Morrison Formation Explained

Morrison Formation
Type:Geologic formation
Age:Upper Jurassic (Kimmeridgian to Tithonian),
Period:Upper Jurassic
Prilithology:Mudstone
Otherlithology:Sandstone, siltstone, limestone
Namedfor:Morrison, Colorado
Region:Central North America:












Country:[1]
Coordinates:39.651°N -105.188°W
Underlies:Cedar Mountain Formation, Cloverly Formation, Lakota Formation, Burro Canyon Formation
Overlies:Summerville Formation, Beclabito Formation, Curtis Formation, Bell Ranch Formation, Sundance Formation
Thickness:Up to 200 m
Paleocoordinates:40.4°N -53.2°W

The Morrison Formation is a distinctive sequence of Upper Jurassic sedimentary rock found in the western United States which has been the most fertile source of dinosaur fossils in North America. It is composed of mudstone, sandstone, siltstone, and limestone and is light gray, greenish gray, or red. Most of the fossils occur in the green siltstone beds and lower sandstones, relics of the rivers and floodplains of the Jurassic period.

It is centered in Wyoming and Colorado, with outcrops in Montana, North Dakota, South Dakota, Nebraska, Kansas, the panhandles of Oklahoma and Texas, New Mexico, Arizona, Utah, and Idaho. Equivalent rocks under different names are found in Canada.[2] It covers an area of 1.5 million square kilometers (600,000 square miles), although only a tiny fraction is exposed and accessible to geologists and paleontologists. Over 75% is still buried under the prairie to the east, and much of its western paleogeographic extent was eroded during exhumation of the Rocky Mountains.

It was named after Morrison, Colorado, where some of the first fossils in the formation were discovered by Arthur Lakes in 1877. That same year, it became the center of the Bone Wars, a fossil-collecting rivalry between early paleontologists Othniel Charles Marsh and Edward Drinker Cope. In Colorado, New Mexico, and Utah, the Morrison Formation was a major source of uranium ore.

Geologic history

According to radiometric dating, the Morrison Formation dates from 156.3 ± 2 million years old (Ma) at its base,[3] to 146.8 ± 1 million years old at the top,[4] which places it in the earliest Kimmeridgian, and early Tithonian stages of the late Jurassic. This is similar in age to the Solnhofen Limestone Formation in Germany and the Tendaguru Formation in Tanzania. The age and much of the fauna is similar to the Lourinhã Formation in Portugal.[5] Throughout the western United States, it variously overlies the Middle Jurassic Summerville, Sundance, Bell Ranch, Wanakah, and Stump Formations.

At the time, the supercontinent of Laurasia had recently split into the continents of North America and Eurasia, although they were still connected by land bridges. North America moved north and was passing through the subtropical regions.

The Morrison Basin, which stretched from New Mexico in the south to Alberta and Saskatchewan in the north, was formed during the Nevadan orogeny, a precursor event to later orogenic episodes that created the Rocky Mountains started pushing up to the west. The deposits from their east-facing drainage basins, carried by streams and rivers from the Elko Highlands (along the borders of present-day Nevada and Utah) and deposited in swampy lowlands, lakes, river channels and floodplains, became the Morrison Formation.[6]

In the north, the Sundance Sea, an extension of the Arctic Ocean, stretched through Canada down to the United States. Coal is found in the Morrison Formation of Montana, which means that the northern part of the formation, along the shores of the sea, was wet and swampy, with more vegetation. Aeolian, or wind-deposited sandstones, are found in the southwestern part, which indicates it was much more arid—a desert, with sand dunes.

Stratigraphy

The Morrison Formation is subdivided into several members, the occurrence of which are varied across the geographic extent of the Morrison. Members are (in alphabetical order):[7] [8]

Other informal or disused designations of the Morrison include the Stockett Bed in Montana, an unofficial sub-unit which contains bituminous coal;[27] the outdated terms Casamero, Chavez, and Prewitt Sandstone for the Brushy Basin, Recapture, and Westwater Canyon, respectively;[28] [29] and the Bullington Member, which has been discarded entirely.

Fossil content

See main article: Paleobiota of the Morrison Formation.

See main article: List of dinosaurs of the Morrison Formation. Though many of the Morrison Formation fossils are fragmentary, they are sufficient to provide a good picture of the flora and fauna in the Morrison Basin during the Kimmeridgian. Overall, the climate was dry, similar to a savanna but, since there were no angiosperms (grasses, flowers, and some trees), the flora was quite different. Conifers, the dominant plants of the time, were to be found with ginkgos, cycads, tree ferns, and horsetail rushes. Much of the fossilized vegetation was riparian, living along the river flood plains. Along the rivers, there were fish, frogs, salamanders, lizards, crocodiles, turtles, pterosaurs, crayfish, clams, and mammaliforms.The dinosaurs were most likely riparian, as well.[6] Hundreds of dinosaur fossils have been discovered, such as Allosaurus, Ceratosaurus, Torvosaurus, Saurophaganax, Camptosaurus, Ornitholestes, several stegosaurs comprising at least two species of Stegosaurus and the slightly older Hesperosaurus, and the early ankylosaurs, Mymoorapelta and Gargoyleosaurus, most notably a very broad range of sauropods (the giants of the Mesozoic era).[30] Since at least some of these species are known to have nested in the area (Camptosaurus embryoes have been discovered), there are indications that it was a good environment for dinosaurs and not just home to migratory, seasonal populations. However, the large body mass of the sauropods has been interpreted as an adaptation to migration in times of drought.[6]

Sauropods that have been discovered include Diplodocus (most famously, the first nearly complete specimen of D. carnegii, which is now exhibited at the Carnegie Museum of Natural History, in Pittsburgh, Pennsylvania), Camarasaurus (the most commonly found sauropod), Brachiosaurus, Apatosaurus, Brontosaurus, Barosaurus, the uncommon Haplocanthosaurus and Supersaurus. The very diversity of the sauropods has raised some questions about how they could all co-exist. While their body shapes are very similar (long neck, long tail, huge elephant-like body), they are assumed to have had very different feeding strategies, in order for all to have existed in the same time frame and similar environment.

Sites and quarries

Locations where significant Morrison Formation fossil discoveries have been made include:

Colorado

Utah

Wyoming

Economic geology

The Morrison Formation contains uranium deposits, including the Jackpile uranium body discovered near Grants, New Mexico in 1951.[12] The ore deposits in the rich Grants mineral belt are concentrated in sandstone beds of the Westwater Canyon Member and the Jackpile Member. Mines in this belt produced 340000000lbs of U3O8 between 1948 and 2002. The uranium was precipitated by plant debris and humate that acted as reducing agents.[35]

See also

Further reading

External links

Notes and References

  1. Web site: Morrison Formation. CGKN. 25 May 2013.
  2. Parrish . J.T. . Peterson, F. . Turner, C.E. . 2004 . Jurassic "savannah"-plant taphonomy and climate of the Morrison Formation (Upper Jurassic, Western USA) . Sedimentary Geology . 167 . 3–4 . 137–162 . 10.1016/j.sedgeo.2004.01.004 . 2004SedG..167..137P .
  3. Trujillo . K.C. . Chamberlain, K.R. . Strickland, A. . 2006 . Oxfordian U/Pb ages from SHRIMP analysis for the Upper Jurassic Morrison Formation of southeastern Wyoming with implications for biostratigraphic correlations . Geological Society of America Abstracts with Programs . 38 . 6 . 7.
  4. Book: Bilbey, S.A. . 1998 . Cleveland-Lloyd Dinosaur Quarry - age, stratigraphy and depositional environments . 87–120 . The Morrison Formation: An Interdisciplinary Study . Carpenter, K. . Chure, D. . Kirkland, J.I. . Modern Geology . 22 . Taylor and Francis Group . 0026-7775.
  5. Mateus, O. 2006. Late Jurassic dinosaurs from the Morrison Formation, the Lourinhã and Alcobaça Formations (Portugal), and the Tendaguru Beds (Tanzania): a comparison. in Foster, J.R. and Lucas, S. G. R.M., eds., 2006, Paleontology and Geology of the Upper Jurassic Morrison Formation. New Mexico Museum of Natural History and Science Bulletin 36: 223-231.
  6. Turner . Christine E. . Peterson . Fred . Reconstruction of the Upper Jurassic Morrison Formation extinct ecosystem—a synthesis . Sedimentary Geology . May 2004 . 167 . 3–4 . 309–355 . 10.1016/j.sedgeo.2004.01.009. 2004SedG..167..309T .
  7. Web site: Geologic Unit: Morrison. December 30, 2020. USGS Geolex.
  8. Web site: Geologic Unit: Windy Hill. December 30, 2020. USGS Geolex.
  9. Web site: Condon . S.M. . Stratigraphic Sections of the Middle Jurassic Wanakah Formation, Cow Springs Sandstone, and adjacent rocks, from Bluff, Utah, to Lupton, Arizona: U.S. Geologic Survey Oil and Gas Investigation Chart, OC-131 . USGS Geolex . U.S. Geological Survey . December 31, 2020.
  10. Bell, Thomas, "Deposition and Diagenesis of the Brushy Basin Member and the Upper Part of the Westwater Canyon Member of the Morrison Formation, San Juan Basin, New Mexico," in A Basin Analysis Case Study: The Morrison Grants Uranium Region New Mexico, edited by Neil S. Fishermen, Elmer S. Santos, and Christine E. Turner-Peterson, American Association of Petroleum Geolgists, Tulsa, 1986.
  11. Peterson . Fred . Revisions to Stratigraphic Nomenclature of Jurassic and Cretaceous Rocks of the Colorado Plateau . U.S. Geological Survey Bulletin . 1988 . 1633 . B . 13-56 . December 31, 2020.
  12. Owen . Donald E. . Walters . Lester J. Jr. . Beck . Ronald G. . The Jackpile Sandstone Member of the Morrison Formation in west-central New Mexicoby Donald E. jwen, Consulting Geologist, Tulsa, 0K 74152, and Lester J.Walters, Jr. and Ronald G. Beck, ARCO Oil and Gas Co., Dallas, IX75221 a formal definiti . New Mexico Geology . August 1984 . 6 . 3 . 10.58799/NMG-v6n3.45 . 4 June 2020.
  13. Dickinson . William R. . Gehrels . George E. . Implications of U-Pb ages of detrital zircons in Mesozoic strata of the Four Corners region for provenance relations in space and time . New Mexico Geological Society Field Conference Series . 2010 . 61 . 135–146 . 27 October 2020.
  14. Cather . Steven M. . Jurassic stratigraphic nomenclature for northwestern New Mexico . New Mexico Geological Society Special Publication . 2020 . 14 . 145–151 . 31 October 2020.
  15. Carpenter. Kenneth. Lindsey. Eugene. 2019-01-31. Redefining the Upper Jurassic Morrison Formation in Garden Park National Natural Landmark and vicinity, eastern Colorado. Geology of the Intermountain West. en. 6. 1–30. 10.31711/giw.v6.pp1-30. 2380-7601. free.
  16. Condon . S.M. . Huffman . A.C. . Revisions in nomenclature of the Middle Jurassic Wanakah Formation, Northwest New Mexico and northeast Arizona . U.S. Geological Survey Bulletin . 1988 . 1633 . A . 1-12 . 8 February 2021.
  17. Book: Allan R. Kirk . Steven M. Condon . Structural Control of Sedimentation Patterns and the Distribution of Uranium Deposits in the Westwater Canyon Member of the Morrison Formation, Northwestern New Mexico--A Subsurface Study . Turner-Peterson . C.E. . Santos . Elmer S. . Fishman . Neil S. . Basin Analysis Case Study: The Morrison Formation, Grants Uranium Region, New Mexico . 1986 . The American Association of Petroleum Geologists . Tulsa . 110-111.
  18. Peterson . Fred . Turner-Peterson . C.E. . The Morrison Formation of the Colorado Plateau: recent advances in sedimentology, stratigraphy, and paleotectonics . Hunter . 1987 . 2 . 1 . 1-18 . 8 February 2021.
  19. O'Sullivan . R.B. . The base of the Upper Jurassic Morrison Formation in east-central Utah . U.S. Geological Survey Bulletin . 1984 . 1561 . 17 . 8 February 2021.
  20. Peterson . Fred . Stratigraphy and Nomenclature of Middle and Upper Jurassic rocks, western Colorado Plateau, Utah and Arizona . U.S. Geological Survey Bulletin . 1988 . 1633 . B . 13-56 . 9 February 2021.
  21. Mapel . W.J. . Chisholm . W.A. . Nonopaque heavy minerals in sandstone of Jurassic and Cretaceous age in the Black Hills, Wyoming and South Dakota . U.S. Geological Survey Bulletin . 1962 . 1161 . C . 1-59.
  22. Book: Szigeti, G.J . Fox, J.E. . Unkpapa Sandstone (Jurassic), Black Hills, South Dakota; an eolian facies of the Morrison Formation . Ethridge . F.G. . Flores . R.M. . Recent and Ancient non marine depositional environments: models for exploration . 1979 . Society of Economic Paleontologists and Mineralogists Special Publication . Casper, WY . 331-349.
  23. Mapel . W.J. . Chisholm . W.A. . Nonopaque heavy minerals in sandstone of Jurassic and Cretaceous age in the Black Hills, Wyoming and South Dakota . U.S. Geological Survey Bulletin . 1962 . 1161 . C . 1-59.
  24. Book: Christine E. Turner-Peterson . Fluvial Sedimentology of a Major Uranium-Bearing Sandstone-- A Study of the Westwater Canyon Member of the Morrison Formation, San Juan Basin, New Mexico . Turner-Peterson . C.E. . Santos . Elmer S. . Fishman . Neil S. . Basin Analysis Case Study: The Morrison Formation, Grants Uranium Region, New Mexico . 1986 . The American Association of Petroleum Geologists . Tulsa . 110-111.
  25. Book: Fred Peterson . Sand dunes, sabkhas, streams, and shallow seas: Jurassic paleogeography in the southern part of the Western Interior Basin . Caputo . M.V. . Peterson . J.A. . Franczyk . K.J. . Mesozoic Systems of the Rocky Mountain Region, USA . Society of Economic Paleontologists and Mineralogists, Rocky Mountain Section . 233-272.
  26. Pipiringos . G.N. . Correlation and Nomenclature of some Triassic and Jurassic Rocks in south-central Wyoming . U.S. Geological Survey Professional Paper . 1968 . 594 . D . 1-26 . 8 February 2021.
  27. Daniel . J.A. . Bartholomew . M.J. . Murray . R.C. . Geological Characteristics of the Stockett Bed Coal in the Central Great Falls Coal Field, Montana . Montana Bureau of Mines and Geology Special Publication . 1992 . 102 . 145-157.
  28. Smith . C.T. . Geology of the Thoreau quadrangle, McKinley and Valencia Counties, New Mexico . New Mexico Bureau of Mines and Mineral Resources . 1954 . 31.
  29. Robertson . J.F. . Geologic map of the Thoreau quadrangle, McKinley County, New Mexico . U.S. Geological Survey . 1990.
  30. Dodson. Peter. Behrensmeyer. A. K.. Bakker. Robert T.. McIntosh. John S.. 1980. Taphonomy and Paleoecology of the Dinosaur Beds of the Jurassic Morrison Formation. Paleobiology. 6. 2. 208–232. 10.1017/s009483730000676x. 1980Pbio....6..208D . 130686856 . 0094-8373.
  31. Evanoff, E., & Carpenter, K. (1998). History, sedimentology, and taphonomy of felch quarry 1 and associated sandbodies, Morrison Formation, Garden Park, Colorado. Modern Geology, 22, 423-170.
  32. Web site: Gates . Terry . The Late Jurassic Cleveland-Lloyd Dinosaur Quarry as a Drought-Induced Assemblage . PALAIOS . 19 June 2024.
  33. Peterson . Joseph E. . Warnock . Jonathan P. . Eberhart . Shawn L. . Clawson . Steven R. . Noto . Christopher R. . New data towards the development of a comprehensive taphonomic framework for the Late Jurassic Cleveland-Lloyd Dinosaur Quarry, Central Utah . PeerJ . e3368 . 10.7717/peerj.3368 . 2017. 5 . free . 28603668 . 5463971 .
  34. Saleiro, A., & Mateus O. (2017). Upper Jurassic bonebeds around Ten Sleep, Wyoming, USA: overview and stratigraphy. Abstract book of the XV Encuentro de Jóvenes Investigadores en Paleontología/XV Encontro de Jovens Investigadores em Paleontologia, Lisboa, 428 pp.. 357-361.
  35. Wilton . Ted . Chavez . William X. Jr. . Caldwell . Samantha . Sandstone-hosted uranium deposits at the Cebolleta Land Grant, Cibola County, New Mexico . New Mexico Geological Society Special Publication . 2020 . 14 . 67–75 . 27 October 2020.