Earth:Western Interior Seaway

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Short description: Large prehistoric inland sea that split the continent of North America
Map of North America with the Western Interior Seaway during the Campanian

The Western Interior Seaway (also called the Cretaceous Seaway, the Niobraran Sea, the North American Inland Sea, and the Western Interior Sea) was a large inland sea that split the continent of North America into two landmasses. The ancient sea, which existed from the early Late Cretaceous (100 million years ago) to the earliest Paleocene (66 Ma), connected the Gulf of Mexico, through the United States and Canada , to the Arctic Ocean. The two land masses it created were Laramidia to the west and Appalachia to the east. At its largest extent, it was 2,500 feet (760 m) deep, 600 miles (970 km) wide and over 2,000 miles (3,200 km) long.

Origin and geology

A broken concretion with fossils inside; late Cretaceous Pierre Shale near Ekalaka, Montana.
Monument Rocks (Kansas), located 25 miles south of Oakley.

By Late-Cretaceous times, Eurasia and the Americas had separated along the south Atlantic, and subduction on the west coast of the Americas had commenced, resulting in the Laramide orogeny, the early phase of growth of the modern Rocky Mountains. The Western Interior Seaway may be seen as a downwarping of the continental crust ahead of the growing Laramide/Rockies mountain chain.[1]

The earliest phase of the Seaway began in the mid-Cretaceous period when an arm of the Arctic Ocean transgressed south over western North America; this formed the Mowry Sea, so named for the Mowry Shale, an organic-rich rock formation.[1] In the south, the Gulf of Mexico was originally an extension of the Tethys Sea. In time, the southern embayment merged with the Mowry Sea in the late Cretaceous, forming the "complete" Seaway, creating isolated environments for land animals and plants.[1]

Relative sea levels fell multiple times, as a margin of land temporarily rose above the water along the ancestral Transcontinental Arch,[2] each time rejoining the separated, divergent land populations, allowing a temporary mixing of newer species before again separating the populations.

At its largest, the Western Interior Seaway stretched from the Rockies east to the Appalachians, some 1,000 km (620 mi) wide. At its deepest, it may have been only 800 or 900 metres (2,600 or 3,000 ft) deep, shallow in terms of seas. Two great continental watersheds drained into it from east and west, diluting its waters and bringing resources in eroded silt that formed shifting delta systems along its low-lying coasts. There was little sedimentation on the eastern shores of the Seaway; the western boundary, however, consisted of a thick clastic wedge eroded eastward from the Sevier orogenic belt.[1][3] The western shore was thus highly variable, depending on variations in sea level and sediment supply.[1]

Widespread carbonate deposition suggests that the Seaway was warm and tropical, with abundant calcareous planktonic algae.[4] Remnants of these deposits are found in northwest Kansas. A prominent example is Monument Rocks, an exposed chalk formation towering 70 feet (21 m) over the surrounding range land. It is designated a National Natural Landmark and one of the Eight Wonders of Kansas. It is located 25 miles (40 km) south of Oakley, Kansas.[5] The Western Interior Seaway is believed to have behaved similarly to a giant estuary in terms of water mass transport. Riverine inputs exited the seaway as coastal jets, while correspondingly drawing in Tethyan waters from the south and Boreal waters from the north.[6] During the late Cretaceous, the Western Interior Seaway went through multiple periods of anoxia, when the bottom water was devoid of oxygen and the water column was stratified.[7]

At the end of the Cretaceous, continued Laramide uplift hoisted the sandbanks (sandstone) and muddy brackish lagoons (shale), thick sequences of silt and sandstone still seen today as the Laramie Formation, while low-lying basins between them gradually subsided. The Western Interior Seaway divided across the Dakotas and retreated south towards the Gulf of Mexico. This shrunken, and final regressive phase is sometimes called the Pierre Seaway.[1]

During the early Paleocene, parts of the Western Interior Seaway still occupied areas of the Mississippi Embayment, submerging the site of present-day Memphis. Later transgression, however, was associated with the Cenozoic Tejas sequence, rather than with the previous event responsible for the Seaway.[8][9][10]

Fauna

The Western Interior Seaway was a shallow sea, filled with abundant marine life. Interior Seaway denizens included predatory marine reptiles such as plesiosaurs, and mosasaurs. Other marine life included sharks such as Squalicorax, Cretoxyrhina, and the giant shellfish-eating Ptychodus mortoni (believed to be 10 metres (33 ft) long);[11] and advanced bony fish including Pachyrhizodus,[12] Enchodus, and the massive 5-metre (16 ft) long Xiphactinus, larger than any modern bony fish.[13] Other sea life included invertebrates such as mollusks, ammonites, squid-like belemnites, and plankton including coccolithophores that secreted the chalky platelets that give the Cretaceous its name, foraminiferans and radiolarians.[14][15]

The Western Interior Seaway was home to early birds, including the flightless Hesperornis that had stout legs for swimming through water and tiny wings used for marine steering rather than flight; and the tern-like Ichthyornis, an early avian with a toothy beak. Ichthyornis shared the sky with large pterosaurs such as Nyctosaurus and Pteranodon. Pteranodon fossils are very common; it was probably a major participant in the surface ecosystem, though it was found in only the southern reaches of the Seaway.[16]

Inoceramids (oyster-like bivalve molluscs) were well-adapted to life in the oxygen-poor bottom mud of the seaway.[17] These left abundant fossils in the Kiowa, Greenhorn, Niobrara, Mancos, and Pierre formations. There is great variety in the shells and the many distinct species have been dated and can be used to identify specific beds in those rock formations of the seaway. Many species can easily fit in the palm of the hand, while some like Inoceramus (Haploscapha) grandis[18] could be well over a meter in diameter. Entire schools of fish sometimes sought shelter within the shell of the giant Platyceramus.[19] The shells of the genus are known for being composed of prismatic calcitic crystals that grew perpendicular to the surface, and fossils often retain a pearly luster.[20]

See also

References

  1. 1.0 1.1 1.2 1.3 1.4 1.5 Stanley, Steven M. (1999). Earth System History. New York: W.H. Freeman and Company. pp. 487–489. ISBN 0-7167-2882-6. 
  2. R.J. Weimer (1984). J.S. Schlee. ed. "Relation of unconformities, tectonics, and sea-level changes, Cretaceous of Western Interior, U.S.A.; in". AAPG Memoir (American Association of Petroleum Geologists) (Memoir 36, Interregional unconformities and hydrocarbon accumulation): 7-35. https://terra.rice.edu/department/faculty/morganj/ESCI536/Readings/Weimer_CretaceousSeaway.pdf. Retrieved March 6, 2021. "[The url is to a Rice University-hosted pdf of a book chapter adapted from the original Weimer 1984 paper.]". 
  3. Monroe, James S.; Wicander, Reed (2009). The Changing Earth: Exploring Geology and Evolution (5th ed.). Belmont, CA: Brooks/Cole, Cengage Learning. p. 605. ISBN 978-0495554806. https://archive.org/details/changingearthexp00monr. 
  4. "Oceans of Kansas Paleontology". Mike Everhart. http://www.oceansofkansas.com/index2.html. 
  5. Stokes, Keith. "Monument Rocks, the Chalk Pyramids - Kansas". http://www.kansastravel.org/monumentrocks.htm. 
  6. Slingerland, Rudy; Kump, Lee R.; Arthur, Michael A.; Fawcett, Peter J.; Sageman, Bradley B.; Barron, Eric J. (1 August 1996). "Estuarine circulation in the Turonian Western Interior seaway of North America". Geological Society of America Bulletin 108 (8): 941–952. doi:10.1130/0016-7606(1996)108<0941:ECITTW>2.3.CO;2. https://pubs.geoscienceworld.org/gsa/gsabulletin/article-abstract/108/8/941/183171/Estuarine-circulation-in-the-Turonian-Western?redirectedFrom=fulltext. Retrieved 5 April 2023. 
  7. Lowery, Christopher M.; Leckie, R. Mark; Bryant, Raquel; Elderbak, Khalifa; Parker, Amanda; Polyak, Desiree E.; Schmidt, Maxine; Snoeyenbos-West, Oona et al. (1 February 2018). "The Late Cretaceous Western Interior Seaway as a model for oxygenation change in epicontinental restricted basins". Earth-Science Reviews 177: 545–564. doi:10.1016/j.earscirev.2017.12.001. Bibcode2018ESRv..177..545L. https://findresearcher.sdu.dk:8443/ws/files/143467468/Manuscript_REVISED.pdf. 
  8. Stanley, Steven M. (1998). Earth system history. New York: W.H. Freeman. p. 516. ISBN 0716728826. 
  9. Monroe, James S. (1997). The changing earth: exploring geology and evolution (2nd ed.). Belmont, Calif.: Wadsworth Pub. p. 643. ISBN 0314095772. 
  10. Frazier, William J.; Schwimmer, David R. (1987). "The Tejas Sequence: Tertiary—Recent". Regional Stratigraphy of North America. pp. 523–652. doi:10.1007/978-1-4613-1795-1_9. ISBN 978-1-4612-9005-6. 
  11. Walker, Matt (24 February 2010). "Giant predatory shark fossil unearthed in Kansas". BBC Earth News. http://news.bbc.co.uk/earth/hi/earth_news/newsid_8530000/8530995.stm. 
  12. Mike Everhart (February 2, 2010). "Pachyrhizodus. A Large Predatory Fish from the Late Cretaceous Western Interior Sea". Oceans of Kansas Paleontology. http://www.oceansofkansas.com/pachyrhi.html. 
  13. Cumbaa, Stephen L.; Tokaryk, Tim T. (1999). "Recent Discoveries of Cretaceous Marine Vertebrates on the Eastern Margins of the Western Interior Seaway". Saskatchewan Geological Survey Summary of Investigations 1: 57–63. http://publications.gov.sk.ca/documents/310/88504-Cumbaa-Tokaryk_1999_volume1_MiscRep99-4.1.pdf. Retrieved 27 August 2021. 
  14. Boyles, M.J.; Scott, A.J. (1982). "Comparison of Wave-Dominated Deltaic Deposits and Associated Sand-Rich Strand Plains, Mesaverde Group, Northwest Colorado". AAPG Bulletin 66 (5): 551–552. 
  15. Kauffman, E.G. (1984). "Paleobiogeography and evolutionary response dynamic in the Cretaceous Western Interior Seaway of North America". Jurassic-Cretaceous biochronology and paleogeography of North America. 27. Geological Association of Canada. pp. 273–306. http://mmtk.ginras.ru/pdf/Kauffman,1984_K2_N_America.pdf. Retrieved 27 August 2021. 
  16. Benton, S.C. (1994). "The Pterosaurs of the Niobrara Chalk." The Earth Scientist, 11(1): 22-25.
  17. Da Gama, Rui O.B.P.; Lutz, Brendan; Desjardins, Patricio; Thompson, Michelle; Prince, Iain; Espejo, Irene (November 2014). "Integrated paleoenvironmental analysis of the Niobrara Formation: Cretaceous Western Interior Seaway, northern Colorado". Palaeogeography, Palaeoclimatology, Palaeoecology 413: 66–80. doi:10.1016/j.palaeo.2014.05.005. Bibcode2014PPP...413...66D. 
  18. Moss, Rycroft G. (May 2004). "Bulletin 19: The Geology of Ness and Hodgeman Counties, Kansas". Bulletin of the University of Kansas—Lawrence 33 (18): Stratigraphy: Rocks Exposed. http://www.kgs.ku.edu/General/Geology/Ness/04_expos.html. Retrieved 2020-11-17. 
  19. Prothero, Donald R. (2013). Bringing fossils to life : an introduction to paleobiology (Third ed.). New York: Columbia University Press. p. 172. ISBN 9780231158930. 
  20. Ludvigsen, Rolf; Beard, Graham (1997). West Coast Fossils: A Guide to the Ancient Life of Vancouver Island. Harbour Pub.. pp. 102–103. ISBN 9781550171792. https://archive.org/details/westcoastfossils0000ludv. 

Further reading

External links