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Decreasing Phanerozoic extinction intensity as a consequence of Earth surface oxygenation and metazoan ecophysiology

Decreasing Phanerozoic extinction intensity as a consequence of Earth surface oxygenation and metazoan ecophysiology
Decreasing Phanerozoic extinction intensity as a consequence of Earth surface oxygenation and metazoan ecophysiology
The decline in background extinction rates of marine animals through geologic time is an established but unexplained feature of the Phanerozoic fossil record. There is also growing consensus that the ocean and atmosphere did not become oxygenated to near-modern levels until the mid-Paleozoic, coinciding with the onset of generally lower extinction rates. Physiological theory provides us with a possible causal link between these two observations—predicting that the synergistic impacts of oxygen and temperature on aerobic respiration would have made marine animals more vulnerable to ocean warming events during periods of limited surface oxygenation. Here, we evaluate the hypothesis that changes in surface oxygenation exerted a first-order control on extinction rates through the Phanerozoic using a combined Earth system and ecophysiological modeling approach. We find that although continental configuration, the efficiency of the biological carbon pump in the ocean, and initial climate state all impact the magnitude of modeled biodiversity loss across simulated warming events, atmospheric oxygen is the dominant predictor of extinction vulnerability, with metabolic habitat viability and global ecophysiotype extinction exhibiting inflection points around 40% of present atmospheric oxygen. Given this is the broad upper limit for estimates of early Paleozoic oxygen levels, our results are consistent with the relative frequency of high-magnitude extinction events (particularly those not included in the canonical big five mass extinctions) early in the Phanerozoic being a direct consequence of limited early Paleozoic oxygenation and temperature-dependent hypoxia responses.
0027-8424
Stockey, Richard G.
005ca449-f5c9-4049-835f-0a9c6df3a93d
Pohl, Alexandre
f16e3cc1-da9c-4fad-b4ee-f640d7978ae6
Ridgwell, Andy
769cea5c-e033-456a-8b53-51dfa307dc35
Finnegan, Seth
530abed4-8fb6-4287-b5df-bc982fe0292b
Sperling, Erik A.
0c67e5ac-bf08-438f-8bb1-55f8f0522a7f
Stockey, Richard G.
005ca449-f5c9-4049-835f-0a9c6df3a93d
Pohl, Alexandre
f16e3cc1-da9c-4fad-b4ee-f640d7978ae6
Ridgwell, Andy
769cea5c-e033-456a-8b53-51dfa307dc35
Finnegan, Seth
530abed4-8fb6-4287-b5df-bc982fe0292b
Sperling, Erik A.
0c67e5ac-bf08-438f-8bb1-55f8f0522a7f

Stockey, Richard G., Pohl, Alexandre, Ridgwell, Andy, Finnegan, Seth and Sperling, Erik A. (2021) Decreasing Phanerozoic extinction intensity as a consequence of Earth surface oxygenation and metazoan ecophysiology. Proceedings of the National Academy of Sciences, 18 (41). (doi:10.1073/pnas.2101900118).

Record type: Article

Abstract

The decline in background extinction rates of marine animals through geologic time is an established but unexplained feature of the Phanerozoic fossil record. There is also growing consensus that the ocean and atmosphere did not become oxygenated to near-modern levels until the mid-Paleozoic, coinciding with the onset of generally lower extinction rates. Physiological theory provides us with a possible causal link between these two observations—predicting that the synergistic impacts of oxygen and temperature on aerobic respiration would have made marine animals more vulnerable to ocean warming events during periods of limited surface oxygenation. Here, we evaluate the hypothesis that changes in surface oxygenation exerted a first-order control on extinction rates through the Phanerozoic using a combined Earth system and ecophysiological modeling approach. We find that although continental configuration, the efficiency of the biological carbon pump in the ocean, and initial climate state all impact the magnitude of modeled biodiversity loss across simulated warming events, atmospheric oxygen is the dominant predictor of extinction vulnerability, with metabolic habitat viability and global ecophysiotype extinction exhibiting inflection points around 40% of present atmospheric oxygen. Given this is the broad upper limit for estimates of early Paleozoic oxygen levels, our results are consistent with the relative frequency of high-magnitude extinction events (particularly those not included in the canonical big five mass extinctions) early in the Phanerozoic being a direct consequence of limited early Paleozoic oxygenation and temperature-dependent hypoxia responses.

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More information

e-pub ahead of print date: 4 October 2021
Published date: 12 October 2021

Identifiers

Local EPrints ID: 474743
URI: http://eprints.soton.ac.uk/id/eprint/474743
ISSN: 0027-8424
PURE UUID: f6a3546c-9dda-4241-8985-688e96431b06
ORCID for Richard G. Stockey: ORCID iD orcid.org/0000-0001-5541-7987

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Date deposited: 02 Mar 2023 17:39
Last modified: 17 Mar 2024 04:15

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Contributors

Author: Richard G. Stockey ORCID iD
Author: Alexandre Pohl
Author: Andy Ridgwell
Author: Seth Finnegan
Author: Erik A. Sperling

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