Meteorological Conditions Conducive to the Rapid Spread of the Deadly Wildfire in Eastern Attica, Greece

On 23 July 2018, Attica, Greece, was impacted by a major wildfire that took place in a wildland–urban interface area and exhibited extreme fire behavior, characterized by a very high rate of spread. One-hundred civilian fatalities were registered, establishing this wildfire as the second-deadliest w...

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Bibliographic Details
Published in:Bulletin of the American Meteorological Society 2019-11, Vol.100 (11), p.2137-2146
Main Authors: Lagouvardos, K., Kotroni, V., Giannaros, T. M., Dafis, S.
Format: Article
Language:English
Subjects:
Casualties
Fatalities
Fire behavior
Fires
Forest & brush fires
Gusts
Heat waves
Humidity
Meteorological conditions
Mountain regions
Mountainous areas
Natural disasters
Observatories
Relative humidity
Simulation
Spatial distribution
Suburban areas
Temporal distribution
THE MAP ROOM
Topography
Topography (geology)
Weather
Westerly flow
Wildfires
Wildland-urban interface
Wind
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Summary:On 23 July 2018, Attica, Greece, was impacted by a major wildfire that took place in a wildland–urban interface area and exhibited extreme fire behavior, characterized by a very high rate of spread. One-hundred civilian fatalities were registered, establishing this wildfire as the second-deadliest weather-related natural disaster in Greece, following the heat wave of July 1987. On the day of the deadly wildfire, a very strong westerly flow was blowing for more than 10 h over Attica. Wind gusts up to 30–34 m s–1 occurred over the mountainous areas of Attica, with 20–25 m s–1 in the city of Athens and surrounding suburban areas. This strong westerly flow interacted with the local topography and acted as downslope flow over the eastern part of Attica, with temperatures rising up to 39°C and relative humidity dropping to 19% prior to the onset of the wildfire. These weather elements are widely acknowledged as the major contributing factors to extreme fire behavior. WRF-SFIRE correctly predicted the spatiotemporal distribution of the fire spread and demonstrated its utility for fire spread warning purposes.
ISSN:0003-0007
1520-0477
DOI:10.1175/BAMS-D-18-0231.1