Kostinskiy et al., 2020 - Google Patents
The mechanism of the origin and development of lightning from initiating event to initial breakdown pulses (v. 2)Kostinskiy et al., 2020
View PDF- Document ID
- 4508336246587495048
- Author
- Kostinskiy A
- Marshall T
- Stolzenburg M
- Publication year
- Publication venue
- Journal of Geophysical Research: Atmospheres
External Links
Snippet
Based on experimental results of recent years, this article presents a qualitative description of a possible mechanism (termed the Mechanism) covering the main stages of lightning initiation, starting before and including the initiating event, followed by the initial electric field …
- 230000000977 initiatory 0 title abstract description 97
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Kostinskiy et al. | The mechanism of the origin and development of lightning from initiating event to initial breakdown pulses (v. 2) | |
| Ebert et al. | Review of recent results on streamer discharges and discussion of their relevance for sprites and lightning | |
| Petersen et al. | A brief review of the problem of lightning initiation and a hypothesis of initial lightning leader formation | |
| Kostinskiy et al. | Abrupt elongation (stepping) of negative and positive leaders culminating in an intense corona streamer burst: Observations in long sparks and implications for lightning | |
| Celestin et al. | Energy and fluxes of thermal runaway electrons produced by exponential growth of streamers during the stepping of lightning leaders and in transient luminous events | |
| Shi et al. | VHF and UHF electromagnetic radiation produced by streamers in lightning | |
| Dwyer et al. | The physics of lightning | |
| Liu et al. | Effects of photoionization on propagation and branching of positive and negative streamers in sprites | |
| Dwyer | The initiation of lightning by runaway air breakdown | |
| Pasko et al. | Three‐dimensional modeling of blue jets and blue starters | |
| Dwyer et al. | Radio emissions from terrestrial gamma‐ray flashes | |
| Babich et al. | A model for electric field enhancement in lightning leader tips to levels allowing X‐ray and γ ray emissions | |
| Edens et al. | VHF lightning mapping observations of a triggered lightning flash | |
| Kuzenov et al. | Computational and experimental modeling in magnetoplasma aerodynamics and high-speed gas and plasma flows (A Review) | |
| Carlson et al. | Terrestrial gamma ray flash production by active lightning leader channels | |
| Starikovskiy et al. | How pulse polarity and photoionization control streamer discharge development in long air gaps | |
| Symbalisty et al. | Finite volume solution of the relativistic Boltzmann equation for electron avalanche studies | |
| Köhn et al. | Electron acceleration during streamer collisions in air | |
| Ihaddadene et al. | Increase of the electric field in head‐on collisions between negative and positive streamers | |
| Köhn et al. | Calculation of beams of positrons, neutrons, and protons associated with terrestrial gamma ray flashes | |
| Inan et al. | Production of terrestrial gamma‐ray flashes by an electromagnetic pulse from a lightning return stroke | |
| Dwyer et al. | Properties of the thundercloud discharges responsible for terrestrial gamma‐ray flashes | |
| Jiang et al. | Luminous crown residual vs. bright space segment: Characteristical structures for the intermittent positive and negative leaders of triggered lightning | |
| Liu | Model of sprite luminous trail caused by increasing streamer current | |
| Köhn et al. | High‐energy emissions induced by air density fluctuations of discharges |