Marine Anoxia and Ocean Acidification During the End-Permian Extinction:An Integrated View From δ 238 U and δ 44/40 Ca Proxies and Earth System Modeling

The largest mass extinction event in the Phanerozoic, known as the end-Permian mass extinction (or EPME, ca. 252 Ma) is coincident with the main eruption phase of Siberian Traps volcanism (ca. 252 to 250 Ma), a large igneous province (LIP). This LIP is estimated to have a volume larger than 2 × 10 6...

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Bibliographic Details
Main Authors: Cui, Ying, Zhang, Feifei, Wang, Jiuyuan, Jiang, Shijun, Shen, Shuzhong
Format: Book Part
Language:English
Published: Wiley-Interscience 2021
Subjects:
Calcium isotope
Earth system modeling
End-permian mass extinction
Large igneous province
Ocean acidification
Ocean anoxia
Soil-based proxies
Uranium isotopes
Online Access:https://curis.ku.dk/portal/da/publications/marine-anoxia-and-ocean-acidification-during-the-endpermian-extinction(0b356b3c-3fa0-457e-a64f-f0f813596b49).html
https://doi.org/10.1002/9781119507444.ch14
https://curis.ku.dk/ws/files/327933209/Marine_Anoxia_and_Ocean_Acidification_During.pdf
Description
Summary:The largest mass extinction event in the Phanerozoic, known as the end-Permian mass extinction (or EPME, ca. 252 Ma) is coincident with the main eruption phase of Siberian Traps volcanism (ca. 252 to 250 Ma), a large igneous province (LIP). This LIP is estimated to have a volume larger than 2 × 10 6 km 3 and to have released both mantle carbon dioxide (CO 2 ) through extrusions and thermogenic methane (CH 4 ) and carbon dioxide (CO 2 ) through intrusions. The climatic consequences of these greenhouse gases is detrimental to both marine and terrestrial life and may have delayed the recovery of ecosystems after the extinction. Quantitatively, the amount of CO 2 released can be estimated using global carbon (C) cycle model or plant and soil-based proxies with varying time resolution. In light of the recent advances in geochemical proxies of ocean anoxia and acidification, we review the latest uranium isotopes (δ 238 U) and calcium isotope (δ 44/40 Ca) records and Earth system modeling results to summarize the environmental response to the forcing of increased atmospheric CO 2 concentrations. The extent of increase in oceanic anoxic area can be estimated by δ 238 U, and the δ 44/40 Ca records may be used to evaluate ocean acidification. This evidence suggests that excessive nutrient load in the ocean (decreased strength of meridional overturning circulation) and ocean acidification in poorly buffered seawater (potentially triggered by the Siberian Traps LIP) worked together to create the most severe biological crisis and delayed recovery of life in the Earth’s history.

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