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Modelling a tropical-like cyclone in the Mediterranean Sea under present and warmer climate.

Authors :
Koseki, Shunya
Mooney, Priscilla A.
Cabos, William
Gaertner, Miguel Ángel
de la Vara, Alba
González-Alemán, Juan Jesus
Source :
Natural Hazards & Earth System Sciences; Jan2021, Vol. 21 Issue 1, p53-71, 19p
Publication Year :
2021

Abstract

This study focuses on a single Mediterranean hurricane (hereafter medicane), to investigate its response to global warming during the middle of the 21st century and assesses the effects of a warmer ocean and a warmer atmosphere on its development. Our investigation uses the state-of-the-art regional climate model WRF to produce the six-member, multi-physics ensembles. Results show that our model setup simulates a realistic cyclone track and the transition from an initial disturbance to a tropical-like cyclone with a deep warm core. However, the simulated transition occurs earlier than for the observed medicane. The response of the medicane to future climate change is investigated with a pseudo global warming (PGW) approach. This is the first application of the PGW framework to medicanes. The PGW approach adds a climate change delta (defined as difference between future and present climate) to WRF's boundary conditions which is obtained for all prognostic variables using the mean change in an ensemble of CMIP5 simulations. A PGW simulation where the climate change delta is added to all prognostic variables (PGW ALL) shows that most of the medicane characteristics moderately intensify, e.g. surface wind speed, uptake of water vapour, and precipitation. However, the minimum sea level pressure (SLP) is almost identical to that under present climate conditions. Two additional PGW simulations were undertaken; One simulation adds the projected change in sea surface and skin temperature only (PGW SST) while the second simulation adds the PGW changes to only atmospheric variables (PGW ATMS); i.e. we use present-day sea surface temperatures. These simulations show opposing responses of the medicane. In PGW SST , the medicane is more intense than PGW ALL as indicated by lower SLP values, the stronger surface wind, and the more intense evaporation and precipitation. In contrast, the medicane in PGW ATMS still transitions into a tropical-like cyclone with a deep warm core, but the PGW ATMS medicane weakens considerably (SLP, surface wind, and rainfall decrease). This difference can be explained by an increase in water vapour driven by the warmer ocean surface (favourable for cumulus convection). The warmer and drier atmosphere in PGW ATMS tends to inhibit condensation (unfavourable for cumulus convection). The warmer ocean and warmer atmosphere have counteracting effects which leads to only a modest enhancement of the medicane by global warming. The novel approach in this study provides new insights into the different roles of warming of the ocean and atmosphere in medicane development. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
15618633
Volume :
21
Issue :
1
Database :
Complementary Index
Journal :
Natural Hazards & Earth System Sciences
Publication Type :
Academic Journal
Accession number :
148540779
Full Text :
https://doi.org/10.5194/nhess-21-53-2021