Skip navigation

Site navigation:

• About
  • Overview
  • Organization
  • Staff
  • Visiting ESRL
• Contact
  • Points of Contact
  • Staff List
• Research
  • Climate-Weather Connection
  • El Niño / La Niña
  • Polar Processes
  • Boundary Layer Applications
  • Publications
  • Field Programs
  • Observing Facillities
• Data
  • Weather & Climate
  • Gridded Climate
  • Cruise Data
  • Profiler Network Data & Image Library
  • Wind Profiler Database
• Products
  • All
  • Publications
  • Map Room
  • Plotting & Analysis
  • Experimental Week-2 Forecasts
• Outreach
  • News
  • PSD Research Spotlight Articles
  • Education Resources
• Intranet

PSD Links

• Home
• Staff
• News
• Publications
• Seminars
• CIRES

PSD Publications Archive

• 2008 (42)
• 2007 (45)
• 2006 (100)
• 2005 (34)

PSD Branches

• Climate Analysis
• Water Cycle
• Weather & Climate Physics

Meetings

• R&D Scoping and Framing Workshop

• ESRL Divisions
  • Global Monitoring (GMD)
  • Physical Sciences (PSD)
  • Chemical Sciences (CSD)
  • Global Systems (GSD)

• Program Links
  • NOAA Research (OAR)
  • Climate Goal
  • Weather & Water Goal
  • Ecosystems Goal

Hoerling, M., J. Hurrell, and J. Eischeid, 2006: Detection and attribution of 20th Century northern and southern African rainfall change. J. Climate, 19, 3989-4008, doi:10.1175/JCLI3842.1.

Abstract

The spatial patterns, time history, and seasonality of African rainfall trends since 1950 are found to be deducible from the atmosphere's response to the known variations of global sea surface temperatures (SSTs). The robustness of the oceanic impact is confirmed through the diagnosis of 80 separate 50-yr climate simulations across a suite of atmospheric general circulation models. Drying over the Sahel during boreal summer is shown to be a response to warming of the South Atlantic relative to North Atlantic SST, with the ensuing anomalous interhemispheric SST contrast favoring a more southern position of the Atlantic intertropical convergence zone. Southern African drying during austral summer is shown to be a response to Indian Ocean warming, with enhanced atmospheric convection over those warm waters driving subsidence drying over Africa.

The ensemble of greenhouse-gas-forced experiments, conducted as part of the Fourth Assessment Report of the Intergovernmental Panel on Climate Change, fails to simulate the pattern or amplitude of the twentieth-century African drying, indicating that the drought conditions were likely of natural origin. For the period 2000-49, the ensemble mean of the forced experiments yields a wet signal over the Sahel and a dry signal over southern Africa. These rainfall changes are physically consistent with a projected warming of the North Atlantic Ocean compared with the South Atlantic Ocean, and a further warming of the Indian Ocean. However, considerable spread exists among the individual members of the multimodel ensemble.