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. 2015 Jul 14;112(28):8543-8.
doi: 10.1073/pnas.1417655112. Epub 2015 Jun 29.

West African monsoon dynamics inferred from abrupt fluctuations of Lake Mega-Chad

Affiliations

West African monsoon dynamics inferred from abrupt fluctuations of Lake Mega-Chad

Simon J Armitage et al. Proc Natl Acad Sci U S A. .

Abstract

From the deglacial period to the mid-Holocene, North Africa was characterized by much wetter conditions than today. The broad timing of this period, termed the African Humid Period, is well known. However, the rapidity of the onset and termination of the African Humid Period are contested, with strong evidence for both abrupt and gradual change. We use optically stimulated luminescence dating of dunes, shorelines, and fluviolacustrine deposits to reconstruct the fluctuations of Lake Mega-Chad, which was the largest pluvial lake in Africa. Humid conditions first occur at ∼ 15 ka, and by 11.5 ka, Lake Mega-Chad had reached a highstand, which persisted until 5.0 ka. Lake levels fell rapidly at ∼ 5 ka, indicating abrupt aridification across the entire Lake Mega-Chad Basin. This record provides strong terrestrial evidence that the African Humid Period ended abruptly, supporting the hypothesis that the African monsoon responds to insolation forcing in a markedly nonlinear manner. In addition, Lake Mega-Chad exerts strong control on global biogeochemical cycles because the northern (Bodélé) basin is currently the world's greatest single dust source and possibly an important source of limiting nutrients for both the Amazon Basin and equatorial Atlantic. However, we demonstrate that the final desiccation of the Bodélé Basin occurred around 1 ka. Consequently, the present-day mode and scale of dust production from the Bodélé Basin cannot have occurred before 1 ka, suggesting that its role in fertilizing marine and terrestrial ecosystems is either overstated or geologically recent.

Keywords: African Humid Period; African monsoon; Lake Chad; dust.

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Conflict of interest statement

The authors declare no conflict of interest.

Figures

Fig. 1.
Fig. 1.
The location and geography of Lake Mega-Chad. (A) Location of Lake Mega-Chad and its catchment within Africa. (B) Lake Mega-Chad catchment, showing the maximum extent of the lake during the Holocene and key geographical features. (C) The stages of Lake Mega-Chad identified in this study. The Bhar el Ghazal River (dashed line) that feeds water from Lake Chad into the Bodélé Depression when the level of Lake Chad rises above the sill at 288 m is also shown. The elevations are given in meters above present-day sea level. The location and elevation of each sample site is shown in more detail in SI Appendix.
Fig. 2.
Fig. 2.
The lake-level history of Lake Mega-Chad plotted alongside key West African monsoon strength records. Data plotting toward the top of the chart indicate wetter conditions. Vertical bars represent key events in the Lake Mega-Chad lake-level history. Red represents the latest evidence for aeolian dunes on the dry lake bed; green represents the main lake highstand; and blue represents the Late Holocene highstand. (A) Lake Mega-Chad lake levels. Red data points are from the Bodélé Basin, whereas blue ones are from the Chad Basin. Open data points represent aeolian sediments, which were deposited above the contemporaneous lake level. Closed data points represent shorelines and therefore contemporaneous lake level. The black dashed line indicates lake-level changes. The horizontal blue dashed line represents the elevation of the BEG sill, below which separate lakes exist in the Chad and Bodélé basins. Consequently, lake-level changes below this line represent the Bodélé Basin only. Separate lake-level reconstructions for the Chad and Bodélé basins are presented in SI Appendix, Fig. S1. (B) The 30°N June insolation and ODP core 658C terrigenous dust content (2). (C) Gulf or Guinea sea surface salinity (SSS), primarily reflecting discharge from the Niger–Benue and Sanaga rivers, which drain similar latitudes to the Lake Mega-Chad catchment (1).

References

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