Tracking the Paleocene‐Eocene Thermal Maximum in the North Atlantic: A Shelf‐to‐Basin Analysis With a Regional Ocean Model

The Paleocene‐Eocene Thermal Maximum (PETM), a transient greenhouse climate interval spurred by a large release of carbon to the ocean‐atmosphere approximately 56 million years ago, provides a geological point of comparison for potential effects of anthropogenic carbon emission. Geochemical proxies...

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Bibliographic Details
Published in:Paleoceanography and paleoclimatology 2018-12, Vol.33 (12), p.1324-1338
Main Authors: Hantsoo, Kalev G., Kump, Lee R., Haupt, Bernd J., Bralower, Timothy J.
Format: Article
Language:English
Subjects:
Anthropogenic factors
Atmosphere
Atmospheric models
Benthos
Calcite
Carbon
Coastal currents
Coastal upwelling
Computer simulation
Continental margins
Continental shelves
Coordinate systems
Coordinates
Eocene
Fossil assemblages
Fossils
Hypoxia
North Atlantic
Ocean circulation
Ocean floor
Ocean models
Oceans
Organic matter
Oxygen
Oxygenation
Palaeocene
Paleocene
Paleocene Eocene Thermal Maximum
Productivity
Regional analysis
Regional Ocean Modeling System
Resolution
Respiration
ROMS
Salisbury Embayment
Saturation
Upper bounds
Upwelling
Water currents
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Summary:The Paleocene‐Eocene Thermal Maximum (PETM), a transient greenhouse climate interval spurred by a large release of carbon to the ocean‐atmosphere approximately 56 million years ago, provides a geological point of comparison for potential effects of anthropogenic carbon emission. Geochemical proxies and fossil assemblages offer insight into the continental shelf response to the PETM, but global ocean‐atmosphere models cannot resolve shelf processes at sufficient resolution for model‐data comparisons. We present high‐resolution simulations of the pre‐PETM and PETM North Atlantic basin using the Regional Ocean Modeling System (ROMS), including a resolved continental shelf along the eastern margin of North America in the Salisbury Embayment. ROMS' high‐resolution, terrain‐following coordinate system permits greater vertical resolution and eddy resolution along continental margins while also capturing open‐ocean processes. We find that during the PETM, benthic oxygen concentration ([O2]) in the Salisbury Embayment decreases 18% to an average state of year‐round mild hypoxia, while average benthic calcite saturation (Ω) declines from 4.4 to 2.3. These benthic decreases are driven largely by enhanced benthic oxic respiration, which occurs despite no increase in shelf productivity. Instead, increased respiration stems from less vigorous off‐shelf transport of organic matter due to (a) weakened along‐shelf water currents and (b) weakened coastal upwelling that forces productivity closer to the shelf seafloor. Model results do not include riverine inputs, which would have further lowered benthic [O2] and Ω. Our data suggest lowered benthic calcite saturation and mild hypoxia as an upper bound on the oxygenation state of the Salisbury Embayment seafloor during the PETM. Key Points We use the Regional Ocean Modeling System to simulate the circulation and biogeochemistry of the U.S. mid‐Atlantic continental shelf before and during the PETM Weakening of coastal upwelling and along‐shelf currents causes 18% decrease in benthic shelf [O2], driving year‐round middle and outer shelf hypoxia Respiration of marine and terrigenous organic matter likely induced continuous bottom water hypoxia and depressed calcite saturation during PETM
ISSN:2572-4517
2572-4525
DOI:10.1029/2018PA003371