Mesozoic

Mesozoic Era 251 - 65.5 million years ago

Key events in the Mesozoic view • discuss • edit -260 — – -240 — – -220 — – -200 — – -180 — – -160 — – -140 — – -120 — – -100 — – -80 — – -60 — – Paleozoic Cenozoic Triassic Jurassic Cretaceous         M e s o z o i c  Phanerozoic An approximate timescale of key Mesozoic events. Axis scale: millions of years ago.

The Mesozoic Era is an interval of geological time from about 250 million years ago to about 65 million years ago. It is often referred to as the age of reptiles because reptiles, namely dinosaurs, were the dominant terrestrial and marine vertebrates of the time. The era began in the wake of the Permian-Triassic event, the largest mass extinction in Earth's history, and ended with the Cretaceous-Paleogene event, another mass extinction which is known for having killed off non-avian dinosaurs, as well as other plant and animal species.

It is one of three geologic eras of the Phanerozoic Eon. The division of time into eras dates back to Giovanni Arduino, in the 18th century, although his original name for the era now called the Mesozoic was Secondary (making everything after, including the modern era, the Tertiary; the current term Quaternary was later proposed for the modern era, following the same numbering principle). Lying between the Paleozoic and the Cenozoic, Mesozoic means "middle life", deriving from the Greek prefix meso-/μεσο- for "between" and zōon/ζωον meaning "animal" or "living being".

The Mesozoic was a time of tectonic, climatic and evolutionary activity. The era witnessed the gradual rifting of the supercontinent Pangaea into separate landmasses which would eventually become the seven continents we are familiar with today. The climate of the Mesozoic was varied, alternating between warming and cooling periods. Overall, however, the Earth was much hotter than it is today. Dinosaurs would become the dominant terrestrial vertebrate group late in the Triassic Period, and would occupy this position for over 150 million years until their demise at the end of the Cretaceous. Mammals also evolved during this era, but would remain small and modest until their ultimate rivals, the dinosaurs, disappeared.

Geologic periods

Following the Paleozoic, the Mesozoic extended roughly 180 million years: from 251 million years ago (Mya) to when the Cenozoic Era began 65 Mya. This time frame is separated into three geologic periods. From oldest to youngest:

• Triassic (251.0 Mya to 199.6 Mya)
• Jurassic (199.6 Mya to 145.5 Mya)
• Cretaceous (145.5 Mya to 65.5 Mya)

The lower (Triassic) boundary is set by the Permian-Triassic extinction event, during which approximately 90% to 96% of marine species and 70% of terrestrial vertebrates became extinct. It is also known as the "Great Dying" because it is considered the largest mass extinction in the Earth's history. The upper (Cretaceous) boundary is set at the Cretaceous-Tertiary (KT) extinction event (now more accurately called the Cretaceous–Paleogene (or K–Pg) extinction event^[1]), which may have been caused by the impactor that created Chicxulub Crater on the Yucatán Peninsula. Towards the Late Cretaceous large volcanic eruptions are also believed to have contributed to the K-Pg extinction event. Approximately 50% of all genera became extinct, including all of the non-avian dinosaurs.

Paleogeography and tectonics

Compared to the vigorous convergent plate mountain-building of the late Paleozoic, Mesozoic tectonic deformation was comparatively mild. The sole major Mesozoic orogeny occurred in what is now the Arctic, creating the Innuitian orogeny, the Brooks Range, the Verkhoyansk and Cherskiy Ranges in Siberia, and the Khingan Mountains in Manchuria. This orogeny was related to the opening of the Arctic Ocean and subduction of the North China and Siberian cratons under the Pacific Ocean^[2]. Nevertheless, the era featured the dramatic rifting of the supercontinent Pangaea. Pangaea gradually split into a northern continent, Laurasia, and a southern continent, Gondwana. This created the passive continental margin that characterizes most of the Atlantic coastline (such as along the U.S. East Coast) today.^[3]

By the end of the era, the continents had rifted into nearly their present form. Laurasia became North America and Eurasia, while Gondwana split into South America, Africa, Australia, Antarctica and the Indian subcontinent, which collided with the Asian plate during the Cenozoic, the impact giving rise to the Himalayas.

Africa

The African prosauropod Massospondylus.

At the beginning of the Mesozoic Era, Africa was joined with Earth's other continents in Pangaea.^[4] Africa shared the supercontinent's relatively uniform fauna which was dominated by theropods, prosauropods and primitive ornithischians by the close of the Triassic Period.^[4] Late Triassic fossils are found throughout Africa, but are more common in the south than north.^[4] The boundary separating the Triassic and Jurassic marks the advent of an extinction event with global impact, although African strata from this time period have not been thoroughly studied.^[4]

Early Jurassic strata are distributed in a similar fashion to Late Triassic beds, with more common outcrops in the south and less common fossil beds which are predominated by tracks to the north.^[4] As the Jurassic proceeded, larger and more iconic groups of dinosaurs like sauropods and ornithopods proliferated in Africa.^[4] Middle Jurassic strata are neither well represented nor well studied in Africa.^[4] Late Jurassic strata are also poorly represented apart from the spectacular Tendaguru fauna in Tanzania.^[4] The Late Jurassic life of Tendaguru is very similar to that found in western North America's Morrison Formation.^[4]

Midway through the Mesozoic, about 150-160 million years ago, Madagascar separated from Africa, although it remained connected to India and the rest of the Gondwanan landmasses.^[4] Fossils from Madagascar include abelisaurs and titanosaurs.^[4]

The African theropod Spinosaurus, the largest known predatory land animal of all time.

Later into the Early Cretaceous Epoch, the India-Madagascar landmass separated from the rest of Gondwana.^[4] By the Late Cretaceous, Madagascar and India had permanently split ways and continued until later reaching their modern configurations.^[4]

By contrast to Madagascar, mainland Africa was relatively stable in position through-out the Mesozoic.^[4] Despite the stable position, major changes occurred to its relation to other landmasses as the remains of Pangaea continued to break apart.^[4] By the beginning of the Late Cretaceous Epoch South America had split off from Africa, completing the southern half of the Atlantic Ocean.^[4] This event had a profound effect on global climate by altering ocean currents.^[4]

During the Cretaceous, Africa was populated by allosauroids and spinosaurids, including the largest known carnivorous dinosaurs.^[4] Titanosaurs were significant herbivores in its ancient ecosystems.^[4] Cretaceous sites are more common than Jurassic ones, but are often unable to be dated radiometrically making it difficult to know their exact ages.^[4] Paleontologist Louis Jacobs, who spent time doing field work in Malawi,^[5] says that African beds are "in need of more field work" and will prove to be a "fertile ground...for discovery."^[4]

Climate

The Triassic was generally dry, a trend that began in the late Carboniferous, and highly seasonal, especially in the interior of Pangaea. Low sea levels may have also exacerbated temperature extremes. With its high specific heat capacity, water acts as a temperature-stabilizing heat reservoir, and land areas near large bodies of water—especially the oceans—experience less variation in temperature. Because much of the land that constituted Pangaea was distant from the oceans, temperatures fluctuated greatly, and the interior of Pangaea probably included expansive areas of desert. Abundant evidence of red beds and evaporites such as halite support these conclusions.

Sea levels began to rise during the Jurassic, which was probably caused by an increase in seafloor spreading. The formation of new crust beneath the surface displaced ocean waters by as much as 200 m (656 ft) more than today, which flooded coastal areas. Furthermore, Pangaea began to rift into smaller divisions, bringing more land area in contact with the ocean by forming the Tethys Sea. Temperatures continued to increase and began to stabilize. Humidity also increased with the proximity of water, and deserts retreated.

The climate of the Cretaceous is less certain and more widely disputed. Higher levels of carbon dioxide in the atmosphere are thought to have caused the world temperature gradient from north to south to become almost flat: temperatures were about the same across the planet. Average temperatures were also higher than today by about 10°C. In fact, by the middle Cretaceous, equatorial ocean waters (perhaps as warm as 20°C in the deep ocean) may have been too warm for sea life, and land areas near the equator may have been deserts despite their proximity to water. The circulation of oxygen to the deep ocean may also have been disrupted. For this reason, large volumes of organic matter that was unable to decompose accumulated, eventually being deposited as "black shale".

Not all of the data support these hypotheses, however. Even with the overall warmth, temperature fluctuations should have been sufficient for the presence of polar ice caps and glaciers, but there is no evidence of either. Quantitative models have also been unable to recreate the flatness of the Cretaceous temperature gradient.^{[citation needed]}

Different studies have come to different conclusions about the amount of oxygen in the atmosphere during different parts of the Mesozoic, with some concluding oxygen levels were lower than the current level (about 21%) throughout the Mesozoic,^[6][7] some concluding they were lower in the Triassic and part of the Jurassic but higher in the Cretaceous,^[8][9][10] and some concluding they were higher throughout most or all of the Triassic, Jurassic and Cretaceous.^[11][12]

Life

The first true mammals appeared in the Mesozoic but remained small and did not diversify widely until the Cenozoic.

The extinction of nearly all animal species at the end of the Permian Period allowed for the radiation of many new lifeforms. In particular, the extinction of the large herbivorous and carnivorous dinocephalia left those ecological niches empty. Some were filled by the surviving cynodonts and dicynodonts, the latter of which subsequently became extinct. Some plant species had distributions that were markedly different from succeeding periods; for example, the Schizeales, a fern order, were skewed to the Northern Hemisphere in the Mesozoic, but are now better represented in the Southern Hemisphere.^[13]

The dominant land plant species of the time were gymnosperms, which are vascular, cone-bearing, non-flowering plants such as conifers that produce seeds without a coating. This is opposed to the earth's current flora, in which the dominant land plants in terms of number of species are angiosperms. One particular plant species, the ginkgo biloba, is perceived to have evolved at this time and still exists today as the only surviving species from its phylum. As well, the extant genus sequoia is believed to have evolved in the Mesozoic. ^[14]

Recent research indicates that the specialized animals that formed complex ecosystems, with high biodiversity, complex food webs and a variety of niches, took much longer to reestablish, recovery did not begin until the start of the mid-Triassic, 4M to 6M years after the extinction^[15] and was not complete until 30M years after the P-Tr extinction.^[16] Animal life was then dominated by large archosaurian reptiles: dinosaurs, pterosaurs, and aquatic reptiles such as ichthyosaurs, plesiosaurs, and mosasaurs.

The climatic changes of the late Jurassic and Cretaceous provided for further adaptive radiation. The Jurassic was the height of archosaur diversity, and the first birds and placental mammals also appeared. Angiosperms radiated sometime in the early Cretaceous, first in the tropics, but the even temperature gradient allowed them to spread toward the poles throughout the period. By the end of the Cretaceous, angiosperms dominated tree floras in many areas, although some evidence suggests that biomass was still dominated by cycad and ferns until after the KT extinction.

Some have argued that insects diversified with angiosperms because insect anatomy, especially the mouth parts, seems particularly well-suited for flowering plants. However, all major insect mouth parts preceded angiosperms and insect diversification actually slowed when they arrived, so their anatomy originally must have been suited for some other purpose.

As the temperatures in the seas increased, the larger animals of the early Mesozoic gradually began to disappear while smaller animals of all kinds, including lizards, snakes, and perhaps primates, evolved. The KT extinction exacerbated this trend. The large archosaurs became extinct, while birds and mammals thrived, as they do today.

See also

• Cenozoic
• Paleozoic
• Precambrian

References

1. Gradstein F, Ogg J, Smith A. A Geologic Time Scale 2004. http://www.cambridge.org/uk/catalogue/catalogue.asp?isbn=0521781426. 
2. See Hughes, T.; “ The case for creation of the North Pacific Ocean during the Mesozoic Era” in Palaeogeography, Palaeoclimatology, Palaeoecology; Volume 18, Issue 1, August 1975, Pages 1-43
3. Stanley, Steven M. Earth System History. New York: W.H. Freeman and Company, 1999. ISBN 0-7167-2882-6
4. ^ Jacobs, Louis, L. (1997). "African Dinosaurs." Encyclopedia of Dinosaurs. Edited by Phillip J. Currie and Kevin Padian. Academic Press. p. 2-4.
5. Jacobs, Louis L. (2000). Quest for the African Dinosaurs: Ancient Roots of the Modern World. JHU Press. pp. 316. ISBN 9780801864810 / 080186481X. http://www.books.google.com/books?id=tpgxFi3x1SgC. 
6. Robert A. Berner, John M. VandenBrooks and Peter D. Ward, 2007, Oxygen and Evolution. Science 27 April 2007, Vol. 316 no. 5824 pp. 557-558 . A graph showing the reconstruction from this paper can be found here, from the webpage Paleoclimate - The History of Climate Change.
7. Berner R. A. 2006 GEOCARBSULF: a combined model for Phanerozoic atmospheric O2 and CO2. Geochim. Cosmochim. Acta 70, 5653–5664. See the dotted line in Fig. 1 of Atmospheric oxygen level and the evolution of insect body size by Jon F. Harrison, Alexander Kaiser and John M. VandenBrooks
8. Berner, Robert A., 2009, Phanerozoic atmospheric oxygen: New results using the GEOCARBSULF model. Am. J. Sci. 309 no. 7, 603-606. A graph showing the reconstructed levels in this paper can be found on p. 31 of the book Living Dinosaurs by Gareth Dyke and Gary Kaiser.
9. Berner R. A., Canfield D. E. 1989 A new model for atmospheric oxygen over phanerozoic time. Am. J. Sci. 289, 333–361. See the solid line in Fig. 1 of Atmospheric oxygen level and the evolution of insect body size by Jon F. Harrison, Alexander Kaiser and John M. VandenBrooks
10. Berner, R, et al., 2003, Phanerozoic atmospheric oxygen, Ann. Rev. Earth Planet. Sci., V, 31, p. 105-134. See the graph near the bottom of the webpage Phanerozoic Eon
11. Glasspool, I.J., Scott, A.C., 2010, Phanerozoic concentrations of atmospheric oxygen reconstructed from sedimentary charcoal, Nature Geosciences, 3, 627-630
12. Bergman N. M., Lenton T. M., Watson A. J. 2004 COPSE: a new model of biogeochemical cycling over Phanaerozoic time. Am. J. Sci. 304, 397–437. See the dashed line in Fig. 1 of Atmospheric oxygen level and the evolution of insect body size by Jon F. Harrison, Alexander Kaiser and John M. VandenBrooks
13. C.Michael Hogan. 2010. Fern. Encyclopedia of Earth. National council for Science and the Environment. Washington, DC
14. Stan Baducci. Mesozoic Plants..
15. Lehrmann, D.J., Ramezan, J., Bowring, S.A., et al. (December 2006). "Timing of recovery from the end-Permian extinction: Geochronologic and biostratigraphic constraints from south China". Geology 34 (12): 1053–1056. doi:10.1130/G22827A.1. http://geology.geoscienceworld.org/cgi/content/abstract/34/12/1053. 
16. Sahney, S. and Benton, M.J. (2008). "Recovery from the most profound mass extinction of all time" (PDF). Proceedings of the Royal Society: Biological 275 (1636): 759–65. doi:10.1098/rspb.2007.1370. PMC 2596898. PMID 18198148. http://journals.royalsociety.org/content/qq5un1810k7605h5/fulltext.pdf. 

• British Mesozoic Fossils, 1983, The Natural History Museum, London.

External links

• The Mesozoic from Palaeos
• The Mesozoic, age of cycads and dinosaurs
• Mesozoic terrestrial ecosystems
• Mesozoic climates
• Paleozoic/Mesozoic climate

Preceded by Proterozoic Eon	542 Ma - Phanerozoic Eon - Present
	542 Ma - Paleozoic Era - 251 Ma						251 Ma - Mesozoic Era - 65 Ma			65 Ma - Cenozoic Era - Present
	Cambrian	Ordovician	Silurian	Devonian	Carboniferous	Permian	Triassic	Jurassic	Cretaceous	Paleogene	Neogene	Quaternary