Atmosphere–ocean oxygen and productivity dynamics during early animal radiations

Atmosphere–ocean oxygen and productivity dynamics during early animal radiations

The proliferation of large, motile animals 540 to 520 Ma has been linked to both rising and declining O2 levels on Earth. To explore this conundrum, we reconstruct the global extent of seafloor oxygenation at approximately submillion-year resolution based on uranium isotope compositions of 187 marin...

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Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 116; no. 39; pp. 19352 - 19361
Main Authors: Dahl, Tais W., Connelly, James N., Li, Da, Kouchinsky, Artem, Gill, Benjamin C., Porter, Susannah, Maloof, Adam C., Bizzarro, Martin
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 24-09-2019
Series:PNAS Plus
Subjects:
Animals
Anoxia
Atmosphere
Atmosphere - chemistry
Biological Evolution
Carbonates
Carbonates - chemistry
Computer simulation
Earth, Planet
Ecosystem
Geologic Sediments - chemistry
Isotopes
Isotopes - analysis
Marine ecosystems
Mass balance
Ocean floor
Oceans
Oceans and Seas
Oxygen - analysis
Oxygenation
Photosynthesis
Physical Sciences
PNAS Plus
Predators
Prey
Seawater - chemistry
Strontium
Strontium isotopes
Sulfur
Time
Uranium
Uranium - analysis
Variations
Cambrian explosion
stable isotopes
oxygenation
global biogeochemical cycles
uranium
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Summary:The proliferation of large, motile animals 540 to 520 Ma has been linked to both rising and declining O2 levels on Earth. To explore this conundrum, we reconstruct the global extent of seafloor oxygenation at approximately submillion-year resolution based on uranium isotope compositions of 187 marine carbonates samples from China, Siberia, and Morocco, and simulate O2 levels in the atmosphere and surface oceans using a mass balance model constrained by carbon, sulfur, and strontium isotopes in the same sedimentary successions. Our results point to a dynamically viable and highly variable state of atmosphere–ocean oxygenation with 2 massive expansions of seafloor anoxia in the aftermath of a prolonged interval of declining atmospheric pO2 levels. Although animals began diversifying beforehand, there were relatively few new appearances during these dramatic fluctuations in seafloor oxygenation. When O2 levels again rose, it occurred in concert with predicted high rates of photosynthetic production, both of which may have fueled more energy to predators and their armored prey in the evolving marine ecosystem.
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2Present address: School of Marine Science and Engineering, Nanjing Normal University, Nanjing, Jiangsu 210023, China.
Edited by Edward A. Boyle, Massachusetts Institute of Technology, Cambridge, MA, and approved August 7, 2019 (received for review January 23, 2019)
Author contributions: T.W.D. designed research; T.W.D. performed research; D.L., A.K., and A.C.M. contributed samples; T.W.D., J.N.C., D.L., B.C.G., and M.B. analyzed data; and T.W.D., J.N.C., S.P., A.C.M., and M.B. wrote the paper.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1901178116