4.7 Article

Origin of the long-term increase in coccolith size and its implication for carbon cycle and climate over the past 2 Myr

Journal

QUATERNARY SCIENCE REVIEWS
Volume 290, Issue -, Pages -

Publisher

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.quascirev.2022.107642

Keywords

Coccolith size; Carbonate counter pump; Carbon cycle; CO2; Climate change; Pleistocene

Funding

  1. National Key Research and Development Program of China [2018YFE0202400]
  2. Strategic Priority Research Program of the Chinese Academy of Sciences [XDB42000000]
  3. National Natural Science Foundation of China [41930536, 42176060]

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This study reveals the long-term increase in coccolith size over the Pleistocene in global oceans and its impact on the carbon cycle. The researchers analyze the data from the Ocean Drilling Program Site 1143 in the South China Sea and find that Earth eccentricity controls coccolith size diversity and calcite export production in tropical oceans. Additionally, they propose that the increased availability of oceanic alkalinity may contribute to the long-term increase in coccolith size.
A long-term increase in coccolith size over the Pleistocene has long been discovered in global oceans. Such a long-term and evolutionary change is expected to exert substantial impact on the carbon cycle as coccolithophores are one of the major components of marine carbonate counter pump (CCP). Here, we present coccolith morphological data as well as coccolith calcite export at Ocean Drilling Program Site 1143 in the South China Sea over the past 2 Myr. The results confirm the idea that Earth eccentricity controlled coccolith size diversity and calcite export production in tropical oceans in the Pleistocene. In addition, we consider a possible origin of the long-term increase in coccolith size as a result of increased oceanic alkalinity availability. As coccolithophores evolved simultaneously in global oceans, the increased coccolith calcification may have promoted global marine particulate inorganic carbon production, especially for the interglacial stages. Therefore, the enhanced coccolith-based CCP may account for a stepwise increase in interglacial CO2 levels over the middle Pleistocene. High CO2 levels at the onset of the interglacial stages may reduce the glaciation rate, thereby prolonging an entire interglacial-glacial cycle after the middle Pleistocene. (C) 2022 Elsevier Ltd. All rights reserved.

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