Sensitivity of the African and Asian Monsoons to Mid-Holocene Insolation and Data-Inferred Surface Changes

Delphine Texier Laboratoire des Sciences du Climat et de l’Environnement/DSM, Unité Mixte de Recherche CEA-CNRS, Gif-sur-Yvette, France

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Nathalie de Noblet Laboratoire des Sciences du Climat et de l’Environnement/DSM, Unité Mixte de Recherche CEA-CNRS, Gif-sur-Yvette, France

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Pascale Braconnot Laboratoire des Sciences du Climat et de l’Environnement/DSM, Unité Mixte de Recherche CEA-CNRS, Gif-sur-Yvette, France

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Abstract

Orbital forcing alone is not sufficient to explain the massive northward penetration of monsoon rains in Africa shown by data during the mid-Holocene (6000 yr ago). Feedbacks associated with changes in SSTs and land surface cover may be necessary to produce a sufficient increase in the monsoon. A step toward a better understanding of the respective role of oceans and land surfaces is to design sensitivity studies with prescribed forcings, inferred from observations. In the first study, SSTs are lowered in the upwelling regions offshore of West Africa and Somalia, and increased in the Bay of Bengal and South China Sea. In the second simulation, the modern Sahara desert is replaced by a combination of xerophytic woods/scrub and grassland.

In both cases the amount of water vapor advected from oceanic sources is increased north of 10°N in Africa in response to the increased land–sea temperature contrast, thereby enhancing rainfall. But the magnitude of the simulated changes is much larger when land surface is modified. The lower albedo (compared to desert) increases the amount of radiation absorbed by the surface in northern Africa and warms it up, and the larger roughness length increases both the sensible and latent heat fluxes. Moreover, vegetation is more efficient in recycling water than a bare soil, and the release of latent heat in the atmosphere increases convection, which in turn helps maintain the onshore oceanic advection. The monsoon season is then lengthened by 1–2 months compared to all other simulations reported in the paper.

The intensity of monsoon rains is also modified in Asia in both sensitivity experiments. Warmer SSTs in the Bay of Bengal and South China Sea reduce the land–sea contrast and therefore the inland penetration of monsoon rains. Changes in the position of the main large-scale convergence area in the case of a green Sahara enhances the precipitation in India.

Changes are also discussed in terms of atmospheric circulation. For example, the tropical easterly jet at 200 hPa is increased in all 6-kyr-BP simulations, but only over Africa in the case of a prescribed green Sahara. The African easterly jet has been pushed at higher altitude in response to all prescribed forcings; wind speed is then reduced at 700 hPa but increased at higher altitude.

* Current affiliation: Department of Meteorology, University of Reading, Reading, United Kingdom.

Corresponding author address: Dr. Nathalie de Noblet, Laboratoire des Sciences du Climat et de l’Environnement/DSM, Unité Mixte de Recherche CEA-CNRS, Bâtiment 709/Orme des Merisiers, 91191 Gif-sur-Yvette Cedex, France.

Abstract

Orbital forcing alone is not sufficient to explain the massive northward penetration of monsoon rains in Africa shown by data during the mid-Holocene (6000 yr ago). Feedbacks associated with changes in SSTs and land surface cover may be necessary to produce a sufficient increase in the monsoon. A step toward a better understanding of the respective role of oceans and land surfaces is to design sensitivity studies with prescribed forcings, inferred from observations. In the first study, SSTs are lowered in the upwelling regions offshore of West Africa and Somalia, and increased in the Bay of Bengal and South China Sea. In the second simulation, the modern Sahara desert is replaced by a combination of xerophytic woods/scrub and grassland.

In both cases the amount of water vapor advected from oceanic sources is increased north of 10°N in Africa in response to the increased land–sea temperature contrast, thereby enhancing rainfall. But the magnitude of the simulated changes is much larger when land surface is modified. The lower albedo (compared to desert) increases the amount of radiation absorbed by the surface in northern Africa and warms it up, and the larger roughness length increases both the sensible and latent heat fluxes. Moreover, vegetation is more efficient in recycling water than a bare soil, and the release of latent heat in the atmosphere increases convection, which in turn helps maintain the onshore oceanic advection. The monsoon season is then lengthened by 1–2 months compared to all other simulations reported in the paper.

The intensity of monsoon rains is also modified in Asia in both sensitivity experiments. Warmer SSTs in the Bay of Bengal and South China Sea reduce the land–sea contrast and therefore the inland penetration of monsoon rains. Changes in the position of the main large-scale convergence area in the case of a green Sahara enhances the precipitation in India.

Changes are also discussed in terms of atmospheric circulation. For example, the tropical easterly jet at 200 hPa is increased in all 6-kyr-BP simulations, but only over Africa in the case of a prescribed green Sahara. The African easterly jet has been pushed at higher altitude in response to all prescribed forcings; wind speed is then reduced at 700 hPa but increased at higher altitude.

* Current affiliation: Department of Meteorology, University of Reading, Reading, United Kingdom.

Corresponding author address: Dr. Nathalie de Noblet, Laboratoire des Sciences du Climat et de l’Environnement/DSM, Unité Mixte de Recherche CEA-CNRS, Bâtiment 709/Orme des Merisiers, 91191 Gif-sur-Yvette Cedex, France.

Save
  • Berger, A., 1978: Long-term variation of daily insolation and quaternary climatic changes. J. Atmos. Sci.,35, 2362–2367.

  • Bröstrom, A., M. Coe, S. P. Harrison, R. Gallimore, J. E. Kutzbach, J. Foley, I. C. Prentice, and P. Behling, 1998: Land-surface processes and paleomonsoons in northern Africa. Geophys. Res. Lett.,25 (19), 3615–3618.

  • Cadet, D. L., and G. Reverdin, 1981: Water vapour transport over the Indian Ocean during the summer 1975. Tellus,33, 476–487.

  • ——, and S. H. Houston, 1984: Precipitable water over Africa and the Eastern/Central Atlantic Ocean during the 1979 summer. J. Meteor. Soc. Japan,62, 761–774.

  • Charney, J. G., 1975: Dynamics of deserts and drought in the Sahel. Quart. J. Roy. Meteor. Soc.,101 (428), 193–202.

  • Claussen, M., and V. Gayler, 1997: The greening of the Sahara during the mid-Holocene: Results of an interactive atmosphere-biome model. Global Ecol. Biogeogr. Lett.,6, 369–377.

  • Coe, M. T., and G. B. Bonan, 1997: Feedbacks between climate and surface water in northern Africa during the middle Holocene. J. Geophys. Res.,102 (D10), 11 087–11 101.

  • COHMAP, 1988: Climatic changes of the last 18,000 years: Observations and model simulations. Science,241, 1043–1052.

  • Dennett, M. D., J. Elston, and J. A. Rodgers, 1985: A reappraised rainfall trend in the Sahel. J. Climatol.,5, 353–361.

  • de Noblet, N., P. Braconnot, S. Joussaume, and V. Masson, 1996a: Sensitivity of simulated Asian and African summer monsoons to orbital induced variations in insolation 126, 115 and 6 kBP. Climate Dyn.,12, 589–603.

  • ——, I. C. Prentice, S. Joussaume, D. Texier, A. Botta, and A. Haxeltine, 1996b: Possible role of atmosphere-biosphere interactions in triggering the last glaciation. Geophys. Res. Lett.,23 (22), 3191–3194.

  • Diedhiou, A., and J. F. Mahfouf, 1996: Comparative influence of land and sea surfaces on the Sahelian drought: A numerical study. Ann. Geofis.,14, 115–130.

  • Druyan, L. M, and R. D. Koster, 1989: Sources of Sahel precipitation for simulated drought and rainy seasons. J. Climate,2, 1438–1446.

  • Ducoudré, N., K. Laval, and A. Perrier, 1993: SECHIBA, a new set of parameterizations of the hydrologic exchanges at the land–atmosphere Interface within the LMD atmospheric general circulation model. J. Climate,6, 248–273.

  • Dümenil, L., and H.-S. Bauer, 1998: The tropical easterly jet in a hierarchy of GCMs and in reanalyses. Max Planck Institute for Meteorology, Rep. ISSN 0937-1060, 45 pp. [Available from Max-Planck-Institut für Meteorologie, Bundesstrasse 55, 20146 Hamburg, Germany.].

  • Duplessy, J. C., 1982: Glacial to interglacial contrasts in the northern Indian Ocean. Nature,295, 494–498.

  • Fouquart, Y., and B. Bonnel, 1980: Computations of solar heating of the Earth’s atmosphere: A new parameterization. Beitr. Phys. Atmos.,53, 35–62.

  • Gadgil, S., A. Guruprasad, D. R. Sikka, and D. K. Paul, 1992: Intraseasonal variation and simulation of the Indian summer monsoon. Simulation of interannual and intraseasonal monsoon variability. Rep. WCRP-68, World Meteorological Organization, 185 pp.

  • Hall, N. M. J., and P. J. Valdes, 1997: A GCM simulation of the climate 6000 years ago. J. Climate,10, 3–17.

  • Harzallah, A., and R. Sadourny, 1995: Internal versus SST-forced atmospheric variability as simulated by an atmospheric general circulation model. J. Climate,8, 474–498.

  • Hewitt, C. D., and J. F. B. Mitchell, 1996: GCM simulations of the climate of 6 kyr BP: Mean changes and interdecadal variability. J. Climate,9, 3505–3529.

  • ——, and ——, 1998: A fully coupled GCM simulation of the mid Holocene. Geophys. Res. Lett.,25, 361–364.

  • Jarvis, D. I., 1993: Pollen evidence of changing Holocene monsoon climate in Sichuan Province, China. Quat. Res.,39, 325–337.

  • Jolly, D., and Coauthors, 1998: Biome reconstruction from pollen and plant macrofossil data for Africa and the Arabian peninsula at 0 and 6 ka. J. Biogeogr.,25, 1007–1028.

  • Joussaume, S., and K. Taylor, 1995: Status of the Paleoclimate Modelling Intercomparison Project (PMIP). Proc. First Int. AMIP Scientific Conf., Monterey, CA, PCMDI, 425–430.

  • ——, and P. Braconnot, 1997: Sensitivity of paleoclimate simulation results to season definition. J. Geophys. Res.,102 (D2), 1943–1956.

  • ——, R. Sadourny, and C. Vignal, 1986: Origin of precipitating water in a numerical simulation of the July climate. Ocean–Air Interact.,1, 43–56.

  • ——, and Coauthors, 1999: Monsoon changes/regional climates for 6000 years ago: Results of 18 simulations from the Palaeoclimate Modelling Intercomparison Project (PMIP). Geophys. Res. Lett.,26, 859–862.

  • Ju, J., and J. Slingo, 1995: The Asian summer monsoon and ENSO. Quart. J. Roy. Meteor. Soc.,121, 1133–1168.

  • Kallel, N., M. Paterne, L. Labeyrie, J.-C. Duplessy, and M. Arnold, 1997: Temperature and salinity records of the Tyrrhenian Sea during the last 18,000 years. Palaeogeogr. Palaeoclimatol. Palaeoecol.,135, 97–108.

  • Kuo, H. L., 1965: On the formation and intensification of tropical cyclones through latent heat release by cumulus convection. J. Atmos. Sci.,22, 40–63.

  • Kutzbach, J. E., and P. J. Guetter, 1986: The influence of changing orbital parameters and surface boundary conditions on climate simulations for the past 18 000 years. J. Atmos. Sci.,43, 1726–1759.

  • ——, and R. G. Gallimore, 1988: Sensitivity of a coupled atmosphere/mixed layer ocean model to changes in orbital forcing at 9000 years BP. J. Geophys. Res.,93 (D1), 803–821.

  • ——, and Z. Liu, 1997: Response of the African monsoon to orbital forcing and ocean feedbacks in the middle Holocene. Science,278, 440–443.

  • ——, P. J. Guetter, P. J. Behling, and R. Selin, 1993: Simulated climatic changes: Results of the COHMAP climate-model experiments. Global Climates Since the Last Glacial Maximum, H. E. Wright Jr. et al., Eds., University of Minnesota Press, 24–93.

  • ——, G. Bonan, J. Foley, and S. P. Harrison, 1996: Vegetation and soil feedbacks on the response of the African monsoon to orbital forcing in the early to middle Holocene. Nature,384, 623–626.

  • Lamb, P. J., and R. A. Peppler, 1992: Further case studies of tropical Atlantic surface atmospheric and oceanic patterns associated with sub-Saharan drought. J. Climate,5, 476–488.

  • Legates, D. R., and C. J. Willmott, 1990: Mean seasonal and spatial variability in gauge-corrected precipitation. Int. J. Climatol.,10, 111–127.

  • Liao, X., F. A. Street-Perrott, and J. F. B. Mitchell, 1994: GCM experiments with different cloud parameterization: Comparisons with palaeoclimatic reconstructions for 6000 years BP. Palaeoclim. Data Modell.,1, 99–123.

  • Manabe, S., and R. F. Strickler, 1964: Thermal equilibrium of the atmosphere with a convective adjustment. J. Atmos. Sci.,21, 361–385.

  • Masson, V., and S. Joussaume, 1997: Energetics of mid-Holocene atmospheric circulation change in boreal summer from large-scale to monsoon areas: A study with two versions of the LMD AGCM. J. Climate,10, 2888–2903.

  • Mitchell, J. F. B., N. S. Grahame, and K. J. Needham, 1988: Climate simulations for 9000 years Before Present: Seasonal variations and effects of the Laurentide Ice Sheet. J. Geophys. Res.,93 (D7), 8283–8303.

  • Morcrette, J. J., 1991: Radiation and cloud radiative properties in the ECMWF operational weather forecast model. J. Geophys. Res.,96, 9121–9132.

  • Morley, J. J., and B. A. Dworetzky, 1993: Holocene temperatures patterns in the south Atlantic, Southern, and Pacific Oceans. Global Climates Since the Last Glacial Maximum, H. E. Wright Jr. et al., Eds., University of Minnesota Press, 194–220.

  • Palmer, T. N., 1986: Influence of the Atlantic, Pacific and Indian oceans on Sahel rainfall. Nature,322, 251–253.

  • Petit-Maire, N., and N. Page, 1992: Remotes sensing and past climatic changes in tropical deserts: Example of the Sahara. Episodes,15, 113–117.

  • Prell, W. L., 1984a: A response to changing solar radiation. Milankowitch and Climate, Part I, A. Berger et al., Eds., D. Reidel, 349–366.

  • ——, 1984b: Variation of monsoonal upwelling: A response to changing solar radiation. Climate Processes and Climate Sensitivity, J. Hansen and T. Takahashi, Eds., American Geophysical Union, 48–57.

  • ——, and E. van Campo, 1986: Coherent response of Arabian Sea upwelling and pollen transport to the late quaternary monsoonal winds. Nature,323, 526–528.

  • ——, and R. E. Marvil, 1990: Variability in upwelling fields in the northwestern Indian Ocean; 2. Data-model comparison at 9000 years BP. Paleoceanography,5 (3), 447–457.

  • Prentice, I. C., W. Cramer, S. P. Harrison, R. Leemans, R. A. Monserud, and A. M. Solomon, 1992: A global biome model based on plant physiology and dominance, soil properties and climate. J. Biogeogr.,19, 117–134.

  • Raynaud, D., J. Jouzel, J. Barnola, J. Chappelaz, R. Delmas, and C. Lorius, 1993: The ice record of greenhouse gases. Science,259, 926–934.

  • Reynolds, R. W., 1988: Real-time global sea surface temperature analysis. J. Climate,1, 75–86.

  • Roberts, N., and H. E. Wright Jr., 1993: Vegetational, lake-level, and climatic history of the near east and southwest Asia. Global Climates Since the Last Glacial Maximum, H. E. Wright Jr. et al., Eds., University of Minnesota Press, 194–220.

  • Ruddiman, W. F., and A. C. Mix, 1993: The north and equatorial Atlantic at 9000 and 6000 yr BP. Global Climates Since the Last Glacial Maximum, H. E. Wright Jr. et al., Eds., University of Minnesota Press, 194–220.

  • Sadourny, R., and K. Laval, 1984: January and July performance of the LMD general circulation model. New Perspectives in Climate Modelling, A. Berger and C. Nicolis, Eds., Elsevier, 173–198.

  • Schulz, H., 1995: Sea-surface temperature 9,000 years BP—Consequences of the early Holocene isolation maximum. Ph.D. thesis, University of Kiel.

  • Semazzi, F. H. M., B. Burns, N. H. Lin, and J. K. Schemm, 1996: A GCM study of the teleconnections between the continental climate of Africa and global sea surface temperature anomalies. J. Climate,9, 2480–2496.

  • Street, F. A., and A. T. Grove, 1976: Environmental and climatic implications of late quaternary lake-level fluctuations in Africa. Nature,261, 385–390.

  • Street-Perrott, F. A., and R. A. Perrott, 1993: Holocene vegetation, lake levels and climate of Africa. Global Climates Since the Last Glacial Maximum, H. E. Wright Jr. et al., Eds., University of Minnesota Press, 318–356.

  • ——, J. F. B. Mitchell, D. S. Marchand, and J. S. Brunner, 1990: Milankovitch and albedo forcing of the tropical monsoons: A comparison of geological evidence and numerical simulations for 9000 yBP. Trans. Roy. Soc. Edinburgh: Earth Sci.,81, 407–427.

  • Sud, Y. C., J. Shukla, and Y. Mintz, 1988: Influence of land-surface roughness on atmospheric circulation and precipitation: A sensitivity study with a general circulation model. J. Appl. Meteor.,27, 1036–1054.

  • Swain, A. M., J. E. Kutzbach, and S. Hastenrath, 1983: Estimates of Holocene precipitation for Rajasthan, India, based on pollen and lake-level data. Quat. Res.,19, 1–17.

  • Texier, D., and Coauthors, 1997: Quantifying the role of biosphere-atmosphere feedbacks in climate change: A coupled model simulation for 6000 yr BP and comparison with palaeodata for northern Eurasia and northern Africa. Climate Dyn.,13, 865–882.

  • Van Campo, E., J. C. Duplessy, and M. Rossignol-Strick, 1982: Climate conditions deduced from a 150-kyr oxigen isotope-pollen record from the Arabian sea. Nature,296, 56–59.

  • Wang, T.-A., Y.-L. Lin, H. F. M. Semazzi, and G. S. Janowitz, 1996:Response of a stably stratified atmosphere to large-scale diabatic forcing with applications to wind patterns in Brazil and the Sahel. J. Geophys. Res.,101 (D3), 7049–7073.

  • Winkler, M. G., and P. K. Wang, 1993: The late-quaternary vegetation and climate of China. Global Climates Since the Last Glacial Maximum, H. E. Wright Jr. et al., Eds., University of Minnesota Press, 221–264.

  • Xue, Y., and J. Shukla, 1993: A numerical experiment to study the influence of changes in the land properties on Sahel climate. Part I: Desertification. J. Climate,6, 2232–2245.

  • ——, and ——, 1996: The influence of land surface properties on Sahel climate. Part II: Afforestation. J. Climate,9, 3260–3275.

  • Yu, G., and S. P. Harrison, 1996: An evaluation of the simulated water balance of Eurasia and northern Africa at 6000 yr BP using lake status data. Climate Dyn.,12 (11), 723–735.

  • ——, I. C. Prentice, S. P. Harrison, and X. Sun, 1998: Pollen-based biome reconstructions for China at 0 and 6ka. J. Biogeogr.,25, 1055–1070.

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