Abstract
A heavy hailstorm developed over Istanbul on July 27, 2017 and inflicted substantial damage on hundreds of buildings and thousands of vehicles. Weather forecast models largely failed to predict this event. In this study, we investigate the performance of the Weather Research and Forecasting (WRF) model in simulating this particular hailstorm through a sensitivity experiment and the development of the supercell using one of the simulations that produce comparatively better performance in reproducing the hail event. A total of 24 sensitivity simulations involving different microphysics (Milbrandt, NSSL2, WDM6, and Goddard), cumulus (New SAS, New Tiedtke, and Kain Fritsch), and planetary boundary layer (PBL) (YSU, and MYNN2) schemes are conducted. The sensitivity simulations produce different rainfall patterns in the innermost domain, and the major differences in the spatial patterns arise because of the cumulus parameterizations, while microphysics schemes seem to influence the magnitude of the precipitation. All simulations reproduce thunderstorms resulting in substantial precipitation over Istanbul, however, only those with Kain Fritsch cumulus scheme are able to generate hail over the city. The simulation with YSU PBL, Kain Fritsch cumulus and Milbrandt microphysics schemes (YKM) produces hail paths that best match the observations. The YKM simulation reproduces a near typical structure of a storm cloud with an anvil shape, an overshooting top reaching about 12 km altitude, and a weak echo region in the front part. The model is able to simulate strong convection supported by the low-level convergence and low-to-mid-tropospheric wind shear that produces an updraft near the center of the storm where warm and moist air rises rapidly upward at velocities up to 28 m/s. The simulation yields 21.5 mm precipitation and 3.9 mm hail during the first 15 min when the storm starts to affect the city center. Our analysis suggests that the WRF model has high potential to realistically simulate the hailstorms if physics options are reasonably selected.
Original language | English |
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Article number | 105373 |
Journal | Atmospheric Research |
Volume | 250 |
DOIs | |
Publication status | Published - Mar 2021 |
Bibliographical note
Publisher Copyright:© 2020 Elsevier B.V.
Funding
This publication has been produced benefiting from the 2232 International Fellowship for Outstanding Researchers Program of TÜBİTAK [Project No: 118C329 ]. However, the entire responsibility of the publication/paper belongs to the owner of the publication/paper. The financial support received from TÜBİTAK does not mean that the content of the publication is approved in a scientific sense by TÜBİTAK. Computing resources used in this work were provided by the National Center for High Performance Computing of Turkey (UHeM) [grant number 1007482020 ]. This publication has been produced benefiting from the 2232 International Fellowship for Outstanding Researchers Program of T?B?TAK [Project No: 118C329]. However, the entire responsibility of the publication/paper belongs to the owner of the publication/paper. The financial support received from T?B?TAK does not mean that the content of the publication is approved in a scientific sense by T?B?TAK. Computing resources used in this work were provided by the National Center for High Performance Computing of Turkey (UHeM) [grant number 1007482020].
Funders | Funder number |
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National Center for High Performance Computing of Turkey | |
TÜBİTAK | 118C329 |
Ulusal Yüksek Başarımlı Hesaplama Merkezi, Istanbul Teknik Üniversitesi | 1007482020 |
Keywords
- Different physics parameterizations
- Hail
- Natural hazards
- Sensitivity simulations
- Severe convective storm
- WRF