Publication

Deep Sea Research Part II: Topical Studies in Oceanography 146, 82-92 (2017)
Paleoceanographic conditions on the S?o Paulo Ridge, SW Atlantic Ocean, for the past 30 million years inferred from Os and Pb isotopes of a hydrogenous ferromanganese crust

Author

Goto, K. T., Nozaki, T., Toyofuku, T., Augustin, A. H., Shimoda, G., Chang, Q., Kimura, J.-I., Kameo, K., Kitazato, H. and Suzuki, K.

Abstract

Hydrogenous ferromanganese (Fe-Mn) crusts can provide records of long-term environmental changes during the Cenozoic. To understand the paleoceanographic conditions in the southwestern Atlantic Ocean, we investigated depth profiles of major- and trace-element concentrations as well as Os and Pb isotopic compositions in a Fe-Mn crust collected from the southern flank of the S?o Paulo Ridge in the southwestern Atlantic. Major and trace element data plotted on ternary Mn?Fe?10×(Ni+Co+Cu) and rare-earth element plus yttrium (REY) discrimination diagrams indicate that the analyzed sample is a typical hydrogenous Fe-Mn crust. The obtained 187Os/188Os data were matched to the Cenozoic seawater Os isotope evolution curve reconstructed from pelagic sediments. The result suggests that the Fe-Mn crust has accreted over ~30 Myr with growth rates of 0.5?3 mm/Myr, although the sample likely grew in two directions during the early stage of its growth. We found no evidence of growth hiatus in the sample, which may contrast with the growth histories of many Pacific Fe-Mn crusts. Hence, the conditions favorable for the accretion of hydrogenous Fe-Mn crusts were likely to have developed on the S?o Paulo Ridge over the past ~30 Myr. The Pb isotopic compositions show very limited ranges (e.g., 206Pb/204Pb=18.80?18.85), and are similar to those of pre-anthropogenic seawater in the Southern Ocean. As the S?o Paulo Ridge is located near the Vema Channel, which is presently a major path of Antarctic Bottom Water, we suggest that a strong northward bottom current has continuously swept detrital and biogenic sediments from the ridge, and played a vital role in the Fe-Mn crust formation since ~30 Ma.