Atmospheric conditions leading to an exceptional fatal flash flood in the Negev Desert, Israel
Open Access
- 25 May 2021
- journal article
- research article
- Published by Copernicus GmbH in Natural Hazards and Earth System Sciences
- Vol. 21 (5), 1583-1597
- https://doi.org/10.5194/nhess-21-1583-2021
Abstract
The study deals with an intense rainstorm that hit the Middle East between 24 and 27 April 2018 and took the lives of 13 people, 10 of them on 26 April during the deadliest flash flood in Tzafit Basin (31.0∘ N, 35.3∘ E), the Negev Desert. The rainfall observed in the southern Negev was comparable to the long-term annual rainfall there, with intensities exceeding a 75-year return period. The timing of the storm, at the end of the rainy season when rain is relatively rare and spotty, raises the question of what the atmospheric conditions were that made this rainstorm one of the most severe late-spring storms. The synoptic background was an upper-level cut-off low that formed south of a blocking high which developed over eastern Europe. The cut-off low entered the Levant near 30∘ N latitude, slowed its movement from ∼10 to −1 and so extended the duration of the storm over the region. The dynamic potential of the cut-off low, as estimated by its curvature vorticity, was the largest among the 12 late-spring rainstorms that occurred during the last 33 years. The lower levels were dominated by a cyclone centred over north-western Saudi Arabia, producing north-westerly winds that advected moist air from the Mediterranean inland. During the approach of the storm, the atmosphere over Israel became unstable, with instability indices reaching values favourable for thunderstorms (e.g. CAPE>1500 J kg−1, LI=4 K) and the precipitable water reaching 30 mm. The latter is explained by lower-level moisture advection from the Mediterranean and an additional contribution of mid-level moist air transport entering the region from the east. Three major rain centres were active over Israel during 26 April, only one of them was orographic and the other two were triggered by instability and mesoscale cyclonic centres. The build-up of the instability is explained by a negative upper-level temperature anomaly over the region caused by a northerly flow east of a blocking high that dominated eastern Europe and ground warming during several hours under clear skies. The intensity of this storm is attributed to an amplification of a mid-latitude disturbance which produced a cut-off low with its implied high relative vorticity, low upper-level temperatures and slow progression. All these, combined with the contribution of moisture supply, led to intense moist convection that prevailed over the region for 3 successive days.Funding Information
- Israel Science Foundation (1123/17)
This publication has 51 references indexed in Scilit:
- Overview of modern atmospheric patterns controlling rainfall and floods into the Dead Sea: Implications for the lake's sedimentology and paleohydrologyQuaternary Science Reviews, 2019
- A Review of People’s Behavior in and around FloodwaterWeather, Climate, and Society, 2015
- Flash flood–producing rainstorms over the Dead Sea: A reviewPublished by Geological Society of America ,2006
- Identification of flood producing atmospheric circulation patternsJournal of Hydrology, 2005
- Semi‐objective classification for daily synoptic systems: application to the eastern Mediterranean climate changeInternational Journal of Climatology, 2004
- A severe autumn storm over the middle-east: synoptic and mesoscale convection analysisTheoretical and Applied Climatology, 2001
- Winter Thunderstorms in Israel: A Study with Lightning Location Systems and Weather RadarMonthly Weather Review, 2001
- Predicting the Movement of Mesoscale Convective ComplexesWeather and Forecasting, 1996
- The Sharav Cyclone: Observations and some theoretical considerationsJournal of Geophysical Research: Atmospheres, 1989
- Great floods in Sinai Peninsula, Palestine, Syria and the Syrian Desert, and the influence of the red sea on their formationQuarterly Journal of the Royal Meteorological Society, 1938