Pennsylvanian (geology) explained

Pennsylvanian
Color:Pennsylvanian
Time Start:323.2
Time Start Uncertainty:0.4
Time End:298.9
Time End Uncertainty:0.15
Caption Map:Map of Earth as it appeared 300 million years ago during the latest Pennsylvanian, Gzhelian stage
Timeline:Carboniferous
Name Formality:Formal
Celestial Body:earth
Usage:Global (ICS)
Timescales Used:ICS Time Scale
Chrono Unit:Subperiod
Timespan Formality:Formal
Lower Boundary Def:First appearance of the Conodont Declinognathodus nodiliferus.
Lower Gssp Location:Arrow Canyon, Nevada, United States
Lower Gssp Accept Date:1996[1]
Upper Boundary Def:First appearance of the Conodont Streptognathodus isolatus within the morphotype Streptognathodus wabaunsensis chronocline.
Upper Gssp Location:Aidaralash, Ural Mountains, Kazakhstan
Upper Gssp Accept Date:1996[2]

The Pennsylvanian (also known as Upper Carboniferous or Late Carboniferous) is, on the ICS geologic timescale, the younger of two subperiods of the Carboniferous Period (or the upper of two subsystems of the Carboniferous System). It lasted from roughly . As with most other geochronologic units, the rock beds that define the Pennsylvanian are well identified, but the exact date of the start and end are uncertain by a few hundred thousand years. The Pennsylvanian is named after the U.S. state of Pennsylvania, where the coal beds of this age are widespread.[3]

The division between Pennsylvanian and Mississippian comes from North American stratigraphy. In North America, where the early Carboniferous beds are primarily marine limestones, the Pennsylvanian was in the past treated as a full-fledged geologic period between the Mississippian and the Permian. In parts of Europe, the Mississippian and Pennsylvanian are one more-or-less continuous sequence of lowland continental deposits and are grouped together as the Carboniferous Period. The current internationally used geologic timescale of the ICS gives the Mississippian and Pennsylvanian the rank of subperiods, subdivisions of the Carboniferous Period.

Life

Fungi

All modern classes of fungi have been found in rocks of Pennsylvanian age.[4]

Invertebrates

The major forms of life at this time were the arthropods. Arthropods were far larger than modern ones. Arthropleura, a giant millipede, was a common sight and the giant griffinfly Meganeura "flew the skies".[5] It is commonly considered that is because of high oxygen level, however some of those large arthropod records are also known from period with relatively low oxygen, which suggest high oxygen pressure may not have been a primary reason for their gigantism.[6] [7]

Vertebrates

Amphibians were diverse and common; some were several meters long as adults. The collapse of the rainforest ecology in the mid-Pennsylvanian (between the Moscovian and the Kasimovian) removed many amphibian species that did not survive as well in the cooler, drier conditions. Amniotes, however, prospered due to specific key adaptations.[8] One of the greatest evolutionary innovations of the Carboniferous was the amniote egg, which allowed for the further exploitation of the land by certain tetrapods. These included the earliest sauropsid reptiles (Hylonomus), and the earliest known "pelycosaur" synapsids (Archaeothyris). Small lizard-like animals quickly gave rise to many descendants. Amniotes underwent a major evolutionary radiation, in response to the drier climate that followed the rainforest collapse.

For some reason, pelycosaurs were able to reach larger sizes before reptiles could, and this trend continued until the end of the Permian, during which their cynodont descendants became smaller and nocturnal, as the reptilian archosaurs took over, although dicynodonts would remain megafaunal until their extinction at the end of the Triassic.[8] [9] Most pre-rainforest collapse tetrapods remained smaller, probably due to the land being primarily occupied by the gigantic millipedes, scorpions, and flying insects. After the rainforest collapse, the giant arthropods disappeared, allowing amniote tetrapods to achieve larger sizes.

Subdivisions

The Pennsylvanian has been variously subdivided. The international timescale of the ICS follows the Russian subdivision into four stages:[10]

North American subdivision is into five stages, but not precisely the same, with additional (older) Appalachian series names following:[11] [12]

The Virgilian or Conemaugh corresponds to the Gzhelian plus the uppermost Kasimovian.The Missourian or Monongahela corresponds to the rest of the Kasimovian.The Desmoinesian or Allegheny corresponds to the upper half of the Moscovian.The Atokan or upper Pottsville corresponds to the lower half of the Moscovian.The Morrowan corresponds to the Bashkirian.

In the European subdivision, the Carboniferous is divided into two epochs: Dinantian (early) and Silesian (late). The Silesian starts earlier than the Pennsylvanian and is divided in three ages:[13]

External links

Notes and References

  1. Lane . H. . Brenckle . Paul . Baesemann . J. . Richards . Barry . The IUGS boundary in the middle of the Carboniferous: Arrow Canyon, Nevada, USA . Episodes . December 1999 . 22 . 4 . 272–283 . 10.18814/epiiugs/1999/v22i4/003 . 8 December 2020.
  2. Davydov . Vladimir . Glenister . Brian . Spinosa . Claude . Ritter . Scott . Chernykh . V. . Wardlaw . B. . Snyder . W. . Proposal of Aidaralash as Global Stratotype Section and Point (GSSP) for base of the Permian System . Episodes . March 1998 . 21 . 11–18 . 10.18814/epiiugs/1998/v21i1/003 . 7 December 2020.
  3. Book: Gradstein. Felix M.. Felix M. Gradstein. James G. Ogg. Alan G. Smith. Alan Gilbert Smith. A Geologic Time Scale 2004. 2005. Cambridge University Press. 978-0-521-78673-7. 288.
  4. [Meredith Blackwell|Blackwell, Meredith]
  5. Book: Paul D. Taylor, David N. Lewis. Fossil Invertebrates. The Natural History Museum; First North American edition. 2005. 0565091832. 160.
  6. Gand . G. . Nel . A. N. . Fleck . G. . Garrouste . R. . 2008-01-01 . The Odonatoptera of the Late Permian Lodève Basin (Insecta) . Journal of Iberian Geology . es . 34 . 1 . 115–122 . 1886-7995.
  7. Davies . Neil S. . Garwood . Russell J. . McMahon . William J. . Schneider . Joerg W. . Shillito . Anthony P. . 2021-12-21 . The largest arthropod in Earth history: insights from newly discoveredArthropleuraremains (Serpukhovian Stainmore Formation, Northumberland, England) . Journal of the Geological Society . 179 . 3 . 10.1144/jgs2021-115 . 0016-7649.
  8. Sahney . S. . Benton . M.J. . Falcon-Lang . H.J. . 2010 . Rainforest collapse triggered Pennsylvanian tetrapod diversification in Euramerica . Geology . 38 . 1079–1082 . 10.1130/G31182.1 . 12.
  9. Web site: Kazlev MA . 1998 . Palaeos Paleozoic: Carboniferous: The Carboniferous Period . March 30, 2012 . https://web.archive.org/web/20120309140141/http://palaeos.com/paleozoic/carboniferous/carboniferous.htm . March 9, 2012 . dead .
  10. Cohen et al. 2013
  11. Web site: Rice . Charles L. . Pennsylvanian system . Contributions to the geology of Kentucky . United States Geological Survey . 26 October 2020.
  12. Kues . Barry S. . The Pennsylvanian System in New Mexico— overview with suggestions for revision of stratigraphic nomenclature . New Mexico Geology . November 2001 . 103–122 . 26 October 2020.
  13. Heckel . P.H. . Clayton . G. . The Carboniferous System. Use of the new official names for the subsystems, series, and stages . Geologica Acta . 2006 . 4 . 3 . 403–407 . 10.1344/105.000000354 . 26 October 2020.