4.6 Article

Distribution of extreme rainfall events and their environmental controls in the West African Sahel and Soudan

Journal

CLIMATE DYNAMICS
Volume 59, Issue 3-4, Pages 997-1026

Publisher

SPRINGER
DOI: 10.1007/s00382-022-06171-x

Keywords

West African Sahel; Extreme rainfall; Mesoscale convective system (MCS); African easterly wave; Intertropical front; Intertropical discontinuity; Dryline; Vertical wind shear; Flooding

Funding

  1. Division of Atmospheric and Geospace Sciences (NSF) [1929074]
  2. Div Atmospheric & Geospace Sciences
  3. Directorate For Geosciences [1929074] Funding Source: National Science Foundation

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This research examines extreme rainfall events in the West African Sahel and Soudan regions. The study finds that these events occur primarily south of 14 degrees N over the Soudan, with clusters in Mali, Burkina Faso, and northern Nigeria. The associated mesoscale convective systems (MCSs) are typically generated upstream, rather than locally. The analysis shows that an increase in atmospheric moisture content prior to development plays a more significant role in extreme storm development than changes in vertical wind shear.
West African Sahel and Soudan extreme rainfall events are impactful when strong mesoscale convective systems (MCSs) produce large amounts of rainfall in short periods. NASA IMERG rainfall estimates and the ERA5 reanalysis are examined to understand where the top 100 highest 12Z-12Z 24-h rainfall totals and MCS storm genesis occur, and to assess the relative importance of environmental conditions in their generation including the influence of atmospheric moisture and vertical wind shear. Most of the top 100 events are located south of 14 degrees N over the Soudan. Events cluster over three regions, namely, Mali, Burkina Faso, and northern Nigeria. The associated MCSs are typically not locally generated, forming instead at distances greater than 100 km upstream. Composites reveal that a significant increase in atmospheric moisture content occurs prior to development, but there is no evidence of significant changes in the 600-925 hPa vertical wind shear. This indicates that changes in vertical wind shear are less influential in extreme storm development than atmospheric moisture preconditioning. The top 10 events are further evaluated. A change in these storms' direction and speed near the maximum rainfall location is common, suggesting the MCSs are reorganizing around peak rainfall intensity time. Three atmospheric conditions are associated with these events. They are (1) moisture preconditioning of the atmosphere, (2) interaction of the storm in the wake of a region of anticyclonic flow, and (3) interaction of the storm in the wake of a region of anticyclonic flow and the Sahel/tropical dryline boundary.

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