Jump to content

Early Cretaceous

From Wikipedia, the free encyclopedia
Early/Lower Cretaceous
~145.0 – 100.5 Ma
A map of Earth as it appeared 120 million years ago during the Early Cretaceous Epoch, Aptian Age
Chronology
Etymology
Chronostratigraphic nameLower Cretaceous
Geochronological nameEarly Cretaceous
Name formalityFormal
Usage information
Celestial bodyEarth
Regional usageGlobal (ICS)
Time scale(s) usedICS Time Scale
Definition
Chronological unitEpoch
Stratigraphic unitSeries
Time span formalityFormal
Lower boundary definitionNot formally defined
Lower boundary definition candidates
Lower boundary GSSP candidate section(s)None
Upper boundary definitionFAD of the Planktonic Foraminifer Rotalipora globotruncanoides
Upper boundary GSSPMont Risoux, Hautes-Alpes, France
44°23′33″N 5°30′43″E / 44.3925°N 5.5119°E / 44.3925; 5.5119
Upper GSSP ratified2002[2]

The Early Cretaceous (geochronological name) or the Lower Cretaceous (chronostratigraphic name) is the earlier or lower of the two major divisions of the Cretaceous. It is usually considered to stretch from 145 Ma to 100.5 Ma.

Geology

[edit]

Proposals for the exact age of the Barremian–Aptian boundary ranged from 126 to 117 Ma until recently (as of 2019), but based on drillholes in Svalbard the defining early Aptian Oceanic Anoxic Event 1a (OAE1a) was carbon isotope dated to 123.1±0.3 Ma, limiting the possible range for the boundary to c. 122–121 Ma. There is a possible link between this anoxic event and a series of Early Cretaceous large igneous provinces (LIP).[3]

The Ontong Java-Manihiki-Hikurangi large igneous province, emplaced in the South Pacific at c. 120 Ma, is by far the largest LIP in Earth's history.[4] The Ontong Java Plateau today covers an area of 1,860,000 km2. In the Indian Ocean another LIP began to form at c. 120 Ma, the Kerguelen PlateauBroken Ridge, together covering 2,300,000 km2.[5] Another LIP on the Liaodong Peninsula, China, c. 131–117 Ma, lasted for 10 million years. It was the result of the subduction of the Kula and Pacific plates, which was probably caused by a superplume.[6]

During the opening of the South Atlantic the Paraná–Etendeka LIP produced 1.5 million km3 of basalts and rhyolites, beginning 133 Ma and lasting for a million years.[7]

The opening of the Central Atlantic continued as the Mid-Atlantic Ridge spread north to separate the Iberian Peninsula from the banks of Newfoundland and to connect to the Canada Basin in the Arctic Ocean. With the opening of the Labrador Sea, Greenland became a separate tectonic plate and Laurentia became North America. The Proto-Caribbean Sea continued to grow and the Paraná-Etendeka LIP began to break Africa into three pieces. The Falkland Plateau broke off from southern Africa at 132 Ma and Madagascar ceased to move independently c. 120 Ma. In the Panthalassic Ocean the Pacific Plate continued to grow; the Arctic Alaska-Chukotka terrane formed the Bering Strait. Continued rifting opened new basins in the Indian Ocean, separating India, Antarctica, and Australia.[8]

By 110 Ma the Mid-Atlantic Ridge reached south into the Proto-Caribbean and South Atlantic, effectively separating South America from Africa, and continued rifting in the northern end completed the longitudinal extent of the Atlantic. In Panthalassa the Ontong-Java Mega-LIP resulted in the formation of new tectonic plates and in the Indian Ocean the Kerguelen LIP began to push India northward.[9]

Evolution

[edit]
Restoration of the environment and animals of the Bahariya Formation

During this time many new types of dinosaur appeared or came into prominence, including ceratopsians, spinosaurids, carcharodontosaurids and coelurosaurs, while survivors from the Late Jurassic continued to persist.[citation needed]

Angiosperms (flowering plants) appeared for the first time during the Early Cretaceous;[10] Archaefructaceae, one of the oldest fossil families (124.6 Ma) was found in the Yixian Formation, China.[11]

This time also saw the evolution of the first members of the Neornithes (modern birds).[12]

Sinodelphys, a 125 Ma-old boreosphenidan mammal found in the Yixian Formation, China, is one of the oldest mammal fossils found. The fossil location indicates early mammals began to diversify from Asia during the Early Cretaceous. Sinodelphys was more closely related to metatherians (marsupials) than eutherians (placentals) and had feet adapted for climbing trees.[13] Steropodon is the oldest monotreme (egg-lying mammal) discovered. It lived in Gondwana (now Australia) at 105 Ma.[14]

Oil shale

[edit]

Oil in the Prudhoe Bay Oil Field has been interpreted as being sourced from the Triassic Shublik Formation shale and carbonate, Lower Cretaceous highly radioactive zone shale, and Lower Jurassic Kingak Shale.[15]

See also

[edit]

icon Geology portal

icon Palaeontology portal

References

[edit]

Notes

[edit]
  1. ^ "International Chronostratigraphic Chart" (PDF). International Commission on Stratigraphy. September 2023. Retrieved December 16, 2024.
  2. ^ Kennedy, W.; Gale, A.; Lees, J.; Caron, M. (March 2004). "The Global Boundary Stratotype Section and Point (GSSP) for the base of the Cenomanian Stage, Mont Risou, Hautes-Alpes, France" (PDF). Episodes. 27: 21–32. doi:10.18814/epiiugs/2004/v27i1/003. Retrieved 13 December 2020.
  3. ^ Midtkandal et al. 2016, Abstract
  4. ^ Taylor 2006, Abstract
  5. ^ Coffin & Gahagan 1995, The Plateaux, p. 1047
  6. ^ Wu et al. 2005, Abstract
  7. ^ Renne et al. 1992, Abstract
  8. ^ Seton et al. 2012, 140–120 Ma (Figs. 21 and 22)
  9. ^ Seton et al. 2012, 120–100 Ma (Figs. 22 and 23)
  10. ^ Herendeen, Patrick S.; Friis, Else Marie; Pedersen, Kaj Raunsgaard; Crane, Peter R. (2017-03-03). "Palaeobotanical redux: revisiting the age of the angiosperms". Nature Plants. 3 (3): 17015. doi:10.1038/nplants.2017.15. ISSN 2055-0278. PMID 28260783. S2CID 205458714.
  11. ^ Sun et al. 2002, Abstract
  12. ^ Lee et al. 2014
  13. ^ Luo et al. 2003, Abstract
  14. ^ Archer et al. 1985, Abstract
  15. ^ Masterson, W. Dallam; Holba, Albert G. (June 2021). "North Alaska Super Basin: Petroleum systems of the central Alaskan North Slope, United States". AAPG Bulletin. 105 (6): 1233–1291. doi:10.1306/01282120057. ISSN 0149-1423.

Sources

[edit]