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Sensitivity of simulated Asian and African summer monsoons to orbitally induced variations in insolation 126, 115 and 6 kBP

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Abstract

We have conducted four numerical experiments with an atmospheric general circulation model (AGCM) to investigate the sensitivity of Asian and African monsoons to small changes (−5 to +12%), with respect to present-day, in incoming solar radiation at the top of the atmosphere. We show that, during the mid-Holocene (6 kBP where kBP means thousands of years before present-day) and the last interglacial (126 kBP), the Northern Hemisphere seasonal contrast was increased, with warmer summers and colder winters. At the time of glacial inception (115 kBP) however, summers were cooler and winters milder. As a consequence, Asia and tropical North Africa experienced stronger (weaker) summer monsoons 6 and 126 kBP (115 kBP), in agreement with previous numerical studies. This present study shows that summer warming/cooling of Eurasia and North Africa induced a shift of the main low-level convergence cell along a northwest/southeast transect. When land was warmer (during the summer months 6 and 126 kBP), the monsoon winds converged further inland bringing more moisture into northern India, western China and the southern Sahara. The southern tips of India, Indochina and southeastern China, as well as equatorial North Africa became drier. When land was cooler (during the summer 115 kBP), the main convergence zone was located over the west Pacific and the wet (dry) areas were those that were dry (wet) 6 and 126 kBP. The location and intensity of the simulated precipitation maxima were therefore very sensitive to changes in insolation. However the total amount of monsoon rain in Asia as well as in Africa remained remarkably stable through the time periods studied. These simulated migrations of convective activities were accompanied by changes in the nature of precipitation events: increased monsoon rains in these experiments were always associated with more high precipitation events (> 5 mm day −1), and fewer light showers (≤1 mm day). Rainy days with rates between 1 and 5 mm day−1 were almost unchanged.

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Authors and Affiliations

  1. Laboratoire de Modélisation du Climat et de l'Environnement, C.E. Saclay, France

    Nathalie de Noblet, Pascale Braconnot, Sylvie Joussaume & Valérie Masson

  2. Laboratoire d'Océanographie Dynamique et de Climatologie, CNRS/ORSTOM/UPMC, Paris, France

    Sylvie Joussaume

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  1. Nathalie de Noblet
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  2. Pascale Braconnot
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  3. Sylvie Joussaume
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  4. Valérie Masson
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de Noblet, N., Braconnot, P., Joussaume, S. et al. Sensitivity of simulated Asian and African summer monsoons to orbitally induced variations in insolation 126, 115 and 6 kBP. Climate Dynamics 12, 589–603 (1996). https://doi.org/10.1007/BF00216268

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