C. A. Metzger scite author profile

The end-Permian mass extinction has been envisaged as the nadir of biodiversity decline due to increasing volcanic gas emissions over some 9 million years. We propose a different tempo and mechanism of extinction because we recognize two separate but geologically abrupt mass extinctions on land, one terminating the Middle Permian (Guadalupian) at 260.4 Ma and a later one ending the Permian Period at 251 Ma. Our evidence comes from new paleobotanical, paleopedological, and carbon isotopic studies of Portal Mountain, Antarctica, and comparable studies in the Karoo Basin, South Africa. Extinctions have long been apparent among marine invertebrates at both the end of the Guadalupian and end of the Permian, which were also times of warm-wet greenhouse climatic transients, marked soil erosion, transition from high-to low-sinuosity and braided streams, soil stagnation in wetlands, and profound negative carbon isotope anomalies. Both mass extinctions may have resulted from catastrophic methane outbursts to the atmosphere from coal intruded by feeder dikes to fl ood basalts, such as the end-Guadalupian Emeishan Basalt and end-Permian Siberian Traps.

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The Permian–Triassic boundary in Antarctica

Retallack

Jahren

Sheldon

et al. 2005

Antartic science

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Abstract:The Permian ended with the largest of known mass extinctions in the history of life. This signal event has been difficult to recognize in Antarctic non-marine rocks, because the boundary with the Triassic is defined by marine fossils at a stratotype section in China. Late Permian leaves (Glossopteris) and roots Vertebraria), and Early Triassic leaves (Dicroidium) and vertebrates (Lystrosaurus) roughly constrain the Permian-Triassic boundary in Antarctica. Here we locate the boundary in Antarctica more precisely using carbon isotope chemostratigraphy and total organic carbon analyses in six measured sections from Allan Hills, Shapeless Mountain, Mount Crean, Portal Mountain, Coalsack Bluff and Graphite Peak. Palaeosols and root traces also are useful for recognizing the Permian-Triassic boundary because there was a complete turnover in terrestrial ecosystems and their soils. A distinctive kind of palaeosol with berthierine nodules, the Dolores pedotype, is restricted to Early Triassic rocks. Late Permian and Middle Triassic root traces are carbonaceous, whereas those of the Early Triassic are replaced by claystone or silica. Antarctic Permian-Triassic sequences are among the most complete known, judging from the fine structure and correlation of carbon isotope anomalies.

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Effect of paleosol formation on rare earth element signatures in fossil bone

Metzger

Terry

Grandstaff

2004

Geol

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Paleosol record of Neogene climate change in the Australian outback

Metzger

Retallack

2010

Australian Journal of Earth Sciences

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Growth and steady state of the Patagonian Andes

Colwyn¹,

Brandon²,

Hren³

et al. 2019

Am J Sci

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C. A. Metzger

Middle-Late Permian mass extinction on land

The Permian–Triassic boundary in Antarctica

Effect of paleosol formation on rare earth element signatures in fossil bone

Paleosol record of Neogene climate change in the Australian outback

Growth and steady state of the Patagonian Andes

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