Carbonate associated trace metal and uranium isotope data for the PETM

The Paleocene Eocene Thermal Maximum (PETM) represents a major carbon cycle and climate perturbation that was associated with ocean de-oxygenation, in a qualitatively similar manner to the more extensive Mesozoic Oceanic Anoxic Events. Although indicators of ocean de-oxygenation are common for the P...

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Bibliographic Details
Main Authors: Clarkson, Matthew O, Lenton, Timothy M, Andersen, Morten B, Bagard, Marie-laure, Dickson, Alexander J, Vance, Derek
Format: Dataset
Language:English
Published: PANGAEA 2020
Subjects:
113-690B
143-865C
48-401
Age
relative
Aluminium/Calcium ratio
Barium/Calcium ratio
Cadmium/Calcium ratio
Calcium
Cerium/Calcium ratio
Chromium/Calcium ratio
Copper/Calcium ratio
Deep Sea Drilling Project
DEPTH
sediment/rock
DRILL
Drilling/drill rig
DSDP
DSDP/ODP/IODP sample designation
Event label
Glomar Challenger
Iron/Calcium ratio
Joides Resolution
Leg113
Leg143
Leg48
Lithium/Calcium ratio
Magnesium/Calcium ratio
Manganese/Calcium ratio
Molybdenum/Calcium ratio
Nickel/Calcium ratio
North Atlantic/TERRACE
North Pacific Ocean
Ocean Drilling Program
ODP
PETM
redox
Sample code/label
Sedimentation rate
South Atlantic Ocean
Strontium/Calcium ratio
Titanium/Calcium ratio
Uranium/Calcium ratio
Uranium isotopes
Vanadium/Calcium ratio
Zinc/Calcium ratio
δ234 Uranium
standard error
δ238 Uranium
North Atlantic
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.925086
https://doi.org/10.1594/PANGAEA.925086
Description
Summary:The Paleocene Eocene Thermal Maximum (PETM) represents a major carbon cycle and climate perturbation that was associated with ocean de-oxygenation, in a qualitatively similar manner to the more extensive Mesozoic Oceanic Anoxic Events. Although indicators of ocean de-oxygenation are common for the PETM, and linked to biotic turnover, the global extent and temporal progression of de-oxygenation is poorly constrained. Here we present carbonate associated uranium isotope (δ238UCAU) data to reconstruct the evolution of global seawater δ238U, and hence quantify the expansion of anoxic U sinks on a global scale. This dataset contains trace element and U isotope data (238U/235U, expressed as δ238U) for the carbonate fraction of three well studied PETM sites; Site 865 (equatorial Pacific), Site 401 (Bay of Biscay) and Site 690 (Walvis Ridge). Samples are carbonate rich pelagic sediments, with a mixture of carbonate nannofossils, foraminifera and detrital clays. Bulk samples were selectively leached for the carbonate fraction using 1M ammonium acetate (pH 5) at room temperature for 24hrs. Trace element concentrations were measured on a Thermo-Finnigan Element XR and reported normalized to Ca. Uranium was purified by ion exchange chromatography and isotopes measured on a Thermo-Finnigan Neptune Plus. Uranium isotopes are reported as δ238U, where CRM-145 = 0‰. Sites 690 and 401 both show elevated U/Ca and δ238UCAU during the PETM and recovery interval, indicative of locally reducing conditions. By contrast, Site 865 records the global seawater δ238U and shows no resolvable change across the PETM. The lack of resolvable perturbation to the U-cycle during the event suggests a limited expansion of seafloor anoxia on a global scale. In the related publication we use this result, in conjunction with a biogeochemical model, to set an upper limit on the extent of global seafloor de-oxygenation. The model suggests that the new U isotope data, whilst also being consistent with plausible carbon emission scenarios and observations of ...

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