The First Terrestrial Electron Beam Observed by the Atmosphere‐Space Interactions Monitor

Autor: Freddy Christiansen, Olivier Chanrion, Pavlo Kochkin, Georgi Genov, Irfan Kuvvetli, Nikolai Lehtinen, Matthias Heumesser, Kjetil Ullaland, Shiming Yang, David Sarria, Martino Marisaldi, Kjetil Albrechtsen, Nikolai Østgaard, C. J. Eyles, Brant Carlson, P. H. Connell, Carl Budtz-Jørgensen, Andrew Mezentsev, Victor Reglero, C. Maiorana, B. H. Qureshi, J. Navarro-González, Krystallia Dimitriadou, Torsten Neubert
Rok vydání: 2019
Předmět:
Zdroj: Journal of Geophysical Research: Space Physics
Sarria, D, Kochkin, P, Østgaard, N, Lehtinen, N, Mezentsev, A, Marisaldi, M, Carlson, B E, Maiorana, C, Albrechtsen, K, Neubert, T, Reglero, V, Ullaland, K, Yang, S, Genov, G, Qureshi, B H, Budtz-Jørgensen, C, Kuvvetli, I, Christiansen, F, Chanrion, O, Heumesser, M, Dimitriadou, K, Navarro-González, J, Connell, P & Eyles, C 2019, ' The First Terrestrial Electron Beam Observed by The Atmosphere-Space Interactions Monitor ', Journal of Geophysical Research: Space Physics, vol. 124, no. 12, pp. 10497-10511 . https://doi.org/10.1029/2019ja027071
ISSN: 2169-9380
DOI: 10.1029/2019ja027071
Popis: We report the first Terrestrial Electron Beam detected by the Atmosphere‐Space Interactions Monitor. It happened on 16 September 2018. The Atmosphere‐Space Interactions Monitor Modular X and Gamma ray Sensor recorded a 2 ms long event, with a softer spectrum than typically recorded for Terrestrial Gamma ray Flashes (TGFs). The lightning discharge associated to this event was found in the World Wide Lightning Location Network data, close to the northern footpoint of the magnetic field line that intercepts the International Space Station location. Imaging from a GOES‐R geostationary satellite shows that the source TGF was produced close to an overshooting top of a thunderstorm. Monte‐Carlo simulations were performed to reproduce the observed light curve and energy spectrum. The event can be explained by the secondary electrons and positrons produced by the TGF (i.e., the Terrestrial Electron Beam), even if about 3.5% to 10% of the detected counts may be due to direct TGF photons. A source TGF with a Gaussian angular distribution with standard deviation between 20.6° and 29.8° was found to reproduce the measurement. Assuming an isotropic angular distribution within a cone, compatible half angles are between 30.6° and 41.9°, in agreement with previous studies. The number of required photons for the source TGF could be estimated for various assumption of the source (altitude of production and angular distribution) and is estimated between 1017.2 and 1018.9 photons, that is, compatible with the current consensus.
Databáze: OpenAIRE