Abstract
Abstract. The global Late Pliocene/Early Pleistocene cooling (~3.0–2.0 million years ago – Ma) concurred with extremely high diatom and biogenic opal production in most of the major coastal upwelling regions. This phenomenon was particularly pronounced in the Benguela upwelling system (BUS), off Namibia, where it is known as the Matuyama Diatom Maximum (MDM). Our study focuses on a new diatom silicon isotope (δ30Si) record covering the MDM in the BUS. Unexpectedly, the variations in δ30Si signal follow biogenic opal content, whereby the highest δ30Si values correspond to the highest biogenic opal content. We interpret the higher δ30Si values during the MDM as a result of a stronger degree of silicate utilisation in the surface waters caused by high productivity of mat-forming diatom species. This was most likely promoted by weak upwelling intensity dominating the BUS during the Late Pliocene/Early Pleistocene cooling combined with a large silicate supply derived from a strong Southern Ocean nutrient leakage responding to the expansion of Antarctic ice cover and the resulting stratification of the polar ocean 3.0–2.7 Ma ago. A similar scenario is hypothesized for other major coastal upwelling systems (e.g. off California) during this time interval, suggesting that the efficiency of the biological carbon pump was probably sufficiently enhanced in these regions during the MDM to have significantly increased the transport of atmospheric CO2 to the deep ocean. In addition, the coeval extension of the area of surface water stratification in both the Southern Ocean and the North Pacific, which decreased CO2 release to the atmosphere, led to further enhanced atmospheric CO2 drawn-down and thus contributed significantly to Late Pliocene/Early Pleistocene cooling.
Highlights
The causes and consequences of global Late Pliocene/Early Pleistocene cooling have been subject to numerous investigations in order to understand mechanisms driving global climate from a state warmer than today towards colder conditions (Lisiecki and Raymo, 2005)
This was most likely promoted by weak upwelling intensity dominating the Benguela upwelling system (BUS) during the Late Pliocene/Early Pleistocene cooling combined with a large silicate supply derived from a strong Southern Ocean nutrient leakage responding to the expansion of Antarctic ice cover and the resulting stratification of the polar ocean 3.0–2.7 Ma ago
During the Matuyama Diatom Maximum (MDM) interval, the diatom δ30Si values at Site 1082 were in the range expected for an upwelling area but experienced large amplitude changes ranging between ∼ 0 and 1.7 ‰ (Fig. 3)
Summary
The causes and consequences of global Late Pliocene/Early Pleistocene cooling (ca. 3.0–2.0 Ma) have been subject to numerous investigations in order to understand mechanisms driving global climate from a state warmer than today towards colder conditions (Lisiecki and Raymo, 2005). In the BUS, this extremely high siliceous productivity event, the socalled MDM (Berger et al, 2002; Lange et al, 1999; Perez et al, 2001), is represented by sedimentary biogenic opal concentrations of up to 60 % along the continental slopes off Namibia and southwest Africa between the Walvis Ridge and Cape Town (Wefer et al, 1998) This high biogenic opal abundance coincided with the first appearance of the diatom flora (e.g. Thalassiothrix antarctica) presently prevailing in the Southern Ocean (Berger et al, 2002; Lange et al, 1999; Perez et al, 2001), which paradoxically evolved under warm surface water conditions and weak upwelling intensity (Etourneau et al, 2009). We compared our results from this region to other upwelling systems and regarding related changes in the polar oceans during this time interval we propose a scenario illustrating a possible significant impact of the MDM on the Plio–Pleistocene global climate transition
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