Land surface coupling in regional climate simulations of the West African monsoon

• Published in: Climate dynamics Vol. 33; no. 6; pp. 869 - 892
• Main Authors: Steiner, Allison L., Pal, Jeremy S., Rauscher, Sara A., Bell, Jason L., Diffenbaugh, Noah S., Boone, Aaron, Sloan, Lisa C., Giorgi, Filippo
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer-Verlag 01.11.2009; Springer; Springer Nature B.V
• Subjects: Atmospheric boundary layer; Atmospheric models; Climate change; Climatology; Climatology. Bioclimatology. Climate change; Earth and Environmental Science; Earth Sciences; Earth, ocean, space; Exact sciences and technology; External geophysics; Geophysics/Geodesy; Meteorology; Oceanography; Rain; Simulation; West Africa; Sahel; Africa; ASE, Africa; Land surface–atmosphere coupling; Regional climate modeling; RegCM3; African monsoon; Land surface modeling; Soil moisture; soil moisture; Precipitation intensity; atmospheric precipitation; Bias; Regional scope; Air ground interaction; climate variability; Climate models; digital simulation; Hydroclimatology; Dynamical climatology; parametrization; algorithm performance; Ground surface; Timing; monsoons
• ISSN: 0930-7575; 1432-0894
• DOI: 10.1007/s00382-009-0543-6

Coupling of the Community Land Model (CLM3) to the ICTP Regional Climate Model (RegCM3) substantially improves the simulation of mean climate over West Africa relative to an older version of RegCM3 coupled to the Biosphere Atmosphere Transfer Scheme (BATS). Two 10-year simulations (1992–2001) show that the seasonal timing and magnitude of mean monsoon precipitation more closely match observations when the new land surface scheme is implemented. Specifically, RegCM3–CLM3 improves the timing of the monsoon advance and retreat across the Guinean Coast, and reduces a positive precipitation bias in the Sahel and Northern Africa. As a result, simulated temperatures are higher, thereby reducing the negative temperature bias found in the Guinean Coast and Sahel in RegCM3–BATS. In the RegCM3–BATS simulation, warmer temperatures in northern latitudes and wetter soils near the coast create excessively strong temperature and moist static energy gradients, which shifts the African Easterly Jet further north than observed. In the RegCM3–CLM3 simulation, the migration and position of the African Easterly Jet more closely match reanalysis winds. This improvement is triggered by drier soil conditions in the RegCM3–CLM3 simulation and an increase in evapotranspiration per unit precipitation. These results indicate that atmosphere–land surface coupling has the ability to impact regional-scale circulation and precipitation in regions exhibiting strong hydroclimatic gradients.