Abstract
Motivated by poor forecasting of a deadly convective event within the Levant, the factor separation technique was used to investigate the impact of non-local versus local moisture sources on simulated precipitation and lightning rates in central and southern Israel on 25 and 26 April 2018. Both days saw unusually heavy rains, and it was hypothesized that antecedent precipitation on 25 April contributed to the development of deadly flooding late morning on the 26th, as well as strong lightning and heavy rains later the same day. Antecedent precipitation led to an increase in the precipitable water content and an overall increase in instability as measured by the Convective Available Potential Energy (CAPE). The deadly flood occurred in the area of the Tzafit river gorge (hereafter, Tzafit river), about 25 km southeast of the city of Dimona, a semi-arid region in the northeastern Negev desert. The heavy rains and strong lightning occurred throughout the Levant with local peaks in the vicinity of Jerusalem. Factor separation conducted in model simulations showed that local ground moisture sources had a large impact on the CAPE and subsequent precipitation and lightning rates in the area of Jerusalem, while non-local moisture sources enabled weak convection to occur over broad areas, with particularly strong convection in the area of the Tzafit river. The coupled impact of both moisture sources also led to localized enhanced areas of convective activity. The results suggest that forecast models for the Levant should endeavor to incorporate an accurate depiction of soil moisture to predict convective rain, especially during the typically drier spring-time season.
Highlights
Motivated by poor forecasting of a deadly convective event within the Levant, the factor separation technique was used to investigate the impact of non-local versus local moisture sources on simulated precipitation and lightning rates in central and southern Israel on 25 and 26 April 2018
The Quantitative Precipitation Estimation (QPE) analysis is based on a constant altitude plan precipitation indicator (CAPPI at height of 1 km) from a C-Band Doppler radar located at Israel Meteorological Service (IMS) headquarters in Bet Dagan (32.01 N, 34.85 E)
The most relevant aspect is the fact that the largest latent heat fluxes were found to be located to the northeast of Bet Shean and the areas immediately west of and including Jerusalem, as well as areas southward over the northern Negev desert and in the area southeast of Dimona
Summary
A tragedy occurred on 26 April 2018 when 10 students hiking in the Tzafit river were swept away by a flash flood (https://www.timesofisrael.com/nahal-tzafit-where-9students-died-in-a-flood-is-a-popular-canyon-trail/, accessed on 1 May 2021). While forecasters realized that the synoptic situation might produce floods and issued general flood warnings, high-resolution forecasts provided by the Israel Meteorological Service did not predict the intensity of rain and lightning in the Jerusalem area or the actual deadly floods that occurred in the vicinity of the Tzafit gorge basin [3]. For this reason, it was hypothesized that discrepancies in forecast model initial conditions—.
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