Modeling of X‐ray emissions produced by stepping lightning leaders

Xu, Wei; Célestin, Sébastien; Pasko, Victor P.

doi:10.1002/2014gl061163

Cited by 19 publications

(41 citation statements)

References 23 publications

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“…The proportionality coefficient in equation is obtained from the assumption that 10 11 photons with energies greater than 10 keV are produced in the case of a potential drop of 5 MV (see section 4). Following this procedure, we find that ξ ≃3.4 × 10 6 , which is consistent with the upper limit of 10 10 found by considering that all the streamers eventually constituting the streamer zone emit runaway electrons when they reached their limit of growth [ Celestin and Pasko , ; Xu et al , ]. The total number of photons corresponding to other potential drops is obtained through the assumption that this coefficient does not depend on the potential drop.…”

Section: Resultssupporting

confidence: 84%

“…This model simulates the dynamics of electrons propagating in air with energies from sub‐eV to GeV. The model has been used in recent studies to quantify thermal runaway electron emissions from streamer discharges [ Celestin and Pasko , ], properties of RREAs in homogeneous fields, and the acceleration of electrons in inhomogeneous fields produced by lightning leaders [ Celestin et al , ; Xu et al , , ]. The initial energy of the thermal runaway electrons is defined as 65 keV because those are believed to be produced by expanded streamers developing in the vicinity of the leader tip during the negative corona flash process [ Celestin and Pasko , ].…”

Section: Model Formulationmentioning

confidence: 99%

“…X‐ray bursts have been observed to be produced during the formation of new leader steps in negative cloud‐to‐ground lightning [ Dwyer et al , ]. Although the energy of these X‐ray bursts was found to be insufficient for the RREA mechanism to be involved [ Dwyer et al , ], they can be explained by the production and acceleration of thermal runaway electrons in the vicinity of the leader tip during negative corona flash stages of stepping lightning leaders and the subsequent production of bremsstrahlung [ Celestin and Pasko , ; Xu et al , ]. The same phenomenon could be at the origin of the production of TGFs under the assumption that high‐potential intracloud leaders are involved [ Celestin and Pasko , ].…”

Section: Introductionmentioning

confidence: 99%

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Variability in fluence and spectrum of high‐energy photon bursts produced by lightning leaders

Célestin

Pasko

2015

JGR Space Physics

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In this paper, we model the production and acceleration of thermal runaway electrons during negative corona flash stages of stepping lightning leaders and the corresponding terrestrial gamma ray flashes (TGFs) or negative cloud‐to‐ground (−CG) lightning‐produced X‐ray bursts in a unified fashion. We show how the source photon spectrum and fluence depend on the potential drop formed in the lightning leader tip region during corona flash and how the X‐ray burst spectrum progressively converges toward typical TGF spectrum as the potential drop increases. Additionally, we show that the number of streamers produced in a negative corona flash, the source electron energy distribution function, the corresponding number of photons, and the photon energy distribution and transport through the atmosphere up to low‐orbit satellite altitudes exhibit a very strong dependence on this potential drop. This leads to a threshold effect causing X‐rays produced by leaders with potentials lower than those producing typical TGFs extremely unlikely to be detected by low‐orbit satellites. Moreover, from the number of photons in X‐ray bursts produced by −CGs estimated from ground observations, we show that the proportionality between the number of thermal runaway electrons and the square of the potential drop in the leader tip region during negative corona flash proposed earlier leads to typical photon fluences on the order of 1 ph/cm2 at an altitude of 500 km and a radial distance of 200 km for intracloud lightning discharges producing 300 MV potential drops, which is consistent with observations of TGF fluences and spectra from satellites.

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Section: Resultssupporting

confidence: 84%

Section: Model Formulationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Variability in fluence and spectrum of high‐energy photon bursts produced by lightning leaders

Célestin

Pasko

2015

JGR Space Physics

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“…[], using an X‐ray pin‐hole‐type camera to image triggered lightning leaders near ground, suggested that the X‐ray source region for subsequent leaders that occurred in a preexisting channel, inferred to be below the leader tip, had a radius of 2 to 3 m. Xu et al . [] found that X‐ray bursts produced by 5 MV to 10 MV leaders would theoretically produce X‐ray burst spectra consistent with the experimental results reported by Schaal et al . [].…”

Section: Introductionsupporting

confidence: 85%

Observations of corona in triggered dart‐stepped leaders

Gamerota

Uman

Hill

et al. 2015

Geophysical Research Letters

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Corona streamers are a critical component of lightning leader step formation and are postulated to produce the very high electric fields at their tips that produce runaway electrons resulting in the observed X-ray bursts associated with leader stepping. Corona emanating from the vicinity of the leader tip between leader steps was analyzed using three sequential high-speed video sequences of dart-stepped leaders in three different triggered lightning flashes during the summers of 2013 and 2014 in northeast Florida. Images were recorded at 648 kiloframes per second (1.16 μs exposure time, 380 ns dead time) at an altitude of 65 m or less. In each image sequence, the leader propagates downward in consecutive frames, with corona streamers observed to fan outward from the bright leader tip in less than the image frame time of about 1.5 μs. In 21 exposures, corona streamers propagate, on average, 9 m below the bright leader tip.

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“…Similarly, with the same assumption for cases II, III and IV, the required numbers of streamers are ∼ 3.5 × 10 5 , ∼ 5 × 10 4 and ∼ 2.5 × 10 6 , respectively, and thus the UHF radiation energy would be ∼3 ×10 −4 J, ∼1 × 10 −5 J, and ∼2 × 10 −5 J, respectively. from the electrostatic consideration of the streamer zone (e.g., Celestin et al, 2015), 10 5 -10 7 streamers are required to give a potential drop of 2-20 MV near the lightning leader tip, which is commonly accepted for typical lightning leaders and also consistent with analysis of ground-based observation of X-rays produced by lightning (e.g., Xu et al, 2014). Specifically, the blue curve corresponds to the parameters: = 1.7 × 10 9 s −1 , = 7.5 × 10 7 s −1 , I CM0 = 0.44 A⋅m, and T 0 = 6 ns.…”

Section: 1029/2018gl080309mentioning

confidence: 74%

VHF and UHF Electromagnetic Radiation Produced by Streamers in Lightning

Shi

Liu

Dwyer

et al. 2019

Geophysical Research Letters

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In this letter, we report simulation results of streamer propagation and collision that produce electromagnetic radiation in the very high frequency (VHF) and ultra high frequency (UHF) bands. The streamers are initiated in overbreakdown field conditions, 1.5Ekand2Ek, respectively, which may be found during the corona flash stage of negative leader stepping processes. We find that while streamer propagation produces stronger VHF radiation, the head‐on collision of streamers dominates UHF, and even higher‐frequency radiation. Analysis of the energy spectral densities obtained from different simulation cases shows that the total length and radii of colliding streamers, as well as the ambient field, are important parameters for the UHF radiation produced by streamer collisions. The larger those parameters are, the stronger UHF radiation produced. Finally, by comparing with the measured spectral magnitude of lightning field in the VHF range, it is found that there are probably 105–107 streamers involved during the lightning corona flash stage.

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Modeling of X‐ray emissions produced by stepping lightning leaders

Cited by 19 publications

References 23 publications

Variability in fluence and spectrum of high‐energy photon bursts produced by lightning leaders

Variability in fluence and spectrum of high‐energy photon bursts produced by lightning leaders

Observations of corona in triggered dart‐stepped leaders

VHF and UHF Electromagnetic Radiation Produced by Streamers in Lightning

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