555 / 2024-09-18 12:41:25
South Asian monsoon induced upper ocean hydrographic changes in the eastern Arabian Sea during the middle Miocene
Planktic foraminifera,Stable oxygen isotopes,Mg/Ca palaeothermometry,Upper ocean thermal gradient,Mixed layer depth,Thermocline depth
Abstract Accepted
Shixian Zou / Xiamen University
Anran Chen / Xiamen University; Xiamen; College of Ocean and Earth Sciences;1Department of Geological Oceanography and State Key Laboratory of Marine Environmental Science; China;2MARUM-Center for Marine Environm
Groeneveld Jeroen / China;Institute of Oceanography; National Taiwan University; Taipei
Stephan Steinke / Xiamen University;State Key Laboratory of Marine Environmental Science
Liviu Giosan / Geology and Geophysics, Woods Hole Oceanographic Institution, Woods Hole, USA;Research Institute of the University of Bucharest (ICUB), Bucharest University, Bucharest, Romania
Global atmospheric circulation experienced drastic changes during the Middle Miocene climate transition (MMCT~14.7–13.0 Ma) possibly related to the glaciation on West-Antarctica. Palaeoceanographic reconstructions have shown that upwelling in the western Arabian Sea due to summer South Asian monsoon (SAM) winds likely occurred since ~14.7 Ma, with fully modern-like monsoonal wind patterns after the end of the MMCT at around ~13 Ma. Whether the changes in monsoonal circulation since ~14.7 Ma are also associated with upper ocean hydrographic changes in the eastern Arabian Sea (EAS) is currently not known for the middle Miocene. For that reason, the difference in Mg/Ca-based temperatures of surface-dwelling with lower mixed layer/thermocline-dwelling and sub-thermocline-dwelling planktic foraminifera was reconstructed to estimate the upper ocean thermal gradient at Site NGHP-01-01 A in the EAS and thus changes in the upper surface water column structure. The Mg/Ca-temperature estimates from the upper mixed layer down to the sub-thermocline show a prominent cooling trend between ~14.2 Ma and 13.2 Ma. The upper water column reconstructions reveal weaker mixing, a shallower thermocline, and therefore a well stratified upper water column in the EAS after ~14.2 Ma. We suggest that the weaker mixing and shallower thermocline in the EAS after ~14.2 Ma are most likely due to an intensification of the summer SAM. A strong salinity stratification because of increased SAM rainfall and advection of low salinity water may have contributed to a weaker mixing and shallower thermocline in the EAS during the investigated time period. The change in the upper ocean hydrography in the EAS after ~14.2 Ma fits well into the emerging picture of monsoonal-driven upper ocean hydrographic changes in the equatorial and northern Indian Ocean due to an intensification of the summer SAM since ~14.7 Ma.
Important Date
  • Conference Date

    Jan 13

    2025

    to

    Jan 17

    2025

  • Sep 27 2024

    Draft paper submission deadline

  • Feb 17 2025

    Registration deadline

Sponsored By
State Key Laboratory of Marine Environmental Science, Xiamen University
Organized By
State Key Laboratory of Marine Environmental Science, Xiamen University
Department of Earth Sciences, National Natural Science Foundation of China
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