Ordovician

The Ordovician (/ɔːr.dəˈvɪʃ.i.ən, -d-, -ˈvɪʃ.ən/ or-də-VISH-ee-ən, -doh-, -VISH-ən)[9] is a geologic period and system, the second of six periods of the Paleozoic Era. The Ordovician spans 41.6 million years from the end of the Cambrian Period 485.4 million years ago (Mya) to the start of the Silurian Period 443.8 Mya.[10]

Ordovician
485.4 ± 1.9 – 443.8 ± 1.5 Ma
Chronology
Etymology
Name formalityFormal
Name ratified1960
Usage information
Celestial bodyEarth
Regional usageGlobal (ICS)
Time scale(s) usedICS Time Scale
Definition
Chronological unitPeriod
Stratigraphic unitSystem
First proposed byCharles Lapworth, 1879
Time span formalityFormal
Lower boundary definitionFAD of the Conodont Iapetognathus fluctivagus
Lower boundary GSSPGreenpoint section, Green Point, Newfoundland, Canada
49.6829°N 57.9653°W / 49.6829; -57.9653
GSSP ratified2000[5]
Upper boundary definitionFAD of the Graptolite Akidograptus ascensus
Upper boundary GSSPDob's Linn, Moffat, U.K.
55.4400°N 3.2700°W / 55.4400; -3.2700
GSSP ratified1984[6][7]
Atmospheric and climatic data
Mean atmospheric O
2
content
c. 13.5 vol %
(68 % of modern)
Mean atmospheric CO
2
content
c. 4200 ppm
(15 times pre-industrial)
Mean surface temperaturec. 16 °C
(2 °C above modern)
Sea level above present day180 m; rising to 220 m in Caradoc and falling sharply to 140 m in end-Ordovician glaciations[8]

The Ordovician, named after the Welsh tribe of the Ordovices, was defined by Charles Lapworth in 1879 to resolve a dispute between followers of Adam Sedgwick and Roderick Murchison, who were placing the same rock beds in North Wales in the Cambrian and Silurian systems, respectively.[11] Lapworth recognized that the fossil fauna in the disputed strata were different from those of either the Cambrian or the Silurian systems, and placed them in a system of their own. The Ordovician received international approval in 1960 (forty years after Lapworth's death), when it was adopted as an official period of the Paleozoic Era by the International Geological Congress.

Life continued to flourish during the Ordovician as it did in the earlier Cambrian period, although the end of the period was marked by the Ordovician–Silurian extinction events. Invertebrates, namely molluscs and arthropods, dominated the oceans. The Great Ordovician Biodiversification Event considerably increased the diversity of life. Fish, the world's first true vertebrates, continued to evolve, and those with jaws may have first appeared late in the period. Life had yet to diversify on land. About 100 times as many meteorites struck the Earth per year during the Ordovician compared with today.[12]

Subdivisions

A number of regional terms have been used to subdivide the Ordovician Period. In 2008, the ICS erected a formal international system of subdivisions.[13] There exist Baltoscandic, British, Siberian, North American, Australian, Chinese Mediterranean and North-Gondwanan regional stratigraphic schemes.[14]

The Ordovician Period in Britain was traditionally broken into Early (Tremadocian and Arenig), Middle (Llanvirn (subdivided into Abereiddian and Llandeilian) and Llandeilo) and Late (Caradoc and Ashgill) epochs. The corresponding rocks of the Ordovician System are referred to as coming from the Lower, Middle, or Upper part of the column. The faunal stages (subdivisions of epochs) from youngest to oldest are:

Late Ordovician

  • Hirnantian stage/Gamach (Ashgill)
  • Rawtheyan/Richmond (Ashgill)
  • Cautleyan/Richmond (Ashgill)
  • Pusgillian/Maysville/Richmond (Ashgill)

Middle Ordovician

  • Trenton (Caradoc)
  • Onnian/Maysville/Eden (Caradoc)
  • Actonian/Eden (Caradoc)
  • Marshbrookian/Sherman (Caradoc)
  • Longvillian/Sherman (Caradoc)
  • Soudleyan/Kirkfield (Caradoc)
  • Harnagian/Rockland (Caradoc)
  • Costonian/Black River (Caradoc)
  • Chazy (Llandeilo)
  • Llandeilo (Llandeilo)
  • Whiterock (Llanvirn)
  • Llanvirn (Llanvirn)

Early Ordovician

  • Cassinian (Arenig)
  • Arenig/Jefferson/Castleman (Arenig)
  • Tremadoc/Deming/Gaconadian (Tremadoc)

British stages

The Tremadoc corresponds to the (modern) Tremadocian. The Floian corresponds to the lower Arenig; the Arenig continues until the early Darriwilian, subsuming the Dapingian. The Llanvirn occupies the rest of the Darriwilian, and terminates with it at the base of the Late Ordovician. The Sandbian represents the first half of the Caradoc; the Caradoc ends in the mid-Katian, and the Ashgill represents the last half of the Katian, plus the Hirnantian.[15]

Ordovician regional stages
ICS EpochICS stageBritish epochBritish stageNorth American epochNorth American stageAustralian epochAustralian stageChinese epochChinese stage
Late OrdovicianHirnantian stageAshgill seriesHirnantian stageCincinnati seriesGamach stageLate OrdovicianBolinda stageLate OrdovicianHirnantian stage
Katian stageRawthey stageRichmond stageChientangkiang stage
Cautley stageMaysville stageEaston stageNeichiashan stage
Pusgill stageEden stage
Caradoc seriesStrefford stageMohawk stageChatfield stage
Cheney stage
Sandbian stageBurrell stageTurin stageGisborne stage
Aureluc stageWhiterock stageChazy stage
Middle OrdovicianDarriwilian stageLlanvirn seriesLlandeilo stageMiddle OrdovicianDarriwilian stageMiddle OrdovicianDarriwilian stage
Abereiddy stageNot defined
Dapingian stageArenig seriesFenn stageEarly OrdovicianYapeen stageDapingian stage
Whitland stageRanger stageCastlemaine stage
Ibex seriesBlack Hills stageChewton stage
Bendigo stage
Early OrdovicianFloian stageMoridun stageTule stageLancefield stageEarly OrdovicianFloian stage
Tremadocian stageTremadoc seriesMigneint stageStairs stageTremadocian stage
Cressage stageSkullrock stage

Paleogeography and tectonics

Paleogeographic map of the Earth in the middle Ordovician, 470 million years ago

During the Ordovician, the southern continents were assembled into Gondwana, which reached from north of the equator to the South Pole. The Panthalassic Ocean, centered in the northern hemisphere, covered over half the globe.[16] At the start of the period, the continents of Laurentia (in present-day North America), Siberia, and Baltica (present-day northern Europe) were separated from Gondwana by over 5,000 kilometres (3,100 mi) of ocean. These smaller continents were also sufficiently widely separated from each other to develop distinct communities of benthic organisms.[17] The small continent of Avalonia had just rifted from Gondwana and began to move north towards Baltica and Laurentia, opening the Rheic Ocean between Gondwana and Avalonia.[18][19][20] Avalonia collided with Baltica towards the end of Ordovician.[21]

Other geographic features of the Ordovician world included the Tornquist Sea, which separated Avalonia from Baltica;[17] the Aegir Ocean, which separated Baltica from Siberia;[22] and an oceanic area between Siberia, Baltica, and Gondwana which expanded to become the Paleoasian Ocean in Carboniferous time. The Mongol-Okhotsk Ocean formed a deep embayment between Siberia and the Central Mongolian terranes. Most of the terranes of central Asia were part of an equatorial archipelago whose geometry is poorly constrained by the available evidence.[23]

The period was one of extensive, widespread tectonism and volcanism. However, orogenesis (mountain-building) was not primarily due to continent-continent collisions. Instead, mountains arose along active continental margins during accretion of arc terranes or ribbon microcontinents. Accretion of new crust was limited to the Iapetus margin of Laurentia; elsewhere, the pattern was of rifting in back-arc basins followed by remerger. This reflected episodic switching from extension to compression. The initiation of new subduction reflected a global reorganization of tectonic plates centered on the amalgamation of Gondwana.[24][17]

The Taconic orogeny, a major mountain-building episode, was well under way in Cambrian times.[25] This continued into the Ordovician, when at least two volcanic island arcs collided with Laurentia to form the Appalachian Mountains. Laurentia was otherwise tectonically stable. An island arc accreted to South China during the period, while subduction along north China (Sulinheer) resulted in the emplacement of ophiolites.[26]

The ash fall of the Millburg/Big Bentonite bed, at about 454 Ma, was the largest in the last 590 million years. This had a dense rock equivalent volume of as much as 1,140 cubic kilometres (270 cu mi). Remarkably, this appears to have had little impact on life.[27]

There was vigorous tectonic activity along northwest margin of Gondwana during the Floian, 478 Ma, recorded in the Central Iberian Zone of Spain. The activity reached as far as Turkey by the end of Ordovician. The opposite margin of Gondwana, in Australia, faced a set of island arcs.[17] The accretion of these arcs to the eastern margin of Gondwana was responsible for the Benambran Orogeny of eastern Australia.[28][29] Subduction also took place along what is now Argentina (Famatinian Orogeny) at 450 Ma.[30] This involved significant back arc rifting.[17] The interior of Gondwana was tectonically quiet until the Triassic.[17]

Towards the end of the period, Gondwana began to drift across the South Pole. This contributed to the Hibernian glaciation and the associated extinction event.[31]

Ordovician meteor event

The Ordovician meteor event is a proposed shower of meteors that occurred during the Middle Ordovician period, about 467.5 ± 0.28 million years ago, due to the break-up of the L chondrite parent body.[32] It is not associated with any major extinction event.[33][34][35]

Geochemistry

External mold of Ordovician bivalve showing that the original aragonite shell dissolved on the sea floor, leaving a cemented mold for biological encrustation (Waynesville Formation of Franklin County, Indiana).

The Ordovician was a time of calcite sea geochemistry in which low-magnesium calcite was the primary inorganic marine precipitate of calcium carbonate. Carbonate hardgrounds were thus very common, along with calcitic ooids, calcitic cements, and invertebrate faunas with dominantly calcitic skeletons. Biogenic aragonite, like that composing the shells of most molluscs, dissolved rapidly on the sea floor after death.[36][37]

Unlike Cambrian times, when calcite production was dominated by microbial and non-biological processes, animals (and macroalgae) became a dominant source of calcareous material in Ordovician deposits.[38]

Climate and sea level

The early Ordovician climate was very hot, with intense greenhouse conditions giving way to a more temperate climate in the Middle Ordovician. Further cooling led to the Late Ordovician glaciation.[39][40] The Ordovician saw the highest sea levels of the Paleozoic, and the low relief of the continents led to many shelf deposits being formed under hundreds of metres of water.[38] The sea level rose more or less continuously throughout the Early Ordovician, leveling off somewhat during the middle of the period.[38] Locally, some regressions occurred, but the sea level rise continued in the beginning of the Late Ordovician. Sea levels fell steadily due to the cooling temperatures for about 30 million years leading up to the Hirnantian glaciation. During this icy stage, sea level seems to have risen and dropped somewhat. Despite much study, the details remain unresolved.[38] In particular, some researches interpret the fluctuations in sea level as pre-Hibernian glaciation,[41] but sedimentary evidence of glaciation is lacking until the end of the period.[21] There is also evidence that global temperatures rose briefly in the early Katian (Boda Event), depositing bioherms and radiating fauna across Europe.[42]

As with North America and Europe, Gondwana was largely covered with shallow seas during the Ordovician. Shallow clear waters over continental shelves encouraged the growth of organisms that deposit calcium carbonates in their shells and hard parts. The Panthalassic Ocean covered much of the Northern Hemisphere, and other minor oceans included Proto-Tethys, Paleo-Tethys, Khanty Ocean, which was closed off by the Late Ordovician, Iapetus Ocean, and the new Rheic Ocean.

As the Ordovician progressed, there is evidence of glaciers on the land we now know as Africa and South America, which were near the South Pole at the time, resulting in the ice caps of the Late Ordovician glaciation.

Life

A diorama depicting Ordovician flora and fauna.

For most of the Late Ordovician life continued to flourish, but at and near the end of the period there were mass-extinction events that seriously affected conodonts and planktonic forms like graptolites. The trilobites Agnostida and Ptychopariida completely died out, and the Asaphida were much reduced. Brachiopods, bryozoans and echinoderms were also heavily affected, and the endocerid cephalopods died out completely, except for possible rare Silurian forms. The Ordovician–Silurian extinction events may have been caused by an ice age that occurred at the end of the Ordovician period, due to the expansion of the first terrestrial plants,[43] as the end of the Late Ordovician was one of the coldest times in the last 600 million years of Earth's history.

Fauna

Nautiloids like Orthoceras were among the largest predators in the Ordovician.
Fossiliferous limestone slab from the Liberty Formation (Upper Ordovician) of Caesar Creek State Park near Waynesville, Ohio.
The trilobite Isotelus from Wisconsin.

On the whole, the fauna that emerged in the Ordovician were the template for the remainder of the Palaeozoic.[38] The fauna was dominated by tiered communities of suspension feeders, mainly with short food chains. The ecological system reached a new grade of complexity far beyond that of the Cambrian fauna,[38] which has persisted until the present day.[38]

Though less famous than the Cambrian explosion, the Ordovician radiation (also known as the Great Ordovician Biodiversification Event)[17] was no less remarkable; marine faunal genera increased fourfold, resulting in 12% of all known Phanerozoic marine fauna.[44] Another change in the fauna was the strong increase in filter-feeding organisms.[45] The trilobite, inarticulate brachiopod, archaeocyathid, and eocrinoid faunas of the Cambrian were succeeded by those that dominated the rest of the Paleozoic, such as articulate brachiopods, cephalopods, and crinoids. Articulate brachiopods, in particular, largely replaced trilobites in shelf communities.[46] Their success epitomizes the greatly increased diversity of carbonate shell-secreting organisms in the Ordovician compared to the Cambrian.[46]

Ordovician geography had its effect on the diversity of fauna. The widely separated continents of Laurentia and Baltica developed distinct trilobite fauna from the trilobite fauna of Gondwana, and Gondwana developed distinct fauna in its tropical and temperature zones. However, tropical articulate brachiopods had a more cosmopolitan distribution, with less diversity on different continents. Faunas become less provincial later in the Ordovician, though they were still distinguishable into the late Ordovician.[47]

In North America and Europe, the Ordovician was a time of shallow continental seas rich in life. Trilobites and brachiopods in particular were rich and diverse. Although solitary corals date back to at least the Cambrian, reef-forming corals appeared in the early Ordovician, corresponding to an increase in the stability of carbonate and thus a new abundance of calcifying animals.[38]

Molluscs, which appeared during the Cambrian or even the Ediacaran, became common and varied, especially bivalves, gastropods, and nautiloid cephalopods. Cephalopods diversified from shallow marine tropical environments to dominate almost all marine environments.[48]

Now-extinct marine animals called graptolites thrived in the oceans. This includes the distinctive Nemagraptus gracilis graptolite fauna, which was distributed widely during peak sea levels in the Sandbian.[49][21][21] Some new cystoids and crinoids appeared.

It was long thought that the first true vertebrates (fish — Ostracoderms) appeared in the Ordovician, but recent discoveries in China reveal that they probably originated in the Early Cambrian. The first gnathostome (jawed fish) appeared in the Late Ordovician epoch.

During the Middle Ordovician there was a large increase in the intensity and diversity of bioeroding organisms. This is known as the Ordovician Bioerosion Revolution.[50] It is marked by a sudden abundance of hard substrate trace fossils such as Trypanites, Palaeosabella, Petroxestes and Osprioneides. Several groups of endobiotic symbionts appeared in the Ordovician.[51][52]

In the Early Ordovician, trilobites were joined by many new types of organisms, including tabulate corals, strophomenid, rhynchonellid, and many new orthid brachiopods, bryozoans, planktonic graptolites and conodonts, and many types of molluscs and echinoderms, including the ophiuroids ("brittle stars") and the first sea stars. Nevertheless, the arthropods remained abundant, all the Late Cambrian orders continued, and were joined by the new group Phacopida. The first evidence of land plants also appeared (see evolutionary history of life).

In the Middle Ordovician, the trilobite-dominated Early Ordovician communities were replaced by generally more mixed ecosystems, in which brachiopods, bryozoans, molluscs, cornulitids, tentaculitids and echinoderms all flourished, tabulate corals diversified and the first rugose corals appeared. The planktonic graptolites remained diverse, with the Diplograptina making their appearance. Bioerosion became an important process, particularly in the thick calcitic skeletons of corals, bryozoans and brachiopods, and on the extensive carbonate hardgrounds that appear in abundance at this time. One of the earliest known armoured agnathan ("ostracoderm") vertebrate, Arandaspis, dates from the Middle Ordovician.

Trilobites in the Ordovician were very different from their predecessors in the Cambrian. Many trilobites developed bizarre spines and nodules to defend against predators such as primitive eurypterids and nautiloids while other trilobites such as Aeglina prisca evolved to become swimming forms. Some trilobites even developed shovel-like snouts for ploughing through muddy sea bottoms. Another unusual clade of trilobites known as the trinucleids developed a broad pitted margin around their head shields.[53] Some trilobites such as Asaphus kowalewski evolved long eyestalks to assist in detecting predators whereas other trilobite eyes in contrast disappeared completely.[54] Molecular clock analyses suggest that early arachnids started living on land by the end of the Ordovician.[55]

The earliest-known octocorals date from the Ordovician.[56]

Flora

Green algae were common in the Late Cambrian (perhaps earlier) and in the Ordovician. Terrestrial plants probably evolved from green algae, first appearing as tiny non-vascular forms resembling liverworts, in the middle to late Ordovician.[58] Fossil spores found in Ordovician sedimentary rock are typical of bryophytes.[59]

Colonization of land would have been limited to shorelines

Among the first land fungi may have been arbuscular mycorrhiza fungi (Glomerales), playing a crucial role in facilitating the colonization of land by plants through mycorrhizal symbiosis, which makes mineral nutrients available to plant cells; such fossilized fungal hyphae and spores from the Ordovician of Wisconsin have been found with an age of about 460 million years ago, a time when the land flora most likely only consisted of plants similar to non-vascular bryophytes.[60]

End of the period

The Ordovician came to a close in a series of extinction events that, taken together, comprise the second largest of the five major extinction events in Earth's history in terms of percentage of genera that became extinct. The only larger one was the Permian–Triassic extinction event.

The extinctions occurred approximately 447–444 million years ago and mark the boundary between the Ordovician and the following Silurian Period. At that time all complex multicellular organisms lived in the sea, and about 49% of genera of fauna disappeared forever; brachiopods and bryozoans were greatly reduced, along with many trilobite, conodont and graptolite families.

The most commonly accepted theory is that these events were triggered by the onset of cold conditions in the late Katian, followed by an ice age, in the Hirnantian faunal stage, that ended the long, stable greenhouse conditions typical of the Ordovician.

The ice age was possibly not long-lasting. Oxygen isotopes in fossil brachiopods show its duration may have been only 0.5 to 1.5 million years.[61] Other researchers (Page et al.) estimate more temperate conditions did not return until the late Silurian.

The late Ordovician glaciation event was preceded by a fall in atmospheric carbon dioxide (from 7000 ppm to 4400 ppm).[62][63] The dip may have been caused by a burst of volcanic activity that deposited new silicate rocks, which draw CO2 out of the air as they erode.[63] Another possibility is that bryophytes and lichens, which colonized land in the middle to late Ordovician, may have increased weathering enough to draw down CO
2
levels.[58] The drop in CO
2
selectively affected the shallow seas where most organisms lived. As the southern supercontinent Gondwana drifted over the South Pole, ice caps formed on it, which have been detected in Upper Ordovician rock strata of North Africa and then-adjacent northeastern South America, which were south-polar locations at the time.

As glaciers grew, the sea level dropped, and the vast shallow intra-continental Ordovician seas withdrew, which eliminated many ecological niches. When they returned, they carried diminished founder populations that lacked many whole families of organisms. They then withdrew again with the next pulse of glaciation, eliminating biological diversity with each change.[64] Species limited to a single epicontinental sea on a given landmass were severely affected.[37] Tropical lifeforms were hit particularly hard in the first wave of extinction, while cool-water species were hit worst in the second pulse.[37]

Those species able to adapt to the changing conditions survived to fill the ecological niches left by the extinctions. For example, there is evidence the oceans became more deeply oxygenated during the glaciation, allowing unusual benthic organisms (Hirnantian fauna) to colonize the depths. These organisms were cosmopolitan in distribution and present at most latitudes.[47]

At the end of the second event, melting glaciers caused the sea level to rise and stabilise once more. The rebound of life's diversity with the permanent re-flooding of continental shelves at the onset of the Silurian saw increased biodiversity within the surviving Orders. Recovery was characterized by an unusual number of "Lazarus taxa", disappearing during the extinction and reappearing well into the Silurian, which suggests that the taxa survived in small numbers in refugia.[65]

An alternate extinction hypothesis suggested that a ten-second gamma-ray burst could have destroyed the ozone layer and exposed terrestrial and marine surface-dwelling life to deadly ultraviolet radiation and initiated global cooling.[66]

Recent work considering the sequence stratigraphy of the Late Ordovician argues that the mass extinction was a single protracted episode lasting several hundred thousand years, with abrupt changes in water depth and sedimentation rate producing two pulses of last occurrences of species.[67]

References

  1. Wellman, C.H.; Gray, J. (2000). "The microfossil record of early land plants". Phil. Trans. R. Soc. B. 355 (1398): 717–732. doi:10.1098/rstb.2000.0612. PMC 1692785. PMID 10905606.
  2. Korochantseva, Ekaterina; Trieloff, Mario; Lorenz, Cyrill; Buykin, Alexey; Ivanova, Marina; Schwarz, Winfried; Hopp, Jens; Jessberger, Elmar (2007). "L-chondrite asteroid breakup tied to Ordovician meteorite shower by multiple isochron 40 Ar- 39 Ar dating". Meteoritics & Planetary Science. 42 (1): 113–130. Bibcode:2007M&PS...42..113K. doi:10.1111/j.1945-5100.2007.tb00221.x.
  3. Lindskog, A.; Costa, M. M.; Rasmussen, C.M.Ø.; Connelly, J. N.; Eriksson, M. E. (2017-01-24). "Refined Ordovician timescale reveals no link between asteroid breakup and biodiversification". Nature Communications. 8: 14066. doi:10.1038/ncomms14066. ISSN 2041-1723. PMC 5286199. PMID 28117834. It has been suggested that the Middle Ordovician meteorite bombardment played a crucial role in the Great Ordovician Biodiversification Event, but this study shows that the two phenomena were unrelated
  4. "Chart/Time Scale". www.stratigraphy.org. International Commission on Stratigraphy.
  5. Cooper, Roger; Nowlan, Godfrey; Williams, S. H. (March 2001). "Global Stratotype Section and Point for base of the Ordovician System" (PDF). Episodes. 24 (1): 19–28. doi:10.18814/epiiugs/2001/v24i1/005. Retrieved 6 December 2020.
  6. Lucas, Sepncer (6 November 2018). "The GSSP Method of Chronostratigraphy: A Critical Review". Frontiers in Earth Science. 6: 191. Bibcode:2018FrEaS...6..191L. doi:10.3389/feart.2018.00191.
  7. Holland, C. (June 1985). "Series and Stages of the Silurian System" (PDF). Episodes. 8 (2): 101–103. doi:10.18814/epiiugs/1985/v8i2/005. Retrieved 11 December 2020.
  8. Haq, B. U.; Schutter, SR (2008). "A Chronology of Paleozoic Sea-Level Changes". Science. 322 (5898): 64–68. Bibcode:2008Sci...322...64H. doi:10.1126/science.1161648. PMID 18832639. S2CID 206514545.
  9. "Ordovician". Dictionary.com Unabridged. Random House.
  10. "International Chronostratigraphic Chart v.2015/01" (PDF). International Commission on Stratigraphy. January 2015.
  11. Charles Lapworth (1879) "On the Tripartite Classification of the Lower Palaeozoic Rocks," Geological Magazine, new series, 6 : 1-15. From pp. 13-14: "North Wales itself — at all events the whole of the great Bala district where Sedgwick first worked out the physical succession among the rocks of the intermediate or so-called Upper Cambrian or Lower Silurian system; and in all probability, much of the Shelve and the Caradoc area, whence Murchison first published its distinctive fossils — lay within the territory of the Ordovices; … Here, then, have we the hint for the appropriate title for the central system of the Lower Paleozoic. It should be called the Ordovician System, after this old British tribe."
  12. "New type of meteorite linked to ancient asteroid collision". Science Daily. 15 June 2016. Retrieved 20 June 2016.
  13. Details on the Dapingian are available at Wang, X.; Stouge, S.; Chen, X.; Li, Z.; Wang, C. (2009). "Dapingian Stage: standard name for the lowermost global stage of the Middle Ordovician Series". Lethaia. 42 (3): 377–380. doi:10.1111/j.1502-3931.2009.00169.x.
  14. "The Ordovician Period". Subcommission on Ordovician Stratigraphy. International Commission on Stratigraphy. 2020. Retrieved 7 June 2021.
  15. Ogg; Ogg; Gradstein, eds. (2008). The Concise Geological Timescale.
  16. Torsvik, Trond H.; Cocks, L. Robin M. (2017). Earth history and palaeogeography. Cambridge, United Kingdom: Cambridge University Press. p. 102. ISBN 9781107105324.
  17. Torsvik & Cocks 2017, p. 102.
  18. Pollock, Jeffrey C.; Hibbard, James P.; Sylvester, Paul J. (May 2009). "Early Ordovician rifting of Avalonia and birth of the Rheic Ocean: U–Pb detrital zircon constraints from Newfoundland". Journal of the Geological Society. 166 (3): 501–515. Bibcode:2009JGSoc.166..501P. doi:10.1144/0016-76492008-088. S2CID 129091590.
  19. Nance, R. Damian; Gutiérrez-Alonso, Gabriel; Keppie, J. Duncan; Linnemann, Ulf; Murphy, J. Brendan; Quesada, Cecilio; Strachan, Rob A.; Woodcock, Nigel H. (March 2012). "A brief history of the Rheic Ocean". Geoscience Frontiers. 3 (2): 125–135. doi:10.1016/j.gsf.2011.11.008.
  20. Torsvik & Cocks 2017, p. 103.
  21. Torsvik & Cocks 2017, p. 112.
  22. Torsvik, Trond H.; Rehnström, Emma F. (March 2001). "Cambrian palaeomagnetic data from Baltica: implications for true polar wander and Cambrian palaeogeography". Journal of the Geological Society. 158 (2): 321–329. Bibcode:2001JGSoc.158..321T. doi:10.1144/jgs.158.2.321. S2CID 54656066.
  23. Torsvik & Cocks 2017, pp. 102, 106.
  24. van Staal, C.R.; Hatcher, R.D., Jr. (2010). "Global setting of Ordovician orogenesis". Geol Soc Am Spec Pap. 466: 1–11. doi:10.1130/2010.2466(01). ISBN 9780813724669.
  25. Torsvik & Cocks 2017, pp. 93-94.
  26. Torsvik & Cocks 2017, pp. 106-109.
  27. Huff, Warren D.; Bergström, Stig M.; Kolata, Dennis R. (1992-10-01). "Gigantic Ordovician volcanic ash fall in North America and Europe: Biological, tectonomagmatic, and event-stratigraphic significance". Geology. 20 (10): 875–878. Bibcode:1992Geo....20..875H. doi:10.1130/0091-7613(1992)020<0875:GOVAFI>2.3.CO;2.
  28. Glen, R. A.; Meffre, S.; Scott, R. J. (March 2007). "Benambran Orogeny in the Eastern Lachlan Orogen, Australia". Australian Journal of Earth Sciences. 54 (2–3): 385–415. Bibcode:2007AuJES..54..385G. doi:10.1080/08120090601147019. S2CID 129843558.
  29. Torsvik & Cocks 2017, p. 105.
  30. Ramos, Victor A. (2018). "The Famatinian Orogen Along the Protomargin of Western Gondwana: Evidence for a Nearly Continuous Ordovician Magmatic Arc Between Venezuela and Argentina". The Evolution of the Chilean-Argentinean Andes. Springer Earth System Sciences: 133–161. doi:10.1007/978-3-319-67774-3_6. ISBN 978-3-319-67773-6.
  31. Torsvik & Cocks 2017, pp. 103–105.
  32. Lindskog, A.; Costa, M. M.; Rasmussen, C.M.Ø.; Connelly, J. N.; Eriksson, M. E. (2017-01-24). "Refined Ordovician timescale reveals no link between asteroid breakup and biodiversification". Nature Communications. 8: 14066. Bibcode:2017NatCo...814066L. doi:10.1038/ncomms14066. ISSN 2041-1723. PMC 5286199. PMID 28117834.
  33. Heck, Philipp R.; Schmitz, Birger; Baur, Heinrich; Halliday, Alex N.; Wieler, Rainer (2004). "Fast delivery of meteorites to Earth after a major asteroid collision". Nature. 430 (6997): 323–5. Bibcode:2004Natur.430..323H. doi:10.1038/nature02736. PMID 15254530. S2CID 4393398.
  34. Haack, Henning; Farinella, Paolo; Scott, Edward R. D.; Keil, Klaus (1996). "Meteoritic, Asteroidal, and Theoretical Constraints on the 500 MA Disruption of the L Chondrite Parent Body". Icarus. 119 (1): 182–91. Bibcode:1996Icar..119..182H. doi:10.1006/icar.1996.0010.
  35. Korochantseva, Ekaterina V.; Trieloff, Mario; Lorenz, Cyrill A.; Buykin, Alexey I.; Ivanova, Marina A.; Schwarz, Winfried H.; Hopp, Jens; Jessberger, Elmar K. (2007). "L-chondrite asteroid breakup tied to Ordovician meteorite shower by multiple isochron 40Ar-39Ar dating". Meteoritics & Planetary Science. 42 (1): 113–30. Bibcode:2007M&PS...42..113K. doi:10.1111/j.1945-5100.2007.tb00221.x. S2CID 54513002.
  36. Stanley, S.; Hardie, L. (1998). "Secular oscillations in the carbonate mineralogy of reef-building and sediment-producing organisms driven by tectonically forced shifts in seawater chemistry". Palaeogeography, Palaeoclimatology, Palaeoecology. 144 (1–2): 3–19. Bibcode:1998PPP...144....3S. doi:10.1016/S0031-0182(98)00109-6.
  37. Stanley, S. M.; Hardie, L. A. (1999). "Hypercalcification; paleontology links plate tectonics and geochemistry to sedimentology". GSA Today. 9: 1–7.
  38. Munnecke, A.; Calner, M.; Harper, D. A. T.; Servais, T. (2010). "Ordovician and Silurian sea-water chemistry, sea level, and climate: A synopsis". Palaeogeography, Palaeoclimatology, Palaeoecology. 296 (3–4): 389–413. Bibcode:2010PPP...296..389M. doi:10.1016/j.palaeo.2010.08.001.
  39. Trotter, J. A.; Williams, I. S.; Barnes, C. R.; Lecuyer, C.; Nicoll, R. S. (2008-07-25). "Did Cooling Oceans Trigger Ordovician Biodiversification? Evidence from Conodont Thermometry". Science. 321 (5888): 550–554. Bibcode:2008Sci...321..550T. doi:10.1126/science.1155814. ISSN 0036-8075. PMID 18653889. S2CID 28224399.
  40. Goldberg, Samuel L.; Present, Theodore M.; Finnegan, Seth; Bergmann, Kristin D. (2021-02-09). "A high-resolution record of early Paleozoic climate". Proceedings of the National Academy of Sciences. 118 (6): e2013083118. Bibcode:2021PNAS..11820130G. doi:10.1073/pnas.2013083118. ISSN 0027-8424. PMC 8017688. PMID 33526667.
  41. Rasmussen, Christian M. Ø.; Ullmann, Clemens V.; Jakobsen, Kristian G.; Lindskog, Anders; Hansen, Jesper; Hansen, Thomas; Eriksson, Mats E.; Dronov, Andrei; Frei, Robert; Korte, Christoph; Nielsen, Arne T.; Harper, David A.T. (May 2016). "Onset of main Phanerozoic marine radiation sparked by emerging Mid Ordovician icehouse". Scientific Reports. 6 (1): 18884. Bibcode:2016NatSR...618884R. doi:10.1038/srep18884. PMC 4702064. PMID 26733399.
  42. Fortey, Richard A.; Cocks, L. Robin M. (2005). "Late Ordovician global warming—The Boda event". Geology. 33 (5): 405. Bibcode:2005Geo....33..405F. doi:10.1130/G21180.1.
  43. Humble moss helped to cool Earth and spurred on life
  44. Dixon, Dougal; et al. (2001). Atlas of Life on Earth. New York: Barnes & Noble Books. p. 87. ISBN 978-0-7607-1957-2.
  45. Palaeos Paleozoic : Ordovician : The Ordovician Period Archived 2007-12-21 at the Wayback Machine
  46. Cooper, John D.; Miller, Richard H.; Patterson, Jacqueline (1986). A Trip Through Time: Principles of Historical Geology. Columbus: Merrill Publishing Company. pp. 247, 255–259. ISBN 978-0-675-20140-7.
  47. Torsvik & Cocks 2017, p. 112-113.
  48. Kröger, Björn; Yun-Bai, Zhang (March 2009). "Pulsed cephalopod diversification during the Ordovician". Palaeogeography, Palaeoclimatology, Palaeoecology. 273 (1–2): 174–183. Bibcode:2009PPP...273..174K. doi:10.1016/j.palaeo.2008.12.015.
  49. Finney, Stanley C.; Bergström, Stig M. (1986). "Biostratigraphy of the Ordovician Nemagraptus gracilis Zone". Geological Society, London, Special Publications. 20 (1): 47–59. Bibcode:1986GSLSP..20...47F. doi:10.1144/GSL.SP.1986.020.01.06. S2CID 129733589.
  50. Wilson, M. A.; Palmer, T. J. (2006). "Patterns and processes in the Ordovician Bioerosion Revolution" (PDF). Ichnos. 13 (3): 109–112. doi:10.1080/10420940600850505. S2CID 128831144. Archived from the original (PDF) on 2008-12-16.
  51. Vinn, O.; Mõtus, M.-A. (2012). "Diverse early endobiotic coral symbiont assemblage from the Katian (Late Ordovician) of Baltica". Palaeogeography, Palaeoclimatology, Palaeoecology. 321–322: 137–141. Bibcode:2012PPP...321..137V. doi:10.1016/j.palaeo.2012.01.028. Retrieved 2014-06-11.
  52. Vinn, O., Wilson, M.A., Mõtus, M.-A. and Toom, U. (2014). "The earliest bryozoan parasite: Middle Ordovician (Darriwilian) of Osmussaar Island, Estonia". Palaeogeography, Palaeoclimatology, Palaeoecology. 414: 129–132. Bibcode:2014PPP...414..129V. doi:10.1016/j.palaeo.2014.08.021. Retrieved 2014-01-09.CS1 maint: multiple names: authors list (link)
  53. "Palaeos Paleozoic : Ordovician : The Ordovician Period". April 11, 2002. Archived from the original on December 21, 2007.
  54. A Guide to the Orders of Trilobites
  55. Garwood, Russell J.; Sharma, Prashant P.; Dunlop, Jason A.; Giribet, Gonzalo (2014). "A Paleozoic Stem Group to Mite Harvestmen Revealed through Integration of Phylogenetics and Development". Current Biology. 24 (9): 1017–1023. doi:10.1016/j.cub.2014.03.039. PMID 24726154.
  56. Bergström, Stig M.; Bergström, Jan; Kumpulainen, Risto; Ormö, Jens; Sturkell, Erik (2007). "Maurits Lindström – A renaissance geoscientist". GFF. 129 (2): 65–70. doi:10.1080/11035890701292065. S2CID 140593975.
  57. Wilson, M. A.; Palmer, T. J. (2001). "Domiciles, not predatory borings: a simpler explanation of the holes in Ordovician shells analyzed by Kaplan and Baumiller, 2000". PALAIOS. 16 (5): 524–525. Bibcode:2001Palai..16..524W. doi:10.1669/0883-1351(2001)016<0524:DNPBAS>2.0.CO;2.
  58. Porada, P.; Lenton, T. M.; Pohl, A.; Weber, B.; Mander, L.; Donnadieu, Y.; Beer, C.; Pöschl, U.; Kleidon, A. (November 2016). "High potential for weathering and climate effects of non-vascular vegetation in the Late Ordovician". Nature Communications. 7 (1): 12113. Bibcode:2016NatCo...712113P. doi:10.1038/ncomms12113. PMC 4941054. PMID 27385026.
  59. Steemans, P.; Herisse, A. L.; Melvin, J.; Miller, M. A.; Paris, F.; Verniers, J.; Wellman, C. H. (2009-04-17). "Origin and Radiation of the Earliest Vascular Land Plants". Science. 324 (5925): 353. Bibcode:2009Sci...324..353S. doi:10.1126/science.1169659. hdl:1854/LU-697223. PMID 19372423. S2CID 206518080.
  60. Redecker, D.; Kodner, R.; Graham, L. E. (2000). "Glomalean fungi from the Ordovician". Science. 289 (5486): 1920–1921. Bibcode:2000Sci...289.1920R. doi:10.1126/science.289.5486.1920. PMID 10988069. S2CID 43553633.
  61. Stanley, Steven M. (1999). Earth System History. New York: W.H. Freeman and Company. pp. 358, 360. ISBN 978-0-7167-2882-5.
  62. Young, Seth A.; Saltzman, Matthew R.; Ausich, William I.; Desrochers, André; Kaljo, Dimitri (2010). "Did changes in atmospheric CO2 coincide with latest Ordovician glacial–interglacial cycles?". Palaeogeography, Palaeoclimatology, Palaeoecology. 296 (3–4): 376–388. Bibcode:2010PPP...296..376Y. doi:10.1016/j.palaeo.2010.02.033.
  63. Jeff Hecht, High-carbon ice age mystery solved, New Scientist, 8 March 2010 (retrieved 30 June 2014)
  64. Emiliani, Cesare. (1992). Planet Earth : Cosmology, Geology, & the Evolution of Life & the Environment (Cambridge University Press) p. 491
  65. Torsvik & Cocks 2017, pp. 122-123.
  66. Melott, Adrian; et al. (2004). "Did a gamma-ray burst initiate the late Ordovician mass extinction?". International Journal of Astrobiology. 3 (1): 55–61. arXiv:astro-ph/0309415. Bibcode:2004IJAsB...3...55M. doi:10.1017/S1473550404001910. hdl:1808/9204. S2CID 13124815.
  67. Holland, Steven M; Patzkowsky, Mark E (2015). "The stratigraphy of mass extinction". Palaeontology. 58 (5): 903–924. doi:10.1111/pala.12188. S2CID 129522636.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.