Upper-atmospheric lightning

Upper-atmospheric lightning or ionospheric lightning are terms sometimes used by researchers to refer to a family of short-lived electrical-breakdown phenomena that occur well above the altitudes of normal lightning and storm clouds. Upper-atmospheric lightning is believed to be electrically induced forms of luminous plasma. The preferred usage is transient luminous event (TLE), because the various types of electrical-discharge phenomena in the upper atmosphere lack several characteristics of the more familiar tropospheric lightning.

Representation of upper-atmospheric lightning and electrical-discharge phenomena

Characteristics
Midsummer night sprites at La Silla Observatory.[1]

There are several types of TLEs, the most common being sprites. Sprites are flashes of bright red light that occur above storm systems. C-sprites (short for “columniform sprites”) is the name given to vertical columns of red light. C-sprites exhibiting tendrils are sometimes called “carrot sprites”. Other types of TLEs include sprite halos, blue jets, gigantic jets, blue starters, and ELVESs. The acronym ELVES (“Emission of Light and Very Low Frequency perturbations due to Electromagnetic Pulse Sources”) refers to a singular event which is commonly thought of as being plural. TLEs are secondary phenomena that occur in the upper atmosphere in association with underlying thunderstorm lightning.

TLEs generally last anywhere from less than a millisecond to more than 2 seconds. The first video recording of a TLE was captured accidentally on July 6, 1989 when researcher R.C Franz left a camera running overnight to view the night sky. When reviewing the video taken, two finger-like vertical images appeared in two frames of the film. The next known video recordings of a TLE were taken in 1989, when the Shuttle Mission STS-34 was conducting the Mesoscale Lightning Observation Experiment. On October 21, 1989 TLE'S were recorded during the Shuttle orbits 44 and 45. TLEs have been captured by a variety of optical recording systems, with the total number of recent recorded events (early 2009) estimated at many tens-of-thousands. The global rate of TLE occurrence has been estimated from satellite (FORMOSAT-2) observations to be several million events per year.

History

In the 1920s, the Scottish physicist C.T.R. Wilson predicted that electrical breakdown should occur in the atmosphere high above large thunderstorms.[2][3] In ensuing decades, high altitude electrical discharges were reported by aircraft pilots and discounted by meteorologists until the first direct visual evidence was documented in 1989. Several years later, the optical signatures of these events were named 'sprites' by researchers to avoid inadvertently implying physical properties that were, at the time, still unknown. The terms red sprites and blue jets gained popularity after a video clip was circulated following an aircraft research campaign to study sprites in 1994. In 2019, a new type of TLE was discovered by meteorologists. These new TLEs are green glows that occur above red sprites. These new types of TLEs are called ghosts.[4]


Sprites
Main article: Sprite (lightning)
First color image of a sprite, taken from an aircraft.

Sprites are large-scale electrical discharges which occur high above a thunderstorm cloud, or cumulonimbus, giving rise to a quite varied range of visual shapes. They are triggered by the discharges of positive lightning between the thundercloud and the ground.[5] The phenomena were named after the mischievous sprite, e.g., Shakespeare's Ariel or Puck,[6] and is also an acronym for Stratospheric/mesospheric Perturbations Resulting from Intense Thunderstorm Electrification.[7] They normally are colored reddish-orange or greenish-blue, with hanging tendrils below and arcing branches above. They can also be preceded by a reddish halo. They often occur in clusters, lying 50 kilometres (31 mi) to 90 kilometres (56 mi) above the Earth's surface. Sprites have been witnessed thousands of times.[8] Sprites have been held responsible for otherwise unexplained accidents involving high altitude vehicular operations above thunderstorms.[9]

Jets

Although jets are considered to be a type of upper-atmospheric lightning, it has been found that they are components of tropospheric lightning and a type of cloud-to-air discharge that initiates within a thunderstorm and travel upwards. In contrast, other types of TLEs are not electrically connected with tropospheric lightning—despite being triggered by it. The two main types of jets are blue jets and gigantic jets. Blue starters are considered to be a weaker form of blue jets.

Blue jets
Blue jet as seen from the summit of Mauna Kea, Hawaii.

Blue jets are believed to be initiated as "normal" lightning discharges between the upper positive charge region in a thundercloud and a negative "screening layer" present above this charge region. The positive end of the leader network fills the negative charge region before the negative end fills the positive charge region, and the positive leader subsequently exits the cloud and propagates upward. It was previously believed that blue jets were not directly related to lightning flashes, and that the presence of hail somehow led to their occurrence.[10] They are also brighter than sprites and, as implied by their name, are blue in color. The color is believed to be due to a set of blue and near-ultraviolet emission lines from neutral and ionized molecular nitrogen. They were first recorded on October 21, 1989, on a monochrome video of a thunderstorm on the horizon taken from the Space Shuttle as it passed over Australia. Blue jets occur much less frequently than sprites. By 2007, fewer than a hundred images had been obtained. The majority of these images, which include the first color imagery, are associated with a single thunderstorm. These were taken in a series of 1994 aircraft flights to study sprites.[11]

Blue starters

Blue starters were discovered on video from a night time research flight around thunderstorms[12] and appear to be "an upward moving luminous phenomenon closely related to blue jets."[13] They appear to be shorter and brighter than blue jets, reaching altitudes of only up to 20 km.[14] "Blue starters appear to be blue jets that never quite make it," according to Dr. Victor P. Pasko, associate professor of electrical engineering.[15]

Gigantic jets
Gigantic jet in Oro Verde, Argentina, February 2, 2014

Where blue jets are believed to initiate between the upper positive charge region and a negative screening layer directly above this region, gigantic jets appear to initiate between the upper positive and lower negative charge regions in the thundercloud. In a similar process to how blue jets form, the higher charge region is discharged by the leader network before the same occurs in the lower charge region, and one end of the leader network propagates upward from the cloud toward the ionosphere. Gigantic jets reach higher altitudes than blue jets, and the upper portion of the jet changes color from blue to red.

Observations

On September 14, 2001, scientists at the Arecibo Observatory photographed a gigantic jet—double the height of those previously observed—reaching around 70 km (45 mi) into the atmosphere.[16] The jet was located above a thunderstorm over an ocean, and lasted under a second. The jet was initially observed to be traveling up at around 50,000 m/s (110,000 mph; 180,000 km/h) at a speed similar to typical lightning, increased to 160,000 and 270,000 m/s (360,000–600,000 mph; 580,000–970,000 km/h), but then split in two and sped upward with speeds of at least 2,000,000 m/s (4,500,000 mph; 7,200,000 km/h) to the ionosphere where it then spread out in a bright burst of light.

On July 22, 2002, five gigantic jets between 60 and 70 kilometres (35 and 45 mi) in length were observed over the South China Sea from Taiwan, reported in Nature.[17][18] The jets lasted under a second, with shapes likened by the researchers to giant trees and carrots.

On November 10, 2012, the Chinese Science Bulletin reported a gigantic jet event observed over a thunderstorm in mainland China on August 12, 2010. "GJ event that was clearly recorded in eastern China (storm center located at 35.6°N,119.8°E, near the Huanghai Sea)".[19]

On February 2, 2014, the Oro Verde Observatory of Argentina reported ten or more gigantic jet events observed over a thunderstorm in Entre Ríos south. The storm center was located at 33°S, 60°W, near the city of Rosario.

On August 13, 2016, photographer Phebe Pan caught a clear wide-angle photo of a gigantic jet on a wide-angle lens while shooting Perseid meteors atop Shi Keng Kong peak in Guangdong province [20] and Li Hualong captured the same jet from a more distant location in Jiahe, Hunan, China.[21]

On March 28, 2017, Photographer Jeff Miles captured four gigantic jets over Australia.[22]

On October 16, 2019, pilot Chris Holmes captured a high-resolution video of a gigantic jet from 35,000 feet above the Gulf of Mexico near the Yucatán Peninsula.[23] From 35 miles, Holmes's video shows a blue streamer reach up from the top of a thunderstorm to the ionosphere, becoming red at the top. Only then does a brilliant white lightning leader crawl slowly from the top of the cloud, reaching about 10% of the height of the gigantic jet before fading.

ELVES

ELVES (Emission of Light and Very Low Frequency perturbations due to Electromagnetic Pulse Sources) often appear as a dim, flattened, expanding glow around 400 km (250 mi) in diameter that lasts for, typically, just one millisecond.[24] They occur in the ionosphere 100 km (62 mi) above the ground over thunderstorms. Their color was a puzzle for some time, but is now believed to be a red hue. ELVES were first recorded on another shuttle mission, this time recorded off French Guiana on October 7, 1990.[13] That ELVES was discovered in the Shuttle Video by the Mesoscale Lightning Experiment (MLE) team at Marshall Space Flight Center, AL led by the Principal Investigator, Otha H."Skeet" Vaughan, Jr.

ELVES is a whimsical acronym for Emissions of Light and Very Low Frequency Perturbations due to Electromagnetic Pulse Sources.[25] This refers to the process by which the light is generated; the excitation of nitrogen molecules due to electron collisions (the electrons possibly having been energized by the electromagnetic pulse caused by a discharge from an underlying thunderstorm).

See also

References
  1. "Midsummer Night Brings Sprites". Retrieved 2015-06-24.
  2. C. T. R. Wilson (1924) "The electric field of a thundercloud and some of its effects," Proceedings of the Physical Society of London, 37 (1) : 32D-37D. Available on-line at: University of São Paulo.
  3. Earle R. Williams (November 2001) "Sprites, elves, and glow discharge tubes," Physics Today, 54 (11) : 41–47. Available on-line at: Physics Today Archived May 27, 2012, at Archive.today.
  4. Schyma, Hank (May 25th 2019). "Red sprites and blue jets explained - New discovery!". YouTube. Check date values in: |date= (help)
  5. Boccippio, D. J.; Williams, E. R.; Heckman, S. J.; Lyons, W. A.; Baker, I. T.; Boldi, R. (August 1995). "Sprites, ELF Transients, and Positive Ground Strokes". Science. 269 (5227): 1088–1091. Bibcode:1995Sci...269.1088B. doi:10.1126/science.269.5227.1088. PMID 17755531.
  6. From page 128 of: John Friedman, Out of the Blue: A History of Lightning (New York, New York: Random House, Inc., 2008):
    "Dr. Davis Sentman of the University of Alaska, one of the few scientists studying these luminous, ghostlike phenomena [i.e., sprites], named the eerie flashes of colored lights after Shakespeare's mischievous spirits of the air — Ariel in The Tempest and Puck in "A Midsummer Night's Dream."
  7. "Sprites and Elves in the Atmosphere | Penn State University".
  8. Walter A. Lyons and Michey D. Schmidt (2003). P1.39 The Discovery of Red Sprites as an Opportunity For Informal Science Education. American Meteorological Society. Retrieved on February 18, 2009.
  9. STRATOCAT – Stratospheric balloons history and present. "Full report on the uncontrolled free fall of a stratospheric balloon payload provoked by a Sprite".
  10. Fractal Models of Blue Jets, Blue Starters Show Similarity, Differences to Red Sprites
  11. 'Red Sprites & Blue Jets – the video', 'Blue Jets & Blue Starters – the video'.
  12. Examples may be seen in the clip 'Blue Jets & Blue Starters – the video' .
  13. Boeck, W. L.; et al. (May 1998). "The Role of the Space Shuttle Videotapes in the Discovery of Sprites, Jets, and Elves". Journal of Atmospheric and Solar-Terrestrial Physics. 60 (7–9): 669–677. Bibcode:1998JASTP..60..669B. doi:10.1016/S1364-6826(98)00025-X.
  14. Blue jets Archived May 11, 2008, at the Wayback Machine
  15. Fractal models of blue jets, blue starters show similarity, differences to red sprites
  16. Pasko, Victor P.; Stanley, Mark A.; Mathews, John D.; Inan, Umran S.; Wood, Troy G. (2002). "Electrical discharge from a thundercloud top to the lower ionosphere". Nature. 416 (6877): 152–154. doi:10.1038/416152a. PMID 11894087.
  17. "Archived copy" (PDF). Archived from the original (PDF) on 2007-07-02. Retrieved 2007-04-21.CS1 maint: archived copy as title (link)
  18. Giant jets caught on camera
  19. Yang, Jing; Feng, Guili (2012). "Chinese Science Bulletin 2012, Vol. 57 DOI: 10.1007/s11434-012-5486-3". Chinese Science Bulletin. 57 (36): 4791. Bibcode:2012ChSBu..57.4791Y. doi:10.1007/s11434-012-5486-3.
  20. "Spaceweather.com Time Machine". spaceweather.com. Retrieved 2016-08-16.
  21. "Sprites Lightning".
  22. "Gigantic jets over Australia".
  23. Phillips, T. (October 25, 2019). Close encounter with a gigantic jet. Retrieved from https://spaceweatherarchive.com/2019/10/25/close-encounter-with-a-gigantic-jet/
  24. ELVES, a primer: Ionospheric Heating By the Electromagnetic Pulses from Lightning
  25. The Free Dictionary – ELVES
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