Lightning Interferometry Uncertainty, Beam Steering Interferometry, and Evidence of Lightning Being Ignited by a Cosmic Ray Shower

We present an uncertainty analysis on correlation‐based time delay estimate, the basis for broadband lightning interferometry. A normal interferometry would yield much higher uncertainties than the theoretically predicted lower bound due to finite correlation window lengths. However, if the signals...

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Bibliographic Details
Published in:Journal of geophysical research. Atmospheres 2020-10, Vol.125 (19), p.n/a
Main Authors: Shao, Xuan‐Min, Ho, Cheng, Bowers, Gregory, Blaine, William, Dingus, Brenda
Format: Article
Language:English
Subjects:
Beam steering
Breakdown
Broadband
Centroids
Correlation
Correlation analysis
Cosmic radiation
Cosmic ray showers
Cosmic rays
Electric field
Electric fields
fast positive breakdown
Geophysics
Interferometry
Intracloud discharges
Lightning
lightning initiation
Lower bounds
Thunderstorm electric field
Thunderstorms
Time lag
Timing
Uncertainty
Uncertainty analysis
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Summary:We present an uncertainty analysis on correlation‐based time delay estimate, the basis for broadband lightning interferometry. A normal interferometry would yield much higher uncertainties than the theoretically predicted lower bound due to finite correlation window lengths. However, if the signals are aligned in time, the uncertainties approach the lower bound and can be used to indicate the interferometric uncertainties. Based on this, we introduce a beam steering interferometry technique. It first estimates a direction centroid for the lightning sources with a normal interferometry and computes the time delays among the signals. It then shifts the raw data with the time delays to align the signals roughly in time and reprocess the aligned signals. It finally pushes the reprocessed results to their correct positions, based on the time delays estimated in the first step. We apply this technique on a fast positive breakdown (FPB) process that started a normal intracloud lightning. The FPB process is shown to have a much more complex structure and development than a normal interferometry would provide. More importantly, from both interferometric and polarization analyses, the FPB appears to be ignited by a cosmic ray shower (CRS). We estimate the radio frequency strength and frequency content related to a presumed CRS in a thunderstorm electric field and find that they are in agreement with the observations. We examine the electric field effect of the CRS front and find that it could raise the field above the threshold for positive breakdown and is capable of igniting the FPB (and the lightning). Key Points An in‐depth uncertainty analysis of broadband lightning interferometry is presented A beam steering interferometry technique is introduced for improved lightning interferometric analysis Detailed analysis suggests that lightning‐initiating process was ignited by a cosmic ray shower
ISSN:2169-897X
2169-8996
DOI:10.1029/2019JD032273