Analysis of the Spatial Nonuniformity of the Electric Field in Spectroscopic Diagnostic Methods of Atmospheric Electricity Phenomena

The spatial nonuniformity of the electric field in air discharges, such as streamers, can influence the accuracy of spectroscopic diagnostic methods and hence the estimation of the peak electric field. In this work, we use a self‐consistent streamer discharge model to investigate the spatial nonunif...

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Bibliographic Details
Published in:Journal of geophysical research. Atmospheres 2019-11, Vol.124 (22), p.12356-12370
Main Authors: Malagón‐Romero, A., Pérez‐Invernón, F. J., Luque, A., Gordillo‐Vázquez, F. J.
Format: Article
Language:English
Subjects:
Air
Atmospheric discharges
Atmospheric Electricity
Atmospheric pressure
Atmospheric Processes
Blue jets (atmospherics)
Cold plasmas
Composition and Chemistry
Computational Geophysics
Diagnostic systems
Electric discharges
Electric field
Electric fields
Electromagnetics
Geophysics
Informatics
Laboratory discharges
Lightning
Low pressure
Measurement methods
Mesosphere
Modeling
Natural Hazards
Nonuniformity
Numerical Modeling
Oceanography: General
Optical communication
Physical Modeling
Plasmas
Spatial analysis
Spatial non‐uniformity
Spectroscopy
Sprites
Streamer gas discharge
Streamers
Transient luminous events
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Summary:The spatial nonuniformity of the electric field in air discharges, such as streamers, can influence the accuracy of spectroscopic diagnostic methods and hence the estimation of the peak electric field. In this work, we use a self‐consistent streamer discharge model to investigate the spatial nonuniformity in streamer heads and streamer glows. We focus our analysis on air discharges at atmospheric pressure and at the low pressure of the mesosphere. This approach is useful to investigate the spatial nonuniformity of laboratory discharges as well as sprite streamers and blue jet streamers, two types of transient luminous events taking place above thunderclouds. This characterization of the spatial nonuniformity of the electric field in air discharges allows us to develop two different spectroscopic diagnostic methods to estimate the peak electric field in cold plasmas. The commonly employed method to derive the peak electric field in streamer heads underestimates the electric field by about 40–50% as a consequence of the high spatial nonuniformity of the electric field. Our diagnostic methods reduce this underestimation to about 10–20%. However, our methods are less accurate than previous methods for streamer glows, where the electric field is uniformly distributed in space. Finally, we apply our diagnostic methods to the measured optical signals in the second positive system of N2 and the first negative system of N2+ of sprites recorded by Armstrong et al. (1998, https://doi.org/10.1016/S1364-6826(98)00026-1) during the SPRITE's 1995 and 1996 campaigns. Key Points The spatial nonuniformity of the electric field in streamer discharges affects the estimation of the peak electric field value We present two diagnostic methods to estimate the peak electric field in streamer heads at different pressures We analyze the optical emissions measured by Armstrong et al. during SPRITE's 1995 and 1996 campaigns
ISSN:2169-897X
2169-8996
DOI:10.1029/2019JD030945