<p><span><span>The north-western Mediterranean basin often experiences thunderstorms with heavy precipitation, strong wind, lightning activity </span><span>and sometimes waterspouts/tornadoes</span><span>. One of the objectives of the EXAEDRE (EXploiting new Atmospheric Electricity Data for Research and the Environment) project is to better monitor the thunderstorms in this area through a better understanding of the physical processes that drive the dynamics, the microphysics and the electrical activity of the convective systems. </span><span>C</span><span>haracteristics </span><span>of the electrical activity </span><span>such as flash rate, charge layer </span><span>distribution</span><span> or flash polarity are good proxies for thunderstorm monitoring and good evidences of the storm severity.</span></span></p><p><span>The 29<sup>th</sup> October 2018, an intense trough developed over Mediterranean Sea between Balearic Islands and Corsica. This storm, called ADRIAN, produced several hazards (heavy precipitation, strong winds, intense lightning activity and hailstorm) in Corsica. Two tornadoes and one waterspout were observed in the morning at Porto Vecchio (EF2 tornado and waterspout) and Aleria (EF1 tornado), causing significant damages.</span></p><p><span>In this study, we take a look at electrical and microphysical characteristics of the two tornadic cells. </span><span>For that, observations of the LMA (Lightning Mapping Array) SAETTA network, deployed in Corsica, are used to document in 3D the total lightning activity. Complementary 2D lightning observations recorded by the French national lightning detection network METEORAGE are also investigated. We also use weather radar data from the M&#233;t&#233;o France network. A clustering algorithm is applied on both the lightning and radar data to identify and track the cells to document the evolution of several lightning-related and microphysical characteristics during the lifetime of each cell. We also applied a new method based on lightning leader velocity to automatically infer the vertical and horizontal structure of the electrical charge regions within each electrical cell.</span></p><p><span><span>We first introduce the different observations and methodologies applied here. Then the main electrical properties </span></span><span><span>of the tornadic cells </span></span><span><span>(e.g. flash duration, vertical flash extension, charge layer, flash type and polarity) </span></span><span><span>and microphysical characteristics </span></span><span><span>as well as their temporal evolution are presented. </span></span><span><span>Overall, t</span></span><span><span>h</span></span><span><span>e </span></span><span><span>studied electrical cells</span></span><span><span> produced few cloud-to-ground lightning </span></span><span><span>flashes</span></span><span> </span><span><span>p</span></span><span><span>redominantly of negative polarity. </span></span><span><span>The peaks of electrical activity occurred when tornadoes </span></span><span><span>hit the land and </span></span><span><span>these storms presented </span></span><span><span>all </span></span><span><span>an anomalous charge structure. </span></span></p>
<p>The aim of this study is to enhance our understanding about the microphysical structure of convective cloud systems and its relationships to the ambient electrical field, and to assess the capability of a model to capture the cloud electrical properties. This study relies on the EXAEDRE (EXploiting new Atmospheric Electricity Data for Research and the Environment) aircraft campaign that took place from 13 September to 8 October 2018 in Corsica Island. Eight electrified convective systems were successfully sampled during the campaign by the French Falcon 20 aircraft (e.g. RASTA Doppler cloud radar, microphysics probes, electric field mills) and ground-based platforms (Lightning Mapping Array network, M&#233;t&#233;orage operational lightning locating system and M&#233;t&#233;o-France weather radars). In this study, a multi-cell thunderstorm which developed over the complex topography of Corsica Island on 17 September 2018 was selected to investigate and to understand the physical processes linking lightning occurrence, electrification efficiency, cloud microphysics and dynamics. The detailed analysis results using the unprecedented airborne and ground-based dataset and their comparison to the numerical simulation results with a horizontal grid spacing of 1 km comprising the explicit electrical scheme CELLS (Cloud Electrification and Lightning Scheme) implemented in the cloud resolving model Meso-NH has been conducted. The key results will be presented at the conference.</p>
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