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Devonian

January 31, 2023

This article is about the geological period. For the residents of the UK county, see Devon. For other uses, see Devonian (disambiguation).

The Devonian (/dɪˈvni.ən, dɛ-/ də-VOH-nee-ən, de-)[9][10] is a geologic period and system of the Paleozoic era, spanning 60.3 million years from the end of the Silurian, 419.2 million years ago (Mya), to the beginning of the Carboniferous, 358.9 Mya.[11] It is named after Devon, England, where rocks from this period were first studied.

Devonian
419.2 ± 3.2 – 358.9 ± 0.4 Ma
Late Devonian world map
Chronology
Etymology
Name formalityFormal
Nickname(s)Age of Fishes
Usage information
Celestial bodyEarth
Regional usageGlobal (ICS)
Time scale(s) usedICS Time Scale
Definition
Chronological unitPeriod
Stratigraphic unitSystem
Time span formalityFormal
Lower boundary definitionFAD of the Graptolite Monograptus uniformis
Lower boundary GSSPKlonk, Czech Republic
49°51′18″N 13°47′31″E / 49.8550°N 13.7920°E / 49.8550; 13.7920
Lower GSSP ratified1972[5]
Upper boundary definitionFAD of the Conodont Siphonodella sulcata (discovered to have biostratigraphic issues as of 2006).[6]
Upper boundary GSSPLa Serre, Montagne Noire, France
43°33′20″N 3°21′26″E / 43.5555°N 3.3573°E / 43.5555; 3.3573
Upper GSSP ratified1990[7]
Atmospheric and climatic data
Sea level above present dayRelatively steady around 189 m, gradually falling to 120 m through period[8]

The first significant adaptive radiation of life on dry land occurred during the Devonian. Free-sporing vascular plants began to spread across dry land, forming extensive forests which covered the continents. By the middle of the Devonian, several groups of plants had evolved leaves and true roots, and by the end of the period the first seed-bearing plants appeared. The arthropod groups of myriapods, arachnids and hexapods also became well-established early in this period, after starting their expansion to land at least from the Ordovician period.

Fish reached substantial diversity during this time, leading the Devonian to often be dubbed the Age of Fishes. The placoderms began dominating almost every known aquatic environment. The ancestors of all four-limbed vertebrates (tetrapods) began adapting to walk on land, as their strong pectoral and pelvic fins gradually evolved into legs, though they were not fully established until the Late Carboniferous.[12] In the oceans, primitive sharks became more numerous than in the Silurian and Late Ordovician.

The first ammonites, a subclass of molluscs, appeared. Trilobites, the mollusc-like brachiopods, and the great coral reefs were still common. The Late Devonian extinction which started about 375 million years ago[13] severely affected marine life, killing off all placodermi, and all trilobites, save for a few species of the order Proetida.

Devonian palaeogeography was dominated by the supercontinent of Gondwana to the south, the small continent of Siberia to the north, and the medium-sized continent of Laurussia to the east. Major tectonic events include the closure of the Rheic Ocean, the separation of South China from Gondwana, and the resulting expansion of the Paleo-Tethys Ocean. The Devonian experienced several major mountain-building events as Laurussia and Gondwana approached; these include the Acadian Orogeny in North America and the beginning of the Variscan Orogeny in Europe. These early collisions preceded the formation of Pangaea in the Late Paleozoic.

History

 
The rocks of Lummaton Quarry in Torquay in Devon played an early role in defining the Devonian Period

The period is named after Devon, a county in southwestern England, where a controversial argument in the 1830s over the age and structure of the rocks found distributed throughout the county was eventually resolved by the definition of the Devonian Period in the geological timescale. The Great Devonian Controversy was a long period of vigorous argument and counter-argument between the main protagonists of Roderick Murchison with Adam Sedgwick against Henry De la Beche supported by George Bellas Greenough. Murchison and Sedgwick won the debate and named the period they proposed as the Devonian System.[14][15][a]

While the rock beds that define the start and end of the Devonian Period are well identified, the exact dates are uncertain. According to the International Commission on Stratigraphy,[19] the Devonian extends from the end of the Silurian 419.2 Mya, to the beginning of the Carboniferous 358.9 Mya – in North America, at the beginning of the Mississippian subperiod of the Carboniferous.

In 19th-century texts the Devonian has been called the "Old Red Age", after the red and brown terrestrial deposits known in the United Kingdom as the Old Red Sandstone in which early fossil discoveries were found. Another common term is "Age of the Fishes",[20] referring to the evolution of several major groups of fish that took place during the period. Older literature on the Anglo-Welsh basin divides it into the Downtonian, Dittonian, Breconian, and Farlovian stages, the latter three of which are placed in the Devonian.[21]

The Devonian has also erroneously been characterised as a "greenhouse age", due to sampling bias: most of the early Devonian-age discoveries came from the strata of western Europe and eastern North America, which at the time straddled the Equator as part of the supercontinent of Euramerica where fossil signatures of widespread reefs indicate tropical climates that were warm and moderately humid. In fact the climate in the Devonian differed greatly during its epochs and between geographic regions. For example, during the Early Devonian, arid conditions were prevalent through much of the world including Siberia, Australia, North America, and China, but Africa and South America had a warm temperate climate. In the Late Devonian, by contrast, arid conditions were less prevalent across the world and temperate climates were more common.[citation needed]

Subdivisions

The Devonian Period is formally broken into Early, Middle and Late subdivisions. The rocks corresponding to those epochs are referred to as belonging to the Lower, Middle and Upper parts of the Devonian System.

Early Devonian

The Early Devonian lasted from 419.2 ± 3.2 to 393.3 ± 0.4 and began with the Lochkovian Stage 419.2 ± 3.2 to 410.8 ± 0.4, which was followed by the Pragian from 410.8 ± 3.2 to 407.6 ± 0.4 and then by the Emsian, which lasted until the Middle Devonian began, 393.3± 1.2 million years ago.[22] During this time, the first ammonoids appeared, descending from bactritoid nautiloids. Ammonoids during this time period were simple and differed little from their nautiloid counterparts. These ammonoids belong to the order Agoniatitida, which in later epochs evolved to new ammonoid orders, for example Goniatitida and Clymeniida. This class of cephalopod molluscs would dominate the marine fauna until the beginning of the Mesozoic Era.

Middle Devonian

The Middle Devonian comprised two subdivisions: first the Eifelian, which then gave way to the Givetian 387.7± 0.8 million years ago. During this time the jawless agnathan fishes began to decline in diversity in freshwater and marine environments partly due to drastic environmental changes and partly due to the increasing competition, predation, and diversity of jawed fishes. The shallow, warm, oxygen-depleted waters of Devonian inland lakes, surrounded by primitive plants, provided the environment necessary for certain early fish to develop such essential characteristics as well developed lungs, and the ability to crawl out of the water and onto the land for short periods of time.[23]

Late Devonian

Finally, the Late Devonian started with the Frasnian, 382.7 ± 3.2 to 372.2 ± 0.4, during which the first forests took shape on land. The first tetrapods appeared in the fossil record in the ensuing Famennian subdivision, the beginning and end of which are marked with extinction events. This lasted until the end of the Devonian, 358.9± 0.4 million years ago.[22]

Climate

The Devonian was a relatively warm period, and probably lacked any glaciers for much of the period. The temperature gradient from the equator to the poles was not as large as it is today. The weather was also very arid, mostly along the equator where it was the driest.[24] Reconstruction of tropical sea surface temperature from conodont apatite implies an average value of 30 °C (86 °F) in the Early Devonian.[24] CO2 levels dropped steeply throughout the Devonian Period. The newly evolved forests drew carbon out of the atmosphere, which were then buried into sediments. This may be reflected by a Mid-Devonian cooling of around 5 °C (9 °F).[24] The Late Devonian warmed to levels equivalent to the Early Devonian; while there is no corresponding increase in CO2 concentrations, continental weathering increases (as predicted by warmer temperatures); further, a range of evidence, such as plant distribution, points to a Late Devonian warming.[24] The climate would have affected the dominant organisms in reefs; microbes would have been the main reef-forming organisms in warm periods, with corals and stromatoporoid sponges taking the dominant role in cooler times. The warming at the end of the Devonian may even have contributed to the extinction of the stromatoporoids. At the terminus of the Devonian, Earth rapidly cooled into an icehouse, marking the beginning of the Late Palaeozoic Ice Age.[25][26]

Paleogeography

The Devonian world involved many continents and ocean basins of various sizes. The largest continent, Gondwana, was located entirely within the Southern Hemisphere. It corresponds to modern day South America, Africa, Australia, Antarctica, and India, as well as minor components of North America and Asia. The second-largest continent, Laurussia, was northwest of Gondwana, and corresponds to much of modern-day North America and Europe. Various smaller continents, microcontinents, and terranes were present east of Laurussia and north of Gondwana, corresponding to parts of Europe and Asia. The Devonian Period was a time of great tectonic activity, as the major continents of Laurussia and Gondwana drew closer together.[27][28]

Sea levels were high worldwide, and much of the land lay under shallow seas, where tropical reef organisms lived. The enormous "world ocean", Panthalassa, occupied much of the Northern Hemisphere as well as wide swathes east of Gondwana and west of Laurussia. Other minor oceans were the Paleo-Tethys Ocean and Rheic Ocean.[27][28]

Laurussia

 
Continental boundary of Laurussia (Euramerica) and its constituents, superimposed onto modern coastlines

By the early Devonian, the continent Laurussia (also known as Euramerica) was fully formed through the collision of the continents Laurentia (modern day North America) and Baltica (modern day northern and eastern Europe). The tectonic effects of this collision continued into the Devonian, producing a string of mountain ranges along the southeastern coast of the continent. In present-day eastern North America, the Acadian Orogeny continued to raise the Appalachian Mountains. Further east, the collision also extended the rise of the Caledonian Mountains of Great Britain and Scandinavia. As the Caledonian Orogeny wound down in the later part of the period, orogenic collapse facilitated a cluster of granite intrusions in Scotland.[27]

Most of Laurussia was located south of the equator, but in the Devonian it moved northwards and began to rotate counterclockwise towards its modern position. While the most northern parts of the continent (such as Greenland and Ellesmere Island) established tropical conditions, most of the continent was located within the natural dry zone along the Tropic of Capricorn, which (as nowadays) is a result of the convergence of two great air-masses, the Hadley cell and the Ferrel cell. In these near-deserts, the Old Red Sandstone sedimentary beds formed, made red by the oxidised iron (hematite) characteristic of drought conditions. The abundance of red sandstone on continental land also lends Laurussia the name "the Old Red Continent".[29] For much of the Devonian, the majority of western Laurussia (North America) was covered by subtropical inland seas which hosted a diverse ecosystem of reefs and marine life. Devonian marine deposits are particularly prevalent in the midwestern and northeastern United States. Devonian reefs also extended along the southeast edge of Laurussia, a coastline now corresponding to southern England, Belgium, and other mid-latitude areas of Europe.[27]

In the Early and Middle Devonian, the west coast of Laurussia was a passive margin with broad coastal waters, deep silty embayments, river deltas and estuaries, found today in Idaho and Nevada. In the Late Devonian, an approaching volcanic island arc reached the steep slope of the continental shelf and began to uplift deep water deposits. This minor collision sparked the start of a mountain-building episode called the Antler orogeny, which extended into the Carboniferous.[27][30] Mountain building could also be found in the far northeastern extent of the continent, as minor tropical island arcs and detached Baltic terranes re-join the continent. Deformed remnants of these mountains can still be found on Ellesmere Island and Svalbard. Many of the Devonian collisions in Laurussia produce both mountain chains and foreland basins, which are frequently fossiliferous.[27][28]

Gondwana

 
The Early-Middle Devonian world, with major continents Gondwana (Go), Euramerica/Laurussia (Eu), and Siberia (Si)

Gondwana was by far the largest continent on the planet. It was completely south of the equator, although the northeastern sector (now Australia) did reach tropical latitudes. The southwestern sector (now South America) was located to the far south, with Brazil situated near the South Pole. The northwestern edge of Gondwana was an active margin for much of the Devonian, and saw the accretion of many smaller land masses and island arcs. These include Chilenia, Cuyania, and Chaitenia, which now form much of Chile and Patagonia.[27][31] These collisions were associated with volcanic activity and plutons, but by the Late Devonian the tectonic situation had relaxed and much of South America was covered by shallow seas. These south polar seas hosted a distinctive brachiopod fauna, the Malvinokaffric Realm, which extended eastward to marginal areas now equivalent to South Africa and Antarctica. Malvinokaffric faunas even managed to approach the South Pole via a tongue of Panthalassa which extended into the Paraná Basin.[27]

The northern rim of Gondwana was mostly a passive margin, hosting extensive marine deposits in areas such as northwest Africa and Tibet. The eastern margin, though warmer than the west, was equally active. Numerous mountain building events and granite and kimberlite intrusions affected areas equivalent to modern day eastern Australia, Tasmania, and Antarctica.[27]

Asian terranes

 
The earth at 380 Ma, centered on the Paleo-Tethys Ocean, which fully opened during the Devonian

Several island microcontinents (which would later coalesce into modern day Asia) stretched over a low-latitude archipelago to the north of Gondwana. They were separated from the southern continent by an oceanic basin: the Paleo-Tethys. Although the western Paleo-Tethys Ocean had existed since the Cambrian, the eastern part only began to rift apart as late as the Silurian. This process accelerated in the Devonian. The eastern branch of the Paleo-Tethys was fully opened when South China and Annamia (a terrane equivalent to most of Indochina), together as a unified continent, detached from the northeastern sector of Gondwana. Nevertheless, they remained close enough to Gondwana that their Devonian fossils were more closely related to Australian species than to north Asian species. Other Asian terranes remained attached to Gondwana, including Sibumasu (western Indochina), Tibet, and the rest of the Cimmerian blocks.[27][28]

 
World map at 400 Ma (Early Devonian), showing continents and terranes with modern continent borders superimposed

While the South China-Annamia continent was the newest addition to the Asian microcontinents, it was not the first. North China and the Tarim Block (now northwesternmost China) were located westward and continued to drift northwards, powering over older oceanic crust in the process. Further west was a small ocean (the Turkestan Ocean), followed by the larger microcontinents of Kazakhstania, Siberia, and Amuria. Kazakhstania was a volcanically active region during the Devonian, as it continued to assimilate smaller island arcs.[27]

Siberia was located just north of the equator as the largest landmass in the Northern Hemisphere. At the beginning of the Devonian, Siberia was inverted (upside down) relative to its modern orientation. Later in the period it moved northwards and began to twist clockwise, though it was not near its modern location. Siberia approached the eastern edge of Laurussia as the Devonian progressed, but it was still separated by a seaway, the Ural Ocean. Although Siberia's margins were generally tectonically stable and ecologically productive, rifting and deep mantle plumes impacted the continent with flood basalts during the Late Devonian. The Altai-Sayan region was shaken by volcanism in the Early and Middle Devonian, while Late Devonian magmatism was magnified further to produce the Vilyuy Traps, flood basalts which may have contributed to the Late Devonian Mass Extinction. The last major round of volcanism, the Yakutsk Large Igneous Province, continued into the Carboniferous to produce extensive kimberlite deposits.[27][28]

Similar volcanic activity also affected the nearby microcontinent of Amuria (now Manchuria, Mongolia and their vicinities). Though certainly close to Siberia in the Devonian, the precise location of Amuria is uncertain due to contradictory paleomagnetic data.[27]

Closure of the Rheic Ocean

The Rheic Ocean, which separated Laurussia from Gondwana, was wide at the start of the Devonian, having formed after the drift of Avalonia away from Gondwana. It steadily shrunk as the period continued, as the two major continents approached near the equator in the early stages of the assembly of Pangaea. The closure of the Rheic Ocean began in the Devonian and continued into the Carboniferous. As the ocean narrowed, endemic marine faunas of Gondwana and Laurussia combined into a single tropical fauna. The history of the western Rheic Ocean is a subject of debate, but there is good evidence that Rheic oceanic crust experienced intense subduction and metamorphism under Mexico and Central America.[27][28]

The closure of the eastern part of the Rheic Ocean is associated with the assemblage of central and southern Europe. In the early Paleozoic, much of Europe was still attached to Gondwana, including the terranes of Iberia, Armorica (France), Palaeo-Adria (the western Mediterranean area), Bohemia, Franconia, and Saxothuringia. These continental blocks, collectively known as the Armorican Terrane Assemblage, split away from Gondwana in the Silurian and drifted towards Laurussia through the Devonian. Their collision with Laurussia leads to the beginning of the Variscan Orogeny, a major mountain-building event which would escalate further in the Late Paleozoic. Franconia and Saxothuringia collided with Laurussia near the end of the Early Devonian, pinching out the easternmost Rheic Ocean. The rest of the Armorican terranes followed, and by the end of the Devonian they were fully connected with Laurussia. This sequence of rifting and collision events led to the successive creation and destruction of several small seaways, including the Rheno-Hercynian, Saxo-Thuringian, and Galicia-Moldanubian oceans. Their sediments were eventually compressed and completely buried as Gondwana fully collided with Laurussia in the Carboniferous.[27][28][32]

Life

Marine biota

 
Spindle diagram for the evolution of vertebrates[33]
See also: Evolution of fish § Devonian: Age of fishes

Sea levels in the Devonian were generally high. Marine faunas continued to be dominated by bryozoa, diverse and abundant brachiopods, the enigmatic hederellids, microconchids and corals. Lily-like crinoids (animals, their resemblance to flowers notwithstanding) were abundant, and trilobites were still fairly common. Bivalves became commonplace in deep water and outer shelf environments.[34] The first ammonites also appeared during or slightly before the early Devonian Period around 400  Mya.[35] Bactritoids make their first appearance in the Early Devonian as well; their radiation, along with that of ammonoids, has been attributed by some authors to increased environmental stress resulting from decreasing oxygen levels in the deeper parts of the water column.[36] Among vertebrates, jawless armored fish (ostracoderms) declined in diversity, while the jawed fish (gnathostomes) simultaneously increased in both the sea and fresh water. Armored placoderms were numerous during the lower stages of the Devonian Period and became extinct in the Late Devonian, perhaps because of competition for food against the other fish species. Early cartilaginous (Chondrichthyes) and bony fishes (Osteichthyes) also become diverse and played a large role within the Devonian seas. The first abundant genus of cartilaginous fish, Cladoselache, appeared in the oceans during the Devonian Period. The great diversity of fish around at the time has led to the Devonian being given the name "The Age of Fish" in popular culture.[37]

The Devonian saw significant expansion in the diversity of nektonic marine life driven by the abundance of planktonic microorganisms in the free water column as well as high ecological competition in benthic habitats, which were extremely saturated; this diversification has been labeled the Devonian Nekton Revolution by many researchers.[38] However, other researchers have questioned whether this revolution existed at all; a 2018 study found that although the proportion of biodiversity constituted by nekton increased across the boundary between the Silurian and Devonian, it decreased across the span of the Devonian, particularly during the Pragian, and that the overall diversity of nektonic taxa did not increase significantly during the Devonian compared to during other geologic periods, and was in fact higher during the intervals spanning from the Wenlock to the Lochkovian and from the Carboniferous to the Permian. The study's authors instead attribute the increased overall diversity of nekton in the Devonian to a broader, gradual trend of nektonic diversification across the entire Palaeozoic.[39]

Reefs

A now-dry barrier reef, located in present-day Kimberley Basin of northwest Australia, once extended 350 km (220 mi), fringing a Devonian continent.[40] Reefs are generally built by various carbonate-secreting organisms that can erect wave-resistant structures near sea level. Although modern reefs are constructed mainly by corals and calcareous algae, Devonian reefs were either microbial reefs built up mostly by autotrophic cyanobacteria or coral-stromatoporoid reefs built up by coral-like stromatoporoids and tabulate and rugose corals. Microbial reefs dominated under the warmer conditions of the early and late Devonian, while coral-stromatoporoid reefs dominated during the cooler middle Devonian.[41]

Terrestrial biota

 
Prototaxites milwaukeensis, a large fungus, initially thought to be a marine alga, from the Middle Devonian of Wisconsin

By the Devonian Period, life was well underway in its colonization of the land. The moss forests and bacterial and algal mats of the Silurian were joined early in the period by primitive rooted plants that created the first stable soils and harbored arthropods like mites, scorpions, trigonotarbids[42] and myriapods (although arthropods appeared on land much earlier than in the Early Devonian[43] and the existence of fossils such as Protichnites suggest that amphibious arthropods may have appeared as early as the Cambrian). By far the largest land organism at the beginning of this period was the enigmatic Prototaxites, which was possibly the fruiting body of an enormous fungus,[44] rolled liverwort mat,[45] or another organism of uncertain affinities[46] that stood more than 8 metres (26 ft) tall, and towered over the low, carpet-like vegetation during the early part of the Devonian. Also, the first possible fossils of insects appeared around 416  Mya, in the Early Devonian. Evidence for the earliest tetrapods takes the form of trace fossils in shallow lagoon environments within a marine carbonate platform/shelf during the Middle Devonian,[47] although these traces have been questioned and an interpretation as fish feeding traces (Piscichnus) has been advanced.[48]

The greening of land

Main article: Devonian explosion
 
The Devonian Period marks the beginning of extensive land colonisation by plants. With large land-dwelling herbivores not yet present, large forests grew and shaped the landscape.

Many Early Devonian plants did not have true roots or leaves like extant plants, although vascular tissue is observed in many of those plants. Some of the early land plants such as Drepanophycus likely spread by vegetative growth and spores.[49] The earliest land plants such as Cooksonia consisted of leafless, dichotomous axes and terminal sporangia and were generally very short-statured, and grew hardly more than a few centimetres tall.[50] Fossils of Armoricaphyton chateaupannense, about 400 million years old, represent the oldest known plants with woody tissue.[51] By the Middle Devonian, shrub-like forests of primitive plants existed: lycophytes, horsetails, ferns, and progymnosperms evolved. Most of these plants had true roots and leaves, and many were quite tall. The earliest-known trees appeared in the Middle Devonian.[52] These included a lineage of lycopods and another arborescent, woody vascular plant, the cladoxylopsids and progymnosperm Archaeopteris.[53] These tracheophytes were able to grow to large size on dry land because they had evolved the ability to biosynthesize lignin, which gave them physical rigidity and improved the effectiveness of their vascular system while giving them resistance to pathogens and herbivores.[54] These are the oldest-known trees of the world's first forests. By the end of the Devonian, the first seed-forming plants had appeared. This rapid appearance of many plant groups and growth forms has been referred to as the Devonian Explosion or the Silurian-Devonian Terrestrial Revolution.[55]

The 'greening' of the continents acted as a carbon sink, and atmospheric concentrations of carbon dioxide may have dropped. This may have cooled the climate and led to a massive extinction event. (See Late Devonian extinction).

  •  

    Lycopod axis (branch) from the Middle Devonian of Wisconsin

  •  

    Bark (possibly from a cladoxylopsid) from the Middle Devonian of Wisconsin

Animals and the first soils

Primitive arthropods co-evolved with this diversified terrestrial vegetation structure. The evolving co-dependence of insects and seed plants that characterized a recognizably modern world had its genesis in the Late Devonian Epoch. The development of soils and plant root systems probably led to changes in the speed and pattern of erosion and sediment deposition. The rapid evolution of a terrestrial ecosystem that contained copious animals opened the way for the first vertebrates to seek terrestrial living. By the end of the Devonian, arthropods were solidly established on the land.[56]

Gallery

  •  

    Dunkleosteus, one of the largest armoured fish ever to roam the planet, lived during the Late Devonian

  •  

    Lower jaw of Eastmanosteus pustulosus from the Middle Devonian of Wisconsin

  •  

    Tooth of the lobe-finned fish Onychodus from the Middle Devonian of Wisconsin

  •  

    Shark-like Cladoselache, several lobe-finned fishes, including Eusthenopteron that was an early marine tetrapod, and the placoderm Bothriolepis in a painting from 1905

  •  

    Melocrinites nodosus spinosus, a spiny, stalked crinoid from the Middle Devonian of Wisconsin

  •  

    Enrolled phacopid trilobite from the Devonian of Ohio

  •  

    The common tabulate coral Aulopora from the Middle Devonian of Ohio – view of colony encrusting a brachiopod valve

  •  

    Tropidoleptus carinatus, an orthid brachiopod from the Middle Devonian of New York

  •  

    Pleurodictyum americanum, Kashong Shale, Middle Devonian of New York

  •  

    SEM image of a hederelloid from the Devonian of Michigan (largest tube diameter is 0.75 mm)

  •  

    Devonian spiriferid brachiopod from Ohio which served as a host substrate for a colony of hederelloids

Late Devonian extinction

Main article: Late Devonian extinction
 
The Late Devonian is characterised by three episodes of extinction ("Late D")

The Late Devonian extinction is not a single event, but rather is a series of pulsed extinctions at the Givetian-Frasnian boundary, the Frasnian-Famennian boundary, and the Devonian-Carboniferous boundary.[57] Together, these are considered one of the "Big Five" mass extinctions in Earth's history.[58] The Devonian extinction crisis primarily affected the marine community, and selectively affected shallow warm-water organisms rather than cool-water organisms. The most important group to be affected by this extinction event were the reef-builders of the great Devonian reef systems.[59]

Amongst the severely affected marine groups were the brachiopods, trilobites, ammonites, and acritarchs, and the world saw the disappearance of an estimated 96% of vertebrates like conodonts and bony fishes, and all of the ostracoderms and placoderms.[57][60] Land plants as well as freshwater species, such as our tetrapod ancestors, were relatively unaffected by the Late Devonian extinction event (there is a counterargument that the Devonian extinctions nearly wiped out the tetrapods[61]).

The reasons for the Late Devonian extinctions are still unknown, and all explanations remain speculative.[62][63][64][65] Canadian paleontologist Digby McLaren suggested in 1969 that the Devonian extinction events were caused by an asteroid impact. However, while there were Late Devonian collision events (see the Alamo bolide impact), little evidence supports the existence of a large enough Devonian crater.[66]

See also

Categories

Notes

  1. ^ Sedgwick and Murchison coined the term "Devonian system" in 1840:[16] "We propose therefore, for the future, to designate these groups collectively by the name Devonian system". Sedgwick and Murchison acknowledged William Lonsdale's role in proposing, on the basis of fossil evidence, the existence of a Devonian stratum between those of the Silurian and Carboniferous periods:[17] "Again, Mr. Lonsdale, after an extensive examination of the fossils of South Devon, had pronounced them, more than a year since, to form a group intermediate between those of the Carboniferous and Silurian systems". William Lonsdale stated that in December 1837 he had suggested the existence of a stratum between the Silurian and Carboniferous ones:[18] "Mr. Austen's communication [was] read December 1837 ... . It was immediately after the reading of that paper ... that I formed the opinion relative to the limestones of Devonshire being of the age of the old red sandstone; and which I afterwards suggested first to Mr. Murchison and then to Prof. Sedgwick".

References

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External links

 
Wikisource has original works on the topic: Paleozoic#Devonian
 
Wikimedia Commons has media related to Devonian.
  • . Devonian Times. Archived from the original on 11 February 2010.
  • "Devonian life". UC Berkeley. – site introduces the Devonian
  • "Geologic Time Scale". International Commission on Stratigraphy (ICS). 2004. Retrieved 19 September 2005.
  • "Examples of Devonian Fossils".
  • "Devonian chronostratigraphy scale".
  • . Palaeos. Archived from the original on 28 October 2007.
  • "Museum". Age of Fishes.

January 31, 2023
devonian, this, article, about, geological, period, residents, county, devon, other, uses, disambiguation, geologic, period, system, paleozoic, spanning, million, years, from, silurian, million, years, beginning, carboniferous, named, after, devon, england, wh. This article is about the geological period For the residents of the UK county see Devon For other uses see Devonian disambiguation The Devonian d ɪ ˈ v oʊ n i en d ɛ de VOH nee en de 9 10 is a geologic period and system of the Paleozoic era spanning 60 3 million years from the end of the Silurian 419 2 million years ago Mya to the beginning of the Carboniferous 358 9 Mya 11 It is named after Devon England where rocks from this period were first studied Devonian419 2 3 2 358 9 0 4 Ma PreꞒ Ꞓ O S D C P T J K Pg NLate Devonian world mapChronology 420 415 410 405 400 395 390 385 380 375 370 365 360 PaleozoicSilurianDevonianCarboniferousEarlyMidLateLochkovianPragianEmsianEifelianGivetianFrasnianFamennian Rhynie chert 1 Hangenberg event Famennian glaciation Kellwasser event Late Devonian extinction 2 Widespread 3 shrubs amp trees Hunsruck faunaSubdivision of the Devonian according to the ICS as of 2021 4 Vertical axis scale millions of years ago EtymologyName formalityFormalNickname s Age of FishesUsage informationCelestial bodyEarthRegional usageGlobal ICS Time scale s usedICS Time ScaleDefinitionChronological unitPeriodStratigraphic unitSystemTime span formalityFormalLower boundary definitionFAD of the Graptolite Monograptus uniformisLower boundary GSSPKlonk Czech Republic49 51 18 N 13 47 31 E 49 8550 N 13 7920 E 49 8550 13 7920Lower GSSP ratified1972 5 Upper boundary definitionFAD of the Conodont Siphonodella sulcata discovered to have biostratigraphic issues as of 2006 6 Upper boundary GSSPLa Serre Montagne Noire France43 33 20 N 3 21 26 E 43 5555 N 3 3573 E 43 5555 3 3573Upper GSSP ratified1990 7 Atmospheric and climatic dataSea level above present dayRelatively steady around 189 m gradually falling to 120 m through period 8 The first significant adaptive radiation of life on dry land occurred during the Devonian Free sporing vascular plants began to spread across dry land forming extensive forests which covered the continents By the middle of the Devonian several groups of plants had evolved leaves and true roots and by the end of the period the first seed bearing plants appeared The arthropod groups of myriapods arachnids and hexapods also became well established early in this period after starting their expansion to land at least from the Ordovician period Fish reached substantial diversity during this time leading the Devonian to often be dubbed the Age of Fishes The placoderms began dominating almost every known aquatic environment The ancestors of all four limbed vertebrates tetrapods began adapting to walk on land as their strong pectoral and pelvic fins gradually evolved into legs though they were not fully established until the Late Carboniferous 12 In the oceans primitive sharks became more numerous than in the Silurian and Late Ordovician The first ammonites a subclass of molluscs appeared Trilobites the mollusc like brachiopods and the great coral reefs were still common The Late Devonian extinction which started about 375 million years ago 13 severely affected marine life killing off all placodermi and all trilobites save for a few species of the order Proetida Devonian palaeogeography was dominated by the supercontinent of Gondwana to the south the small continent of Siberia to the north and the medium sized continent of Laurussia to the east Major tectonic events include the closure of the Rheic Ocean the separation of South China from Gondwana and the resulting expansion of the Paleo Tethys Ocean The Devonian experienced several major mountain building events as Laurussia and Gondwana approached these include the Acadian Orogeny in North America and the beginning of the Variscan Orogeny in Europe These early collisions preceded the formation of Pangaea in the Late Paleozoic Contents 1 History 2 Subdivisions 3 Climate 4 Paleogeography 4 1 Laurussia 4 2 Gondwana 4 3 Asian terranes 4 4 Closure of the Rheic Ocean 5 Life 5 1 Marine biota 5 2 Reefs 5 3 Terrestrial biota 5 3 1 The greening of land 5 3 2 Animals and the first soils 5 4 Gallery 6 Late Devonian extinction 7 See also 8 Notes 9 References 10 External linksHistory Edit The rocks of Lummaton Quarry in Torquay in Devon played an early role in defining the Devonian Period The period is named after Devon a county in southwestern England where a controversial argument in the 1830s over the age and structure of the rocks found distributed throughout the county was eventually resolved by the definition of the Devonian Period in the geological timescale The Great Devonian Controversy was a long period of vigorous argument and counter argument between the main protagonists of Roderick Murchison with Adam Sedgwick against Henry De la Beche supported by George Bellas Greenough Murchison and Sedgwick won the debate and named the period they proposed as the Devonian System 14 15 a While the rock beds that define the start and end of the Devonian Period are well identified the exact dates are uncertain According to the International Commission on Stratigraphy 19 the Devonian extends from the end of the Silurian 419 2 Mya to the beginning of the Carboniferous 358 9 Mya in North America at the beginning of the Mississippian subperiod of the Carboniferous In 19th century texts the Devonian has been called the Old Red Age after the red and brown terrestrial deposits known in the United Kingdom as the Old Red Sandstone in which early fossil discoveries were found Another common term is Age of the Fishes 20 referring to the evolution of several major groups of fish that took place during the period Older literature on the Anglo Welsh basin divides it into the Downtonian Dittonian Breconian and Farlovian stages the latter three of which are placed in the Devonian 21 The Devonian has also erroneously been characterised as a greenhouse age due to sampling bias most of the early Devonian age discoveries came from the strata of western Europe and eastern North America which at the time straddled the Equator as part of the supercontinent of Euramerica where fossil signatures of widespread reefs indicate tropical climates that were warm and moderately humid In fact the climate in the Devonian differed greatly during its epochs and between geographic regions For example during the Early Devonian arid conditions were prevalent through much of the world including Siberia Australia North America and China but Africa and South America had a warm temperate climate In the Late Devonian by contrast arid conditions were less prevalent across the world and temperate climates were more common citation needed Subdivisions EditThe Devonian Period is formally broken into Early Middle and Late subdivisions The rocks corresponding to those epochs are referred to as belonging to the Lower Middle and Upper parts of the Devonian System Early DevonianThe Early Devonian lasted from 419 2 3 2 to 393 3 0 4 and began with the Lochkovian Stage 419 2 3 2 to 410 8 0 4 which was followed by the Pragian from 410 8 3 2 to 407 6 0 4 and then by the Emsian which lasted until the Middle Devonian began 393 3 1 2 million years ago 22 During this time the first ammonoids appeared descending from bactritoid nautiloids Ammonoids during this time period were simple and differed little from their nautiloid counterparts These ammonoids belong to the order Agoniatitida which in later epochs evolved to new ammonoid orders for example Goniatitida and Clymeniida This class of cephalopod molluscs would dominate the marine fauna until the beginning of the Mesozoic Era Middle DevonianThe Middle Devonian comprised two subdivisions first the Eifelian which then gave way to the Givetian 387 7 0 8 million years ago During this time the jawless agnathan fishes began to decline in diversity in freshwater and marine environments partly due to drastic environmental changes and partly due to the increasing competition predation and diversity of jawed fishes The shallow warm oxygen depleted waters of Devonian inland lakes surrounded by primitive plants provided the environment necessary for certain early fish to develop such essential characteristics as well developed lungs and the ability to crawl out of the water and onto the land for short periods of time 23 Late DevonianFinally the Late Devonian started with the Frasnian 382 7 3 2 to 372 2 0 4 during which the first forests took shape on land The first tetrapods appeared in the fossil record in the ensuing Famennian subdivision the beginning and end of which are marked with extinction events This lasted until the end of the Devonian 358 9 0 4 million years ago 22 Climate EditThe Devonian was a relatively warm period and probably lacked any glaciers for much of the period The temperature gradient from the equator to the poles was not as large as it is today The weather was also very arid mostly along the equator where it was the driest 24 Reconstruction of tropical sea surface temperature from conodont apatite implies an average value of 30 C 86 F in the Early Devonian 24 CO2 levels dropped steeply throughout the Devonian Period The newly evolved forests drew carbon out of the atmosphere which were then buried into sediments This may be reflected by a Mid Devonian cooling of around 5 C 9 F 24 The Late Devonian warmed to levels equivalent to the Early Devonian while there is no corresponding increase in CO2 concentrations continental weathering increases as predicted by warmer temperatures further a range of evidence such as plant distribution points to a Late Devonian warming 24 The climate would have affected the dominant organisms in reefs microbes would have been the main reef forming organisms in warm periods with corals and stromatoporoid sponges taking the dominant role in cooler times The warming at the end of the Devonian may even have contributed to the extinction of the stromatoporoids At the terminus of the Devonian Earth rapidly cooled into an icehouse marking the beginning of the Late Palaeozoic Ice Age 25 26 Paleogeography EditThe Devonian world involved many continents and ocean basins of various sizes The largest continent Gondwana was located entirely within the Southern Hemisphere It corresponds to modern day South America Africa Australia Antarctica and India as well as minor components of North America and Asia The second largest continent Laurussia was northwest of Gondwana and corresponds to much of modern day North America and Europe Various smaller continents microcontinents and terranes were present east of Laurussia and north of Gondwana corresponding to parts of Europe and Asia The Devonian Period was a time of great tectonic activity as the major continents of Laurussia and Gondwana drew closer together 27 28 Sea levels were high worldwide and much of the land lay under shallow seas where tropical reef organisms lived The enormous world ocean Panthalassa occupied much of the Northern Hemisphere as well as wide swathes east of Gondwana and west of Laurussia Other minor oceans were the Paleo Tethys Ocean and Rheic Ocean 27 28 Laurussia Edit Continental boundary of Laurussia Euramerica and its constituents superimposed onto modern coastlines By the early Devonian the continent Laurussia also known as Euramerica was fully formed through the collision of the continents Laurentia modern day North America and Baltica modern day northern and eastern Europe The tectonic effects of this collision continued into the Devonian producing a string of mountain ranges along the southeastern coast of the continent In present day eastern North America the Acadian Orogeny continued to raise the Appalachian Mountains Further east the collision also extended the rise of the Caledonian Mountains of Great Britain and Scandinavia As the Caledonian Orogeny wound down in the later part of the period orogenic collapse facilitated a cluster of granite intrusions in Scotland 27 Most of Laurussia was located south of the equator but in the Devonian it moved northwards and began to rotate counterclockwise towards its modern position While the most northern parts of the continent such as Greenland and Ellesmere Island established tropical conditions most of the continent was located within the natural dry zone along the Tropic of Capricorn which as nowadays is a result of the convergence of two great air masses the Hadley cell and the Ferrel cell In these near deserts the Old Red Sandstone sedimentary beds formed made red by the oxidised iron hematite characteristic of drought conditions The abundance of red sandstone on continental land also lends Laurussia the name the Old Red Continent 29 For much of the Devonian the majority of western Laurussia North America was covered by subtropical inland seas which hosted a diverse ecosystem of reefs and marine life Devonian marine deposits are particularly prevalent in the midwestern and northeastern United States Devonian reefs also extended along the southeast edge of Laurussia a coastline now corresponding to southern England Belgium and other mid latitude areas of Europe 27 In the Early and Middle Devonian the west coast of Laurussia was a passive margin with broad coastal waters deep silty embayments river deltas and estuaries found today in Idaho and Nevada In the Late Devonian an approaching volcanic island arc reached the steep slope of the continental shelf and began to uplift deep water deposits This minor collision sparked the start of a mountain building episode called the Antler orogeny which extended into the Carboniferous 27 30 Mountain building could also be found in the far northeastern extent of the continent as minor tropical island arcs and detached Baltic terranes re join the continent Deformed remnants of these mountains can still be found on Ellesmere Island and Svalbard Many of the Devonian collisions in Laurussia produce both mountain chains and foreland basins which are frequently fossiliferous 27 28 Gondwana Edit The Early Middle Devonian world with major continents Gondwana Go Euramerica Laurussia Eu and Siberia Si Gondwana was by far the largest continent on the planet It was completely south of the equator although the northeastern sector now Australia did reach tropical latitudes The southwestern sector now South America was located to the far south with Brazil situated near the South Pole The northwestern edge of Gondwana was an active margin for much of the Devonian and saw the accretion of many smaller land masses and island arcs These include Chilenia Cuyania and Chaitenia which now form much of Chile and Patagonia 27 31 These collisions were associated with volcanic activity and plutons but by the Late Devonian the tectonic situation had relaxed and much of South America was covered by shallow seas These south polar seas hosted a distinctive brachiopod fauna the Malvinokaffric Realm which extended eastward to marginal areas now equivalent to South Africa and Antarctica Malvinokaffric faunas even managed to approach the South Pole via a tongue of Panthalassa which extended into the Parana Basin 27 The northern rim of Gondwana was mostly a passive margin hosting extensive marine deposits in areas such as northwest Africa and Tibet The eastern margin though warmer than the west was equally active Numerous mountain building events and granite and kimberlite intrusions affected areas equivalent to modern day eastern Australia Tasmania and Antarctica 27 Asian terranes Edit The earth at 380 Ma centered on the Paleo Tethys Ocean which fully opened during the DevonianSeveral island microcontinents which would later coalesce into modern day Asia stretched over a low latitude archipelago to the north of Gondwana They were separated from the southern continent by an oceanic basin the Paleo Tethys Although the western Paleo Tethys Ocean had existed since the Cambrian the eastern part only began to rift apart as late as the Silurian This process accelerated in the Devonian The eastern branch of the Paleo Tethys was fully opened when South China and Annamia a terrane equivalent to most of Indochina together as a unified continent detached from the northeastern sector of Gondwana Nevertheless they remained close enough to Gondwana that their Devonian fossils were more closely related to Australian species than to north Asian species Other Asian terranes remained attached to Gondwana including Sibumasu western Indochina Tibet and the rest of the Cimmerian blocks 27 28 World map at 400 Ma Early Devonian showing continents and terranes with modern continent borders superimposed While the South China Annamia continent was the newest addition to the Asian microcontinents it was not the first North China and the Tarim Block now northwesternmost China were located westward and continued to drift northwards powering over older oceanic crust in the process Further west was a small ocean the Turkestan Ocean followed by the larger microcontinents of Kazakhstania Siberia and Amuria Kazakhstania was a volcanically active region during the Devonian as it continued to assimilate smaller island arcs 27 Siberia was located just north of the equator as the largest landmass in the Northern Hemisphere At the beginning of the Devonian Siberia was inverted upside down relative to its modern orientation Later in the period it moved northwards and began to twist clockwise though it was not near its modern location Siberia approached the eastern edge of Laurussia as the Devonian progressed but it was still separated by a seaway the Ural Ocean Although Siberia s margins were generally tectonically stable and ecologically productive rifting and deep mantle plumes impacted the continent with flood basalts during the Late Devonian The Altai Sayan region was shaken by volcanism in the Early and Middle Devonian while Late Devonian magmatism was magnified further to produce the Vilyuy Traps flood basalts which may have contributed to the Late Devonian Mass Extinction The last major round of volcanism the Yakutsk Large Igneous Province continued into the Carboniferous to produce extensive kimberlite deposits 27 28 Similar volcanic activity also affected the nearby microcontinent of Amuria now Manchuria Mongolia and their vicinities Though certainly close to Siberia in the Devonian the precise location of Amuria is uncertain due to contradictory paleomagnetic data 27 Closure of the Rheic Ocean Edit The Rheic Ocean which separated Laurussia from Gondwana was wide at the start of the Devonian having formed after the drift of Avalonia away from Gondwana It steadily shrunk as the period continued as the two major continents approached near the equator in the early stages of the assembly of Pangaea The closure of the Rheic Ocean began in the Devonian and continued into the Carboniferous As the ocean narrowed endemic marine faunas of Gondwana and Laurussia combined into a single tropical fauna The history of the western Rheic Ocean is a subject of debate but there is good evidence that Rheic oceanic crust experienced intense subduction and metamorphism under Mexico and Central America 27 28 The closure of the eastern part of the Rheic Ocean is associated with the assemblage of central and southern Europe In the early Paleozoic much of Europe was still attached to Gondwana including the terranes of Iberia Armorica France Palaeo Adria the western Mediterranean area Bohemia Franconia and Saxothuringia These continental blocks collectively known as the Armorican Terrane Assemblage split away from Gondwana in the Silurian and drifted towards Laurussia through the Devonian Their collision with Laurussia leads to the beginning of the Variscan Orogeny a major mountain building event which would escalate further in the Late Paleozoic Franconia and Saxothuringia collided with Laurussia near the end of the Early Devonian pinching out the easternmost Rheic Ocean The rest of the Armorican terranes followed and by the end of the Devonian they were fully connected with Laurussia This sequence of rifting and collision events led to the successive creation and destruction of several small seaways including the Rheno Hercynian Saxo Thuringian and Galicia Moldanubian oceans Their sediments were eventually compressed and completely buried as Gondwana fully collided with Laurussia in the Carboniferous 27 28 32 Life EditMarine biota Edit Spindle diagram for the evolution of vertebrates 33 See also Evolution of fish Devonian Age of fishes Sea levels in the Devonian were generally high Marine faunas continued to be dominated by bryozoa diverse and abundant brachiopods the enigmatic hederellids microconchids and corals Lily like crinoids animals their resemblance to flowers notwithstanding were abundant and trilobites were still fairly common Bivalves became commonplace in deep water and outer shelf environments 34 The first ammonites also appeared during or slightly before the early Devonian Period around 400 Mya 35 Bactritoids make their first appearance in the Early Devonian as well their radiation along with that of ammonoids has been attributed by some authors to increased environmental stress resulting from decreasing oxygen levels in the deeper parts of the water column 36 Among vertebrates jawless armored fish ostracoderms declined in diversity while the jawed fish gnathostomes simultaneously increased in both the sea and fresh water Armored placoderms were numerous during the lower stages of the Devonian Period and became extinct in the Late Devonian perhaps because of competition for food against the other fish species Early cartilaginous Chondrichthyes and bony fishes Osteichthyes also become diverse and played a large role within the Devonian seas The first abundant genus of cartilaginous fish Cladoselache appeared in the oceans during the Devonian Period The great diversity of fish around at the time has led to the Devonian being given the name The Age of Fish in popular culture 37 The Devonian saw significant expansion in the diversity of nektonic marine life driven by the abundance of planktonic microorganisms in the free water column as well as high ecological competition in benthic habitats which were extremely saturated this diversification has been labeled the Devonian Nekton Revolution by many researchers 38 However other researchers have questioned whether this revolution existed at all a 2018 study found that although the proportion of biodiversity constituted by nekton increased across the boundary between the Silurian and Devonian it decreased across the span of the Devonian particularly during the Pragian and that the overall diversity of nektonic taxa did not increase significantly during the Devonian compared to during other geologic periods and was in fact higher during the intervals spanning from the Wenlock to the Lochkovian and from the Carboniferous to the Permian The study s authors instead attribute the increased overall diversity of nekton in the Devonian to a broader gradual trend of nektonic diversification across the entire Palaeozoic 39 Reefs Edit A now dry barrier reef located in present day Kimberley Basin of northwest Australia once extended 350 km 220 mi fringing a Devonian continent 40 Reefs are generally built by various carbonate secreting organisms that can erect wave resistant structures near sea level Although modern reefs are constructed mainly by corals and calcareous algae Devonian reefs were either microbial reefs built up mostly by autotrophic cyanobacteria or coral stromatoporoid reefs built up by coral like stromatoporoids and tabulate and rugose corals Microbial reefs dominated under the warmer conditions of the early and late Devonian while coral stromatoporoid reefs dominated during the cooler middle Devonian 41 Terrestrial biota Edit Prototaxites milwaukeensis a large fungus initially thought to be a marine alga from the Middle Devonian of Wisconsin By the Devonian Period life was well underway in its colonization of the land The moss forests and bacterial and algal mats of the Silurian were joined early in the period by primitive rooted plants that created the first stable soils and harbored arthropods like mites scorpions trigonotarbids 42 and myriapods although arthropods appeared on land much earlier than in the Early Devonian 43 and the existence of fossils such as Protichnites suggest that amphibious arthropods may have appeared as early as the Cambrian By far the largest land organism at the beginning of this period was the enigmatic Prototaxites which was possibly the fruiting body of an enormous fungus 44 rolled liverwort mat 45 or another organism of uncertain affinities 46 that stood more than 8 metres 26 ft tall and towered over the low carpet like vegetation during the early part of the Devonian Also the first possible fossils of insects appeared around 416 Mya in the Early Devonian Evidence for the earliest tetrapods takes the form of trace fossils in shallow lagoon environments within a marine carbonate platform shelf during the Middle Devonian 47 although these traces have been questioned and an interpretation as fish feeding traces Piscichnus has been advanced 48 The greening of land Edit Main article Devonian explosion The Devonian Period marks the beginning of extensive land colonisation by plants With large land dwelling herbivores not yet present large forests grew and shaped the landscape Many Early Devonian plants did not have true roots or leaves like extant plants although vascular tissue is observed in many of those plants Some of the early land plants such as Drepanophycus likely spread by vegetative growth and spores 49 The earliest land plants such as Cooksonia consisted of leafless dichotomous axes and terminal sporangia and were generally very short statured and grew hardly more than a few centimetres tall 50 Fossils of Armoricaphyton chateaupannense about 400 million years old represent the oldest known plants with woody tissue 51 By the Middle Devonian shrub like forests of primitive plants existed lycophytes horsetails ferns and progymnosperms evolved Most of these plants had true roots and leaves and many were quite tall The earliest known trees appeared in the Middle Devonian 52 These included a lineage of lycopods and another arborescent woody vascular plant the cladoxylopsids and progymnosperm Archaeopteris 53 These tracheophytes were able to grow to large size on dry land because they had evolved the ability to biosynthesize lignin which gave them physical rigidity and improved the effectiveness of their vascular system while giving them resistance to pathogens and herbivores 54 These are the oldest known trees of the world s first forests By the end of the Devonian the first seed forming plants had appeared This rapid appearance of many plant groups and growth forms has been referred to as the Devonian Explosion or the Silurian Devonian Terrestrial Revolution 55 The greening of the continents acted as a carbon sink and atmospheric concentrations of carbon dioxide may have dropped This may have cooled the climate and led to a massive extinction event See Late Devonian extinction Lycopod axis branch from the Middle Devonian of Wisconsin Bark possibly from a cladoxylopsid from the Middle Devonian of Wisconsin Animals and the first soils Edit Primitive arthropods co evolved with this diversified terrestrial vegetation structure The evolving co dependence of insects and seed plants that characterized a recognizably modern world had its genesis in the Late Devonian Epoch The development of soils and plant root systems probably led to changes in the speed and pattern of erosion and sediment deposition The rapid evolution of a terrestrial ecosystem that contained copious animals opened the way for the first vertebrates to seek terrestrial living By the end of the Devonian arthropods were solidly established on the land 56 Gallery Edit Dunkleosteus one of the largest armoured fish ever to roam the planet lived during the Late Devonian Lower jaw of Eastmanosteus pustulosus from the Middle Devonian of Wisconsin Tooth of the lobe finned fish Onychodus from the Middle Devonian of Wisconsin Shark like Cladoselache several lobe finned fishes including Eusthenopteron that was an early marine tetrapod and the placoderm Bothriolepis in a painting from 1905 Melocrinites nodosus spinosus a spiny stalked crinoid from the Middle Devonian of Wisconsin Enrolled phacopid trilobite from the Devonian of Ohio The common tabulate coral Aulopora from the Middle Devonian of Ohio view of colony encrusting a brachiopod valve Tropidoleptus carinatus an orthid brachiopod from the Middle Devonian of New York Pleurodictyum americanum Kashong Shale Middle Devonian of New York SEM image of a hederelloid from the Devonian of Michigan largest tube diameter is 0 75 mm Devonian spiriferid brachiopod from Ohio which served as a host substrate for a colony of hederelloidsLate Devonian extinction EditMain article Late Devonian extinction The Late Devonian is characterised by three episodes of extinction Late D The Late Devonian extinction is not a single event but rather is a series of pulsed extinctions at the Givetian Frasnian boundary the Frasnian Famennian boundary and the Devonian Carboniferous boundary 57 Together these are considered one of the Big Five mass extinctions in Earth s history 58 The Devonian extinction crisis primarily affected the marine community and selectively affected shallow warm water organisms rather than cool water organisms The most important group to be affected by this extinction event were the reef builders of the great Devonian reef systems 59 Amongst the severely affected marine groups were the brachiopods trilobites ammonites and acritarchs and the world saw the disappearance of an estimated 96 of vertebrates like conodonts and bony fishes and all of the ostracoderms and placoderms 57 60 Land plants as well as freshwater species such as our tetrapod ancestors were relatively unaffected by the Late Devonian extinction event there is a counterargument that the Devonian extinctions nearly wiped out the tetrapods 61 The reasons for the Late Devonian extinctions are still unknown and all explanations remain speculative 62 63 64 65 Canadian paleontologist Digby McLaren suggested in 1969 that the Devonian extinction events were caused by an asteroid impact However while there were Late Devonian collision events see the Alamo bolide impact little evidence supports the existence of a large enough Devonian crater 66 See also EditFalls of the Ohio State Park State park in Indiana United States One of the largest exposed Devonian fossil beds in the world Geologic time scale System that relates geologic strata to time List of Early Devonian land plants List of fossil sites with link directory Phacops rana a Devonian trilobiteCategories Category Devonian plantsNotes Edit Sedgwick and Murchison coined the term Devonian system in 1840 16 We propose therefore for the future to designate these groups collectively by the name Devonian system Sedgwick and Murchison acknowledged William Lonsdale s role in proposing on the basis of fossil evidence the existence of a Devonian stratum between those of the Silurian and Carboniferous periods 17 Again Mr Lonsdale after an extensive examination of the fossils of South Devon had pronounced them more than a year since to form a group intermediate between those of the Carboniferous and Silurian systems William Lonsdale stated that in December 1837 he had suggested the existence of a stratum between the Silurian and Carboniferous ones 18 Mr Austen s communication was read December 1837 It was immediately after the reading of that paper that I formed the opinion relative to the limestones of Devonshire being of the age of the old red sandstone and which I afterwards suggested first to Mr Murchison and then to Prof Sedgwick References Edit Parry S F Noble S R Crowley Q G Wellman C H 2011 A high precision U Pb age constraint on the Rhynie Chert Konservat Lagerstatte time scale and other implications Journal of the Geological Society London Geological Society 168 4 863 872 doi 10 1144 0016 76492010 043 Kaufmann B Trapp E Mezger K 2004 The numerical age of the Upper Frasnian Upper Devonian Kellwasser horizons A new U Pb zircon date from Steinbruch Schmidt Kellerwald Germany The Journal of Geology 112 4 495 501 Bibcode 2004JG 112 495K doi 10 1086 421077 Algeo T J 1998 Terrestrial marine teleconnections in the Devonian links between the evolution of land plants weathering processes and marine anoxic events Philosophical Transactions of the Royal Society B Biological Sciences 353 1365 113 130 doi 10 1098 rstb 1998 0195 Chart Time Scale www stratigraphy org International Commission on Stratigraphy Chlupac Ivo Hladil Jindrich January 2000 The global stratotype section and point of the Silurian Devonian boundary CFS Courier Forschungsinstitut Senckenberg 1 8 Retrieved 7 December 2020 Kaiser Sandra 1 April 2009 The Devonian Carboniferous boundary stratotype section La Serre France revisited Newsletters on Stratigraphy 43 2 195 205 doi 10 1127 0078 0421 2009 0043 0195 Retrieved 7 December 2020 Paproth Eva Feist Raimund Flajs Gerd December 1991 Decision on the Devonian Carboniferous boundary stratotype PDF Episodes 14 4 331 336 doi 10 18814 epiiugs 1991 v14i4 004 Archived PDF from the original on 9 June 2020 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 Wells John 3 April 2008 Longman Pronunciation Dictionary 3rd ed Pearson Longman ISBN 978 1 4058 8118 0 Devonian Dictionary com Unabridged Online n d Gradstein Felix M Ogg James G Smith Alan G 2004 A Geologic Time Scale 2004 Cambridge Cambridge University Press ISBN 978 0521786737 Amos Jonathan Fossil tracks record oldest land walkers BBC News Retrieved 24 December 2016 Newitz Annalee 13 June 2013 How do you have a mass extinction without an increase in extinctions The Atlantic Gradstein Ogg amp Smith 2004 Rudwick M S J 1985 The great Devonian controversy The shaping of scientific knowledge among gentlemanly specialists Chicago University of Chicago Press ISBN 978 0226731025 Sedgwick Adam Murchison Roderick Impey 1840 On the physical structure of Devonshire and on the subdivisions and geological relations of its older stratified deposits etc Part I and Part II Transactions of the Geological Society of London Second series Vol 5 part II p 701 Sedgwick amp Murchison 1840 p 690 Lonsdale William 1840 Notes on the age of limestones from south Devonshire Transactions of the Geological Society of London Second series Vol 5 part II p 724 Gradstein Ogg amp Smith 2004 Farabee Michael J 2006 Paleobiology The Late Paleozoic Devonian The Online Biology Book Estrella Mountain Community College Barclay W J 1989 Geology of the South Wales Coalfield Part II the country around Abergavenny Memoir for 1 50 000 geological sheet England and Wales 3rd ed pp 18 19 ISBN 0 11 884408 3 a b Cohen K M Finney S C Gibbard P L Fan J X 2013 The ICS International Chronostratigraphic Chart PDF Episodes 36 3 199 204 doi 10 18814 epiiugs 2013 v36i3 002 Archived PDF from the original on 13 September 2015 Retrieved 7 January 2021 Clack Jennifer 13 August 2007 Devonian climate change breathing and the origin of the tetrapod stem group Integrative and Comparative Biology 47 4 510 523 doi 10 1093 icb icm055 PMID 21672860 Estimates of oxygen levels during this period suggest that they were unprecedentedly low during the Givetian and Frasnian periods At the same time plant diversification was at its most rapid changing the character of the landscape and contributing via soils soluble nutrients and decaying plant matter to anoxia in all water systems The co occurrence of these global events may explain the evolution of air breathing adaptations in at least two lobe finned groups contributing directly to the rise of the tetrapod stem group a b c d Joachimski M M Breisig S Buggisch W F Talent J A Mawson R Gereke M Morrow J R Day J Weddige K July 2009 Devonian climate and reef evolution Insights from oxygen isotopes in apatite Earth and Planetary Science Letters 284 3 4 599 609 Bibcode 2009E amp PSL 284 599J doi 10 1016 j epsl 2009 05 028 Rosa Eduardo L M Isbell John L 2021 Late Paleozoic Glaciation In Alderton David Elias Scott A eds Encyclopedia of Geology 2nd ed Academic Press pp 534 545 doi 10 1016 B978 0 08 102908 4 00063 1 ISBN 978 0 08 102909 1 S2CID 226643402 McClung Wilson S Eriksson Kenneth A Terry Jr Dennis O Cuffey Clifford A 1 October 2013 Sequence stratigraphic hierarchy of the Upper Devonian Foreknobs Formation central Appalachian Basin USA Evidence for transitional greenhouse to icehouse conditions Palaeogeography Palaeoclimatology Palaeoecology 387 104 125 doi 10 1016 j palaeo 2013 07 020 Retrieved 16 November 2022 a b c d e f g h i j k l m n o Cocks L Robin M Torsvik Trond H eds 2016 Devonian Earth History and Palaeogeography Cambridge Cambridge University Press pp 138 158 doi 10 1017 9781316225523 009 ISBN 978 1 316 22552 3 retrieved 24 July 2022 a b c d e f g Golonka Jan 1 March 2020 Late Devonian paleogeography in the framework of global plate tectonics Global and Planetary Change 186 103129 Bibcode 2020GPC 18603129G doi 10 1016 j gloplacha 2020 103129 ISSN 0921 8181 S2CID 212928195 Devonian Period Encyclopedia Britannica geochronology Retrieved 15 December 2017 Blakey Ron C Devonian Paleogeography Southwestern US jan ucc nau edu Northern Arizona University Archived from the original on 15 April 2010 Herve Francisco Calderon Mauricio Fanning Mark Pankhurst Robert Rapela Carlos W Quezada Paulo 2018 The country rocks of Devonian magmatism in the North Patagonian Massif and Chaitenia Andean Geology 45 3 301 317 doi 10 5027 andgeoV45n3 3117 Franke Wolfgang Cocks L Robin M Torsvik Trond H 2017 The Palaeozoic Variscan oceans revisited Gondwana Research 48 257 284 Bibcode 2017GondR 48 257F doi 10 1016 j gr 2017 03 005 Benton M J 2005 Vertebrate Palaeontology 3rd ed John Wiley p 14 ISBN 9781405144490 Nagel Myers Judith 5 August 2021 An updated look at the taxonomy stratigraphy and palaeoecology of the Devonian bivalve genus Ontario Clarke 1904 Cardiolidae Bivalvia Palaeobiodiversity and Palaeoenvironments 102 3 541 555 doi 10 1007 s12549 021 00491 2 S2CID 236921239 Retrieved 8 November 2022 Kazlev M Alan 28 May 1998 Palaeos Paleozoic Devonian The Devonian Period 1 Palaeos Retrieved 24 January 2019 Klug Christian Kroeger Bjoern Korn Dieter Ruecklin Martin Schemm Gregory Mena De Baets Kenneth Mapes Royal H April 2008 Ecological change during the early Emsian Devonian in the Tafilalt Morocco the origin of the Ammonoidea and the first African pyrgocystid edrioasteroids machaerids and phyllocarids Palaeontographica Abteilung A Palaozoologie Stratigraphie 283 4 6 83 U58 doi 10 1127 pala 283 2008 83 Retrieved 8 November 2022 Dalton Rex January 2006 Hooked on fossils Nature 439 7074 262 263 doi 10 1038 439262a PMID 16421540 S2CID 4357313 Klug Christian Kroger Bjorn Kiessling Wolfgang Mullins Gary L Servais Thomas Fryda Jiri Korn Dieter Turner Susan 26 October 2010 The Devonian nekton revolution Lethaia 43 4 465 477 doi 10 1111 j 1502 3931 2009 00206 x Retrieved 3 September 2022 Whalen Christopher D Briggs Derek E G 18 July 2018 The Palaeozoic colonization of the water column and the rise of global nekton Proceedings of the Royal Society B 285 1883 1 9 doi 10 1098 rspb 2018 0883 PMC 6083262 PMID 30051837 Tyler Ian M Hocking Roger M Haines Peter W 1 March 2012 Geological evolution of the Kimberley region of Western Australia Episodes 35 1 298 306 doi 10 18814 epiiugs 2012 v35i1 029 Joachimski M M Breisig S Buggisch W Talent J A Mawson R Gereke M Morrow J R Day J Weddige K July 2009 Devonian climate and reef evolution Insights from oxygen isotopes in apatite Earth and Planetary Science Letters 284 3 4 599 609 Bibcode 2009E amp PSL 284 599J doi 10 1016 j epsl 2009 05 028 Garwood Russell J Dunlop Jason July 2014 The walking dead Blender as a tool for paleontologists with a case study on extinct arachnids Journal of Paleontology 88 4 735 746 doi 10 1666 13 088 ISSN 0022 3360 S2CID 131202472 Retrieved 21 July 2015 Garwood Russell J Edgecombe Gregory D September 2011 Early Terrestrial Animals Evolution and Uncertainty Evolution Education and Outreach 4 3 489 501 doi 10 1007 s12052 011 0357 y Hueber Francis M 2001 Rotted wood alga fungus The history and life of Prototaxites Dawson 1859 Review of Palaeobotany and Palynology 116 1 2 123 159 doi 10 1016 s0034 6667 01 00058 6 Graham Linda E Cook Martha E Hanson David T Pigg Kathleen B Graham James M 2010 Rolled liverwort mats explain major Prototaxites features Response to commentaries American Journal of Botany 97 7 1079 1086 doi 10 3732 ajb 1000172 PMID 21616860 Taylor Thomas N Taylor Edith L Decombeix Anne Laure Schwendemann Andrew Serbet Rudolph Escapa Ignacio Krings Michael 2010 The enigmatic Devonian fossil Prototaxites is not a rolled up liverwort mat Comment on the paper by Graham et al AJB 97 268 275 American Journal of Botany 97 7 1074 1078 doi 10 3732 ajb 1000047 PMID 21616859 Niedzwiedzki 2010 Tetrapod trackways from the early middle Devonian period of Poland Nature 463 7277 43 48 Bibcode 2010Natur 463 43N doi 10 1038 nature08623 PMID 20054388 S2CID 4428903 Lucas 2015 Thinopus and a Critical Review of Devonian Tetrapod Footprints Ichnos 22 3 4 136 154 doi 10 1080 10420940 2015 1063491 S2CID 130053031 Zhang Ying ying Xue Jin Zhuang Liu Le Wang De ming 2016 Periodicity of reproductive growth in lycopsids An example from the Upper Devonian of Zhejiang Province China Paleoworld 25 1 12 20 doi 10 1016 j palwor 2015 07 002 Gonez Paul Gerrienne Philippe 2010 A new definition and a lectotypification of the genus Cooksonia Lang 1937 International Journal of Plant Sciences 171 2 199 215 doi 10 1086 648988 S2CID 84956576 MacPherson C 28 August 2019 Analyzing the World s Oldest Woody Plant Fossil Canadian Light Source Retrieved 19 May 2021 Smith Lewis 19 April 2007 Fossil from a forest that gave Earth its breath of fresh air The Times London Retrieved 1 May 2010 Hogan C Michael 2010 Fern In Basu Saikat Cleveland C eds Encyclopedia of Earth Washington DC National Council for Science and the Environment Weng Jing Ke Chapple Clint July 2010 The origin and evolution of lignin biosynthesis Tansley review New Phytologist 187 2 273 285 doi 10 1111 j 1469 8137 2010 03327 x PMID 20642725 Capel Elliot Cleal Christopher J Xue Jinzhuang Monnet Claude Servais Thomas Cascales Minana Borja August 2022 The Silurian Devonian terrestrial revolution Diversity patterns and sampling bias of the vascular plant macrofossil record Earth Science Reviews 231 104085 doi 10 1016 j earscirev 2022 104085 S2CID 249616013 Retrieved 8 November 2022 Gess R W 2013 The earliest record of terrestrial animals in Gondwana A scorpion from the Famennian Late Devonian Witpoort Formation of South Africa African Invertebrates 54 2 373 379 doi 10 5733 afin 054 0206 a b Becker R T Marshall J E A Da Silva A C Agterberg F P Gradstein F M Ogg J G 1 January 2020 Gradstein Felix M Ogg James G Schmitz Mark D Ogg Gabi M eds Chapter 22 The Devonian Period Geologic Time Scale 2020 Elsevier pp 733 810 doi 10 1016 b978 0 12 824360 2 00022 x ISBN 978 0 12 824360 2 S2CID 241766371 retrieved 19 March 2021 Raup D M Sepkoski J J 19 March 1982 Mass Extinctions in the Marine Fossil Record Science 215 4539 1501 1503 Bibcode 1982Sci 215 1501R doi 10 1126 science 215 4539 1501 ISSN 0036 8075 PMID 17788674 S2CID 43002817 McGhee George R 1996 The Late Devonian mass extinction the Frasnian Famennian crisis New York Columbia University Press ISBN 0 231 07504 9 OCLC 33010274 After a Mass Extinction Only the Small Survive Carl Zimmer McGhee George R 2013 When the invasion of land failed The legacy of the Devonian extinctions New York Columbia University Press ISBN 9780231160568 Carmichael Sarah K Waters Johnny A Konigshof Peter Suttner Thomas J Kido Erika 1 December 2019 Paleogeography and paleoenvironments of the Late Devonian Kellwasser event A review of its sedimentological and geochemical expression Global and Planetary Change 183 102984 Bibcode 2019GPC 18302984C doi 10 1016 j gloplacha 2019 102984 ISSN 0921 8181 S2CID 198415606 Lu Man Lu YueHan Ikejiri Takehitio Sun Dayang Carroll Richard Blair Elliot H Algeo Thomas J Sun Yongge 15 May 2021 Periodic oceanic euxinia and terrestrial fluxes linked to astronomical forcing during the Late Devonian Frasnian Famennian mass extinction Earth and Planetary Science Letters 562 116839 Bibcode 2021E amp PSL 56216839L doi 10 1016 j epsl 2021 116839 ISSN 0012 821X S2CID 233578058 Kaiser Sandra Isabella Aretz Markus Becker Ralph Thomas 11 November 2015 The global Hangenberg Crisis Devonian Carboniferous transition review of a first order mass extinction Geological Society London Special Publications 423 1 387 437 doi 10 1144 sp423 9 ISSN 0305 8719 S2CID 131270834 Racki Grzegorz 1 January 2005 Over D J Morrow J R Wignall P B eds Chapter 2Toward understanding Late Devonian global events few answers many questions Developments in Palaeontology and Stratigraphy Understanding Late Devonian And Permian Triassic Biotic and Climatic Events Elsevier vol 20 pp 5 36 doi 10 1016 s0920 5446 05 80002 0 ISBN 9780444521279 retrieved 19 March 2021 Rendall Tapanila 2020 Impact resilience Ecological recovery of a carbonate factory in the wake of the Late Devonian impact event PALAIOS 35 1 12 21 Bibcode 2020Palai 35 12R doi 10 2110 palo 2019 001 S2CID 210944155 External links Edit Wikisource has original works on the topic Paleozoic Devonian Wikimedia Commons has media related to Devonian Devonian Devonian Times Archived from the original on 11 February 2010 Devonian life UC Berkeley site introduces the Devonian Geologic Time Scale International Commission on Stratigraphy ICS 2004 Retrieved 19 September 2005 Examples of Devonian Fossils Devonian chronostratigraphy scale Devonian Palaeos Archived from the original on 28 October 2007 Museum Age of Fishes Retrieved from https en wikipedia org w index php title Devonian amp oldid 1136170746, wikipedia, wiki, book, books, library,

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