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Greatest Mass Extinctions of the Phanerozoic Eon

Greatest Mass Extinctions of the Phanerozoic Eon. Group 4 Jennifer Sullivan Zoe Gentes AJ Infante Amy Lombari Dennis Titterton. The Basics. end-Permian Extinction ~251 Ma (#1 greatest mass extinction) ~94% of all marine life; up to ~70% of land species. Late Ordovician Extinction

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Greatest Mass Extinctions of the Phanerozoic Eon

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  1. Greatest Mass Extinctionsof thePhanerozoic Eon Group 4 Jennifer Sullivan Zoe Gentes AJ Infante Amy Lombari Dennis Titterton

  2. The Basics • end-Permian Extinction • ~251 Ma (#1 greatest mass extinction) • ~94% of all marine life; up to ~70% of land species. • Late Ordovician Extinction • ~443 Ma (#2 greatest mass extinction) • ~65% of all life;

  3. General Causes • Primary Suspects • Volcanism – Gas emissions of Hydrogen Sulfide can lead to anoxia in deep ocean environments, which then may reach the atmosphere. H2S in the atmosphere also weakens the ozone layer, allowing harmful levels of UV radiation to reach the Earth. • H2S Emissions – Global warming can cause an imbalance between organisms and bacteria that reduce Sulfate, allowing an increase in Hydrogen Sulfate in the oceans. This can rise into the atmosphere as well, lethal to life everywhere. • Methane Hydrate Gas – Methane gases can be released by volcanism. • Anoxia – Oceans became severely anoxic by the end of the Permian.

  4. General Causes • Secondary Suspects • Sea Level Fluctuations – A marine regression occurred in Late Permian, killing shallow marine habitats. There is only partial evidence for regressions being linked to extinctions. • Formation of a Supercontinent – This reduced the amount of shallow marine environments and altered oceanic circulations, as well as the changes in weather and climates to seasonal monsoons along the coasts and arid climates within the continent's interior. • Impacts – Although impacts have led to other large extinctions, no evidence for a part in the Permian-Triassic extinction has been found. • Gamma Ray Bursts – When a star explodes it sends out gamma ray bursts. It is suspected that this initiated the Ordovician extinction when a gamma ray burst occurred close enough to the Earth for it to receive UV radiation.

  5. End-Permian: The Likely Causes • Scientists generally conclude that the P/T extinction was due to a combination of events that fell together much like a “domino effect” causing phases or “pulses” of extinctions that spanned over ~8 million years. • During the Permian, ocean salinity dropped significantly for the first time. • Oxygen levels in the atmosphere went from high (~30%) to very low (~15%). • There is evidence for global warming as well as cooling and glaciation. • Extreme erosion on Pangaea created extensive bare, arid environments. • Large-scale ocean regression led to oxidization of trapped organic matter in the now-exposed shallow marine environments. • A gigantic volcanic event spread flood basalts, now called the Siberian Traps. • Lastly, a large-scale transgression flooded habitats along the shore.

  6. End-Permian: The Evidence • Siberian Traps:Extensive volcanic activity (basaltic lava flows) occurred towards the end of the Permian, but before the “pulses” of extinction began. The remains are located in Russia and span 2,000,000 square kilometers. • Studies on the Maokov Formation, located in Meishan, China. • 333 marine fossil species were traced in the rock layers. • Isotopic analysis of volcanic ash layers were used to find relative ages. • Concluded that the range of extinctions occurred within 500,000 years.

  7. Siberian Traps http://palaeo.gly.bris.ac.uk/Palaeofiles/Permian/Map.html

  8. End-Permian: The Evidence • The excessive lava floods produced CO2 and SO2 emissions. • Which led to global warming (followed later by short-term cooling), acid rain, sea level fluctuations, and the release of methane reservoirs. • Global warming reduces an ocean's ability to retain oxygen, thus making the deep ocean anoxic. • Gas levels increased, leading to extreme anoxia around the globe that spread through the atmosphere as well as the ocean. • Such large amounts of CO2 can severely damage the ozone layer, enough to allow lethal UV radiation to penetrate.

  9. Late Ordovician Mass Extinction • Significant volcanic activity and weathering of silicate terrains from the mountains increased CO2 levels. • The increased CO2 levels raised temperature, however as Gondwana moved towards the South Pole, glaciation covered the land. • When the ice sheets formed they reduced the silicate weathering lowered the sea level. • However CO2 levels continued to rise and led to a Greenhouse effect that ended the period of glaciation. • Fluctuations in sea level occurred during these stages as ice sheets formed and melted.

  10. Affected Life

  11. Permian-Triassic Extinction Example Reconstruction of ancient seabed in southern China representing before and after the P/T mass extinction. (Benton and Twitchett, 2003)

  12. End-Permian vs. Late Ordovician • Similarities • Global warming and global cooling events, including glaciations. • Marine regressions. • Marine life was affected the most for both of these mass extinction events. • Increased CO2 levels. • Anoxia Differences

  13. Conclusion • Glaciation is considered the most significant cause for extinctions in the Late Ordovician mass extinction. • The basaltic floods had a significant and direct influence on the Permian-Triassic mass extinction. The type of extinction even that occurred forming the Permian/Triassic boundary would be the most likely to occur again today. • We are moving towards a period of global warming due to an increase in CO2 emissions. Our ozone layer is also beginning to weaken.

  14. References • Benton, Michael J.; Twitchett, Richard J., 2003, How to kill (almost) all life: the end-Permian extinction event, University of Bristol, UK, TRENDS in Ecology and Evolution, Vol.18, No.7., pp.358-365. • Erwin, Douglas H., 2006, Extinction: how life on earth nearly ended 250 million years ago, Princeton University Press, Princeton, New Jersey, pp.10-15 • Finney, Stanley C.; Berry, William B. N.; Cooper, John D.; Ripperdan, Robert L.; Sweet, Walter C.; Jacobson, Stephen R.; Soufiane, Azzedine; Achab, Aicha; Noble, Paula J., 1999, Late Ordovician mass extinction: A new perspective from stratigraphic sections in central Nevada, Geology, Geological Society of America, Vol.27, No. 3, p.215-218. • Goodwin, Anna; Wyles, Jon; Morley, Alex, 2001, The Permo-Triassic Extinction, University of Bristol, UK, <http://palaeo.gly.bris.ac.uk/Palaeofiles/Permian/intro.html> • Hallam, A.; Wignall, P.B., 1997, Mass Extinctions and Their Aftermath, Oxford University Press, N.Y., p.4. • Sheehan, Peter M., 2001, The Late Ordovician Mass Extinction, Annual Reviews: Earth Planetary Science, 29:331-64. • Warmuth, Laura, 2008, The Late Ordovician Mass Extinction: A review of the Second-Largest Extinction Event in Earth's History, <http://evolution.suite101.com/article.cfm/the_late_ordovician_mass_extinction> • Thomas, Ellen, 2001, Biodiversity - Invasive Species - Mass Extinctions, <http://ethomas.web.wesleyan.edu/ees123/mass_extinctions.htm>

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