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Mountain related supercell events analysis using radar observations and the COSMO model pre-convective environments in the Western Carpathians
- 1.0510865 - ÚFA 2020 DE eng A - Abstract
Kvak, Róbert - Zacharov, Petr, jr. - Kašpar, Marek
Mountain related supercell events analysis using radar observations and the COSMO model pre-convective environments in the Western Carpathians.
10th European Conference on Severe Storms (ECSS 2019). Münchene: European Severe Storms Laboratory e.V. (ESSL), 2019.
[European Conference on Severe Storms (ECSS) /10./. 04.11.2019-08.11.2019, Kraków]
Institutional support: RVO:68378289
Keywords : thunderstorm * supercell events * convection storm * mountain meteolorogy * numerical weather prediction * reanalysis
OECD category: Meteorology and atmospheric sciences
https://meetingorganizer.copernicus.org/ECSS2019/ECSS2019-67.pdf
Currently, it is a matter of great concern to understand a spatial activity of deep atmospheric convection within
mountains in mid-latitudes. The process of clustering thunderstorms into long-lived systems or rotating supercells
over complex terrain and its vicinity has received a little research attention to date. The aim of this study is precisely analyze a bond between supercells occurrence – convective environment – terrain characteristics, searching
for cases, in which mountains can enhance the potential for supercell’s formation in their close proximity. The area
of interest covers the geomorphological unit of the Western Carpathians within the domain of Slovak weather radar
network range (300 x 500 km). Digital elevation model is described by the specific morphometric characteristics
(e.g. altitude). The presence of supercells in the mountain areas in warm parts of the years 2010 – 2018, primarily
since 2015, is studied. Multiple events are chosen thanks to Slovak radar detection network, and complete observational reports (SHMI). Based on ERA-interim reanalysis as initial and boundary conditions, basic fields of
physical quantities (e.g. dew point) and pre-supercell indicators (e.g. wind shear) are performed using NWP model
COSMO during the events. COSMO is the non-hydrostatic compressible model which we use with the 2.8 km
grid-spacing and 50 atmospheric model levels up to a height of 20 km. The products of simulations (starting time
at 00 UTC) are statistically compared with spatial changes in the maximal vertical reflectivity of radar detection
and with basic morphometric characteristics of the topography using digital earth model with appropriate spatial
resolution. In addition, maximal vertical reflectivity is simulated to verify the COSMO‘s capability of forecasting
severe convection storm activity in a mountainous region.
Permanent Link: http://hdl.handle.net/11104/0301236
Number of the records: 1