Paleoenvironmental Significance of Magnetofossils in Pelagic Sediments in the Equatorial Pacific Ocean Before and After the Eocene/Oligocene Boundary

Magnetotactic bacteria (MTB), sensitive to redox status, leave fossil bacterial magnetite (magnetofossils) in sediments. The relative contents of cuboctahedral, elongated prismatic, and bullet-shaped magnetofossils archive changes in redox conditions, which indicate paleoenvironmental variations. Th...

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Bibliographic Details
Published in:Journal of Geophysical Research: Solid Earth
Main Authors: Lu, Yang, Wang, Dunfan, Jiang, Xiaodong, Lin, Zhiyong, Yang, Yiping, Liu, Qingsong
Format: Report
Language:English
Published: AMER GEOPHYSICAL UNION 2021
Subjects:
Geochemistry & Geophysics
environmental magnetism
magnetofossils
EOT
equatorial Pacific
EOCENE-OLIGOCENE TRANSITION
ORGANIC-CARBON FLUX
DEEP-SEA
BACTERIAL MAGNETITE
ICE GROWTH
RECORD
PRODUCTIVITY
TEMPERATURES
GLACIATION
COMPONENTS
Antarctic
Pacific
Antarc*
Online Access:http://ir.gig.ac.cn/handle/344008/62765
https://doi.org/10.1029/2021JB022221
Description
Summary:Magnetotactic bacteria (MTB), sensitive to redox status, leave fossil bacterial magnetite (magnetofossils) in sediments. The relative contents of cuboctahedral, elongated prismatic, and bullet-shaped magnetofossils archive changes in redox conditions, which indicate paleoenvironmental variations. The Eocene-Oligocene transition (EOT) is a turning point in the Cenozoic climate evolution from greenhouse to icehouse. Global cooling, Antarctic glaciation, and/or a new tectonic structure modified the global ocean and atmosphere circulation mode. In the eastern equatorial Pacific Ocean (EEPO), the organic matter and aeolian supply, which are important for the proliferation of MTB, did not vary synchronously. Here, we study the magnetic particles and environmental magnetism characteristics of samples from EEPO to test the hypothesis that magnetofossil assemblages respond to the dramatic paleoclimatic changes across the EOT. Results show that the abundances of all kinds of magnetic particles are significantly decreased with the reduction of aeolian supply after the EOT. However, the relative abundance of magnetofossils and the proportion of bullet-shaped ones both increased. Simultaneously, organic matter input was enhanced as indicated by (a) similar productivity but decreased organic carbon consumption and (b) the increased mass accumulation rates of total organic carbon after the EOT. The enhanced organic matter flux increased redox gradient in pelagic sediment, which together with sufficient iron from aeolian particles, supported the metabolism of MTB, especially those synthesizing bullet-shaped magnetofossils. Therefore, the magnetofossils in the EEPO vary synchronously with the evolution of paleoenvironment before and after the EOT, which thus supports the use of magnetofossil as an effective proxy archiving paleoenvironment.

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