Review of recent results on streamer discharges and discussion of their relevance for sprites and lightning

Review of recent results on streamer discharges and discussion of their relevance for sprites and lightning

It is by now well understood that large sprite discharges at the low air densities of the mesosphere are physically similar to small streamer discharges in air at standard temperature and pressure. This similarity is based on Townsend scaling with air density. First, the theoretical basis of Townsen...

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Bibliographic Details
Published in:Journal of Geophysical Research: Space Physics Vol. 115; no. A7
Main Authors: Ebert, Ute, Nijdam, Sander, Li, Chao, Luque, Alejandro, Briels, Tanja, van Veldhuizen, Eddie
Format: Journal Article
Language:English
Published: Washington Blackwell Publishing Ltd 01-07-2010
Subjects:
Atmospheric density
Atmospheric electricity
Atmospheric sciences
Density dependence
Electromagnetics
Electrons
Ionizing radiation
Lightning
Magnetic fields
Mesosphere
Polarity
Radiation
Scaling
Similarity
sprite discharges
Sprites
streamer discharges
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Summary:It is by now well understood that large sprite discharges at the low air densities of the mesosphere are physically similar to small streamer discharges in air at standard temperature and pressure. This similarity is based on Townsend scaling with air density. First, the theoretical basis of Townsend scaling and a list of six possible corrections to scaling are discussed; then the experimental evidence for the similarity between streamers and sprites is reviewed. We then discuss how far present sprite and streamer theory has been developed, and we show how streamer experiments can be interpreted as sprite simulations. We review those results of recent streamer research that are relevant for sprites and other forms of atmospheric electricity and discuss their implications for sprite understanding. These include the large range of streamer diameters and velocities and the overall 3‐D morphology with branching, interaction and reconnection, the dependence on voltage and polarity, the electron energies in the streamer head, and the consecutive chemical efficiency and hard radiation. New theoretical and experimental results concern measurements of streamer spectra in air, the density dependence of streamer heating (hot leaders are unlikely at 80 km altitude and cold streamers are unlikely in liquids), and a discussion of the influence of magnetic fields on thermal electrons or on energetic electrons in streamers or sprites.
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content type line 23
ISSN:0148-0227
2169-9380
2156-2202
2169-9402
DOI:10.1029/2009JA014867