Observations of the connection of positive and negative leaders in meter‐scale electric discharges generated by clouds of negatively charged water droplets

Alexander, Kostinskiy; Syssoev, V. S.; Bogatov, N. A.; Mareev, E. A.; Andreev, M. G.; Bulatov, M. U.; Makalsky, L. M.; Sukharevsky, D. I.; Rakov, Vladimir A.

doi:10.1002/2016jd025079

Cited by 28 publications

(42 citation statements)

References 24 publications

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“…Sometimes between those two connections there are additional (attempted hot‐channel) connections (see Tran & Rakov () and references therein). Two current and light pulses have been documented during the attachment process in long negative sparks by Kostinskiy et al (, Figures 2 and 4).…”

Section: Resultsmentioning

confidence: 86%

“…Sometimes between those two connections there are additional (attempted hot-channel) connections (see Tran & Rakov (2017) and references therein). Two current and light pulses have been documented during the attachment process in long negative sparks by Kostinskiy et al (2016, Figures 2 and 4). Figure 7 shows the current and power density waves in different sections of the channel associated with a single step presented in Figure 6.…”

Section: Step Formation Dynamicsmentioning

confidence: 99%

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Numerical Simulation of Stepping and Branching Processes in Negative Lightning Leaders

et al. 2020

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A numerical model with physical timing and grid spacing of 3 m is applied to studying the progression (including stepping and branching) of negative lightning stepped leader. The asymmetry between positive and negative streamers is taken into account via using polarity‐dependent initiation and propagation field thresholds. The stepped nature of negative leader is confirmed to be caused by this asymmetry. The step formation process of the negative leader is modeled to begin with the appearance of space stems inside and in the immediate vicinity of its streamer zone (corona streamer burst completing the preceding step). Some of those space stems evolve into space leaders, which can connect to the primary leader channel, thereby facilitating its extension. Model‐predicted morphology and dynamics of negative leaders are in good agreement with the recent recordings of lightning stepped and dart‐stepped leaders obtained using high‐speed video cameras, and their electrical parameters are in line with the current knowledge on negative lightning leaders.

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Section: Resultsmentioning

confidence: 86%

Section: Step Formation Dynamicsmentioning

confidence: 99%

Numerical Simulation of Stepping and Branching Processes in Negative Lightning Leaders

et al. 2020

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“…Negative leaders propagate in discrete steps, with waiting time of tens of microseconds punctuated by sudden jumps (Berger, 1966;C J Biagi et al, 2014;Guimaraes et al, 2017;Hill et al, 2011;Reess et al, 1995;Malagón-Romero & Luque, 2019). The underlying mechanisms leading to the formation of negative leader steps were first discovered in laboratory discharges and only recently confirmed in natural lightning (Bazelyan & Raizer, 2000;Kostinskiy et al, 2016). Positive leaders usually propagate continuously but exhibit steps/restrikes characterized by intense reilluminations under the slow varying ambient electric field or at high moisture (Berger, 1966;Domens et al, 1991;Idone, 1992; V A Rakov et al, 2003;Marcelo M F Saba et al, 2008;Christopher J Biagi et al, 2011;Warner, 2012;Jiang et al, 2013;Wang et al, 2016;M.…”

Section: Introductionmentioning

confidence: 99%

The Discharge Preceding the Intense Reillumination in Positive Leader Steps Under the Slow Varying Ambient Electric Field

Huang

Chen

Pei

et al. 2020

Geophysical Research Letters

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Under the slow varying ambient electric field, positive leader propagation exhibits steps characterized by intense reilluminations and abrupt elongations. These steps are currently not well understood. In this work, we investigate these steps in laboratory atmospheric discharges, using a high‐speed video camera and a synchronized electrical parameter measurement system. The discharge, emitting weak light and preceding the intense reillumination, is discovered. This finding suggests that the leader channel actually restarts and extends forward before the intense reillumination, which deepens our understanding of the dynamic process of the positive leader step. The discharge before the intense reillumination contributes to the corona inception from the electrode, leading to the intense reillumination of the leader channel and the emergence of an intense corona streamer burst from the leader tip.

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“…Установлено, что скорости положительных и отрицательных лидеров внутри общей стримерной зоны совпадают и увеличиваются с ростом силы тока. Полученные результаты важны для решения фундаментальных проблем динамики главной стадии молнии [40]. В работе [41] впервые продемонстрирована возможность инициирования электрических разря-дов арбалетным болтом (снарядом), движущимся в электрическом поле облака отрицательно заряженных капель воды.…”

Section: электрические процессы в облакахunclassified

Russian studies of atmospheric electricity in 2015–2018

Mareev

Stasenko

Shatalina

et al. 2019

Известия Российской академии наук. Физика атмосферы и океана

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This review contains the most significant results of Russian studies in the field of atmospheric electricity in 20152018. It is part of the Russian National Report on Meteorology and Atmospheric Sciencesto the International Association of Meteorology and Atmospheric Sciences (IAMAS). The report was presented and approved at the XXVII General Assembly of the International Union of Geodesy and Geophysics (IUGG) 1. The review is followed by a list of the main published works on the studies of atmospheric electricity of Russian scientists in 20152018.

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Observations of the connection of positive and negative leaders in meter‐scale electric discharges generated by clouds of negatively charged water droplets

Cited by 28 publications

References 24 publications

Numerical Simulation of Stepping and Branching Processes in Negative Lightning Leaders

Numerical Simulation of Stepping and Branching Processes in Negative Lightning Leaders

The Discharge Preceding the Intense Reillumination in Positive Leader Steps Under the Slow Varying Ambient Electric Field

Russian studies of atmospheric electricity in 2015–2018

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