A molybdenum isotope record of Eocene Thermal Maximum 2: implications for global ocean redox during the early Eocene

During the early Eocene, a series of short-term global warming events (‘hyperthermals’) occurred in response to the rapid release of carbon into the oceans and atmosphere. In order to investigate the response of ocean redox to global warming, we have determined the molybdenum isotope compositions (δ...

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Bibliographic Details
Published in:Paleoceanography
Main Authors: Dickson, Alexander J., Cohen, Anthony S.
Format: Article in Journal/Newspaper
Language:unknown
Published: 2012
Subjects:
Online Access:https://oro.open.ac.uk/35515/
https://oro.open.ac.uk/35515/1/ETM2%20Mo%20manuscript%20v.5-1.doc
https://oro.open.ac.uk/35515/2/34EF4F4B.pdf
http://www.agu.org/pubs/crossref/2012/2012PA002346.shtml
https://doi.org/10.1029/2012PA002346
Description
Summary:During the early Eocene, a series of short-term global warming events (‘hyperthermals’) occurred in response to the rapid release of carbon into the oceans and atmosphere. In order to investigate the response of ocean redox to global warming, we have determined the molybdenum isotope compositions (δ 98/95 Mo) of samples spanning one such hyperthermal (Eocene Thermal Maximum 2 (ETM-2, 54.1Ma)), from Integrated Ocean Drilling Program Expedition 302 Site M0004A in the Arctic Ocean. The highest δ 98/95 Mo in our sample set (2.00±0.11‰) corresponds to the development of local euxinia at Site M0004A during the peak of ETM-2, which we interpret as recording the global seawater δ 98/95 Mo at that time. The ETM-2 seawater δ 98/95 Mo is indistinguishable from a recent estimate of seawater δ 98/95 Mo from an earlier hyperthermal (Paleocene Eocene Thermal Maximum (PETM, 55.9Ma), δ 98/95 Mo = 2.08±0.11‰). It is argued that the similarity in seawater δ 98/95 Mo during ETM-2 and the PETM was caused by the development of transient euxinia in the Arctic Ocean during each hyperthermal that allowed sediments accumulating in this basin to capture the long term δ 98/95 Mo of early Eocene seawater. Our new data therefore place a minimum constraint on the magnitude of transient global seafloor deoxygenation during early Eocene hyperthermals.