Modeling the electric structures of two thunderstorms and their contributions to the global circuit |
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| Authors: | Stanislav S Davydenko Thomas C Marshall Maribeth Stolzenburg |
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| Institution: | aInstitute of Applied Physics, Russian Academy of Science, 46 Ulyanov Str., 603950 Nizhny Novgorod, Russia;bDepartment of Physics & Astronomy, University of Mississippi, MS, 38677, USA |
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| Abstract: | This study examines the electricity in two thunderstorms, typical for their respective locales (the Great Plains and the New Mexico mountains), by modeling them as a set of steady-state horizontal layers of external currents. The model electric sources, corresponding to the charge separation processes in the thundercloud, are embedded in an exponential conducting atmosphere. The source parameters are determined by fitting the model electric field to measured profiles. The resulting currents to the ionosphere (i.e., the Wilson current) from the two storms are 0.53 A and 0.16 A, while the calculated electrical energies of the storms are 2.3 × 1010 J and 2.8 × 109 J, respectively. The more vigorous storm is estimated to transfer 16 000 C in the global circuit during 8.5 h of its lifetime, while the weaker mountain storm transferred about 1200 C in its entire 2-h lifetime. Removal of the screening charge layer from above the updraft region in one modeled storm leads to only a small increase in the net Wilson current of less than 3%, while it provides a substantial local disturbance of the electric field. Overall, the model findings indicate that differences in the Wilson currents and electrical energies of the two storms result from differences in their internal dynamical and electrical structures as well as their geographical locations. |
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| Keywords: | Global electric circuit Wilson current Electrostatic energy Generator current Screening layer |
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