Generation of seed electrons by extensive air showers, and the lightning inception problem including narrow bipolar events

Casper Rutjes, Ute Ebert (Corresponding author), Stijn Buitink, Olaf Scholten, Thi Ngoc Gia Trinh

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Uittreksel

Lightning streamers and leaders need thermal electrons to initiate, but free electrons are extremely rare in the wet air of a thundercloud. Here we analyze the probabilities that high electron densities occur in extensive air showers. We argue that relevant air showers are created by cosmic particles with energies between 1015 and 1017 eV impinging onto our atmosphere. We simulate a large number of air showers and perform a stochastic analysis of their results. We present the available densities of thermal electrons as a function of altitude, time interval, and considered area, while neglecting effects of local electric fields. We find that free electron densities at altitudes between 5 and 13 km can reach values of order 103 cm−3, but only in shower cores with a radius on a centimeter scale. Above 6 km, the availability of extreme free electron densities decreases significantly with increasing altitude. Recent measurements by Rison et al. (2016, https://doi.org/10.1038/ncomms10721) indicate that several streamers must have been triggered simultaneously during discharge inception, and we suggest that an extensive air shower could have been the trigger. Rison's measurements show further that the streamers are laterally separated by several tens of meters, so they must have been triggered by electron densities as low as 1 cm−3. Such low electron densities demand a stochastic approach to streamer initiation near hydrometeors.

TaalEngels
Pagina's7255-7269
TijdschriftJournal of Geophysical Research. D, Atmospheres
Volume124
Nummer van het tijdschrift13
Vroegere onlinedatum3 jun 2019
DOI's
StatusGepubliceerd - 8 jul 2019

Vingerafdruk

lightning
cosmic ray showers
Lightning
electron density
Carrier concentration
Seed
seeds
electrons
seed
electron
air
Electrons
free electrons
Air
hydrometeors
thundercloud
showers
availability
electric field
heat

Trefwoorden

    Citeer dit

    Rutjes, Casper ; Ebert, Ute ; Buitink, Stijn ; Scholten, Olaf ; Trinh, Thi Ngoc Gia. / Generation of seed electrons by extensive air showers, and the lightning inception problem including narrow bipolar events. In: Journal of Geophysical Research. D, Atmospheres. 2019 ; Vol. 124, Nr. 13. blz. 7255-7269
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    abstract = "Lightning streamers and leaders need thermal electrons to initiate, but free electrons are extremely rare in the wet air of a thundercloud. Here we analyze the probabilities that high electron densities occur in extensive air showers. We argue that relevant air showers are created by cosmic particles with energies between 1015 and 1017 eV impinging onto our atmosphere. We simulate a large number of air showers and perform a stochastic analysis of their results. We present the available densities of thermal electrons as a function of altitude, time interval, and considered area, while neglecting effects of local electric fields. We find that free electron densities at altitudes between 5 and 13 km can reach values of order 103 cm−3, but only in shower cores with a radius on a centimeter scale. Above 6 km, the availability of extreme free electron densities decreases significantly with increasing altitude. Recent measurements by Rison et al. (2016, https://doi.org/10.1038/ncomms10721) indicate that several streamers must have been triggered simultaneously during discharge inception, and we suggest that an extensive air shower could have been the trigger. Rison's measurements show further that the streamers are laterally separated by several tens of meters, so they must have been triggered by electron densities as low as 1 cm−3. Such low electron densities demand a stochastic approach to streamer initiation near hydrometeors.",
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    Generation of seed electrons by extensive air showers, and the lightning inception problem including narrow bipolar events. / Rutjes, Casper; Ebert, Ute (Corresponding author); Buitink, Stijn; Scholten, Olaf; Trinh, Thi Ngoc Gia.

    In: Journal of Geophysical Research. D, Atmospheres, Vol. 124, Nr. 13, 08.07.2019, blz. 7255-7269.

    Onderzoeksoutput: Bijdrage aan tijdschriftTijdschriftartikelAcademicpeer review

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