Abstract
This paper overviews observations and examines modeling issues associated with the mean state, climate variability and climate change in West Africa. The Tropical Rain Measuring Mission (TRMM) satellite allows for the first time estimates of Unconditional, Convective and Stratiform rain rates in West Africa. The 1998 estimated TRMM rates are compared to long-term observed rain rates and a merged rain data set (CMAP) during 1998. Further, the TRMM estimates are compared to the simulated rain rates from the Community Climate Model Version 3.6. The TRMM Precipitation Radar rain estimates are generally lower than either the long-term observations or the CMAP rates during 1998. Moreover, the TRMM rain estimates show a significant fraction of the total rain (convective + stratiform) is characterized as stratiform rain (30–40%). The CCM3 simulates primarily convective rain and negligible amounts of non-convective rain for West Africa. Furthermore, the TRMM high-resolution rain patterns strongly imply that rain in West Africa occurs on mesoscales in association with mesoscale convective systems (squall lines, mesoscale convective complexes and non-squall tropical clusters). We demonstrate this by briefly examining two mesoscale convective systems during May 1998 with METEOSAT data. Regional climate models may offer the best solution to understanding climate change in West Africa because of their ability to capture mesoscale systems and better their representation of orographic features. Adequate boundary conditions from Global Climate Models are still necessary for regional climate model simulations to successfully reproduce mean climate conditions and provide understanding with respect to future climate change. Observations in West Africa should be maintained or increased for monitoring climate variability and possibility of climate change in West Africa, proper initialization of numerical weather prediction models and the validation of climate models.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adler, R. E., Huffman, G. J., Bolvin, D. T., Curtis, S., and Nelkin, E. J.: 2000, ‘Tropical Rainfall Distributions Determined Using TRMM Combined with Other Satellite and Rain Gauge Information’, J. Appl. Meteorol. 39, 2007–2023.
Arkin, P. A. and Meisner, B. N.: 1987, ‘The Relationship between Large Scale Convective Rain and Cold Cloud over the Western Hemisphere during 1982–, 1984’, MWR 115, 51–74.
Bengtsson, L., Botzet, M., and Esch, M.: 1996, ‘Will Greenhouse Gas-Induced Warming over the Next 50 Years Lead to Higher Frequency and Greater Intensity of Hurricanes?’, Tellus 48A, 57–73.
Burpee, R. W.: 1972, ‘The Origin and Structure of Easterly Waves in the Lower Troposphere of North Africa’, J. Atmos. Sci. 29, 77–90.
Charney, J. G.: 1975, ‘Dynamics of Deserts and Drought in the Sahel’, Quart. J. Roy. Meteorol. Soc., 193–202.
Chong, M., Amayenc, P., Scialom, G., and Testud, J.: 1987, ‘A Tropical Squall Line Observed during the COPT 81 Experiment in West Africa. Part II: Kinematic Structure Inferred from Dual-Doppler Radar Data’, MWR 115, 670–694.
Druyan, L. M.: 1998, ‘The Role of Synoptic Systems in the Interannual Variability of Sahel Rain’, Meteorol. Atmos. Phys. 65, 55–75.
Druyan, L. M. and Fulakeza, M. B.: 2000, ‘Regional Model Simulations of African Wave Disturbances’, J. Geophys. Res. 105, 7231–7255.
Druyan, L. M. and Hall, T.: 1994, ‘Studies of African Wave Disturbances with the GISS GCM’, J. Climate 7, 261–276.
Druyan, L. M., Lonergan, P., and Eichler, P.: 1999, ‘A GCM Investigtion of GlobalWarming Impacts Relevant to Tropical Cyclone Genesis’, Int. J. Clim. 19, 607–617.
Eltahir, E. A. B. and Gong, C.: 1996, ‘Dynamics of Wet and Dry Years inWest Africa’, J. Climate 9, 1030–1042.
Folland, C. K, Palmer, T. N., and Parker, D. E.: 1986, ‘Sahel Rainfall and Worldwide Sea Surface Temperatures: 1905–, 85’, Nature 320, 602–605.
Fortune, M.: 1980, ‘Properties of African Squall Lines Inferred from Time-Lapse Satellite Imagery’, MWR 108, 153–167.
Fyfe, J. C.: 1999, ‘Climate Simulations of African Easterly Waves’, J. Climate 12, 1747–1769.
Glantz, M. H.: 1992, ‘Global Warming and Environmental Change in Sub-Saharan Africa’, Global Environ. Change 2, 183–204.
Houze, R. A: 1977, ‘Structure and Dynamics of a Tropical Squall-Line System’, MWR 105, 1540–1567.
Hulme, M.: 1996, ‘Recent Climate Change in the World's Drylands’, Geophys. Res. Lett. 23, 61–64.
Hurell, J.W. and Campbell, C. G.: 1992, Monthly Mean Global Satellite Data Sets Available in CCM History Tape Format, NCAR Technical Note, NCAR/TN-371+STR.
Jenkins, G. S.: 1997, ‘The 1988 and 1990 Summer Season Simulations for West Africa Using a Regional Climate Model’, J. Climate 10, 1255–1272.
Jenkins, G. S.: 2000, ‘TRMM Satellite Estimates of Convective Processes in Central Africa during September, October, November 1998: Implications for Elevated Atlantic Tropospheric Ozone’, Geophys. Res. Lett. 27, 1711–1714.
Kalnay, E. et al.: 1996, ‘The NCEP/NCAR 40–, Year Reanalysis Project’, Bull. Amer. Meteorol. Soc. 77, 437–490.
Kiehl, J. T., Hack, J. J., Bonan, G. B., Boville, B. A., Williamson, D. L., and Rasch, P. J.: 1998, ‘the National Center for Atmospheric Research Community Climate Model: CCM3’, J. Climate 11, 1131–1149.
King'Uyu, S. M., Ogallo, L. A., and Anyamba, E. K.: 2000, ‘Recent Trends of Minimum and Maximum Surface Temperatures over Eastern Africa’, J. Climate 13, 2876–2886.
Kummerow, C., Barnes,W., Kozu, T., Shieu, J., and Simpson, J.: 1998, ‘The Tropical Rain Measuring Mission (TRMM) Sensor Package’, J. Atmos. Ocean. Technol. 15, 809–817.
Laing, A. G. and Fritsch, J. M.: 1993, ‘Mesoscale Convective Complexes in Africa’, Mon. Wea. Rev. 121, 2254–2263.
Lamb, P. J.: 1978, ‘Large-Scale Tropical Atlantic Surface Circulation Patterns Associated with Subsaharan Weather Anomalies’, Tellus 30A, 240–251.
Lamb, P. J. and Peppler, R. A.: 1992, ‘Further Case Studies of Tropical Atlantic Surface Atmospheric and Oceanic Patterns Associated with Sub-Saharan Drought’, J. Climate 5, 476–488.
Leary, C.: 1984, ‘Precipitation Structure of the Cloud Clusters in a Tropical Easterly Wave’, MWR 112, 313–325.
Leary, C. and Houze, R. A.: 1979, ‘The Structure and Evolution of Convection in a Tropical Cluster’, J. Atmos. Sci. 36, 437–457.
Legates, D. R. and Willmott, C. J.: 1990, ‘Mean Seasonal and Spatial Variability in Gauge-Corrected Global Precipitation’, Int. J. Clim. 10, 111–127.
Mohr, K. I., Famiglietti, J. S., and Zipser, E. J.: 1999, ‘The Contribution to Tropical Rain with Respect to Convective System Type, Size and Intensity Estimated from the 85-GHz Ice-Scattering Signature’, J. Appl. Meteorol. 38, 596–606.
Mohr, K. I. and Zipser, E. J.: 1996, ‘Defining Mesoscale Convective Systems by their 85 GHz Ice Scattering Signature’, Bull. Amer. Meteorol. Soc. 77, 1179–1189.
Newell, R. E. and Kidson, J.W.: 1984, ‘African Mean Wind Changes between Sahelian Wet and Dry Periods’, J. Climatol. 4, 27–33.
Nicholson, S. E., Some, B., and Kone, B.: 2000, ‘An Analysis of Recent Rain Conditions in West Africa, Including the Rainy Seasons of the 1997 El Niño and the 1998 La Niña Years’, J. Climate 13, 2628–2640.
Peters, M. G., Tetzlaff, W., and Janssen, W.: 1989, ‘Rain Intensity of West African Squall Lines’, Ann. Geophysicae 7, 227–238.
Reed, R. J., Klinker, E., and Hollingsworth, A.: 1988, ‘The Structure and Characteristics of African Easterly Wave Disturbances as Determined from the ECMWF Operational Analysis/Forecast System’, Meteorol. Atmos. Phys. 38, 22–33.
Rowell, D. P., Folland, C. K., Maskell, K., and Ward, M. N.: 1995, ‘Variability of Summer Rain over Tropical North Africa (1906–, 92): Observations and Modelling’, Quart. J. Roy. Meteorol. Soc. 121, 669–704.
Rowell, D. P. and Milford, J.: 1993, ‘On the Generation of African Squall Lines’, J. Climate 6, 1181–1193.
Semazzi, F. H. M., Lin, N.-H., Lin, Y.-L., and Giorgi, F.: 1993, ‘A Nested Model Study of Sahelian Climate Responses to Sea-Surface Temperature Anomalies’, Geophys. Res. Lett. 20, 2897–2900.
Simpson, J., Adler, R. F., and North, G. R.: 1988, ‘A Proposed Tropical Rain Measuring Mission (TRMM) Satellite’, Bull. Amer. Meteorol. Soc. 69, 278–325.
Thompson, S. L. and Pollard, D.: 1995, ‘A Global Climate Model (GENESIS) with a Land-Surface-Transfer Scheme (LSX). Part 1: Present Climate Simulations’, J. Climate 8, 732–761.
Thorncroft, C. D. and Rowell, D. P.: 1998, ‘Interannual Variability of African Wave Activity in a GCM’, Int. J. Clim. 18, 1305–1323.
Wang, G. and Eltahir, E. A. B.: 2000a, ‘Ecosystem Dynamics and the Sahel Drought’, Geophys. Res. Lett. 27, 795–798.
Wang, G. and Eltahir, E. A. B.: 2000b, ‘Role of Vegetation Dynamics in Enhancing the Low-Frequency Variability of the Sahel Rain’, Water Resour. Res. 36, 1013–1021.
Xie, P. and Arkin, P. A.: 1997, ‘Global Precipitation: 17-Year Montly Analysis Based on Gauge Observations, Satellites Estimates and Numerical Model Outputs’, Bull. Amer. Meteorol. Soc. 78, 2539–2558.
Xue, Y. and Shukla, J.: 1993, ‘The Influence of Land Surface Properties on Sahel Climate. Part I: Desertification’, J. Climate 6, 2232–2245.
Zheng, X. and Eltahir, E. A. B.: 1998, ‘The Role of Vegetation in the Dynamics of West African Monsoons’, J. Climate 11, 2078–2096. (Received 18 September 2000; in revised form 22 June 2001)
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Jenkins, G.S., Adamou, G. & Fongang, S. The Challenges of Modeling Climate Variability and Change in West Africa. Climatic Change 52, 263–286 (2002). https://doi.org/10.1023/A:1013741803144
Issue Date:
DOI: https://doi.org/10.1023/A:1013741803144