov . NASA's APOD (Astronomy Picture of the Day blog) . 19 July 2022.
  7. News: National Geographic. October 3, 2016. October 3, 2016. Rare, Colorful Lightning Sprites Dance Over Hurricane Matthew. https://web.archive.org/web/20161004171420/http://news.nationalgeographic.com/2016/10/lightning-sprites-form-over-hurricane-matthew/. dead. October 4, 2016.
  8. Web site: University of Wisconsin–Madison. Cooperative Institute for Meteorological Satellite Studies. October 7, 2016. November 3, 2016. Hurricane Matthew and the Day/Night Band.
  9. Kathy Berry (1994). Spectacular Color Flashes Recorded Above Electrical Storms. NASA. Retrieved on 2009-02-18.
  10. Don Savage and Kathy Berry (1995). Sprites Confirmed Over Storms Outside U.S. For First Time. NASA. Retrieved on 2009-02-18.
  11. Web site: Rare Atmospheric Phenomenon Observed from Armagh . 2013-08-21 . https://web.archive.org/web/20130905165731/http://star.arm.ac.uk/press/2013/sprite.html . 2013-09-05 . dead.
  12. Boccippio . D. J. . Sprites, ELF Transients, and Positive Ground Strokes. Science . 269 . 1088–1091 . August 1995 . 10.1126/science.269.5227.1088 . 17755531 . Williams . ER . Heckman . SJ . Lyons . WA . Baker . IT . Boldi . R . 5227 . 1995Sci...269.1088B. 8840716.
  13. 10.1029/2011JD016890. Lightning morphology and impulse charge moment change of high peak current negative strokes. Journal of Geophysical Research: Atmospheres. 117. D4. 2012. Lu. Gaopeng. Cummer. Steven A. Blakeslee. Richard J. Weiss. Stephanie. Beasley. William H. n/a. 2012JGRD..117.4212L. 10.1.1.308.9842.
  14. Stenbaek-Nielsen . H. C.. McHarg . M.G. . Kanmae . T.. Sentman . D.D. . Observed emission rates in sprite streamer heads . Geophys. Res. Lett.. 34 . 11 . June 6, 2007 . 10.1029/2007GL029881. L11105 . L11105 . 2007GeoRL..3411105S. free.
  15. Grønne, Jesper. "Første danske 'red sprites' fanget fra Silkeborg" Danish Meteorological Institute, 20 August 2012. Retrieved: 20 August 2012.
  16. Sonnenfeld . Richard G. . Hager . William W. . 2013-05-01 . Electric Field Reversal in Sprite Electric Field Signature . Monthly Weather Review . en . 141 . 5 . 1731–1735 . 10.1175/MWR-D-12-00220.1 . 2013MWRv..141.1731S . 1520-0493.
  17. Pasko . V. P. . Inan . U. S. . Bell . T. F. . Taranenko . Y. N. . March 1997 . Sprites produced by quasi-electrostatic heating and ionization in the lower ionosphere . Journal of Geophysical Research: Space Physics . en . 102 . A3 . 4529–4561 . 10.1029/96JA03528 . 1997JGR...102.4529P . 0148-0227.
  18. Sentman . D. D. . Stenbaek-Nielsen . H. C. . McHarg . M. G. . Morrill . J. S. . 2008-06-16 . Plasma chemistry of sprite streamers . Journal of Geophysical Research: Atmospheres . en . 113 . D11 . 10.1029/2007JD008941 . 2008JGRD..11311112S . 0148-0227.
  19. Liu . Ningyu . Pasko . Victor P. . March 2005 . Molecular nitrogen LBH band system far-UV emissions of sprite streamers . Geophysical Research Letters . en . 32 . 5 . 10.1029/2004GL022001 . 2005GeoRL..32.5104L . 0094-8276.
  20. Rina Miyasato, Hiroshi Fukunishi, Yukihiro Takahashi, Michael J. Taylor, Hans. C. Stenbaek-Nielsen (2002). Characteristics of Lightning-induced Sprite Halos and Their Generation Mechanisms. Academic Society Home Village. Retrieved on 2009-02-18.
  21. Christopher Barrington Leigh (2000). Sprite halos. Stanford University. Retrieved on 2008-02-18.
  22. Barrington-Leigh, C. P., U. S. Inan, and M. Stanley, "Identification of Sprites and Elves with Intensified Video and Broadband Array Photometry", J. Geophys. Res. 106, No. 2, February, 2001.
  23. 10.1029/2004GL021943 . VLF/ELF sferic evidence for in-cloud discharge activity producing sprites . 2005 . A. . Ohkubo . H. . Fukunishi . Y. . Takahashi . T. . Adachi . 53059204 . Geophysical Research Letters. 32 . 4 . L04812 . 2005GeoRL..32.4812O .
  24. Web site: Data of the stratospheric balloon launched on 6/5/1989 from Columbia Scientific Balloon Facility, Palestine, Texas, US for Molecules observation made fluorescent with a Laser . 2009 . STRATOCAT . 2009-02-18.