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Large Igneous provinces (LIPS) were originally defined by Coffin and Eldholm (1992) as areas of Earth's Surface that contain very large volumes of magmatic rocks (typically Basalt but including Rhyolite s) erupted over extremely short Geological Time intervals of a few million years or less. These provinces are not associated with normal Plate Tectonic magmatism, ie, Mid-ocean Ridge s and Island Arc s. LIPS include continental Flood Basalt s, Oceanic Plateau s, large dike swarms (the eroded roots of a volcanic province), and Volcanic Rifted Margins , recognized by the presence of dike swarms and "seaward dipping reflectors" -- seismically-imaged tabular features buried deep beneath sediment that lie parallel to a passive continental margin along the continental slope, and interpreted to represent Lava flows or sills that formed during rifting of the continent). Most LIPS consist of basalt, but some contain large volumes of associated rhyolite; the rhyolite is typically very dry compared to island arc rhyolites, with much higher eruption temperatures (850º to 1000º C) than normal rhyolites.

When created, LIPS often occupy a few million km&2 and have volumes on the order of 1 million km3. In most cases, the majority of a LIP's volume is emplaced in less than 1 million years. One of the conundrums of LIPS origins is to understand how enormous volumes of basaltic magma are formed and erupted over such short time scales, with effusion rates up to an order of magnitude greater than mid-ocean ridge basalts.


THEORIES OF FORMATION

Large igneous provinces are often linked to active Hotspots by linear chains of volcanic islands or volcanoes, leading to models that connect their origins to Mantle Plume s. In this hypothesis, mantle plumes consist of a bulbous head and a thin tail that feeds hot mantle into the head. When the rising plume head encounters the lithosphere, it spreads out and melts catastrophically to form large volumes of basalt magma in 1-2 million years. Subsequent volcanism originates with the plume tail. The movement of lithosphere across the surface of the Earth in response to plate tectonics causes the plume tail volcanics to form linear island chains. The impact of the plume on the base of continental lithosphere may cause rifting and breakup of the continent, creating conjugate LIPS on opposite sides of an ocean basin (e.g., the Parana-Etendeka pair of South America-Africa).

Alternate theories include delamination of eclogitic lower crust, edge effects of thick lithosphere, and meteorite impact (see Mantle Plume s for more complete discussion of alternate models).


Relationship to extinction events

Because a LIP may in several cases have occurred simultaneously with Oceanic Anoxic Event s and Extinction Event s, it has been proposed that the volcanic byproducts of LIP formation may have had a profound and deleterious effect on the global environment, perhaps contributing to extinction events. The most important examples are the Deccan Traps ( Cretaceous–Tertiary Extinction Event ), the Karoo-Ferrar ( Pliensbachian-Toarcian Extinction ), the Central Atlantic Magmatic Province ( Triassic-Jurassic Extinction Event ), and the Siberian Traps ( Permian-Triassic Extinction Event ).

LIPS have two impacts on environment that can cause extinction: first, they release large volumes of sulfate gas that forms sulfuric acid in the atmosphere; this absorbs heat and causes substantial cooling (e.g., the Laki eruption in Iceland, 1783). Second, oceanic LIPS can reduce oxygen in seawater by either direct oxidation reactions with metals in hydrothermal fluids or by causing algal blooms that consume large amounts of oxygen (Kerr, 2005).


EXAMPLES OF LIPS

These are well documented large igneous provinces in geological research.

Continental Flood basalts

Oceanic Plateaux

Volcanic Rifted Margins

Dike Swarms


SEE ALSO



REFERENCES





  • Anderson, DL, 2005, Large igneous provinces, delammination, and fertile mantle: Elements, vol. 1, December 2005, 271-275. http://www.elementsmagazine.org/

  • Baragar WRA, R.E. Ernst, L. Hulbert, T. Peterson, Longitudinal petrochemical variation in the Mackenzie dyke swarm, northwestern Canadian Shield. J. Petrol. 37: 317-359, 1996.

  • Campbell, IH, 2005, Large igneous provinces and the plume hypothesis: Elements, vol. 1, December 2005, 265-269. http://www.elementsmagazine.org/

  • Coffin, M.F., Eldholm, O., 1992. Volcanism and continental break-up: a global compilation of large igneous provinces. In: Storey, B.C., Alabaster, T., Pankhurst, R.J. (Eds.), Magmatism and the Causes of Continental Breakup. Special Publication. Geological Society of London, London, pp. 17-30.

  • Coffin, M and Eldholm, O, 1994, Large igneous provinces: crustal structure, dimensions, and external consequences. Reviews in Geophysics, vol. 32, 1-36.

  • Cohen, B., Vasconcelos, P.M.D., Knesel, K. M., 2004 ''Tertiary magmatism in Southeast Queensland'' in, ''Dynamic Earth: Past, Present and Future'', pp. 256 - 256, Geological Society of Australia

  • Jones, AP, 2005, Meteor impacts as triggers to large igneous provinces: Elements, vol. 1, December 2005, 277-281. http://www.elementsmagazine.org/

  • Kerr, AC, 2005, Oceanic LIPS: Kiss of death: Elements, vol. 1, December 2005, 289-292. http://www.elementsmagazine.org/

  • Marsh, JS, Hooper PR, Rehacek J, Duncan RA, Duncan AR, 1997. Stratigraphy and age of Karoo basalts of Lesotho and implications for correlations within the Karoo igneous province. In: Mahoney JJ and Coffin MF, editors, Large Igneous Provinces: continental, oceanic, and planetary flood volcanism, Geophysical Monograph 100, American Geophysical Union, Washington, DC, 247-272.

  • Peate DW, 1997. The Parana-Etendeka Province. In: Mahoney JJ and Coffin MF, editors, Large Igneous Provinces: continental, oceanic, and planetary flood volcanism, Geophysical Monograph 100, American Geophysical Union, Washington, DC, 247-272.

  • Ratajeski, K. (November 25, 2005). The Cretaceous Superplume

  • Ritsema, J., H.J. van Heijst, and J.H. Woodhouse, ''Complex shear wave velocity structure imaged beneath Africa and Iceland,'' Science, 286, 1925-1928, 1999.

  • Saunders, AD, 2005, Large igneous provinces: origin and environmental consequences: Elements, vol. 1, December 2005, 259-263. http://www.elementsmagazine.org/

  • Wignall, P, 2005, The link between large igneous provinces eruptions and mass extinctions: Elements, vol. 1, December 2005, 293-297. http://www.elementsmagazine.org/

  • R.E. Ernst, I.H. Campbell, and K.L. Buchan, 2005, Frontiers in Large Igneous Province Research. Lithos Special Issue 79, edited by A. Kerr, R. England, and P. Wignall, p. 271-297.



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