Capitanian

System/ Period	Series/ Epoch	Stage/ Age	Age (Ma)
Triassic	Lower/ Early	Induan	younger
Permian	Lopingian	Changhsingian	252.2–254.1
	Lopingian	Wuchiapingian	254.1–259.8
	Guadalupian	Capitanian	259.8–265.1
		Wordian	265.1–268.8
		Roadian	268.8–272.3
	Cisuralian	Kungurian	272.3–283.5
		Artinskian	283.5–290.1
		Sakmarian	290.1–295.0
		Asselian	295.0–298.9
Carboniferous	Pennsylvanian	Gzhelian	older
Subdivision of the Permian system according to the ICS (Geologic Time Scale 2013).^[1]

In the geologic timescale, the Capitanian is an age or stage of the Permian. It is also the uppermost or latest of three subdivisions of the Guadalupian epoch or series. The Capitanian lasted between 265.1 and 259.8. It was preceded by the Wordian and followed by the Wuchiapingian.^[2]

A significant mass extinction event (the End-Capitanian extinction event) occurred at the end of this stage, which was associated with anoxia and acidification in the oceans and possibly caused by the volcanic eruptions that produced the Emeishan Traps.^[3] This extinction event may be related to the much larger Permian-Triassic extinction event that followed about 10 million years later.

Stratigraphy

The Capitanian stage was introduced into scientific literature by George Burr Richardson in 1904. The name comes from the Capitan Reef in the Guadalupe Mountains (Texas, United States). The Capitanian was first used as a stratigraphic subdivision of the Guadalupian in 1961,^[4] when both names were still only used regionally in the southern US. The stage was added to the internationally used ISC timescale in 2001.^[5]

Definitions

The base of the Capitanian stage is defined as the place in the stratigraphic record where fossils of conodont species Jinogondolella postserrata first appear. The global reference profile for this stratigraphic boundary is located at Nipple Hill in the southern Guadalupe Mountains of Texas.

The top of the Capitanian (the base of the Wuchiapingian and Lopingian series) is defined as the place in the stratigraphic record where the conodont species Clarkina postbitteri postbitteri first appears.

The Capitanian stage was part of the time in which the Zechstein was deposited in Europe.^[2] It is coeval with the old European regional Saxonian stage. In the eastern Tethys domain, the Capitanian overlaps the regional Murgabian stage, the Midian stage and the lower part of the Laibinian stage. In Russia the Capitanian equals the lower part of the regional Severodvinian stage.

Biostratigraphy

The Capitanian contains one ammonite biozone (Timorites) and three conodont biozones:

zone of Clarkina postbitteri hongshuiensis
zone of Jinogondolella altudaensis
zone of Jinogondolella postserrata

Larger fusulinid species permit a division in two biozones:

zone of Rausserella
zone of Afganella schenki

Biodiversity

Olson’s Extinction, in the Early Guadalupian (Roadian, Wordian), led to an extended period of low diversity when worldwide two-thirds of terrestrial vertebrate life was lost.^[6] Global diversity rose dramatically in the Capitanian, probably the result of disaster taxa filling empty guilds, only to fall again when the end-Guadalupian event caused a diversity drop in the Wuchiapingian.^[7]

Events

Carbon isotopes in marine limestone from the Capitanian age show an increase in δ¹³C values. The change in carbon isotopes in the sea water reflects cooling of global climates.^[8]

This climatic cooling may have caused the end-Capitanian extinction event among species that lived in warm water, like larger fusulinids (Verbeekninidae), large bivalves (Alatoconchidae) and Rugosa corals, and Waagenophyllidae.

Fauna

Synapsids

Synapsids of the Capitanian
Taxa	Presence	Location	Description	Images
Anteosaurus
Titanosuchus

References

↑ "Chronostratigraphic chart 2013". ICS. Retrieved 27 March 2013.
1 2 Gradstein, F.M.; Ogg, J.G. & Smith, A.G.; 2004: A Geologic Time Scale 2004, Cambridge University Press
↑ Bond, D. P. G.; Wignall, P. B.; Joachimski, M. M.; Sun, Y.; Savov, I.; Grasby, S. E.; Beauchamp, B.; Blomeier, D. P. G. (2015-04-14). "An abrupt extinction in the Middle Permian (Capitanian) of the Boreal Realm (Spitsbergen) and its link to anoxia and acidification". Geological Society of America Bulletin. ISSN 0016-7606. doi:10.1130/B31216.1.
↑ Glenister, B.F. & Furnish, W.M.; 1961: The Permian ammonoids of Australia, Journal of Paleontology 35(4), pp 673–736.
↑ Glenister, B.F.; Wardlaw, B.R.; Lambert, L.L.; Spinosa, C.; Bowring, S.A.; Erwin, D.H.; Menning, M. & Wilde, G.L.; 1999: Proposal of Guadalupian and Component Roadian, Wordian and Capitanian Stages as International Standards for the Middle Permian Series, Permophiles 34: pp 3–11.
↑ Bond, David; Hilton, Jason (2010). "The Middle Permian (Capitanian) mass extinction on land and in the oceans". Earth Science Reviews. 102 (1): 100–116.
↑ Sahney, S.; 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. PMC 2596898 . PMID 18198148. doi:10.1098/rspb.2007.1370.
↑ Isozaki, Yukio. "A Unique Carbon Isotope Record across the Guadalupian-Lopingian (Middle-Upper Permian) Boundary in Mid-oceanic Paleo-atoll Carbonates: The High-productivity "Kamura Event" and Its Collapse in Panthalassa." ScienceDirect (2006): 21-38. Web.

External links

GeoWhen Database - Capitanian
Upper Paleozoic stratigraphic chart at the website of the subcommission for stratigraphic information of the ICS

Geologic history of Earth

Cenozoic era
(present–66.0 Mya)

Quaternary (present–2.588 Mya)	Holocene (present–11.784 kya) Pleistocene (11.784 kya–2.588 Mya)
Neogene (2.588–23.03 Mya)	Pliocene (2.588–5.333 Mya) Miocene (5.333–23.03 Mya)
Paleogene (23.03–66.0 Mya)	Oligocene (23.03–33.9 Mya) Eocene (33.9–56.0 Mya) Paleocene (56.0–66.0 Mya)

Mesozoic era
(66.0–252.17 Mya)

Cretaceous (66.0–145.0 Mya)	Late (66.0–100.5 Mya) Early (100.5–145.0 Mya)
Jurassic (145.0–201.3 Mya)	Late (145.0–163.5 Mya) Middle (163.5–174.1 Mya) Early (174.1–201.3 Mya)
Triassic (201.3–252.17 Mya)	Late (201.3–237 Mya) Middle (237–247.2 Mya) Early (247.2–252.17 Mya)

Paleozoic era
(252.17–541.0 Mya)

Permian (252.17–298.9 Mya)	Lopingian (252.17–259.8 Mya) Guadalupian (259.8–272.3 Mya) Cisuralian (272.3–298.9 Mya)
Carboniferous (298.9–358.9 Mya)	Pennsylvanian (298.9–323.2 Mya) Mississippian (323.2–358.9 Mya)
Devonian (358.9–419.2 Mya)	Late (358.9–382.7 Mya) Middle (382.7–393.3 Mya) Early (393.3–419.2 Mya)
Silurian (419.2–443.8 Mya)	Pridoli (419.2–423.0 Mya) Ludlow (423.0–427.4 Mya) Wenlock (427.4–433.4 Mya) Llandovery (433.4–443.8 Mya)
Ordovician (443.8–485.4 Mya)	Late (443.8–458.4 Mya) Middle (458.4–470.0 Mya) Early (470.0–485.4 Mya)
Cambrian (485.4–541.0 Mya)	Furongian (485.4–497 Mya) Series 3 (497–509 Mya) Series 2 (509–521 Mya) Terreneuvian (521–541.0 Mya)

Proterozoic eon
(541.0 Mya–2.5 Gya)

Neoproterozoic (541.0 Mya–1 Gya)	Ediacaran (541.0-~635 Mya) Cryogenian (~635-~720 Mya) Tonian (~720 Mya-1 Gya)
Mesoproterozoic (1–1.6 Gya)	Stenian (1-1.2 Gya) Ectasian (1.2-1.4 Gya) Calymmian (1.4-1.6 Gya)
Paleoproterozoic (1.6–2.5 Gya)	Statherian (1.6-1.8 Gya) Orosirian (1.8-2.05 Gya) Rhyacian (2.05-2.3 Gya) Siderian (2.3-2.5 Gya)

Archean eon (2.5–4 Gya)

Eras	Neoarchean (2.5–2.8 Gya) Mesoarchean (2.8–3.2 Gya) Paleoarchean (3.2–3.6 Gya) Eoarchean (3.6–4 Gya)

Hadean eon (4–4.6 Gya)

(Informal)

kya = thousands years ago. Mya = millions years ago. Gya = billions years ago.
Source: (2015/01). International Commission on Stratigraphy. Retrieved 13 July 2015. Divisions of Geologic Time—Major Chronostratigraphic and Geochronologic Units USGS Retrieved 10 March 2013.

Coordinates: 31°54′33″N 104°47′21″W / 31.9091°N 104.7892°W / 31.9091; -104.7892

Preceded by Proterozoic Eon	Phanerozoic Eon
	Paleozoic Era						Mesozoic Era			Cenozoic Era
	Cambrian	Ordovician	Silurian	Devonian	Carboniferous	Permian	Triassic	Jurassic	Cretaceous	Paleogene	Neogene	4ry