fbpx
Wikipedia

Paleocene

February 16, 2024

Not to be confused with Paleogene.

The Paleocene (IPA: /ˈpæli.əsn, -i.-, ˈpli-/ PAL-ee-ə-seen, -⁠ee-oh-, PAY-lee-),[4] or Palaeocene, is a geological epoch that lasted from about 66 to 56 million years ago (mya). It is the first epoch of the Paleogene Period in the modern Cenozoic Era. The name is a combination of the Ancient Greek παλαιός palaiós meaning "old" and the Eocene Epoch (which succeeds the Paleocene), translating to "the old part of the Eocene".

Paleocene
66.0 – 56.0 Ma
Chronology
Etymology
Name formalityFormal
Name ratified1978
Alternate spelling(s)Palaeocene
Usage information
Regional usageGlobal (ICS)
Time scale(s) usedICS Time Scale
Definition
Chronological unitEpoch
Stratigraphic unitSeries
First proposed byWilhelm Philipp Schimper, 1874
Time span formalityFormal
Lower boundary definitionIridium enriched layer associated with a major meteorite impact and subsequent K–Pg extinction event[2]
Lower boundary GSSPEl Kef Section, El Kef, Tunisia
36°09′13″N 8°38′55″E / 36.1537°N 8.6486°E / 36.1537; 8.6486[2]
Lower GSSP ratified1991[2]
Upper boundary definitionStrong negative anomaly in δ13C values at the PETM[3]
Upper boundary GSSPDababiya section, Luxor, Egypt[3]
25°30′00″N 32°31′52″E / 25.5000°N 32.5311°E / 25.5000; 32.5311
Upper GSSP ratified2003[3]

The epoch is bracketed by two major events in Earth's history. The K–Pg extinction event, brought on by an asteroid impact (Chicxulub impact) and possibly volcanism (Deccan Traps), marked the beginning of the Paleocene and killed off 75% of species, most famously the non-avian dinosaurs. The end of the epoch was marked by the Paleocene–Eocene Thermal Maximum (PETM), which was a major climatic event wherein about 2,500–4,500 gigatons of carbon were released into the atmosphere and ocean systems, causing a spike in global temperatures and ocean acidification.

In the Paleocene, the continents of the Northern Hemisphere were still connected via some land bridges; and South America, Antarctica, and Australia had not completely separated yet. The Rocky Mountains were being uplifted, the Americas had not yet joined, the Indian Plate had begun its collision with Asia, and the North Atlantic Igneous Province was forming in the third-largest magmatic event of the last 150 million years. In the oceans, the thermohaline circulation probably was much different from what it is today, with downwellings occurring in the North Pacific rather than the North Atlantic, and water density mainly being controlled by salinity rather than temperature.

The K–Pg extinction event caused a floral and faunal turnover of species, with previously abundant species being replaced by previously uncommon ones. In the Paleocene, with a global average temperature of about 24–25 °C (75–77 °F), compared to 14 °C (57 °F) in more recent times, the Earth had a greenhouse climate without permanent ice sheets at the poles, like the preceding Mesozoic. As such, there were forests worldwide—including at the poles—but they had low species richness in regards to plant life, and were populated by mainly small creatures that were rapidly evolving to take advantage of the recently emptied Earth. Though some animals attained great size, most remained rather small. The forests grew quite dense in the general absence of large herbivores. Mammals proliferated in the Paleocene, and the earliest placental and marsupial mammals are recorded from this time, but most Paleocene taxa have ambiguous affinities. In the seas, ray-finned fish rose to dominate open ocean and recovering reef ecosystems.

Etymology edit

 
Portrait of Wilhelm Philipp Schimper who coined the term "Paleocene"

The word "Paleocene" was first used by French paleobotanist and geologist Wilhelm Philipp Schimper in 1874 while describing deposits near Paris (spelled "Paléocène" in his treatise).[5][6] By this time, Italian geologist Giovanni Arduino had divided the history of life on Earth into the Primary (Paleozoic), Secondary (Mesozoic), and Tertiary in 1759; French geologist Jules Desnoyers had proposed splitting off the Quaternary from the Tertiary in 1829;[7] and Scottish geologist Charles Lyell (ignoring the Quaternary) had divided the Tertiary Epoch into the Eocene, Miocene, Pliocene, and New Pliocene (Holocene) Periods in 1833.[8][n 1] British geologist John Phillips had proposed the Cenozoic in 1840 in place of the Tertiary,[9] and Austrian paleontologist Moritz Hörnes had introduced the Paleogene for the Eocene and Neogene for the Miocene and Pliocene in 1853.[10] After decades of inconsistent usage, the newly formed International Commission on Stratigraphy (ICS), in 1969, standardized stratigraphy based on the prevailing opinions in Europe: the Cenozoic Era subdivided into the Tertiary and Quaternary sub-eras, and the Tertiary subdivided into the Paleogene and Neogene Periods.[11] In 1978, the Paleogene was officially defined as the Paleocene, Eocene, and Oligocene Epochs; and the Neogene as the Miocene and Pliocene Epochs.[12] In 1989, Tertiary and Quaternary were removed from the time scale due to the arbitrary nature of their boundary, but Quaternary was reinstated in 2009.[13]

The term "Paleocene" is a portmanteau combination of the Ancient Greek palaios παλαιός meaning "old", and the word "Eocene", and so means "the old part of the Eocene". The Eocene, in turn, is derived from Ancient Greek eo—eos ἠώς meaning "dawn", and—cene kainos καινός meaning "new" or "recent", as the epoch saw the dawn of recent, or modern, life. Paleocene did not come into broad usage until around 1920. In North America and mainland Europe, the standard spelling is "Paleocene", whereas it is "Palaeocene" in the UK. Geologist T. C. R. Pulvertaft has argued that the latter spelling is incorrect because this would imply either a translation of "old recent" or a derivation from "pala" and "Eocene", which would be incorrect because the prefix palæo- uses the ligature æ instead of "a" and "e" individually, so only both characters or neither should be dropped, not just one.[6]

Geology edit

Boundaries edit

 
K–Pg boundary recorded in a Wyoming rock (the white stripe in the middle)

The Paleocene Epoch is the 10 million year time interval directly after the K–Pg extinction event, which ended the Cretaceous Period and the Mesozoic Era, and initiated the Cenozoic Era and the Paleogene Period. It is divided into three ages: the Danian spanning 66 to 61.6 million years ago (mya), the Selandian spanning 61.6 to 59.2 mya, and the Thanetian spanning 59.2 to 56 mya. It is succeeded by the Eocene.[14]

The K–Pg boundary is clearly defined in the fossil record in numerous places around the world by a high-iridium band, as well as discontinuities with fossil flora and fauna. It is generally thought that a 10 to 15 km (6 to 9 mi) wide asteroid impact, forming the Chicxulub Crater in the Yucatán Peninsula in the Gulf of Mexico, and Deccan Trap volcanism caused a cataclysmic event at the boundary resulting in the extinction of 75% of all species.[15][16][17][18]

The Paleocene ended with the Paleocene–Eocene thermal maximum, a short period of intense warming and ocean acidification brought about by the release of carbon en masse into the atmosphere and ocean systems,[19] which led to a mass extinction of 30–50% of benthic foraminifera–planktonic species which are used as bioindicators of the health of a marine ecosystem—one of the largest in the Cenozoic.[20][21] This event happened around 55.8 mya, and was one of the most significant periods of global change during the Cenozoic.[19][22][23]

Stratigraphy edit

Geologists divide the rocks of the Paleocene into a stratigraphic set of smaller rock units called stages, each formed during corresponding time intervals called ages. Stages can be defined globally or regionally. For global stratigraphic correlation, the ICS ratify global stages based on a Global Boundary Stratotype Section and Point (GSSP) from a single formation (a stratotype) identifying the lower boundary of the stage. In 1989, the ICS decided to split the Paleocene into three stages: the Danian, Selandian, and Thanetian.[24]

The Danian was first defined in 1847 by German-Swiss geologist Pierre Jean Édouard Desor based on the Danish chalks at Stevns Klint and Faxse, and was part of the Cretaceous, succeeded by the Tertiary Montian Stage.[25][26] In 1982, after it was shown that the Danian and the Montian are the same, the ICS decided to define the Danian as starting with the K–Pg boundary, thus ending the practice of including the Danian in the Cretaceous. In 1991, the GSSP was defined as a well-preserved section in the El Haria Formation near El Kef, Tunisia, 36°09′13″N 8°38′55″E / 36.1537°N 8.6486°E / 36.1537; 8.6486, and the proposal was officially published in 2006.[27]

 
The sea cliffs of Itzurun beach near the town of Zumaia, Spain, the GSSP for the Selandian and Thanetian

The Selandian and Thanetian are both defined in Itzurun beach by the Basque town of Zumaia, 43°18′02″N 2°15′34″W / 43.3006°N 2.2594°W / 43.3006; -2.2594, as the area is a continuous early Santonian to early Eocene sea cliff outcrop. The Paleocene section is an essentially complete, exposed record 165 m (541 ft) thick, mainly composed of alternating hemipelagic sediments deposited at a depth of about 1,000 m (3,300 ft). The Danian deposits are sequestered into the Aitzgorri Limestone Formation, and the Selandian and early Thanetian into the Itzurun Formation. The Itzurun Formation is divided into groups A and B corresponding to the two stages respectively. The two stages were ratified in 2008, and this area was chosen because of its completion, low risk of erosion, proximity to the original areas the stages were defined, accessibility, and the protected status of the area due to its geological significance.[24]

The Selandian was first proposed by Danish geologist Alfred Rosenkrantz in 1924 based on a section of fossil-rich glauconitic marls overlain by gray clay which unconformably overlies Danian chalk and limestone. The area is now subdivided into the Æbelø Formation, Holmehus Formation, and the Østerrende Clay. The beginning of this stage was defined by the end of carbonate rock deposition from an open ocean environment in the North Sea region (which had been going on for the previous 40 million years). The Selandian deposits in this area are directly overlain by the Eocene Fur Formation—the Thanetian was not represented here—and this discontinuity in the deposition record is why the GSSP was moved to Zumaia. Today, the beginning of the Selandian is marked by the appearances of the nannofossils Fasciculithus tympaniformis, Neochiastozygus perfectus, and Chiasmolithus edentulus, though some foraminifera are used by various authors.[24]

The Thanetian was first proposed by Swiss geologist Eugène Renevier, in 1873; he included the south England Thanet, Woolwich, and Reading formations. In 1880, French geologist Gustave Frédéric Dollfus narrowed the definition to just the Thanet Formation. The Thanetian begins a little after the mid-Paleocene biotic event[24]—a short-lived climatic event caused by an increase in methane[28]—recorded at Itzurun as a dark 1 m (3.3 ft) interval from a reduction of calcium carbonate. At Itzurun, it begins about 29 m (95 ft) above the base of the Selandian, and is marked by the first appearance of the algae Discoaster and a diversification of Heliolithus, though the best correlation is in terms of paleomagnetism. A chron is the occurrence of a geomagnetic reversal—when the North and South poles switch polarities. Chron 1 (C1n) is defined as modern day to about 780,000 years ago, and the n denotes "normal" as in the polarity of today, and an r "reverse" for the opposite polarity.[29] The beginning of the Thanetian is best correlated with the C26r/C26n reversal.[24]

Mineral and hydrocarbon deposits edit

 
Paleocene coal is extracted at the Cerrejón mine, the world's largest open-pit mine

Several economically important coal deposits formed during the Paleocene, such as the sub-bituminous Fort Union Formation in the Powder River Basin of Wyoming and Montana,[30] which produces 43% of American coal;[31] the Wilcox Group in Texas, the richest deposits of the Gulf Coastal Plain;[32] and the Cerrejón mine in Colombia, the largest open-pit mine in the world.[33] Paleocene coal has been mined extensively in Svalbard, Norway, since near the beginning of the 20th century,[34] and late Paleocene and early Eocene coal is widely distributed across the Canadian Arctic Archipelago[35] and northern Siberia.[36] In the North Sea, Paleocene-derived natural gas reserves, when they were discovered, totaled approximately 2.23 trillion m3 (7.89 trillion ft3), and oil in place 13.54 billion barrels.[37] Important phosphate deposits—predominantly of francolite—near Métlaoui, Tunisia were formed from the late Paleocene to the early Eocene.[38]

Impact craters edit

 
The crater underneath the Greenlandic Hiawatha Glacier dates to the Paleocene, 58 mya.[39]

Impact craters formed in the Paleocene include: the Connolly Basin crater in Western Australia less than 60 mya,[40] the Texan Marquez crater 58 mya,[41] the Greenlandic Hiawatha Glacier crater 58 mya,[39] and possibly the Jordan Jabel Waqf as Suwwan crater which dates to between 56 and 37 mya.[42] Vanadium-rich osbornite from the Isle of Skye, Scotland, dating to 60 mya may be impact ejecta.[43] Craters were also formed near the K–Pg boundary, the largest the Mexican Chicxulub crater whose impact was a major precipitator of the K–Pg extinction,[44] and also the Ukrainian Boltysh crater, dated to 65.4 mya[45] the Canadian Eagle Butte crater (though it may be younger),[46] the Vista Alegre crater[47] (though this may date to about 115 mya[48]). Silicate glass spherules along the Atlantic coast of the U.S. indicate a meteor impact in the region at the PETM.[49]

Paleogeography edit

Paleotectonics edit

 
The Laramide orogeny was caused by the subduction of oceanic crust under the North American plate

During the Paleocene, the continents continued to drift toward their present positions.[50] In the Northern Hemisphere, the former components of Laurasia (North America and Eurasia) were, at times, connected via land bridges: Beringia (at 65.5 and 58 mya) between North America and East Asia, the De Geer route (from 71 to 63 mya) between Greenland and Scandinavia, the Thulean route (at 57 and 55.8 mya) between North America and Western Europe via Greenland, and the Turgai route connecting Europe with Asia (which were otherwise separated by the Turgai Strait at this time).[51][52]

The Laramide orogeny, which began in the Late Cretaceous, continued to uplift the Rocky Mountains; it ended at the end of the Paleocene.[53] Because of this and a drop in sea levels resulting from tectonic activity, the Western Interior Seaway, which had divided the continent of North America for much of the Cretaceous, had receded.[54]

Between about 60.5 and 54.5 mya, there was heightened volcanic activity in the North Atlantic region—the third largest magmatic event in the last 150 million years—creating the North Atlantic Igneous Province.[55][56] The proto-Iceland hotspot is sometimes cited as being responsible for the initial volcanism, though rifting and resulting volcanism have also contributed.[56][57][58] This volcanism may have contributed to the opening of the North Atlantic Ocean and seafloor spreading, the divergence of the Greenland Plate from the North American Plate,[59] and, climatically, the PETM by dissociating methane clathrate crystals on the seafloor resulting in the mass release of carbon.[55][60]

North and South America remained separated by the Central American Seaway, though an island arc (the South Central American Arc) had already formed about 73 mya. The Caribbean Large Igneous Province (now the Caribbean Plate), which had formed from the Galápagos hotspot in the Pacific in the latest Cretaceous, was moving eastward as the North American and South American plates were getting pushed in the opposite direction due to the opening of the Atlantic (strike-slip tectonics).[61][62] This motion would eventually uplift the Isthmus of Panama by 2.6 mya. The Caribbean Plate continued moving until about 50 mya when it reached its current position.[63]

 
The breakup of Gondwana:
A) Early Cretaceous
B) Late Cretaceous
C) Paleocene
D) Present

The components of the former southern supercontinent Gondwanaland in the Southern Hemisphere continued to drift apart, but Antarctica was still connected to South America and Australia. Africa was heading north towards Europe, and the Indian subcontinent towards Asia, which would eventually close the Tethys Ocean.[50] The Indian and Eurasian Plates began colliding in the Paleocene,[64] with uplift (and a land connection) beginning in the Miocene about 24–17 mya. There is evidence that some plants and animals could migrate between India and Asia during the Paleocene, possibly via intermediary island arcs.[65]

Paleoceanography edit

In the modern thermohaline circulation, warm tropical water becomes colder and saltier at the poles and sinks (downwelling or deep water formation) that occurs at the North Atlantic near the North Pole and the Southern Ocean near the Antarctic Peninsula. In the Paleocene, the waterways between the Arctic Ocean and the North Atlantic were somewhat restricted, so North Atlantic Deep Water (NADW) and the Atlantic Meridional Overturning Circulation (AMOC)—which circulates cold water from the Arctic towards the equator—had not yet formed, and so deep water formation probably did not occur in the North Atlantic. The Arctic and Atlantic would not be connected by sufficiently deep waters until the early to middle Eocene.[66]

There is evidence of deep water formation in the North Pacific to at least a depth of about 2,900 m (9,500 ft). The elevated global deep water temperatures in the Paleocene may have been too warm for thermohaline circulation to be predominately heat driven.[67][68] It is possible that the greenhouse climate shifted precipitation patterns, such that the Southern Hemisphere was wetter than the Northern, or the Southern experienced less evaporation than the Northern. In either case, this would have made the Northern more saline than the Southern, creating a density difference and a downwelling in the North Pacific traveling southward.[67] Deep water formation may have also occurred in the South Atlantic.[69]

It is largely unknown how global currents could have affected global temperature. The formation of the Northern Component Waters by Greenland in the Eocene—the predecessor of the AMOC—may have caused an intense warming in the North Hemisphere and cooling in the Southern, as well as an increase in deep water temperatures.[66] In the PETM, it is possible deep water formation occurred in saltier tropical waters and moved polewards, which would increase global surface temperatures by warming the poles.[21][68] Also, Antarctica was still connected to South America and Australia, and, because of this, the Antarctic Circumpolar Current—which traps cold water around the continent and prevents warm equatorial water from entering—had not yet formed. Its formation may have been related in the freezing of the continent.[70] Warm coastal upwellings at the poles would have inhibited permanent ice cover.[68] Conversely, it is possible deep water circulation was not a major contributor to the greenhouse climate, and deep water temperatures more likely change as a response to global temperature change rather than affecting it.[67][68]

In the Arctic, coastal upwelling may have been largely temperature and wind-driven. In summer, the land surface temperature was probably higher than oceanic temperature, and the opposite was true in the winter, which is consistent with monsoon seasons in Asia. Open-ocean upwelling may have also been possible.[68]

Climate edit

Average climate edit

 
 
Global average land (above) and deep sea (below) temperatures throughout the Cenozoic

The Paleocene climate was, much like in the Cretaceous, tropical or subtropical,[71][72][73] and the poles were temperate,[74] with an average global temperature of roughly 24–25 °C (75–77 °F).[75] For comparison, the average global temperature for the period between 1951 and 1980 was 14 °C (57 °F).[76] The latitudinal temperature gradient was approximately 0.24 °C per degree of latitude.[77] The poles also lacked ice caps,[78] though some alpine glaciation did occur in the Transantarctic Mountains.[79]

The poles probably had a cool temperate climate; northern Antarctica, Australia, the southern tip of South America, what is now the US and Canada, eastern Siberia, and Europe warm temperate; middle South America, southern and northern Africa, South India, Middle America, and China arid; and northern South America, central Africa, North India, middle Siberia, and what is now the Mediterranean Sea tropical.[80] South-central North America had a humid, monsoonal climate along its coastal plain, but conditions were drier to the west and at higher altitudes.[81]

Global deep water temperatures in the Paleocene likely ranged from 8–12 °C (46–54 °F),[67][68] compared to 0–3 °C (32–37 °F) in modern day.[82] Based on the upper limit, average sea surface temperatures (SSTs) at 60°N and S would have been the same as deep sea temperatures, at 30°N and S about 23 °C (73 °F), and at the equator about 28 °C (82 °F).[68] In the Danish Palaeocene sea, SSTs were cooler than those of the preceding Late Cretaceous and the succeeding Eocene.[83] The Paleocene foraminifera assemblage globally indicates a defined deep-water thermocline (a warmer mass of water closer to the surface sitting on top of a colder mass nearer the bottom) persisting throughout the epoch.[84] The Atlantic foraminifera indicate a general warming of sea surface temperature–with tropical taxa present in higher latitude areas–until the Late Paleocene when the thermocline became steeper and tropical foraminifera retreated back to lower latitudes.[85]

Early Paleocene atmospheric CO2 levels at what is now Castle Rock, Colorado, were calculated to be between 352 and 1,110 parts per million (ppm), with a median of 616 ppm. Based on this and estimated plant-gas exchange rates and global surface temperatures, the climate sensitivity was calculated to be +3 °C when CO2 levels doubled, compared to 7 °C following the formation of ice at the poles. CO2 levels alone may have been insufficient in maintaining the greenhouse climate, and some positive feedbacks must have been active, such as some combination of cloud, aerosol, or vegetation related processes.[86] A 2019 study identified changes in orbital eccentricity as the dominant drivers of climate between the late Cretaceous and the early Eocene.[87]

Climatic events edit

The effects of the meteor impact and volcanism 66 mya and the climate across the K–Pg boundary were likely fleeting, and climate reverted to normal in a short time frame.[88] The freezing temperatures probably reversed after three years[89] and returned to normal within decades,[90] sulfuric acid aerosols causing acid rain probably dissipated after 10 years,[91] and dust from the impact blocking out sunlight and inhibiting photosynthesis would have lasted up to a year[92] though potential global wildfires raging for several years would have released more particulates into the atmosphere.[93] For the following half million years, the carbon isotope gradient—a difference in the 13C/12C ratio between surface and deep ocean water, causing carbon to cycle into the deep sea—may have shut down. This, termed a "Strangelove ocean", indicates low oceanic productivity;[94] resultant decreased phytoplankton activity may have led to a reduction in cloud seeds and, thus, marine cloud brightening, causing global temperatures to increase by 6 °C (CLAW hypothesis).[95]

The Dan–C2 Event 65.2 mya in the early Danian spanned about 100,000 years, and was characterized by an increase in carbon, particularly in the deep sea. Since the mid-Maastrichtian, more and more carbon had been sequestered in the deep sea possibly due to a global cooling trend and increased circulation into the deep sea. The Dan–C2 event may represent a release of this carbon after deep sea temperatures rose to a certain threshold, as warmer water can dissolve a lesser amount of carbon.[96] Savanna may have temporarily displaced forestland in this interval.[97]

Following the extreme disruptions in the aftermath of the K-Pg extinction event, the relatively cool, though still greenhouse, conditions of the Late Cretaceous-Early Palaeogene Cool Interval (LKEPCI) that began in the Late Cretaceous continued.[98]

Around 62.2 mya in the late Danian, there was a warming event and evidence of ocean acidification associated with an increase in carbon;[99] at this time, there was major seafloor spreading in the Atlantic and volcanic activity along the southeast margin of Greenland. The Latest Danian Event, also known as the Top Chron C27n Event, lasted about 200,000 years and resulted in a 1.6–2.8 °C increase in temperatures throughout the water column. Though the temperature in the latest Danian varied at about the same magnitude, this event coincides with an increase of carbon.[100]

About 60.5 mya at the Danian/Selandian boundary, there is evidence of anoxia spreading out into coastal waters, and a drop in sea levels which is most likely explained as an increase in temperature and evaporation, as there was no ice at the poles to lock up water.[101]

During the mid-Palaeocene biotic event (MPBE), also known as the Early Late Palaeocene Event (ELPE),[102][103] around 59 Ma (roughly 50,000 years before the Selandian/Thanetian boundary), the temperature spiked probably due to a mass release of the deep sea methane hydrate into the atmosphere and ocean systems. Carbon was probably output for 10–11,000 years, and the aftereffects likely subsided around 52–53,000 years later.[104] There is also evidence this occurred again 300,000 years later in the early Thanetian dubbed MPBE-2. Respectively, about 83 and 132 gigatons of methane-derived carbon were ejected into the atmosphere, which suggests a 2–3 °C (3.6–5.4 °F) rise in temperature, and likely caused heightened seasonality and less stable environmental conditions. It may have also caused an increase of grass in some areas.[28]

From 59.7 to 58.1 Ma, during the late Selandian and early Thanetian, organic carbon burial resulted in a period of climatic cooling, sea level fall and transient ice growth. This interval saw the highest δ18O values of the epoch.[105]

Paleocene–Eocene Thermal Maximum edit

Main article: Paleocene–Eocene Thermal Maximum

The Paleocene–Eocene Thermal Maximum was an approximately 200,000-year-long event where the global average temperature rose by some 5 to 8 °C (9 to 14 °F),[55] and mid-latitude and polar areas may have exceeded modern tropical temperatures of 24–29 °C (75–84 °F).[106] This was due to an ejection of 2,500–4,500 gigatons of carbon into the atmosphere, most commonly explained as the perturbation and release of methane clathrate deposits in the North Atlantic from tectonic activity and resultant increase in bottom water temperatures.[55] Other proposed hypotheses include methane release from the heating of organic matter at the seafloor rather than methane clathrates,[107][108] or melting permafrost.[109] The duration of carbon output is controversial, but most likely about 2,500 years.[110] This carbon also interfered with the carbon cycle and caused ocean acidification,[111][112] and potentially altered[69] and slowed down ocean currents, the latter leading to the expansion of oxygen minimum zones (OMZs) in the deep sea.[113] In surface water, OMZs could have also been caused from the formation of strong thermoclines preventing oxygen inflow, and higher temperatures equated to higher productivity leading to higher oxygen usurpation.[114] Further, expanding OMZs could have caused the proliferation of sulfate-reducing microorganisms which create highly toxic hydrogen sulfide H2S as a waste product. During the event, the volume of sulfidic water may have been 10–20% of total ocean volume, in comparison to today's 1%. This may have also caused chemocline upwellings along continents and the dispersal of H2S into the atmosphere.[115] During the PETM there was a temporary dwarfing of mammals apparently caused by the upward excursion in temperature.[116]

Flora edit

 
Restoration of a Patagonian landscape during the Danian

The warm, wet climate supported tropical and subtropical forests worldwide, mainly populated by conifers and broad-leafed trees.[117][78] In Patagonia, the landscape supported tropical rainforests, cloud rainforests, mangrove forests, swamp forests, savannas, and sclerophyllous forests.[78] In the Colombian Cerrejón Formation, fossil flora belong to the same families as modern day flora—such as palm trees, legumes, aroids, and malvales[118]—and the same is true in the North Dakotan Almont/Beicegel Creek—such as Ochnaceae, Cyclocarya, and Ginkgo cranei[119]—indicating the same floral families have characterized South American rainforests and the American Western Interior since the Paleocene.[118][119]

 
Reconstruction of the late Paleocene Ginkgo cranei

The extinction of large herbivorous dinosaurs may have allowed the forests to grow quite dense,[74] and there is little evidence of wide open plains.[117] Plants evolved several techniques to cope with high plant density, such as buttressing to better absorb nutrients and compete with other plants, increased height to reach sunlight, larger diaspore in seeds to provide added nutrition on the dark forest floor, and epiphytism where a plant grows on another plant in response to less space on the forest floor.[117] Despite increasing density—which could act as fuel—wildfires decreased in frequency from the Cretaceous to the early Eocene as the atmospheric oxygen levels decreased to modern day levels, though they may have been more intense.[120]

Recovery edit

There was a major die-off of plant species over the boundary; for example, in the Williston Basin of North Dakota, an estimated 1/3 to 3/5 of plant species went extinct.[121] The K–Pg extinction event ushered in a floral turnover; for example, the once commonplace Araucariaceae conifers were almost fully replaced by Podocarpaceae conifers, and the Cheirolepidiaceae, a group of conifers that had dominated during most of the Mesozoic but had become rare during the Late Cretaceous became dominant trees in Patagonia, before going extinct.[122][117][123] Some plant communities, such as those in eastern North America, were already experiencing an extinction event in the late Maastrichtian, particularly in the 1 million years before the K–Pg extinction event.[124] The "disaster plants" that refilled the emptied landscape crowded out many Cretaceous plants, and resultantly, many went extinct by the middle Paleocene.[71]

 
The conifer Glyptostrobus europaeus from the Canadian Paskapoo Formation

The strata immediately overlaying the K–Pg extinction event are especially rich in fern fossils. Ferns are often the first species to colonize areas damaged by forest fires, so this "fern spike" may mark the recovery of the biosphere following the impact (which caused blazing fires worldwide).[125][126] The diversifying herb flora of the early Paleocene either represent pioneer species which re-colonized the recently emptied landscape, or a response to the increased amount of shade provided in a forested landscape.[124] Lycopods, ferns, and angiosperm shrubs may have been important components of the Paleocene understory.[117]

In general, the forests of the Paleocene were species-poor, and diversity did not fully recover until the end of the Paleocene.[71][127] For example, the floral diversity of what is now the Holarctic region (comprising most of the Northern Hemisphere) was mainly early members of Ginkgo, Metasequoia, Glyptostrobus, Macginitiea, Platanus, Carya, Ampelopsis, and Cercidiphyllum.[117] Patterns in plant recovery varied significantly with latitude, climate, and altitude. For example, what is now Castle Rock, Colorado featured a rich rainforest only 1.4 million years after the event, probably due to a rain shadow effect causing regular monsoon seasons.[127] Conversely, low plant diversity and a lack of specialization in insects in the Colombian Cerrejón Formation, dated to 58 mya, indicates the ecosystem was still recovering from the K–Pg extinction event 7 million years later.[118]

Angiosperms edit

 
Fossil Platanus fruit from the Canadian Paskapoo Formation

Flowering plants (angiosperms), which had become dominant among forest taxa by the middle Cretaceous 110–90 mya,[128] continued to develop and proliferate, more so to take advantage of the recently emptied niches and an increase in rainfall.[124] Along with them coevolved the insects that fed on these plants and pollinated them. Predation by insects was especially high during the PETM.[129] Many fruit-bearing plants appeared in the Paleocene in particular, probably to take advantage of the newly evolving birds and mammals for seed dispersal.[130]

In what is now the Gulf Coast, angiosperm diversity increased slowly in the early Paleocene, and more rapidly in the middle and late Paleocene. This may have been because the effects of the K–Pg extinction event were still to some extent felt in the early Paleocene, the early Paleocene may not have had as many open niches, early angiosperms may not have been able to evolve at such an accelerated rate as later angiosperms, low diversity equates to lower evolution rates, or there was not much angiosperm migration into the region in the early Paleocene.[124] Over the K–Pg extinction event, angiosperms had a higher extinction rate than gymnosperms (which include conifers, cycads, and relatives) and pteridophytes (ferns, horsetails, and relatives); zoophilous angiosperms (those that relied on animals for pollination) had a higher rate than anemophilous angiosperms; and evergreen angiosperms had a higher rate than deciduous angiosperms as deciduous plants can become dormant in harsh conditions.[124]

In the Gulf Coast, angiosperms experienced another extinction event during the PETM, which they recovered quickly from in the Eocene through immigration from the Caribbean and Europe. During this time, the climate became warmer and wetter, and it is possible that angiosperms evolved to become stenotopic by this time, able to inhabit a narrow range of temperature and moisture; or, since the dominant floral ecosystem was a highly integrated and complex closed-canopy rainforest by the middle Paleocene, the plant ecosystems were more vulnerable to climate change.[124] There is some evidence that, in the Gulf Coast, there was an extinction event in the late Paleocene preceding the PETM, which may have been due to the aforementioned vulnerability of complex rainforests, and the ecosystem may have been disrupted by only a small change in climate.[131]

Polar forests edit

 
Metasequoia occidentalis from the Canadian Scollard Formation

The warm Paleocene climate, much like that of the Cretaceous, allowed for diverse polar forests. Whereas precipitation is a major factor in plant diversity nearer the equator, polar plants had to adapt to varying light availability (polar nights and midnight suns) and temperatures. Because of this, plants from both poles independently evolved some similar characteristics, such as broad leaves. Plant diversity at both poles increased throughout the Paleocene, especially at the end, in tandem with the increasing global temperature.[132]

At the North Pole, woody angiosperms had become the dominant plants, a reversal from the Cretaceous where herbs proliferated. The Iceberg Bay Formation on Ellesmere Island, Nunavut (latitude 7580° N) shows remains of a late Paleocene dawn redwood forest, the canopy reaching around 32 m (105 ft), and a climate similar to the Pacific Northwest.[74] On the Alaska North Slope, Metasequoia was the dominant conifer. Much of the diversity represented migrants from nearer the equator. Deciduousness was dominant, probably to conserve energy by retroactively shedding leaves and retaining some energy rather than having them die from frostbite.[132]

At the South Pole, due to the increasing isolation of Antarctica, many plant taxa were endemic to the continent instead of migrating down. Patagonian flora may have originated in Antarctica.[132][133] The climate was much cooler than in the Late Cretaceous, though frost probably was not common in at least coastal areas. East Antarctica was likely warm and humid. Because of this, evergreen forests could proliferate as, in the absence of frost and a low probability of leaves dying, it was more energy efficient to retain leaves than to regrow them every year. One possibility is that the interior of the continent favored deciduous trees, though prevailing continental climates may have produced winters warm enough to support evergreen forests. As in the Cretaceous, podocarpaceous conifers, Nothofagus, and Proteaceae angiosperms were common.[132]

Fauna edit

In the K–Pg extinction event, every land animal over 25 kg (55 lb) was wiped out, leaving open several niches at the beginning of the epoch.[134]

Mammals edit

 
Restoration of the herbivorous late Paleocene pantodont Barylambda, which could have weighed up to 650 kg (1,430 lb)[135]

Mammals had first appeared in the Late Triassic, and remained small and nocturnal throughout the Mesozoic to avoid competition with dinosaurs (nocturnal bottleneck),[136] though, by the Middle Jurassic, they had branched out into several habitats—such as subterranean, arboreal, and aquatic—[137] and the largest known Mesozoic mammal, Repenomamus robustus reached about 1 m (3 ft 3 in) in length and 12–14 kg (26–31 lb) in weight–comparable to the modern day Virginia opossum.[138] Though some mammals could sporadically venture out in daytime (cathemerality) by roughly 10 million years before the K–Pg extinction event, they only became strictly diurnal (active in the daytime) sometime after.[136]

In general, Paleocene mammals retained this small size until near the end of the epoch, and, consequently, early mammal bones are not well preserved in the fossil record, and most of what is known comes from fossil teeth.[50] Multituberculates, a now-extinct rodent-like group not closely related to any modern mammal, were the most successful group of mammals in the Mesozoic, and they reached peak diversity in the early Paleocene. During this time, multituberculate taxa had a wide range of dental complexity, which correlates to a broader range in diet for the group as a whole. Multituberculates declined in the late Paleocene and went extinct at the end of the Eocene, possibly due to competition from newly evolving rodents.[139]

 
The mesonychid Sinonyx at the Museo delle Scienze

Nonetheless, following the K–Pg extinction event, mammals very quickly diversified and filled the empty niches.[140][141] Modern mammals are subdivided into therians (modern members are placentals and marsupials) and monotremes. These three groups all originated in the Cretaceous.[142] Paleocene marsupials include Peradectes,[143] and monotremes Monotrematum.[144][145] The epoch featured the rise of many crown placental groups—groups that have living members in modern day—such as the earliest afrotherian Ocepeia, xenarthran Utaetus, rodent Tribosphenomys and Paramys, the forerunners of primates the Plesiadapiformes, earliest carnivorans Ravenictis and Pristinictis, possible pangolins Palaeanodonta, possible forerunners of odd-toed ungulates Phenacodontidae, and eulipotyphlans Nyctitheriidae.[146] Though therian mammals had probably already begun to diversify around 10 to 20 million years before the K–Pg extinction event, average mammal size increased greatly after the boundary, and a radiation into frugivory (fruit-eating) and omnivory began, namely with the newly evolving large herbivores such as the Taeniodonta, Tillodonta, Pantodonta, Polydolopimorphia, and the Dinocerata.[147][148] Large carnivores include the wolf-like Mesonychia, such as Ankalagon[149] and Sinonyx.[150]

Though there was an explosive diversification, the affinities of most Paleocene mammals are unknown, and only primates, carnivorans, and rodents have unambiguous Paleocene origins, resulting in a 10 million year gap in the fossil record of other mammalian crown orders. The most species-rich order of Paleocene mammals is Condylarthra, which is a wastebasket taxon for miscellaneous bunodont hoofed mammals. Other ambiguous orders include the Leptictida, Cimolesta, and Creodonta. This uncertainty blurs the early evolution of placentals.[146]

Birds edit

 
Gastornis restoration

According to DNA studies, modern birds (Neornithes) rapidly diversified following the extinction of the other dinosaurs in the Paleocene, and nearly all modern bird lineages can trace their origins to this epoch with the exception of fowl. This was one of the fastest diversifications of any group,[151] probably fueled by the diversification of fruit-bearing trees and associated insects, and the modern bird groups had likely already diverged within four million years of the K–Pg extinction event. However, the fossil record of birds in the Paleocene is rather poor compared to other groups, limited globally to mainly waterbirds such as the early penguin Waimanu. The earliest arboreal crown group bird known is Tsidiiyazhi, a mousebird dating to around 62 mya.[152] The fossil record also includes early owls such as the large Berruornis from France,[153] and the smaller Ogygoptynx from the United States.[154]

Almost all archaic birds (any bird outside Neornithes) went extinct during the K–Pg extinction event, although the archaic Qinornis is recorded in the Paleocene.[152] Their extinction may have led to the proliferation of neornithine birds in the Paleocene, and the only known Cretaceous neornithine bird is the waterbird Vegavis, and possibly also the waterbird Teviornis.[155]

In the Mesozoic, birds and pterosaurs exhibited size-related niche partitioning—no known Late Cretaceous flying bird had a wingspan greater than 2 m (6 ft 7 in) nor exceeded a weight of 5 kg (11 lb), whereas contemporary pterosaurs ranged from 2–10 m (6 ft 7 in – 32 ft 10 in), probably to avoid competition. Their extinction allowed flying birds to attain greater size, such as pelagornithids and pelecaniformes.[156] The Paleocene pelagornithid Protodontopteryx was quite small compared to later members, with a wingspan of about 1 m (3.3 ft), comparable to a gull.[157] On the archipelago-continent of Europe, the flightless bird Gastornis was the largest herbivore at 2 m (6 ft 7 in) tall for the largest species, possibly due to lack of competition from newly emerging large mammalian herbivores which were prevalent on the other continents.[134][158] The carnivorous terror birds in South America have a contentious appearance in the Paleocene with Paleopsilopterus, though the first definitive appearance is in the Eocene.[159]

Reptiles edit

 
Borealosuchus at the Field Museum of Natural History

It is generally believed all non-avian dinosaurs went extinct at the K–Pg extinction event 66 mya, though there are a couple of controversial claims of Paleocene dinosaurs which would indicate a gradual decline of dinosaurs. Contentious dates include remains from the Hell Creek Formation dated 40,000 years after the boundary,[160] and a hadrosaur femur from the San Juan Basin dated to 64.5 mya,[161] but such stray late forms may be zombie taxa that were washed out and moved to younger sediments.[162]

In the wake of the K–Pg extinction event, 83% of lizard and snake (squamate) species went extinct, and the diversity did not fully recover until the end of the Paleocene. However, since the only major squamate lineages to disappear in the event were the mosasaurs and polyglyphanodontians (the latter making up 40% of Maastrichtian lizard diversity), and most major squamate groups had evolved by the Cretaceous, the event probably did not greatly affect squamate evolution, and newly evolving squamates did not seemingly branch out into new niches as mammals. That is, Cretaceous and Paleogene squamates filled the same niches. Nonetheless, there was a faunal turnover of squamates, and groups that were dominant by the Eocene were not as abundant in the Cretaceous, namely the anguids, iguanas, night lizards, pythons, colubrids, boas, and worm lizards. Only small squamates are known from the early Paleocene—the largest snake Helagras was 950 mm (37 in) in length[163]—but the late Paleocene snake Titanoboa grew to over 13 m (43 ft) long, the longest snake ever recorded.[164] Kawasphenodon peligrensis from the early Paleocene of South America represents the youngest record of Rhynchocephalia outside of New Zealand, where the only extant representative of the order, the tuatara, resides.[165]

Freshwater crocodilians and choristoderans were among the aquatic reptiles to have survived the K–Pg extinction event, probably because freshwater environments were not as impacted as marine ones.[166] One example of a Paleocene crocodile is Borealosuchus, which averaged 3.7 m (12 ft) in length at the Wannagan Creek site.[167] Among crocodyliformes, the aquatic and terrestrial dyrosaurs and the fully terrestrial sebecids would also survive the K-Pg extinction event, and a late surviving member of Pholidosauridae is also known from the Danian of Morocco.[168] Three choristoderans are known from the Paleocene: The gharial-like neochoristoderans Champsosaurus—the largest is the Paleocene C. gigas at 3 m (9.8 ft), Simoedosaurus—the largest specimen measuring 5 m (16 ft), and an indeterminate species of the lizard like non-neochoristoderan Lazarussuchus around 44 centimetres in length.[169] The last known choristoderes, belonging to the genus Lazarussuchus, are known from the Miocene.[170]

Turtles experienced a decline in the Campanian (Late Cretaceous) during a cooling event, and recovered during the PETM at the end of the Paleocene.[171] Turtles were not greatly affected by the K–Pg extinction event, and around 80% of species survived.[172] In Colombia, a 60 million year old turtle with a 1.7 m (5 ft 7 in) carapace, Carbonemys, was discovered.[173]

Amphibians edit

There is little evidence amphibians were affected very much by the K–Pg extinction event, probably because the freshwater habitats they inhabited were not as greatly impacted as marine environments.[174] In the Hell Creek Formation of eastern Montana, a 1990 study found no extinction in amphibian species across the boundary.[175] The true toads evolved during the Paleocene.[176] The final record of albanerpetontids from North America and outside of Europe and Anatolia, an unnamed species of Albanerpeton, is known from the Paleocene aged Paskapoo Formation in Canada.[177]

Fish edit

 
The early Paleocene trumpetfish Eekaulostomus from Palenque, Mexico

The small pelagic fish population recovered rather quickly, and there was a low extinction rate for sharks and rays. Overall, only 12% of fish species went extinct.[178] During the Cretaceous, fishes were not very abundant, probably due to heightened predation by or competition with ammonites and squid, although large predatory fish did exist, including ichthyodectids, pachycormids and pachyrhizodontids.[179] Almost immediately following the K–Pg extinction event, ray-finned fish — today, representing nearly half of all vertebrate taxa – became much more numerous and increased in size, and rose to dominate the open-oceans. Acanthomorphs—a group of ray-finned fish which, today, represent a third of all vertebrate life—experienced a massive diversification following the K–Pg extinction event, dominating marine ecosystems by the end of the Paleocene, refilling vacant, open-ocean predatory niches as well as spreading out into recovering reef systems. In specific, percomorphs diversified faster than any other vertebrate group at the time, with the exception of birds; Cretaceous percomorphs varied very little in body plan, whereas, by the Eocene, percomorphs evolved into vastly varying creatures[180] such as early scombrids (today, tuna, mackerels, and bonitos),[179] barracudas,[181] jacks,[180] billfish,[182] flatfishes,[183] and aulostomoid (trumpetfish and cornetfish).[184][180][185] However, the discovery of the Cretaceous cusk eel Pastorius shows that the body plans of at least some percomorphs were already highly variable, perhaps indicating an already diverse array of percomorph body plans before the Paleocene.[186]

 
Otodus obliquus shark tooth from Oued Zem, Morocco

Conversely, sharks and rays appear to have been unable to exploit the vacant niches, and recovered the same pre-extinction abundance.[178][187] There was a faunal turnover of sharks from mackerel sharks to ground sharks, as ground sharks are more suited to hunting the rapidly diversifying ray-finned fish whereas mackerel sharks target larger prey.[188] The first megatoothed shark, Otodus obliquus—the ancestor of the giant megalodon—is recorded from the Paleocene.[189]

Several Paleocene freshwater fish are recorded from North America, including bowfins, gars, arowanas, Gonorynchidae, common catfish, smelts, and pike.[190]

Insects and arachnids edit

 
Earwig from the late Paleocene Danish Fur Formation

Insect recovery varied from place to place. For example, it may have taken until the PETM for insect diversity to recover in the western interior of North America, whereas Patagonian insect diversity had recovered by four million years after the K–Pg extinction event. In some areas, such as the Bighorn Basin in Wyoming, there is a dramatic increase in plant predation during the PETM, although this is probably not indicative of a diversification event in insects due to rising temperatures because plant predation decreases following the PETM. More likely, insects followed their host plant or plants which were expanding into mid-latitude regions during the PETM, and then retreated afterward.[129][191]

The middle-to-late Paleocene French Menat Formation shows an abundance of beetles (making up 77.5% of the insect diversity)—especially weevils (50% of diversity), jewel beetles, leaf beetles, and reticulated beetles—as well as other true bugs—such as pond skaters—and cockroaches. To a lesser degree, there are also orthopterans, hymenopterans, butterflies, and flies, though planthoppers were more common than flies. Representing less than 1% of fossil remains dragonflies, caddisflies, mayflies, earwigs, mantises, net-winged insects, and possibly termites.[192]

The Wyoming Hanna Formation is the only known Paleocene formation to produce sizable pieces of amber, as opposed to only small droplets. The amber was formed by a single or a closely related group of either taxodiaceaen or pine tree(s) which produced cones similar to those of dammaras. Only one insect, a thrips, has been identified.[193]

 
The ant Napakimyrma paskapooensis from the Canadian Paskapoo Formation

There is a gap in the ant fossil record from 78 to 55 mya, except for the aneuretine Napakimyrma paskapooensis from the 62–56 million year old Canadian Paskapoo Formation.[194] Given high abundance in the Eocene, two of the modern dominant ant subfamilies—Ponerinae and Myrmicinae—likely originated and greatly diversified in the Paleocene, acting as major hunters of arthropods, and probably competed with each other for food and nesting grounds in the dense angiosperm leaf litter. Myrmicines expanded their diets to seeds and formed trophobiotic symbiotic relationships with aphids, mealybugs, treehoppers, and other honeydew secreting insects which were also successful in angiosperm forests, allowing them to invade other biomes, such as the canopy or temperate environments, and achieve a worldwide distribution by the middle Eocene.[195]

About 80% of the butterfly and moth (lepidopteran) fossil record occurs in the early Paleogene, specifically the late Paleocene and the middle-to-late Eocene. Most Paleocene lepidopteran compression fossils come from the Danish Fur Formation. Though there is low family-level diversity in the Paleocene compared to later epochs, this may be due to a largely incomplete fossil record.[196] The evolution of bats had a profound effect on lepidopterans, which feature several anti-predator adaptations such as echolocation jamming and the ability to detect bat signals.[197]

Bees were likely heavily impacted by the K–Pg extinction event and a die-off of flowering plants, though the bee fossil record is very limited.[198] The oldest kleptoparasitic bee, Paleoepeolus, is known from the Paleocene 60 mya.[199]

Though the Eocene features, by far, the highest proportion of known fossil spider species, the Paleocene spider assemblage is quite low.[200] Some spider groups began to diversify around the PETM, such as jumping spiders,[201] and possibly coelotine spiders (members of the funnel weaver family).[202]

The diversification of mammals had a profound effect on parasitic insects, namely the evolution of bats, which have more ectoparasites than any other known mammal or bird. The PETM's effect on mammals greatly impacted the evolution of fleas, ticks, and oestroids.[203]

Marine invertebrates edit

Among marine invertebrates, plankton and those with a planktonic stage in their development (meroplankton) were most impacted by the K–Pg extinction event, and plankton populations crashed. Nearly 90% of all calcifying plankton species perished. This reverberated up and caused a global marine food chain collapse, namely with the extinction of ammonites and large raptorial marine reptiles. Nonetheless, the rapid diversification of large fish species indicates a healthy plankton population through the Paleocene.[178]

Marine invertebrate diversity may have taken about 7 million years to recover, though this may be a preservation artifact as anything smaller than 5 mm (0.20 in) is unlikely to be fossilized, and body size may have simply decreased across the boundary.[204] A 2019 study found that in Seymour Island, Antarctica, the marine life assemblage consisted primarily of burrowing creatures—such as burrowing clams and snails—for around 320,000 years after the K–Pg extinction event, and it took around a million years for the marine diversity to return to previous levels. Areas closer to the equator may have been more affected.[88] Sand dollars first evolved in the late Paleocene.[205] The Late Cretaceous decapod crustacean assemblage of James Ross Island appears to have been mainly pioneer species and the ancestors of modern fauna, such as the first Antarctic crabs and the first appearance of the lobsters of the genera Linuparus, Metanephrops, and Munidopsis which still inhabit Antarctica today.[206]

 
A rudist, the dominant reef-building organism of the Cretaceous

In the Cretaceous, the main reef-building creatures were the box-like bivalve rudists instead of coral—though a diverse Cretaceous coral assemblage did exist—and rudists had collapsed by the time of the K–Pg extinction event. Some corals are known to have survived in higher latitudes in the Late Cretaceous and into the Paleogene, and hard coral-dominated reefs may have recovered by 8 million years after the K–Pg extinction event, though the coral fossil record of this time is rather sparse.[207] Though there was a lack of extensive coral reefs in the Paleocene, there were some colonies—mainly dominated by zooxanthellate corals—in shallow coastal (neritic) areas. Starting in the latest Cretaceous and continuing until the early Eocene, calcareous corals rapidly diversified. Corals probably competed mainly with red and coralline algae for space on the seafloor. Calcified dasycladalean green algae experienced the greatest diversity in their evolutionary history in the Paleocene.[208] Though coral reef ecosystems do not become particularly abundant in the fossil record until the Miocene (possibly due to preservation bias), strong Paleocene coral reefs have been identified in what are now the Pyrenees (emerging as early as 63 mya), with some smaller Paleocene coral reefs identified across the Mediterranean region.[209]

See also edit

Notes edit

  1. ^ In Lyell's time, epochs were divided into periods. In modern geology, periods are divided into epochs.

References edit

  1. ^ "International Chronostratigraphic Chart". International Commission on Stratigraphy.
  2. ^ a b c Molina, Eustoquio; Alegret, Laia; Arenillas, Ignacio; José A. Arz; Gallala, Njoud; Hardenbol, Jan; Katharina von Salis; Steurbaut, Etienne; Vandenberghe, Noel; Dalila Zaghibib-Turki (2006). (PDF). Episodes. 29 (4): 263–278. doi:10.18814/epiiugs/2006/v29i4/004. Archived from the original (PDF) on 7 December 2012. Retrieved 14 September 2012.
  3. ^ a b c Aubry, Marie-Pierre; Ouda, Khaled; Dupuis, Christian; William A. Berggren; John A. Van Couvering; Working Group on the Paleocene/Eocene Boundary (2007). "The Global Standard Stratotype-section and Point (GSSP) for the base of the Eocene Series in the Dababiya section (Egypt)" (PDF). Episodes. 30 (4): 271–286. doi:10.18814/epiiugs/2007/v30i4/003.
  4. ^ Jones, Daniel (2003) [1917], Peter Roach; James Hartmann; Jane Setter (eds.), English Pronouncing Dictionary, Cambridge: Cambridge University Press, ISBN 3-12-539683-2
  5. ^ Schimper, W. P. (1874). Traité de Paléontologie Végétale [Treatise on Paleobotany] (in French). Vol. 3. Paris J.G. Bailliere. pp. 680–689.
  6. ^ a b Pulvertaft, T. C. R. (1999). ""Paleocene" or "Palaeocene"" (PDF). Bulletin of the Geological Society of Denmark. 46: 52. doi:10.37570/bgsd-1999-46-17. S2CID 246504439. (PDF) from the original on 20 June 2016.
  7. ^ Desnoyers, J. (1829). "Observations sur un ensemble de dépôts marins plus récents que les terrains tertiaires du bassin de la Seine, et constituant une formation géologique distincte; précédées d'un aperçu de la nonsimultanéité des bassins tertiares" [Observations on a set of marine deposits more recent than the tertiary terrains of the Seine basin and constitute a distinct geological formation; preceded by an outline of the non-simultaneity of tertiary basins]. Annales des Sciences Naturelles (in French). 16: 171–214. from the original on 10 September 2018. Retrieved 20 October 2019.
  8. ^ Lyell, C. (1833). Principles of Geology. Vol. 3. Geological Society of London. p. 378.
  9. ^ Phillips, J. (1840). "Palæozoic series". Penny Cyclopaedia of the Society for the Diffusion of Useful Knowledge. Vol. 17. London, England: Charles Knight and Co. pp. 153–154.
  10. ^ Hörnes, M. (1853). "Mittheilungen an Professor Bronn gerichtet" [Reports addressed to Professor Bronn]. Neues Jahrbuch für Mineralogie, Geognosie, Geologie und Petrefaktenkunde (in German): 806–810. hdl:2027/hvd.32044106271273.
  11. ^ George, T. N.; Harland, W. B. (1969). "Recommendations on stratigraphical usage". Proceedings of the Geological Society of London. 156 (1, 656): 139–166.
  12. ^ Odin, G. S.; Curry, D.; Hunziker, J. Z. (1978). "Radiometric dates from NW European glauconites and the Palaeogene time-scale". Journal of the Geological Society. 135 (5): 481–497. Bibcode:1978JGSoc.135..481O. doi:10.1144/gsjgs.135.5.0481. S2CID 129095948.
  13. ^ Knox, R. W. O.'B.; Pearson, P. N.; Barry, T. L. (2012). "Examining the case for the use of the Tertiary as a formal period or informal unit" (PDF). Proceedings of the Geologists' Association. 123 (3): 390–393. Bibcode:2012PrGA..123..390K. doi:10.1016/j.pgeola.2012.05.004. S2CID 56290221.
  14. ^ "ICS – Chart/Time Scale". www.stratigraphy.org. from the original on 30 May 2014. Retrieved 28 August 2019.
  15. ^ Schulte, P. (2010). "The Chicxulub Asteroid Impact and Mass Extinction at the Cretaceous-Paleogene Boundary" (PDF). Science. 327 (5970): 1214–1218. Bibcode:2010Sci...327.1214S. doi:10.1126/science.1177265. PMID 20203042. S2CID 2659741. (PDF) from the original on 21 September 2017. Retrieved 28 August 2019.
  16. ^ Vellekoop, J.; Sluijs, A.; Smit, J.; Schouten, S.; Weijers, J. W. H.; Sinninghe Damste, J. S.; Brinkhuis, H. (2014). "Rapid short-term cooling following the Chicxulub impact at the Cretaceous-Paleogene boundary". Proceedings of the National Academy of Sciences. 111 (21): 7537–7541. Bibcode:2014PNAS..111.7537V. doi:10.1073/pnas.1319253111. PMC 4040585. PMID 24821785.
  17. ^ Jablonski, D.; Chaloner, W. G. (1994). "Extinctions in the fossil record (and discussion)". Philosophical Transactions of the Royal Society of London B. 344 (1307): 11–17. doi:10.1098/rstb.1994.0045.
  18. ^ Sprain, C. J.; Renne, P. R.; Vanderkluysen, L. (2019). "The eruptive tempo of Deccan volcanism in relation to the Cretaceous-Paleogene boundary". Science. 363 (6429): 866–870. Bibcode:2019Sci...363..866S. doi:10.1126/science.aav1446. PMID 30792301. S2CID 67876911.
  19. ^ a b Turner, S. K.; Hull, P. M.; Ridgwell, A. (2017). "A probabilistic assessment of the rapidity of PETM onset". Nature Communications. 8 (353): 353. Bibcode:2017NatCo...8..353K. doi:10.1038/s41467-017-00292-2. PMC 5572461. PMID 28842564.
  20. ^ Zhang, Q.; Willems, H.; Ding, L.; Xu, X. (2019). "Response of larger benthic foraminifera to the Paleocene–Eocene thermal maximum and the position of the Paleocene/Eocene boundary in the Tethyan shallow benthic zones: Evidence from south Tibet". GSA Bulletin. 131 (1–2): 84–98. Bibcode:2019GSAB..131...84Z. doi:10.1130/B31813.1. S2CID 134560025.
  21. ^ a b Kennet, J. P.; Stott, L. D. (1995). "Terminal Paleocene Mass Extinction in the Deep Sea: Association with Global Warming". Effects of Past Global Change on Life: Studies in Geophysics. National Academy of Sciences.
  22. ^ Winguth, C.; Thomas, E. (2012). "Global decline in ocean ventilation, oxygenation, and productivity during the Paleocene–Eocene Thermal Maximum: Implications for the benthic extinction". Geology. 40 (3): 263–266. Bibcode:2012Geo....40..263W. doi:10.1130/G32529.1.
  23. ^ Schmidt, G. A.; Shindell, D. T. (2003). (PDF). Paleoceanography. 18 (1): n/a. Bibcode:2003PalOc..18.1004S. doi:10.1029/2002PA000757. Archived from the original (PDF) on 20 October 2011.
  24. ^ a b c d e Schmitz, B.; Pujalte, V.; Molina, E. (2011). "The Global Stratotype Sections and Points for the bases of the Selandian (Middle Paleocene) and Thanetian (Upper Paleocene) Stages at Zumaia, Spain" (PDF). Episodes. 34 (4): 220–243. doi:10.18814/epiiugs/2011/v34i4/002. (PDF) from the original on 20 August 2018.
  25. ^ Desor, P. J. É. "Sur le terrain Danien, nouvel étage de la craie". Bulletin de la Société Géologique de France (in French). 2.
  26. ^ Harland, W. B.; Armstrong, R. L.; Cox, A. V.; Craig, L. E.; Smith, A. G.; Smith, D. G. (1990). A Geologic Time Scale 1989. Cambridge University Press. p. 61. ISBN 978-0-521-38765-1.
  27. ^ Molina, E.; Alagret, L.; Arenillas, I. (2006). "The Global Boundary Stratotype Section and Point for the base of the Danian Stage (Paleocene, Paleogene, "Tertiary", Cenozoic) at El Kef, Tunisia – Original definition and revision" (PDF). Episodes. 29 (4): 263–273. doi:10.18814/epiiugs/2006/v29i4/004. (PDF) from the original on 14 February 2019.
  28. ^ a b Hyland, E. G.; Sheldon, N. D.; Cotton, J. M. (2015). "Terrestrial evidence for a two-stage mid-Paleocene biotic event" (PDF). Palaeogeography, Palaeoclimatology, Palaeoecology. 417: 371–378. Bibcode:2015PPP...417..371H. doi:10.1016/j.palaeo.2014.09.031. (PDF) from the original on 5 August 2016.
  29. ^ Tauxe, L.; Banerjee, S. K.; Butler, R. F.; van der Voo, R. (2018). "The GPTS and magnetostratigraphy". Essentials of Paleomagnetism: Fifth Web Edition. Scripps Institute of Oceanography. from the original on 8 October 2019.
  30. ^ Flores, R. M.; Bader, L. R. Fort Union coal in the Powder River Basin, Wyoming and Montana: a synthesis (PDF). US Geological Survey. pp. 1–30. (PDF) from the original on 4 May 2017. Retrieved 3 November 2019.
  31. ^ "Sixteen mines in the Powder River Basin produce 43% of U.S. coal". U.S. Energy Information Administration. 16 August 2019. from the original on 7 November 2019. Retrieved 7 November 2019.
  32. ^ Hook, R. W.; Warwick, P. D.; San Felipo, J. R.; Schultz, A. C.; Nichols, D. J.; Swanson, S. M. (2011). "Paleocene coal deposits of the Wilcox group, central Texas". In Warwick, P. D.; Karlsen, A. K.; Merrill, M. D.; Valentine, B. J. (eds.). Geologic Assessment of Coal in the Gulf of Mexico Coastal Plain. American Association of Petroleum Geologists. doi:10.1306/13281367St621291. ISBN 978-1-62981-025-6.
  33. ^ Jaramillo, C. A.; Bayona, G.; Pardo-Trujillo, A.; Rueda, M.; Torres, V.; Harrington, G. J.; Mora, G. (2007). "The Palynology of the Cerrejón Formation (Upper Paleocene) of Northern Colombia". Palynology. 31 (1): 159–183. Bibcode:2007Paly...31..153J. doi:10.1080/01916122.2007.9989641. S2CID 220343205.
  34. ^ Lüthje, C. J.; Milàn, J.; Hurum, J. H. (2009). "Paleocene tracks of the mammal Pantodont genus Titanoides in coal-bearing strata, Svalbard, Arctic Norway". Journal of Vertebrate Paleontology. 30 (2): 521–527. doi:10.1080/02724631003617449. hdl:1956/3854. S2CID 59125537.
  35. ^ Kalkreuth, W. D.; Riediger, C. L.; McIntyre, D. J.; Richardson, R. J. H.; Fowler, M. G.; Marchioni, D. (1996). "Petrological, palynological and geochemical characteristics of Eureka Sound Group coals (Stenkul Fiord, southern Ellesmere Island, Arctic Canada)". International Journal of Coal Geology. 30 (1–2): 151–182. Bibcode:1996IJCG...30..151K. doi:10.1016/0166-5162(96)00005-5.
  36. ^ Akhmetiev, M. A. (2015). "High-latitude regions of Siberia and Northeast Russia in the Paleogene: Stratigraphy, flora, climate, coal accumulation". Stratigraphy and Geological Correlation. 23 (4): 421–435. Bibcode:2015SGC....23..421A. doi:10.1134/S0869593815040024. S2CID 131114773.
  37. ^ Bain, J. S. (1993). "Historical overview of exploration of Tertiary plays in the UK North Sea". Petroleum Geology Conference. 4: 5–13. doi:10.1144/0040005.
  38. ^ Garnit, H.; Bouhlel, S.; Jarvis, I. (2017). "Geochemistry and depositional environments of Paleocene–Eocene phosphorites: Metlaoui Group, Tunisia" (PDF). Journal of African Earth Sciences. 134: 704–736. Bibcode:2017JAfES.134..704G. doi:10.1016/j.jafrearsci.2017.07.021. (PDF) from the original on 29 April 2019. Retrieved 7 November 2019.
  39. ^ a b Kenny, Gavin G.; Hyde, William R.; Storey, Michael; Garde, Adam A.; Whitehouse, Martin J.; Beck, Pierre; Johansson, Leif; Søndergaard, Anne Sofie; Bjørk, Anders A.; MacGregor, Joseph A.; Khan, Shfaqat A. (11 March 2022). "A Late Paleocene age for Greenland's Hiawatha impact structure". Science Advances. 8 (10): eabm2434. Bibcode:2022SciA....8M2434K. doi:10.1126/sciadv.abm2434. ISSN 2375-2548. PMC 8906741. PMID 35263140.
  40. ^ "Connolly Basin". Earth Impact Database. from the original on 12 April 2019. Retrieved 3 November 2019.
  41. ^ "Marquez". Earth Impact Database. from the original on 12 April 2019. Retrieved 3 November 2019.
  42. ^ "Jebel Waqf as Suwwan". Earth Impact Database. from the original on 8 June 2019. Retrieved 3 November 2019.
  43. ^ Drake, S. M.; Beard, A. D.; Jones, A. P.; Brown, D. J.; Fortes, A. D.; Millar, I. L.; Carter, A.; Baca, J.; Downes, H. (2018). "Discovery of a meteoritic ejecta layer containing unmelted impactor fragments at the base of Paleocene lavas, Isle of Skye, Scotland" (PDF). Geology. 46 (2): 171–174. Bibcode:2018Geo....46..171D. doi:10.1130/G39452.1. S2CID 4807661.
  44. ^ Renne, Paul (2013). "Time Scales of Critical Events Around the Cretaceous-Paleogene Boundary" (PDF). Science. 339 (6120): 684–7. Bibcode:2013Sci...339..684R. doi:10.1126/science.1230492. PMID 23393261. S2CID 6112274. (PDF) from the original on 3 April 2018. Retrieved 4 November 2019.
  45. ^ Pickersgill, Annemarie E.; Mark, Darren F.; Lee, Martin R.; Kelley, Simon P.; Jolley, David W. (1 June 2021). "The Boltysh impact structure: An early Danian impact event during recovery from the K-Pg mass extinction". Science Advances. 7 (25): eabe6530. Bibcode:2021SciA....7.6530P. doi:10.1126/sciadv.abe6530. ISSN 2375-2548. PMC 8213223. PMID 34144979.
  46. ^ "Eagle Butte". Earth Impact Database. from the original on 12 May 2019. Retrieved 3 November 2019.
  47. ^ "Vista Alegre". Earth Impact Database. from the original on 12 May 2019. Retrieved 4 November 2019.
  48. ^ Vasconcelos, M. A. R. (2013). "Update on the current knowledge of the Brazilian impact craters" (PDF). 44th Lunar and Planetary Science Conference (1318): 1318. Bibcode:2013LPI....44.1318C. (PDF) from the original on 8 October 2016. Retrieved 4 November 2019.
  49. ^ Schaller, M. F.; Fung, M. K.; Wright, J. D.; Katz, M. E.; Kent, D. V. (2016). "Impact ejecta at the Paleocene–Eocene boundary". Science. 354 (6309): 225–229. Bibcode:2016Sci...354..225S. doi:10.1126/science.aaf5466. PMID 27738171. S2CID 30852592.
  50. ^ a b c Hooker, J. J. (2005). "Tertiary to Present: Paleocene". In Selley, R. C.; Cocks, R.; Plimer, I. R. (eds.). Encyclopedia of Geology. Vol. 5. Elsevier Limited. pp. 459–465. ISBN 978-0-12-636380-7.
  51. ^ Brikiatis, L. (2014). "The De Geer, Thulean and Beringia routes: key concepts for understanding early Cenozoic biogeography". Journal of Biogeography. 41 (6): 1036–1054. Bibcode:2014JBiog..41.1036B. doi:10.1111/jbi.12310. S2CID 84506301.
  52. ^ Graham, A. (2018). "The role of land bridges, ancient environments, and migrations in the assembly of the North American flora". Journal of Systematics and Evolution. 56 (5): 405–429. doi:10.1111/jse.12302. S2CID 90782505.
  53. ^ English, Joseph M.; Johnston, Stephen T. (2004). "The Laramide Orogeny: What Were the Driving Forces?". International Geology Review. 46 (9): 833–838. Bibcode:2004IGRv...46..833E. doi:10.2747/0020-6814.46.9.833. S2CID 129901811.
  54. ^ Slattery, J.; Cobban, W. A.; McKinney, K. C.; Harries, P. J.; Sandness, A. (2013). Early Cretaceous to Paleocene Paleogeography of the Western Interior Seaway: The Interaction of Eustasy and Tectonism. Wyoming Geological Association 68th Annual Field Conference. doi:10.13140/RG.2.1.4439.8801.
  55. ^ a b c d Jolley, D. W.; Bell, B. R. (2002). "The evolution of the North Atlantic Igneous Province and the opening of the NE Atlantic rift". Geological Society of London. 197 (1): 1–13. Bibcode:2002GSLSP.197....1J. doi:10.1144/GSL.SP.2002.197.01.01. S2CID 129653395.
  56. ^ a b Rousse, S.; M. Ganerød; M.A. Smethurst; T.H. Torsvik; T. Prestvik (2007). "The British Tertiary Volcanics: Origin, History and New Paleogeographic Constraints for the North Atlantic". Geophysical Research Abstracts. 9.
  57. ^ Hansen, J.; Jerram, D. A.; McCaffrey, K.; Passey, S. R. (2009). "The onset of the North Atlantic Igneous Province in a rifting perspective". Geological Magazine. 146 (3): 309–325. Bibcode:2009GeoM..146..309H. doi:10.1017/S0016756809006347. S2CID 130266576. from the original on 7 October 2019.
  58. ^ Torsvik, T. H.; Mosar, J.; Eide, E. A. (2001). "Cretaceous-Tertiary geodynamics: a North Atlantic exercise" (PDF). Geophysical Journal. 146 (3): 850–866. Bibcode:2001GeoJI.146..850T. doi:10.1046/j.0956-540x.2001.01511.x. S2CID 129961946.
  59. ^ White, R. S.; McKenzie, D. P. (1989). "Magmatism at rift zones: The generation of volcanic continental margins and flood basalts" (PDF). Journal of Geophysical Research: Solid Earth. 94 (B6): 7685–7729. Bibcode:1989JGR....94.7685W. doi:10.1029/JB094iB06p07685. (PDF) from the original on 15 December 2017. Retrieved 24 September 2019.
  60. ^ Maclennan, John; Jones, Stephen M. (2006). "Regional uplift, gas hydrate dissociation and the origins of the Paleocene–Eocene Thermal Maximum". Earth and Planetary Science Letters. 245 (1): 65–80. Bibcode:2006E&PSL.245...65M. doi:10.1016/j.epsl.2006.01.069.
  61. ^ Buchs, David M.; Arculus, Richard J.; Baumgartner, Peter O.; Baumgartner-Mora, Claudia; Ulianov, Alexey (July 2010). "Late Cretaceous arc development on the SW margin of the Caribbean Plate: Insights from the Golfito, Costa Rica, and Azuero, Panama, complexes" (PDF). Geochemistry, Geophysics, Geosystems. 11 (7): n/a. Bibcode:2010GGG....11.7S24B. doi:10.1029/2009GC002901. hdl:1885/55979. S2CID 12267720. (PDF) from the original on 14 August 2017. Retrieved 24 October 2019.
  62. ^ Escuder-Viruete, J.; Pérez-Estuán, A.; Joubert, M.; Weis, D. (2011). "The Pelona-Pico Duarte basalts Formation, Central Hispaniola: an on-land section of Late Cretaceous volcanism related to the Caribbean large igneous province" (PDF). Geologica Acta. 9 (3–4): 307–328. doi:10.1344/105.000001716. (PDF) from the original on 4 March 2016.
  63. ^ O'Dea, A.; Lessios, H. A.; Coates, A. G.; Eytan, R. I.; Restrepo-Moreno, S. A.; Cione, R. A. (2016). "Formation of the Isthmus of Panama". Science Advances. 2 (8): e1600883. Bibcode:2016SciA....2E0883O. doi:10.1126/sciadv.1600883. PMC 4988774. PMID 27540590.
  64. ^ Hu, Xiumian; Garzanti, Eduardo; Moore, Ted; Raffi, Isabella (1 October 2015). "Direct stratigraphic dating of India-Asia collision onset at the Selandian (middle Paleocene, 59 ± 1 Ma)". Geology. 43 (10): 859–862. Bibcode:2015Geo....43..859H. doi:10.1130/G36872.1. hdl:10281/95315. ISSN 0091-7613. Retrieved 23 September 2023.
  65. ^ Frederiksen, N. O. (1994). "Middle and Late Paleocene Angiosperm Pollen from Pakistan". Palynology. 18 (1): 91–137. Bibcode:1994Paly...18...91F. doi:10.1080/01916122.1994.9989442.
  66. ^ a b Vahlenkamp, M.; Niezgodzki, I.; Niezgodzki, D.; Lohmann, G.; Bickert, T.; Pälike, H. (2018). "Ocean and climate response to North Atlantic seaway changes at the onset of long-term Eocene cooling" (PDF). Earth and Planetary Science Letters. 498: 185–195. Bibcode:2018E&PSL.498..185V. doi:10.1016/j.epsl.2018.06.031. S2CID 135252669.
  67. ^ a b c d Thomas, D. J. (2004). "Evidence for deep-water production in the North Pacific Ocean during the early Cenozoic warm interval". Nature. 430 (6995): 65–68. Bibcode:2004Natur.430...65T. doi:10.1038/nature02639. PMID 15229597. S2CID 4422834.
  68. ^ a b c d e f g Kitchell, J. A.; Clark, D. L. (1982). "Late Cretaceous–Paleogene paleogeography and paleocirculation: Evidence of north polar upwelling". Palaeogeography, Palaeoclimatology, Palaeoecology. 40 (1–3): 135–165. Bibcode:1982PPP....40..135K. doi:10.1016/0031-0182(82)90087-6.
  69. ^ a b Nunes, F.; Norris, R. D. (2006). "Abrupt reversal in ocean overturning during the Palaeocene/Eocene warm period". Nature. 439 (7072): 60–63. Bibcode:2006Natur.439...60N. doi:10.1038/nature04386. PMID 16397495. S2CID 4301227.
  70. ^ Hassold, N. J. C.; Rea, D. K.; van der Pluijm, B. A.; Parés, J. M. (2009). "A physical record of the Antarctic Circumpolar Current: late Miocene to recent slowing of abyssal circulation" (PDF). Palaeogeography, Palaeoclimatology, Palaeoecology. 275 (1–4): 28–36. Bibcode:2009PPP...275...28H. doi:10.1016/j.palaeo.2009.01.011. (PDF) from the original on 29 October 2015. Retrieved 10 September 2019.
  71. ^ a b c Wilf, P.; Johnson, K. R. (2004). "Land plant extinction at the end of the Cretaceous: A quantitative analysis of the North Dakota megafloral record". Paleobiology. 30 (3): 347–368. doi:10.1666/0094-8373(2004)030<0347:LPEATE>2.0.CO;2. S2CID 33880578. Retrieved 16 December 2023.
  72. ^ Akhmetiev, M. A. (2007). "Paleocene and Eocene floras of Russia and adjacent regions: Climatic conditions of their development". Paleontological Journal. 41 (11): 1032–1039. Bibcode:2007PalJ...41.1032A. doi:10.1134/S0031030107110020. S2CID 128882063.
  73. ^ Akhmetiev, M. A.; Beniamovsky, V. N. (2009). "Paleogene floral assemblages around epicontinental seas and straits in Northern Central Eurasia: proxies for climatic and paleogeographic evolution". Geologica Acta. 7 (1): 297–309. doi:10.1344/105.000000278.
  74. ^ a b c Williams, C. J.; LePage, B. A.; Johnson, A. H.; Vann, D. R. (2009). "Structure, Biomass, and Productivity of a Late Paleocene Arctic Forest". Proceedings of the Academy of Natural Sciences of Philadelphia. 158 (1): 107–127. doi:10.1635/053.158.0106. S2CID 130110536.
  75. ^ Hansen, J.; Sato, M.; Russell, G.; Kharecha, P. (2013). "Climate sensitivity, sea level and atmospheric carbon dioxide". Philosophical Transactions of the Royal Society A. 371 (2001): 20120294. arXiv:1211.4846. Bibcode:2013RSPTA.37120294H. doi:10.1098/rsta.2012.0294. PMC 3785813. PMID 24043864.
  76. ^ "World of Change: Global Temperatures". NASA Earth Observatory. 9 December 2010. from the original on 3 September 2019. Retrieved 10 September 2019.
  77. ^ Hao, Hui; Ferguson, David K.; Feng, Guang-Ping; Ablaev, Albert; Wang, Yu-Fei; Li, Cheng-Sen (11 November 2009). "Early Paleocene vegetation and climate in Jiayin, NE China". Climatic Change. 99 (3–4): 547–566. doi:10.1007/s10584-009-9728-6. ISSN 0165-0009. S2CID 55815633. Retrieved 23 September 2023.
  78. ^ a b c Brea, M.; Matheos, S. D.; Raigemborn, M. S.; Iglesias, A.; Zucol, A. F.; Prámparo, M. (2011). "Paleoecology and paleoenvironments of Podocarp trees in the Ameghino Petrified forest (Golfo San Jorge Basin, Patagonia, Argentina): Constraints for Early Paleogene paleoclimate" (PDF). Geologica Acta. 9 (1): 13–28. doi:10.1344/105.000001647. (PDF) from the original on 28 August 2017.
  79. ^ Barr, Iestyn D.; Spagnolo, Matteo; Rea, Brice R.; Bingham, Robert G.; Oien, Rachel P.; Adamson, Kathryn; Ely, Jeremy C.; Mullan, Donal J.; Pellitero, Ramón; Tomkins, Matt D. (21 September 2022). "60 million years of glaciation in the Transantarctic Mountains". Nature Communications. 13 (1): 5526. Bibcode:2022NatCo..13.5526B. doi:10.1038/s41467-022-33310-z. ISSN 2041-1723. PMC 9492669. PMID 36130952.
  80. ^ "Paleocene Climate". PaleoMap Project. from the original on 4 April 2019. Retrieved 7 September 2019.
  81. ^ Sewall, Jacob O.; Sloan, Lisa Cirbus (1 February 2006). "Come a little bit closer: A high-resolution climate study of the early Paleogene Laramide foreland". Geology. 34 (2): 81. Bibcode:2006Geo....34...81S. doi:10.1130/G22177.1. ISSN 0091-7613. Retrieved 23 September 2023.
  82. ^ Bergman, J. (16 February 2011). "Temperature of Ocean Water". Windows to the Universe. from the original on 25 September 2019. Retrieved 4 October 2019.
  83. ^ Buchardt, Bjørn (1 October 1977). "Oxygen isotope ratios from shell material from the Danish middle paleocene (Selandian) deposits and their interpretation as paleotemperature indicators". Palaeogeography, Palaeoclimatology, Palaeoecology. 22 (3): 209–230. Bibcode:1977PPP....22..209B. doi:10.1016/0031-0182(77)90029-3. ISSN 0031-0182.
  84. ^ Quillévéré, F.; Norris, R. D. (2003). "Ecological development of acarininids (planktonic foraminifera) and hydrographic evolution of Paleocene surface waters". Geological Society of America: 223–238. doi:10.1130/0-8137-2369-8.223. ISBN 9780813723693.
  85. ^ Boersma, A.; Silva, I. P. (1991). "Distribution of Paleogene planktonic foraminifera — analogies with the Recent?". Palaeogeography, Palaeoclimatology, Palaeoecology. 83 (1–3): 38–40. Bibcode:1991PPP....83...29B. doi:10.1016/0031-0182(91)90074-2.
  86. ^ Kowalczyk, J. B.; Royer, D. L.; Miller, I. M.; Anderson, C. W. (2018). "Multiple Proxy Estimates of Atmospheric CO2 From an Early Paleocene Rainforest". Paleoceanography and Paleoclimatology. 33 (12): 1, 427–1, 438. Bibcode:2018PaPa...33.1427K. doi:10.1029/2018PA003356. S2CID 130296033. from the original on 29 April 2019. Retrieved 7 November 2019.[page needed]
  87. ^ Barnet, J. S. K.; Littler, K.; Westerhold, T.; Kroon, D.; Leng, M. J.; Bailey, I.; Röhl, U.; Zachos, J. C. (3 April 2019). "A High-Fidelity Benthic Stable Isotope Record of Late Cretaceous–Early Eocene Climate Change and Carbon-Cycling". Paleoceanography and Paleoclimatology. 34 (4): 672–691. Bibcode:2019PaPa...34..672B. doi:10.1029/2019PA003556. hdl:20.500.11820/71e8a0b8-eec2-46bd-8559-bfc98ee3d21c. S2CID 134124572.
  88. ^ a b Whittle, Rowan; Witts, James; Bowman, Vanessa; Crame, Alistair; Francis, Jane; Ineson, Ion (2019). "Mass extinction". Data from: Nature and timing of biotic recovery in Antarctic benthic marine ecosystems following the Cretaceous–Palaeogene mass extinction. Dryad Digital Repository. doi:10.5061/dryad.v1265j8.
  89. ^ Brugger, Julia; Feulner, Georg; Petri, Stefan (2016). "Baby, it's cold outside: Climate model simulations of the effects of the asteroid impact at the end of the Cretaceous" (PDF). Geophysical Research Letters. 44 (1): 419–427. Bibcode:2017GeoRL..44..419B. doi:10.1002/2016GL072241. S2CID 53631053.
  90. ^ Vellekoop, J.; Sluijs, A.; Smit, J.; Schouten, S.; Weijers, J. W. H.; Sinninghe Damste, J. S.; Brinkhuis, H. (12 May 2014). "Rapid short-term cooling following the Chicxulub impact at the Cretaceous-Paleogene boundary". Proceedings of the National Academy of Sciences. 111 (21): 7537–7541. Bibcode:2014PNAS..111.7537V. doi:10.1073/pnas.1319253111. PMC 4040585. PMID 24821785.
  91. ^ Ohno, S.; et al. (2014). "Production of sulphate-rich vapour during the Chicxulub impact and implications for ocean acidification". Nature Geoscience. 7 (4): 279–282. Bibcode:2014NatGe...7..279O. doi:10.1038/ngeo2095.
  92. ^ Pope, K. O.; D'Hondt, S. L.; Marshall, C. R. (15 September 1998). "Meteorite impact and the mass extinction of species at the Cretaceous/Tertiary boundary". Proceedings of the National Academy of Sciences. 95 (19): 11028–11029. Bibcode:1998PNAS...9511028P. doi:10.1073/pnas.95.19.11028. PMC 33889. PMID 9736679.
  93. ^ Belcher, C. M. (2009). "Reigniting the Cretaceous-Palaeogene firestorm debate". Geology. 37 (12): 1147–1148. Bibcode:2009Geo....37.1147B. doi:10.1130/focus122009.1.{{cite journal}}: CS1 maint: ignored DOI errors (link)
  94. ^ Zanthos, J. C.; Arthur, M. A.; Dean, W. E. (1989). "Geochemical evidence for suppression of pelagic marine productivity at the Cretaceous/Tertiary boundary". Nature. 337 (6202): 61–64. Bibcode:1989Natur.337...61Z. doi:10.1038/337061a0. S2CID 4307681. from the original on 7 June 2017. Retrieved 19 November 2019.
  95. ^ Rampino, M. R.; Volk, T. (1988). "Mass extinctions, atmospheric sulphur and climatic warming at the K/T boundary". Nature. 332 (6159): 63–65. Bibcode:1988Natur.332...63R. doi:10.1038/332063a0. S2CID 4343787.
  96. ^ Quillévéré, F.; Norris, R. D.; Koon, D.; Wilson, P. A. (2007). "Transient ocean warming and shifts in carbon reservoirs during the early Danian". Earth and Planetary Science Letters. 265 (3): 600–615. doi:10.1016/j.epsl.2007.10.040.
  97. ^ Jolley, D. W.; Gilmour, I.; Gilmour, M.; Kemp, D. B.; Kelley, S. P. (2015). "Long-term resilience decline in plant ecosystems across the Danian Dan-C2 hyperthermal event, Boltysh crater, Ukraine". Journal of the Geological Society. 172 (4): 491–498. Bibcode:2015JGSoc.172..491J. doi:10.1144/jgs2014-130. hdl:2164/6186. S2CID 130611763.
  98. ^ Scotese, Christopher R.; Song, Haijun; Mills, Benjamin J.W.; van der Meer, Douwe G. (April 2021). "Phanerozoic paleotemperatures: The earth's changing climate during the last 540 million years". Earth-Science Reviews. 215: 103503. Bibcode:2021ESRv..21503503S. doi:10.1016/j.earscirev.2021.103503. S2CID 233579194. Retrieved 23 September 2023.
  99. ^ Jehle, Sofie; Bornemann, André; Lägel, Anna Friederike; Deprez, Arne; Speijer, Robert P. (1 July 2019). "Paleoceanographic changes across the Latest Danian Event in the South Atlantic Ocean and planktic foraminiferal response". Palaeogeography, Palaeoclimatology, Palaeoecology. 525: 1–13. Bibcode:2019PPP...525....1J. doi:10.1016/j.palaeo.2019.03.024. ISSN 0031-0182. S2CID 134929774. Retrieved 23 September 2023.
  100. ^ Jehl, S.; Bornemann, A.; Deprez, A.; Speijer, R. P. (2015). "The Impact of the Latest Danian Event on Planktic Foraminiferal Faunas at ODP Site 1210 (Shatsky Rise, Pacific Ocean)". PLOS ONE. 10 (11): e0141644. Bibcode:2015PLoSO..1041644J. doi:10.1371/journal.pone.0141644. PMC 4659543. PMID 26606656.
  101. ^ Speijer, R. P. (2003). "Danian-Selandian sea-level change and biotic excursion on the southern Tethyan margin (Egypt)". In Wing, S. L.; Gingerich, P. D.; Schmitz, B.; Thomas, E. (eds.). Causes and Consequences of Globally Warm Climates in the Early Paleogene. Geological Society of America. pp. 275–290. doi:10.1130/0-8137-2369-8.275. ISBN 978-0-8137-2369-3. S2CID 130152164.
  102. ^ Coccioni, Rodolfo; Frontalini, Fabrizio; Catanzariti, Rita; Jovane, Luigi; Rodelli, Daniel; Rodrigues, Ianco M. M.; Savian, Jairo F.; Giorgioni, Martino; Galbrun, Bruno (1 June 2019). "Paleoenvironmental signature of the Selandian-Thanetian Transition Event (STTE) and Early Late Paleocene Event (ELPE) in the Contessa Road section (western Neo-Tethys)". Palaeogeography, Palaeoclimatology, Palaeoecology. 523: 62–77. Bibcode:2019PPP...523...62C. doi:10.1016/j.palaeo.2019.03.023. ISSN 0031-0182. S2CID 134340748. Retrieved 23 September 2023.
  103. ^ Faris, Mahmoud; Shabaan, Manal; Abdelhady, Ahmed Awad; Ahmed, Mohamed S.; Shaker, Fatma (4 July 2023). "The Paleocene climate in west central Sinai (Egypt): insights from the calcareous nannofossils". Arabian Journal of Geosciences. 16 (8): 448. Bibcode:2023ArJG...16..448F. doi:10.1007/s12517-023-11566-z. ISSN 1866-7511. S2CID 259318736. Retrieved 23 September 2023.
  104. ^ Bernoala, G.; Baceta, J. I.; Orue-Etxebarria, X.; Alegret, L. (2008). "The mid-Paleocene biotic event at the Zumaia section (western Pyrenees); evidence of an abrupt environmental disruption". Geophysical Research Abstracts. 10.
  105. ^ Hollis, Christopher J.; Naeher, Sebastian; Clowes, Christopher D.; Naafs, B. David A.; Pancost, Richard D.; Taylor, Kyle W. R.; Dahl, Jenny; Li, Xun; Ventura, G. Todd; Sykes, Richard (20 June 2022). "Late Paleocene CO<sub>2</sub> drawdown, climatic cooling and terrestrial denudation in the southwest Pacific". Climate of the Past. 18 (6): 1295–1320. Bibcode:2022CliPa..18.1295H. doi:10.5194/cp-18-1295-2022. hdl:1983/b43317da-8fdd-4f4d-baf4-36a467a9d5cf. ISSN 1814-9332. Retrieved 28 October 2023.
  106. ^ Frieling, J.; Gebhardt, H.; Huber, M. (2017). "Extreme warmth and heat-stressed plankton in the tropics during the Paleocene-Eocene Thermal Maximum". Science Advances. 3 (3): e1600891. Bibcode:2017SciA....3E0891F. doi:10.1126/sciadv.1600891. PMC 5336354. PMID 28275727.
  107. ^ Gutjahr, M.; Ridgewell, A.; Sexton, P. F.; et al. (2017). "Very large release of mostly volcanic carbon during the Palaeocene–Eocene Thermal Maximum". Nature. 538 (7669): 573–577. Bibcode:2017Natur.548..573G. doi:10.1038/nature23646. PMC 5582631. PMID 28858305.
  108. ^ Svensen, H.; Planke, S.; Malthe-Sørrensen, A.; et al. (2004). "Release of methane from a volcanic basin as a mechanism for initial Eocene global warming". Nature. 429 (6991): 542–545. Bibcode:2004Natur.429..542S. doi:10.1038/nature02566. PMID 15175747. S2CID 4419088.
  109. ^ DeConto, R. M.; et al. (2012). "Past extreme warming events linked to massive carbon release from thawing permafrost". Nature. 484 (7392): 87–91. Bibcode:2012Natur.484...87D. doi:10.1038/nature10929. PMID 22481362. S2CID 3194604.
  110. ^ Turner, S. K. (2018). "Constraints on the onset duration of the Paleocene–Eocene Thermal Maximum". Philosophical Transactions of the Royal Society B. 376 (2130): 20170082. Bibcode:2018RSPTA.37670082T. doi:10.1098/rsta.2017.0082. PMC 6127381. PMID 30177565.
  111. ^ Bowen, G. J. (2015). "Two massive, rapid releases of carbon during the onset of the Palaeocene–Eocene thermal maximum". Nature Geoscience. 8 (1): 44–47. Bibcode:2015NatGe...8...44B. doi:10.1038/ngeo2316.
  112. ^ McInerney, Francesca A.; Wing, Scott L. (30 May 2011). "The Paleocene–Eocene Thermal Maximum: A Perturbation of Carbon Cycle, Climate, and Biosphere with Implications for the Future". Annual Review of Earth and Planetary Sciences. 39 (1): 489–516. Bibcode:2011AREPS..39..489M. doi:10.1146/annurev-earth-040610-133431. S2CID 39683046.
  113. ^ Panchuk, K.; Ridgwell, A.; Kump, L. R. (2008). "Sedimentary response to Paleocene–Eocene Thermal Maximum carbon release: A model-data comparison". Geology. 36 (4): 315–318. Bibcode:2008Geo....36..315P. doi:10.1130/G24474A.1.
  114. ^ Zhou, X.; Thomas, E.; Rickaby, R. E. M.; Winguth, A. M. E.; Lu, Z. (2014). "I/Ca evidence for upper ocean deoxygenation during the PETM". Paleoceanography and Paleoclimatology. 29 (10): 964–975. Bibcode:2014PalOc..29..964Z. doi:10.1002/2014PA002702. Retrieved 17 October 2023.
  115. ^ Yao, W.; Paytan, A.; Wortmann, U. G. (2018). "Large-scale ocean deoxygenation during the Paleocene–Eocene Thermal Maximum". Science. 361 (6404): 804–806. Bibcode:2018Sci...361..804Y. doi:10.1126/science.aar8658. PMID 30026315. S2CID 206666570.
  116. ^ Secord, R.; Bloch, J.I.; Chester, S.G.B.; Boyer, D.M.; Wood, A.R.; Wing, S.L.; Kraus, M.J.; McInerney, F.A.; Krigbaum, J. (2012). "Evolution of the Earliest Horses Driven by Climate Change in the Paleocene-Eocene Thermal Maximum". Science. 335 (6071): 959–962. Bibcode:2012Sci...335..959S. doi:10.1126/science.1213859. PMID 22363006. S2CID 4603597. from the original on 9 April 2019. Retrieved 8 January 2020.
  117. ^ a b c d e f Graham, A. (1999). Late Cretaceous and Cenozoic History of North American Vegetation (PDF). Oxford University Press. pp. 162–169. ISBN 978-0-19-511342-6. (PDF) from the original on 1 October 2019.
  118. ^ a b c Wing, S. L.; Herrera, F.; Jaramillo, C. A.; Gómez-Navarro, C.; Wilf, P.; Labandeira, C. C. (2009). "Late Paleocene fossils from the Cerrejón Formation, Colombia, are the earliest record of Neotropical rainforest". Proceedings of the National Academy of Sciences of the United States of America. 106 (44): 18627–18632. Bibcode:2009PNAS..10618627W. doi:10.1073/pnas.0905130106. PMC 2762419. PMID 19833876.
  119. ^ a b Ickert-Bond, S. M.; Pigg, K. B.; DeVore, M. L. (2015). "Paleoochna tiffneyi gen. et sp. nov. (Ochnaceae) from the Late Paleocene Almont/Beicegel Creek Flora, North Dakota, USA". International Journal of Plant Sciences. 176 (9): 892–900. doi:10.1086/683275. S2CID 88105238.
  120. ^ Robson, B. E.; Collinson, M. E.; Riegel, W.; Wilde, V.; Scott, A. C.; Pancost, Richard D. (2015). "Early Paleogene wildfires in peat-forming environments at Schöningen, Germany" (PDF). Palaeogeography, Palaeoclimatology, Palaeoecology. 437: 43–62. Bibcode:2015PPP...437...53R. doi:10.1016/j.palaeo.2015.07.016. S2CID 126619743. Retrieved 17 October 2023.
  121. ^ Tschudy, R. H.; Tschudy, B. D. (1986). "Extinction and survival of plant life following the Cretaceous/Tertiary boundary event, Western Interior, North America". Geology. 14 (8): 667–670. Bibcode:1986Geo....14..667T. doi:10.1130/0091-7613(1986)14<667:EASOPL>2.0.CO;2.
  122. ^ Vajda, V.; Bercovici, A. (2014). "The global vegetation pattern across the Cretaceous–Paleogene mass extinction interval: A template for other extinction events". Global and Planetary Change. 122: 24–49. Bibcode:2014GPC...122...29V. doi:10.1016/j.gloplacha.2014.07.014.
  123. ^ Barreda, Viviana D.; Cúneo, Nestor R.; Wilf, Peter; Currano, Ellen D.; Scasso, Roberto A.; Brinkhuis, Henk (17 December 2012). Newsom, Lee A. (ed.). "Cretaceous/Paleogene Floral Turnover in Patagonia: Drop in Diversity, Low Extinction, and a Classopollis Spike". PLOS ONE. 7 (12): e52455. Bibcode:2012PLoSO...752455B. doi:10.1371/journal.pone.0052455. ISSN 1932-6203. PMC 3524134. PMID 23285049.
  124. ^ a b c d e f Frederiksen, N. O. (1994). "Paleocene floral diversities and turnover events in eastern North America and their relation to diversity models". Review of Palaeobotany and Palynology. 82 (3–4): 225–238. Bibcode:1994RPaPa..82..225F. doi:10.1016/0034-6667(94)90077-9.
  125. ^ Vajda, V.; Raine, J. I.; Hollis, C. J. (2001). "Indication of global deforestation at the Cretaceous-Tertiary boundary by New Zealand fern spike". Science. 294 (5547): 1700–1702. Bibcode:2001Sci...294.1700V. doi:10.1126/science.1064706. PMID 11721051. S2CID 40364945.
  126. ^ Schultz, P. H.; D'Hondt, S. (1996). "Cretaceous-Tertiary (Chicxulub) impact angle and its consequences". Geology. 24 (11): 963–967. Bibcode:1996Geo....24..963S. doi:10.1130/0091-7613(1996)024<0963:CTCIAA>2.3.CO;2.
  127. ^ a b Johnson, K. R.; Ellis, B. (2002). "A Tropical Rainforest in Colorado 1.4 Million Years After the Cretaceous–Tertiary Boundary". Science. 296 (5577): 2379–2383. Bibcode:2002Sci...296.2379J. doi:10.1126/science.1072102. PMID 12089439. S2CID 11207255.
  128. ^ Wang, W.; Lin, L.; Xiang, X. (2016). "The rise of angiosperm-dominated herbaceous floras: Insights from Ranunculaceae". Scientific Reports. 6: e27259. Bibcode:2016NatSR...627259W. doi:10.1038/srep27259. PMC 4890112. PMID 27251635.
  129. ^ a b Wilf, P.; Labandeira, C. C. (1999). "Response of Plant–Insect Associations to Paleocene–Eocene Warming" (PDF). Science. 284 (5423): 2153–2156. CiteSeerX 10.1.1.304.8853. doi:10.1126/science.284.5423.2153. PMID 10381875.
  130. ^ Dilcher, D. (2000). "Toward a new synthesis: Major evolutionary trends in the angiosperm fossil record". Proceedings of the National Academy of Sciences of the United States of America. 97 (13): 7030–7036. Bibcode:2000PNAS...97.7030D. doi:10.1073/pnas.97.13.7030. PMC 34380. PMID 10860967.
  131. ^ Frederiksen, N. O. (1998). "Upper Paleocene and Lowermost Eocene Angiosperm Pollen Biostratigraphy of the Eastern Gulf Coast and Virginia". Micropaleontology. 44 (1): 45–68. Bibcode:1998MiPal..44...45F. doi:10.2307/1486084. JSTOR 1486084.
  132. ^ a b c d Askin, R. A.; Spicer, R. A. (1995). "The Late Cretaceous and Cenozoic History of Vegetation and Climate at Northern and Southern High Latitudes: A Comparison". Effects of Past Global Change on Life. National Academy Press. pp. 156–173.
  133. ^ Tosolini, A.; Cantrill, D. J.; Francis, J. E. (2013). "Paleocene flora from Seymour Island, Antarctica: Revision of Dusén's (1908) angiosperm taxa". Alcheringa: An Australasian Journal of Palaeontology. 37 (3): 366–391. Bibcode:2013Alch...37..366T. doi:10.1080/03115518.2013.764698. S2CID 87955445.
  134. ^ a b Angst D, Lécuyer C, Amiot R, Buffetaut E, Fourel F, Martineau F, Legendre S, Abourachid A, Herrel A (2014). "Isotopic and anatomical evidence of an herbivorous diet in the Early Tertiary giant bird Gastornis. Implications for the structure of Paleocene terrestrial ecosystems". Naturwissenschaften. 101 (4): 313–322. Bibcode:2014NW....101..313A. doi:10.1007/s00114-014-1158-2. PMID 24563098. S2CID 18518649.
  135. ^ Lucas, S. G. (1998). "Pantodonta". In Janis, C. M.; Scott, K. M.; Jacobs, L. L.; Gunnel, G. F.; Uhen, M. D. (eds.). Evolution of Mammals of North America. Cambridge University Press. p. 274. ISBN 978-0-521-35519-3.
  136. ^ a b Maor, R.; Dayan, T.; Ferguson-Gow, H.; Jones, K. E. (2017). "Temporal niche expansion in mammals from a nocturnal ancestor after dinosaur extinction". Nature Ecology and Evolution. 1 (12): 1889–1895. Bibcode:2017NatEE...1.1889M. doi:10.1038/s41559-017-0366-5. PMID 29109469. S2CID 20732677.
  137. ^ Close, R. A.; Friedman, M.; Lloyd, G. T.; Benson, R. B. J. (2015). "Evidence for a Mid-Jurassic Adaptive Radiation in Mammals". Current Biology. 25 (16): 2, 137–2, 142. doi:10.1016/j.cub.2015.06.047. PMID 26190074. S2CID 527196.
  138. ^ Hu, Y.; Meng, J.; Wang, Y.; Li, C. (2005). "Large Mesozoic mammals fed on young dinosaurs" (PDF). Nature. 433 (7022): 149–152. Bibcode:2005Natur.433..149H. doi:10.1038/nature03102. PMID 15650737. S2CID 2306428.
  139. ^ Wilson, G. P.; Evans, A. R.; Corfe, I. J.; Smits, P. D.; Fortelius, M.; Jernvall, J. (2012). "Adaptive radiation of multituberculate mammals before the extinction of dinosaurs" (PDF). Nature. 483 (7390): 457–460. Bibcode:2012Natur.483..457W. doi:10.1038/nature10880. PMID 22419156. S2CID 4419772. (PDF) from the original on 12 August 2017.
  140. ^ Hunter, J. P. (1999). "The radiation of Paleocene mammals with the demise of the dinosaurs: Evidence from southwestern North Dakota". Proceedings of the North Dakota Academy of Sciences. 53.
  141. ^ Alroy, John; Waddell, P. (March 1999). (PDF). Systematic Biology. 48 (1): 107–118. doi:10.1080/106351599260472. PMID 12078635. Archived from the original (PDF) on 10 August 2017. Retrieved 8 January 2020.
  142. ^ Luo, Z.-X.; Ji, Q.; Wible, J. R.; Yuan, C.-X. (2003). "An early Cretaceous tribosphenic mammal and metatherian evolution". Science. 302 (5652): 1934–1940. Bibcode:2003Sci...302.1934L. doi:10.1126/science.1090718. PMID 14671295. S2CID 18032860.
  143. ^ Williamson, T. E.; Taylor, L. (2011). "New species of Peradectes and Swaindelphys (Mammalia: Metatheria) from the Early Paleocene (Torrejonian) Nacimiento Formation, San Juan Basin, New Mexico, USA". Palaeontologia Electronica. 14 (3).
  144. ^ Pascual, R.; Archer, M.; Ortiz-Jaureguizar, E.; Prado, J. L.; Goldthep, H.; Hand, S. J. (1992). "First discovery of monotremes in South America". Nature. 356 (6371): 704–706. Bibcode:1992Natur.356..704P. doi:10.1038/356704a0. S2CID 4350045.
  145. ^ Musser, A. M. (2003). "Review of the monotreme fossil record and comparison of palaeontological and molecular data". Comparative Biochemistry and Physiology A. 136 (4): 927–942. doi:10.1016/s1095-6433(03)00275-7. PMID 14667856. from the original on 4 March 2016.
  146. ^ a b Halliday, T. J. D.; Upchurch, P.; Goswami, A. (2017). "Resolving the relationships of Paleocene placental mammals". Biological Reviews. 92 (1): 521–550. doi:10.1111/brv.12242. PMC 6849585. PMID 28075073.
  147. ^ Grossnickle, D. M.; Newham, E. (2016). "Therian mammals experience an ecomorphological radiation during the Late Cretaceous and selective extinction at the K–Pg boundary". Proceedings of the Royal Society B. 283 (1832): 20160256. doi:10.1098/rspb.2016.0256. PMC 4920311.
  148. ^ Janis, C. M. (2005). Sues, H. (ed.). Evolution of Herbivory in Terrestrial Vertebrates: Perspectives from the Fossil Record. Cambridge University Press. p. 182. ISBN 978-0-521-02119-7.
  149. ^ O'Leary, M. A.; Lucas, S. G.; Williamson, T. E. (1999). "A new specimen of Ankalagon (Mammalia, Mesonychia) and evidence of sexual dimorphism in mesonychians". Journal of Vertebrate Paleontology. 20 (2): 387–393. doi:10.1671/0272-4634(2000)020[0387:ANSOAM]2.0.CO;2. S2CID 86542114.
  150. ^ Zhou, X.; Zhai, R.; Gingerich, P. D.; Chen, L. (1995). "Skull of a New Mesonychid (Mammalia, Mesonychia) from the Late Paleocene of China" (PDF). Journal of Vertebrate Paleontology. 15 (2): 387–400. Bibcode:1995JVPal..15..387Z. doi:10.1080/02724634.1995.10011237. (PDF) from the original on 4 March 2016. Retrieved 27 August 2019.
  151. ^ Suh, A.; Smeds, L.; Ellegren, H. (2015). "The dynamics of incomplete lineage sorting across the ancient adaptive radiation of Neoavian birds". PLOS Biology. 13 (8): e1002224. doi:10.1371/journal.pbio.1002224. PMC 4540587. PMID 26284513.
  152. ^ a b Ksepka, D. T.; Stidham, T. A.; Williamson, T. E. (2017). "Early Paleocene landbird supports rapid phylogenetic and morphological diversification of crown birds after the K–Pg mass extinction". Proceedings of the National Academy of Sciences. 114 (30): 8047–8052. Bibcode:2017PNAS..114.8047K. doi:10.1073/pnas.1700188114. PMC 5544281. PMID 28696285.
  153. ^ Mourer-Chauviré, C. (1994). "A Large Owl from the Paleocene of France" (PDF). Palaeontology. 37 (2): 339–348. (PDF) from the original on 25 August 2019.
  154. ^ Rich, P. V.; Bohaska, D. J. (1981). "The Ogygoptyngidae, a new family of owls from the Paleocene of North America". Alcheringa: An Australasian Journal of Palaeontology. 5 (2): 95–102. Bibcode:1981Alch....5...95R. doi:10.1080/03115518108565424.
  155. ^ Longrich, N. R.; Tokaryk, T.; Field, D. J. (2011). "Mass extinction of birds at the Cretaceous–Paleogene (K–Pg) boundary". Proceedings of the National Academy of Sciences of the United States of America. 108 (37): 15253–15257. Bibcode:2011PNAS..10815253L. doi:10.1073/pnas.1110395108. PMC 3174646. PMID 21914849.
  156. ^ Longrich, N. R.; Martill, D. M.; Andres, B. (2018). "Late Maastrichtian pterosaurs from North Africa and mass extinction of Pterosauria at the Cretaceous-Paleogene boundary". PLOS Biology. 16 (3): e2001663. doi:10.1371/journal.pbio.2001663. PMC 5849296. PMID 29534059.
  157. ^ Mayr, G.; Pietri, V. L. D.; Love, L.; Mannering, A.; Scofield, R. P. (2019). "Oldest, smallest and phylogenetically most basal pelagornithid, from the early Paleocene of New Zealand, sheds light on the evolutionary history of the largest flying birds". Papers in Palaeontology. 7: 217–233. doi:10.1002/spp2.1284. S2CID 203884619.
  158. ^ Witmer, Lawrence M.; Rose, Kenneth D. (8 February 2016). "Biomechanics of the jaw apparatus of the gigantic Eocene bird Diatryma: implications for diet and mode of life". Paleobiology. 17 (2): 95–120. doi:10.1017/s0094837300010435. S2CID 18212799.
  159. ^ Angst, Delphine; Buffetaut, Eric; Lécuyer, Christophe; Amiot, Romain; Farke, Andrew A. (27 November 2013). "'Terror Birds' (Phorusrhacidae) from the Eocene of Europe Imply Trans-Tethys Dispersal". PLOS ONE. 8 (11): e80357. Bibcode:2013PLoSO...880357A. doi:10.1371/journal.pone.0080357. PMC 3842325. PMID 24312212.
  160. ^ Sloan, R. E.; Rigby, K.; Van Valen, L. M.; Gabriel, D. (2 May 1986). "Gradual dinosaur extinction and simultaneous ungulate radiation in the Hell Creek formation". Science. 232 (4750): 629–633. Bibcode:1986Sci...232..629S. doi:10.1126/science.232.4750.629. PMID 17781415. S2CID 31638639.
  161. ^ Fassett JE, Lucas SG, Zielinski RA, Budahn JR (2001). "Compelling new evidence for Paleocene dinosaurs in the Ojo Alamo Sandstone, San Juan Basin, New Mexico and Colorado, USA" (PDF). Catastrophic Events and Mass Extinctions, Lunar and Planetary Contribution. 1053: 45–46. Bibcode:2001caev.conf.3139F. (PDF) from the original on 5 June 2011.
  162. ^ Sullivan, R. M. (2003). "No Paleocene dinosaurs in the San Juan Basin, New Mexico". Geological Society of America Abstracts with Programs. 35 (5): 15. from the original on 8 April 2011.
  163. ^ Longrich, N. R.; Bhullar, B. S.; Gauthier, J. A. (2012). "Mass extinction of lizards and snakes at the Cretaceous–Paleogene boundary". Proceedings of the National Academy of Sciences. 109 (52): 21396–21401. Bibcode:2012PNAS..10921396L. doi:10.1073/pnas.1211526110. PMC 3535637. PMID 23236177.
  164. ^ Head, J. J.; Bloch, J. I.; Moreno-Bernal, J. W.; Rincon, A. F. (2013). Cranial osteology, Body Size, Systematics, and Ecology of the giant Paleocene Snake Titanoboa cerrejonensis. 73nd Annual Meeting of the Society of Vertebrate Paleontology, Los Angeles, California. Society of Vertebrate Paleontology. pp. 140–141.
  165. ^ Apesteguía, Sebastián; Gómez, Raúl O.; Rougier, Guillermo W. (7 October 2014). "The youngest South American rhynchocephalian, a survivor of the K/Pg extinction". Proceedings of the Royal Society B: Biological Sciences. 281 (1792): 20140811. doi:10.1098/rspb.2014.0811. ISSN 0962-8452. PMC 4150314. PMID 25143041.
  166. ^ MacLeod, N.; Rawson, P. F.; Forey, P. L.; Banner, F. T.; Boudagher-Fadel, M. K.; Bown, P. R.; Burnett, J. A.; Chambers, P.; Culver, S.; Evans, S.E.; Jeffery, C.; Kaminski, M. A.; Lord, A. R.; Milner, A. C.; Milner, A. R.; Morris, N.; Owen, E.; Rosen, B. R.; Smith, A. B.; Taylor, P. D.; Urquhart, E.; Young, J. R. (1997). "The Cretaceous–Tertiary biotic transition". Journal of the Geological Society. 154 (2): 265–292. Bibcode:1997JGSoc.154..265M. doi:10.1144/gsjgs.154.2.0265. S2CID 129654916. from the original on 7 May 2019.
  167. ^ Erickson, B. R. (2007). "Crocodile and Arthropod Tracks from the Late Paleocene Wannagan Creek Fauna of North Dakota, USA". Ichnos. 12 (4): 303–308. doi:10.1080/1042094050031111. S2CID 129085761.
  168. ^ Jouve, Stéphane; Jalil, Nour-Eddine (September 2020). "Paleocene resurrection of a crocodylomorph taxon: Biotic crises, climatic and sea level fluctuations". Gondwana Research. 85: 1–18. Bibcode:2020GondR..85....1J. doi:10.1016/j.gr.2020.03.010. S2CID 219451890.
  169. ^ Matsumoto, Ryoko; Buffetaut, Eric; Escuillie, Francois; Hervet, Sophie; Evans, Susan E. (March 2013). "New material of the choristodere Lazarussuchus (Diapsida, Choristodera) from the Paleocene of France". Journal of Vertebrate Paleontology. 33 (2): 319–339. Bibcode:2013JVPal..33..319M. doi:10.1080/02724634.2012.716274. ISSN 0272-4634. S2CID 129438118. Retrieved 23 September 2023.
  170. ^ Matsumoto, R.; Evans, S. E. (2010). "Choristoderes and the freshwater assemblages of Laurasia". Journal of Iberian Geology. 36 (2): 253–274. Bibcode:2010JIbG...36..253M. doi:10.5209/rev_JIGE.2010.v36.n2.11.
  171. ^ Weems, R. E. (1988). "Paleocene turtles from the Aquia and Brightseat Formations, with a discussion of their bearing on sea turtle evolution and phylogeny". Proceedings of the Biological Society of Washington. 101 (1): 109–145.
  172. ^ Novacek, M. J. (1999). "100 Million Years of Land Vertebrate Evolution: The Cretaceous–Early Tertiary Transition". Annals of the Missouri Botanical Garden. 86 (2): 230–258. doi:10.2307/2666178. JSTOR 2666178.
  173. ^ Cadena, E. A.; Ksepka, D. T.; Jaramillo, C. A.; Bloch, J. I. (2012). "New pelomedusoid turtles from the late Palaeocene Cerrejón Formation of Colombia and their implications for phylogeny and body size evolution". Journal of Systematic Palaeontology. 10 (2): 313. Bibcode:2012JSPal..10..313C. doi:10.1080/14772019.2011.569031. S2CID 59406495.
  174. ^ Sheehan, P. M.; Fastovsky, D. E. (1992). "Major extinctions of land-dwelling vertebrates at the Cretaceous–Tertiary boundary, Eastern Montana". Geology. 20 (6): 556–560. Bibcode:1992Geo....20..556S. doi:10.1130/0091-7613(1992)020<0556:meoldv>2.3.co;2.
  175. ^ Archibald, J D; Bryant, L J (1990). "Differential Cretaceous–Tertiary extinction of nonmarine vertebrates; evidence from northeastern Montana". In Sharpton, V L; Ward, P D (eds.). Global Catastrophes in Earth History: an Interdisciplinary Conference on Impacts, Volcanism, and Mass Mortality. Geological Society of America, Special Paper. Vol. 247. pp. 549–562. doi:10.1130/spe247-p549. ISBN 978-0-8137-2247-4.
  176. ^ Rage, J. (2001). "Oldest Bufonidae (Amphibia, Anura) from the Old World: a bufonid from the Paleocene of France" (PDF). Journal of Vertebrate Paleontology. 23 (2): 462–463. doi:10.1671/0272-4634(2003)023[0462:OBAAFT]2.0.CO;2. S2CID 86030507.
  177. ^ Gardner JD. Revised taxonomy of albanerpetontid amphibians. Acta Palaeontol Pol. 2000;45:55–70.
  178. ^ a b c Sibert, E. C.; Norris, R. D. (2015). "New Age of Fishes initiated by the Cretaceous−Paleogene mass extinction". Proceedings of the National Academy of Sciences. 112 (28): 8537–8542. Bibcode:2015PNAS..112.8537S. doi:10.1073/pnas.1504985112. PMC 4507219. PMID 26124114.
  179. ^ a b Miya, M.; Friedman, M.; Satoh, T. P. (2013). "Evolutionary origin of the Scombridae (tunas and mackerels): members of a paleogene adaptive radiation with 14 other pelagic fish families". PLOS ONE. 8 (9): e73535. Bibcode:2013PLoSO...873535M. doi:10.1371/journal.pone.0073535. PMC 3762723. PMID 24023883.
  180. ^ a b c Friedman, M. (2010). "Explosive morphological diversification of spiny-finned teleost fishes in the aftermath of the end-Cretaceous extinction". Proceedings of the Royal Society B. 277 (1688): 1675–1683. doi:10.1098/rspb.2009.2177. PMC 2871855. PMID 20133356.
  181. ^ Santini, F.; Carnevale, G.; Sorenson, L. (2015). "First timetree of Sphyraenidae (Percomorpha) reveals a Middle Eocene crown age and an Oligo–Miocene radiation of barracudas". Italian Journal of Zoology. 82 (1): 133–142. doi:10.1080/11250003.2014.962630. S2CID 86305952.
  182. ^ Wilson, A. B.; Orr, J. W. (June 2011). "The evolutionary origins of Syngnathidae: pipefishes and seahorses". Journal of Fish Biology. 78 (6): 1603–1623. Bibcode:2011JFBio..78.1603W. doi:10.1111/j.1095-8649.2011.02988.x. PMID 21651519.
  183. ^ Harrington, R. C.; Faircloth, B. C.; Eytan, R. I.; Smith, W. L.; Near, T. J.; Alfaro, M. E.; Friedman, M. (2016). "Phylogenomic analysis of carangimorph fishes reveals flatfish asymmetry arose in a blink of the evolutionary eye". BMC Evolutionary Biology. 16 (1): 224. Bibcode:2016BMCEE..16..224H. doi:10.1186/s12862-016-0786-x. PMC 5073739. PMID 27769164.
  184. ^ Cantalice, K.; Alvarado–Ortega, J. (2016). "Eekaulostomus cuevasae gen. and sp. nov., an ancient armored trumpet fish (Aulostomoidea) from Danian (Paleocene) marine deposits of Belisario Domínguez, Chiapas, southeastern Mexico". Palaeontologia Electronica. 19. doi:10.26879/682.
  185. ^ Near, T. J. (2013). "Phylogeny and tempo of diversification in the superradiation of spiny-rayed fishes". Proceedings of the National Academy of Sciences. 110 (31): 12738–12743. Bibcode:2013PNAS..11012738N. doi:10.1073/pnas.1304661110. PMC 3732986. PMID 23858462.
  186. ^ Carnevale, G.; Johnson, G. D. (2015). "A Cretaceous Cusk-Eel (Teleostei, Ophidiiformes) from Italy and the Mesozoic Diversification of Percomorph Fishes". Copeia. 103 (4): 771–791. doi:10.1643/CI-15-236. S2CID 86033746.
  187. ^ Adolfssen, J. S.; Ward, D. J. (2013). "Neoselachians from the Danian (Early Paleocene) of Denmark" (PDF). Acta Palaeontologica Polonica. 60 (2): 313–338. doi:10.4202/app.2012.0123. S2CID 128949365.
  188. ^ Bazzi, M.; Kear, B. P.; Blom, H.; Ahlberg, P. E.; Campione, N. E. (2018). "Static Dental Disparity and Morphological Turnover in Sharks across the End-Cretaceous Mass Extinction". Current Biology. 28 (16): 2607–2615. doi:10.1016/j.cub.2018.05.093. PMID 30078565. S2CID 51893337.
  189. ^ Ehret, D. J.; Ebersole, J. (2014). "Occurrence of the megatoothed sharks (Lamniformes: Otodontidae) in Alabama, USA". PeerJ. 2: e625. doi:10.7717/peerj.625. PMC 4201945. PMID 25332848.
  190. ^ Cavender, T. M. (1998). "Development of the North American Tertiary freshwater fish fauna with a look at parallel trends found in the European record". Italian Journal of Palaeontology. 36 (1): 149–161. doi:10.1080/11250009809386807.
  191. ^ Currano, E. D.; Wilf, P.; Wing, S. C.; Labandeira, C. C.; Lovelock, E. C.; Royer, D. L. (2008). "Sharply increased insect herbivory during the Paleocene–Eocene Thermal Maximum". Proceedings of the National Academy of Sciences. 105 (6): 1960–1964. Bibcode:2008PNAS..105.1960C. doi:10.1073/pnas.0708646105. PMC 2538865. PMID 18268338.
  192. ^ Wedmann, S.; Uhl, D.; Lehmann, T.; Garrouste, R.; Nel, A.; Gomez, B.; Smith, K.; Schaal, S. F. K. (2018). "The Konservat-Lagerstätte Menat (Paleocene; France) – an overview and new insights" (PDF). Geologica Acta. 16 (2): 189–213. doi:10.1344/GeologicaActa2018.16.2.5. (PDF) from the original on 6 November 2019. Retrieved 6 November 2019.
  193. ^ Grimaldi, D. A.; Lillegraven, J. A.; Wampler, T. W.; Bookwalter, D.; Shredrinsky, A. (2000). "Amber from Upper Cretaceous through Paleocene strata of the Hanna Basin, Wyoming, with evidence for source and taphonomy of fossil resins". Rocky Mountain Geology. 35 (2): 163–204. Bibcode:2000RMGeo..35..163G. doi:10.2113/35.2.163.
  194. ^ Lapolla, J. S.; Barden, P. (2018). "A new aneuretine ant from the Paleocene Paskapoo Formation of Canada" (PDF). Acta Palaeontologica Polonica. 63 (3): 435–440. doi:10.4202/app.00478.2018. S2CID 55921254. (PDF) from the original on 5 October 2019.
  195. ^ Wilson, E. O.; Hölldobler, B. (2005). "The rise of the ants: A phylogenetic and ecological explanation". Proceedings of the National Academy of Sciences of the United States of America. 102 (21): 7411–7414. Bibcode:2005PNAS..102.7411W. doi:10.1073/pnas.0502264102. PMC 1140440. PMID 15899976.
  196. ^ Sohn, J.; Labandeira, C. C.; Davis, D. R. (2015). "The fossil record and taphonomy of butterflies and moths (Insecta, Lepidoptera): implications for evolutionary diversity and divergence-time estimates". BMC Evolutionary Biology. 15 (12): 12. Bibcode:2015BMCEE..15...12S. doi:10.1186/s12862-015-0290-8. PMC 4326409. PMID 25649001.
  197. ^ ter Hofstede, H. M.; Ratcliffe, J. M. (2016). (PDF). Journal of Experimental Biology. 219 (11): 1589–1902. doi:10.1242/jeb.086686. PMID 27252453. S2CID 13590132. Archived from the original (PDF) on 16 February 2020.
  198. ^ Rehan, S. M.; Reys, R.; Schwarz, M. P. (2013). "First Evidence for a Massive Extinction Event Affecting Bees Close to the K–T Boundary". PLOS ONE. 8 (10): e76683. Bibcode:2013PLoSO...876683R. doi:10.1371/journal.pone.0076683. PMC 3806776. PMID 24194843.
  199. ^ Dehon, M.; Perrard, A.; Engel, M. S.; Nel, A.; Michez, D. (2017). "Antiquity of cleptoparasitism among bees revealed by morphometric and phylogenetic analysis of a Paleocene fossil nomadine (Hymenoptera: Apidae)". Systematic Entomology. 42 (3): 543–554. Bibcode:2017SysEn..42..543D. doi:10.1111/syen.12230. S2CID 73595252.
  200. ^ Pen

February 16, 2024
paleocene, confused, with, paleogene, seen, palaeocene, geological, epoch, that, lasted, from, about, million, years, first, epoch, paleogene, period, modern, cenozoic, name, combination, ancient, greek, παλαιός, palaiós, meaning, eocene, epoch, which, succeed. Not to be confused with Paleogene The Paleocene IPA ˈ p ae l i e s iː n i oʊ ˈ p eɪ l i PAL ee e seen ee oh PAY lee 4 or Palaeocene is a geological epoch that lasted from about 66 to 56 million years ago mya It is the first epoch of the Paleogene Period in the modern Cenozoic Era The name is a combination of the Ancient Greek palaios palaios meaning old and the Eocene Epoch which succeeds the Paleocene translating to the old part of the Eocene Paleocene66 0 56 0 Ma PreꞒ Ꞓ O S D C P T J K Pg NChronology 66 65 64 63 62 61 60 59 58 57 56 MZCenozoicKP a l e o g e n eLate KP a l e o c e n eEoceneDanianSelandianThanetian K Pg massextinction PETMAges of the Paleocene Epoch according to the ICS as ofJanuary 2020 1 Axis scale millions of years ago EtymologyName formalityFormalName ratified1978Alternate spelling s PalaeoceneUsage informationRegional usageGlobal ICS Time scale s usedICS Time ScaleDefinitionChronological unitEpochStratigraphic unitSeriesFirst proposed byWilhelm Philipp Schimper 1874Time span formalityFormalLower boundary definitionIridium enriched layer associated with a major meteorite impact and subsequent K Pg extinction event 2 Lower boundary GSSPEl Kef Section El Kef Tunisia36 09 13 N 8 38 55 E 36 1537 N 8 6486 E 36 1537 8 6486 2 Lower GSSP ratified1991 2 Upper boundary definitionStrong negative anomaly in d13C values at the PETM 3 Upper boundary GSSPDababiya section Luxor Egypt 3 25 30 00 N 32 31 52 E 25 5000 N 32 5311 E 25 5000 32 5311Upper GSSP ratified2003 3 The epoch is bracketed by two major events in Earth s history The K Pg extinction event brought on by an asteroid impact Chicxulub impact and possibly volcanism Deccan Traps marked the beginning of the Paleocene and killed off 75 of species most famously the non avian dinosaurs The end of the epoch was marked by the Paleocene Eocene Thermal Maximum PETM which was a major climatic event wherein about 2 500 4 500 gigatons of carbon were released into the atmosphere and ocean systems causing a spike in global temperatures and ocean acidification In the Paleocene the continents of the Northern Hemisphere were still connected via some land bridges and South America Antarctica and Australia had not completely separated yet The Rocky Mountains were being uplifted the Americas had not yet joined the Indian Plate had begun its collision with Asia and the North Atlantic Igneous Province was forming in the third largest magmatic event of the last 150 million years In the oceans the thermohaline circulation probably was much different from what it is today with downwellings occurring in the North Pacific rather than the North Atlantic and water density mainly being controlled by salinity rather than temperature The K Pg extinction event caused a floral and faunal turnover of species with previously abundant species being replaced by previously uncommon ones In the Paleocene with a global average temperature of about 24 25 C 75 77 F compared to 14 C 57 F in more recent times the Earth had a greenhouse climate without permanent ice sheets at the poles like the preceding Mesozoic As such there were forests worldwide including at the poles but they had low species richness in regards to plant life and were populated by mainly small creatures that were rapidly evolving to take advantage of the recently emptied Earth Though some animals attained great size most remained rather small The forests grew quite dense in the general absence of large herbivores Mammals proliferated in the Paleocene and the earliest placental and marsupial mammals are recorded from this time but most Paleocene taxa have ambiguous affinities In the seas ray finned fish rose to dominate open ocean and recovering reef ecosystems Contents 1 Etymology 2 Geology 2 1 Boundaries 2 2 Stratigraphy 2 3 Mineral and hydrocarbon deposits 2 4 Impact craters 3 Paleogeography 3 1 Paleotectonics 3 2 Paleoceanography 4 Climate 4 1 Average climate 4 2 Climatic events 4 2 1 Paleocene Eocene Thermal Maximum 5 Flora 5 1 Recovery 5 2 Angiosperms 5 3 Polar forests 6 Fauna 6 1 Mammals 6 2 Birds 6 3 Reptiles 6 4 Amphibians 6 5 Fish 6 6 Insects and arachnids 6 7 Marine invertebrates 7 See also 8 Notes 9 References 10 External linksEtymology edit nbsp Portrait of Wilhelm Philipp Schimper who coined the term Paleocene The word Paleocene was first used by French paleobotanist and geologist Wilhelm Philipp Schimper in 1874 while describing deposits near Paris spelled Paleocene in his treatise 5 6 By this time Italian geologist Giovanni Arduino had divided the history of life on Earth into the Primary Paleozoic Secondary Mesozoic and Tertiary in 1759 French geologist Jules Desnoyers had proposed splitting off the Quaternary from the Tertiary in 1829 7 and Scottish geologist Charles Lyell ignoring the Quaternary had divided the Tertiary Epoch into the Eocene Miocene Pliocene and New Pliocene Holocene Periods in 1833 8 n 1 British geologist John Phillips had proposed the Cenozoic in 1840 in place of the Tertiary 9 and Austrian paleontologist Moritz Hornes had introduced the Paleogene for the Eocene and Neogene for the Miocene and Pliocene in 1853 10 After decades of inconsistent usage the newly formed International Commission on Stratigraphy ICS in 1969 standardized stratigraphy based on the prevailing opinions in Europe the Cenozoic Era subdivided into the Tertiary and Quaternary sub eras and the Tertiary subdivided into the Paleogene and Neogene Periods 11 In 1978 the Paleogene was officially defined as the Paleocene Eocene and Oligocene Epochs and the Neogene as the Miocene and Pliocene Epochs 12 In 1989 Tertiary and Quaternary were removed from the time scale due to the arbitrary nature of their boundary but Quaternary was reinstated in 2009 13 The term Paleocene is a portmanteau combination of the Ancient Greek palaios palaios meaning old and the word Eocene and so means the old part of the Eocene The Eocene in turn is derived from Ancient Greek eo eos ἠws meaning dawn and cene kainos kainos meaning new or recent as the epoch saw the dawn of recent or modern life Paleocene did not come into broad usage until around 1920 In North America and mainland Europe the standard spelling is Paleocene whereas it is Palaeocene in the UK Geologist T C R Pulvertaft has argued that the latter spelling is incorrect because this would imply either a translation of old recent or a derivation from pala and Eocene which would be incorrect because the prefix palaeo uses the ligature ae instead of a and e individually so only both characters or neither should be dropped not just one 6 Geology editBoundaries edit nbsp K Pg boundary recorded in a Wyoming rock the white stripe in the middle The Paleocene Epoch is the 10 million year time interval directly after the K Pg extinction event which ended the Cretaceous Period and the Mesozoic Era and initiated the Cenozoic Era and the Paleogene Period It is divided into three ages the Danian spanning 66 to 61 6 million years ago mya the Selandian spanning 61 6 to 59 2 mya and the Thanetian spanning 59 2 to 56 mya It is succeeded by the Eocene 14 The K Pg boundary is clearly defined in the fossil record in numerous places around the world by a high iridium band as well as discontinuities with fossil flora and fauna It is generally thought that a 10 to 15 km 6 to 9 mi wide asteroid impact forming the Chicxulub Crater in the Yucatan Peninsula in the Gulf of Mexico and Deccan Trap volcanism caused a cataclysmic event at the boundary resulting in the extinction of 75 of all species 15 16 17 18 The Paleocene ended with the Paleocene Eocene thermal maximum a short period of intense warming and ocean acidification brought about by the release of carbon en masse into the atmosphere and ocean systems 19 which led to a mass extinction of 30 50 of benthic foraminifera planktonic species which are used as bioindicators of the health of a marine ecosystem one of the largest in the Cenozoic 20 21 This event happened around 55 8 mya and was one of the most significant periods of global change during the Cenozoic 19 22 23 Stratigraphy edit Geologists divide the rocks of the Paleocene into a stratigraphic set of smaller rock units called stages each formed during corresponding time intervals called ages Stages can be defined globally or regionally For global stratigraphic correlation the ICS ratify global stages based on a Global Boundary Stratotype Section and Point GSSP from a single formation a stratotype identifying the lower boundary of the stage In 1989 the ICS decided to split the Paleocene into three stages the Danian Selandian and Thanetian 24 The Danian was first defined in 1847 by German Swiss geologist Pierre Jean Edouard Desor based on the Danish chalks at Stevns Klint and Faxse and was part of the Cretaceous succeeded by the Tertiary Montian Stage 25 26 In 1982 after it was shown that the Danian and the Montian are the same the ICS decided to define the Danian as starting with the K Pg boundary thus ending the practice of including the Danian in the Cretaceous In 1991 the GSSP was defined as a well preserved section in the El Haria Formation near El Kef Tunisia 36 09 13 N 8 38 55 E 36 1537 N 8 6486 E 36 1537 8 6486 and the proposal was officially published in 2006 27 nbsp The sea cliffs of Itzurun beach near the town of Zumaia Spain the GSSP for the Selandian and ThanetianThe Selandian and Thanetian are both defined in Itzurun beach by the Basque town of Zumaia 43 18 02 N 2 15 34 W 43 3006 N 2 2594 W 43 3006 2 2594 as the area is a continuous early Santonian to early Eocene sea cliff outcrop The Paleocene section is an essentially complete exposed record 165 m 541 ft thick mainly composed of alternating hemipelagic sediments deposited at a depth of about 1 000 m 3 300 ft The Danian deposits are sequestered into the Aitzgorri Limestone Formation and the Selandian and early Thanetian into the Itzurun Formation The Itzurun Formation is divided into groups A and B corresponding to the two stages respectively The two stages were ratified in 2008 and this area was chosen because of its completion low risk of erosion proximity to the original areas the stages were defined accessibility and the protected status of the area due to its geological significance 24 The Selandian was first proposed by Danish geologist Alfred Rosenkrantz in 1924 based on a section of fossil rich glauconitic marls overlain by gray clay which unconformably overlies Danian chalk and limestone The area is now subdivided into the AEbelo Formation Holmehus Formation and the Osterrende Clay The beginning of this stage was defined by the end of carbonate rock deposition from an open ocean environment in the North Sea region which had been going on for the previous 40 million years The Selandian deposits in this area are directly overlain by the Eocene Fur Formation the Thanetian was not represented here and this discontinuity in the deposition record is why the GSSP was moved to Zumaia Today the beginning of the Selandian is marked by the appearances of the nannofossils Fasciculithus tympaniformis Neochiastozygus perfectus and Chiasmolithus edentulus though some foraminifera are used by various authors 24 The Thanetian was first proposed by Swiss geologist Eugene Renevier in 1873 he included the south England Thanet Woolwich and Reading formations In 1880 French geologist Gustave Frederic Dollfus narrowed the definition to just the Thanet Formation The Thanetian begins a little after the mid Paleocene biotic event 24 a short lived climatic event caused by an increase in methane 28 recorded at Itzurun as a dark 1 m 3 3 ft interval from a reduction of calcium carbonate At Itzurun it begins about 29 m 95 ft above the base of the Selandian and is marked by the first appearance of the algae Discoaster and a diversification of Heliolithus though the best correlation is in terms of paleomagnetism A chron is the occurrence of a geomagnetic reversal when the North and South poles switch polarities Chron 1 C1n is defined as modern day to about 780 000 years ago and the n denotes normal as in the polarity of today and an r reverse for the opposite polarity 29 The beginning of the Thanetian is best correlated with the C26r C26n reversal 24 Mineral and hydrocarbon deposits edit nbsp Paleocene coal is extracted at the Cerrejon mine the world s largest open pit mineSeveral economically important coal deposits formed during the Paleocene such as the sub bituminous Fort Union Formation in the Powder River Basin of Wyoming and Montana 30 which produces 43 of American coal 31 the Wilcox Group in Texas the richest deposits of the Gulf Coastal Plain 32 and the Cerrejon mine in Colombia the largest open pit mine in the world 33 Paleocene coal has been mined extensively in Svalbard Norway since near the beginning of the 20th century 34 and late Paleocene and early Eocene coal is widely distributed across the Canadian Arctic Archipelago 35 and northern Siberia 36 In the North Sea Paleocene derived natural gas reserves when they were discovered totaled approximately 2 23 trillion m3 7 89 trillion ft3 and oil in place 13 54 billion barrels 37 Important phosphate deposits predominantly of francolite near Metlaoui Tunisia were formed from the late Paleocene to the early Eocene 38 Impact craters edit nbsp The crater underneath the Greenlandic Hiawatha Glacier dates to the Paleocene 58 mya 39 Impact craters formed in the Paleocene include the Connolly Basin crater in Western Australia less than 60 mya 40 the Texan Marquez crater 58 mya 41 the Greenlandic Hiawatha Glacier crater 58 mya 39 and possibly the Jordan Jabel Waqf as Suwwan crater which dates to between 56 and 37 mya 42 Vanadium rich osbornite from the Isle of Skye Scotland dating to 60 mya may be impact ejecta 43 Craters were also formed near the K Pg boundary the largest the Mexican Chicxulub crater whose impact was a major precipitator of the K Pg extinction 44 and also the Ukrainian Boltysh crater dated to 65 4 mya 45 the Canadian Eagle Butte crater though it may be younger 46 the Vista Alegre crater 47 though this may date to about 115 mya 48 Silicate glass spherules along the Atlantic coast of the U S indicate a meteor impact in the region at the PETM 49 Paleogeography editPaleotectonics edit nbsp The Laramide orogeny was caused by the subduction of oceanic crust under the North American plateDuring the Paleocene the continents continued to drift toward their present positions 50 In the Northern Hemisphere the former components of Laurasia North America and Eurasia were at times connected via land bridges Beringia at 65 5 and 58 mya between North America and East Asia the De Geer route from 71 to 63 mya between Greenland and Scandinavia the Thulean route at 57 and 55 8 mya between North America and Western Europe via Greenland and the Turgai route connecting Europe with Asia which were otherwise separated by the Turgai Strait at this time 51 52 The Laramide orogeny which began in the Late Cretaceous continued to uplift the Rocky Mountains it ended at the end of the Paleocene 53 Because of this and a drop in sea levels resulting from tectonic activity the Western Interior Seaway which had divided the continent of North America for much of the Cretaceous had receded 54 Between about 60 5 and 54 5 mya there was heightened volcanic activity in the North Atlantic region the third largest magmatic event in the last 150 million years creating the North Atlantic Igneous Province 55 56 The proto Iceland hotspot is sometimes cited as being responsible for the initial volcanism though rifting and resulting volcanism have also contributed 56 57 58 This volcanism may have contributed to the opening of the North Atlantic Ocean and seafloor spreading the divergence of the Greenland Plate from the North American Plate 59 and climatically the PETM by dissociating methane clathrate crystals on the seafloor resulting in the mass release of carbon 55 60 North and South America remained separated by the Central American Seaway though an island arc the South Central American Arc had already formed about 73 mya The Caribbean Large Igneous Province now the Caribbean Plate which had formed from the Galapagos hotspot in the Pacific in the latest Cretaceous was moving eastward as the North American and South American plates were getting pushed in the opposite direction due to the opening of the Atlantic strike slip tectonics 61 62 This motion would eventually uplift the Isthmus of Panama by 2 6 mya The Caribbean Plate continued moving until about 50 mya when it reached its current position 63 nbsp The breakup of Gondwana A Early Cretaceous B Late Cretaceous C Paleocene D PresentThe components of the former southern supercontinent Gondwanaland in the Southern Hemisphere continued to drift apart but Antarctica was still connected to South America and Australia Africa was heading north towards Europe and the Indian subcontinent towards Asia which would eventually close the Tethys Ocean 50 The Indian and Eurasian Plates began colliding in the Paleocene 64 with uplift and a land connection beginning in the Miocene about 24 17 mya There is evidence that some plants and animals could migrate between India and Asia during the Paleocene possibly via intermediary island arcs 65 Paleoceanography edit In the modern thermohaline circulation warm tropical water becomes colder and saltier at the poles and sinks downwelling or deep water formation that occurs at the North Atlantic near the North Pole and the Southern Ocean near the Antarctic Peninsula In the Paleocene the waterways between the Arctic Ocean and the North Atlantic were somewhat restricted so North Atlantic Deep Water NADW and the Atlantic Meridional Overturning Circulation AMOC which circulates cold water from the Arctic towards the equator had not yet formed and so deep water formation probably did not occur in the North Atlantic The Arctic and Atlantic would not be connected by sufficiently deep waters until the early to middle Eocene 66 There is evidence of deep water formation in the North Pacific to at least a depth of about 2 900 m 9 500 ft The elevated global deep water temperatures in the Paleocene may have been too warm for thermohaline circulation to be predominately heat driven 67 68 It is possible that the greenhouse climate shifted precipitation patterns such that the Southern Hemisphere was wetter than the Northern or the Southern experienced less evaporation than the Northern In either case this would have made the Northern more saline than the Southern creating a density difference and a downwelling in the North Pacific traveling southward 67 Deep water formation may have also occurred in the South Atlantic 69 It is largely unknown how global currents could have affected global temperature The formation of the Northern Component Waters by Greenland in the Eocene the predecessor of the AMOC may have caused an intense warming in the North Hemisphere and cooling in the Southern as well as an increase in deep water temperatures 66 In the PETM it is possible deep water formation occurred in saltier tropical waters and moved polewards which would increase global surface temperatures by warming the poles 21 68 Also Antarctica was still connected to South America and Australia and because of this the Antarctic Circumpolar Current which traps cold water around the continent and prevents warm equatorial water from entering had not yet formed Its formation may have been related in the freezing of the continent 70 Warm coastal upwellings at the poles would have inhibited permanent ice cover 68 Conversely it is possible deep water circulation was not a major contributor to the greenhouse climate and deep water temperatures more likely change as a response to global temperature change rather than affecting it 67 68 In the Arctic coastal upwelling may have been largely temperature and wind driven In summer the land surface temperature was probably higher than oceanic temperature and the opposite was true in the winter which is consistent with monsoon seasons in Asia Open ocean upwelling may have also been possible 68 Climate editAverage climate edit nbsp nbsp Global average land above and deep sea below temperatures throughout the Cenozoic The Paleocene climate was much like in the Cretaceous tropical or subtropical 71 72 73 and the poles were temperate 74 with an average global temperature of roughly 24 25 C 75 77 F 75 For comparison the average global temperature for the period between 1951 and 1980 was 14 C 57 F 76 The latitudinal temperature gradient was approximately 0 24 C per degree of latitude 77 The poles also lacked ice caps 78 though some alpine glaciation did occur in the Transantarctic Mountains 79 The poles probably had a cool temperate climate northern Antarctica Australia the southern tip of South America what is now the US and Canada eastern Siberia and Europe warm temperate middle South America southern and northern Africa South India Middle America and China arid and northern South America central Africa North India middle Siberia and what is now the Mediterranean Sea tropical 80 South central North America had a humid monsoonal climate along its coastal plain but conditions were drier to the west and at higher altitudes 81 Global deep water temperatures in the Paleocene likely ranged from 8 12 C 46 54 F 67 68 compared to 0 3 C 32 37 F in modern day 82 Based on the upper limit average sea surface temperatures SSTs at 60 N and S would have been the same as deep sea temperatures at 30 N and S about 23 C 73 F and at the equator about 28 C 82 F 68 In the Danish Palaeocene sea SSTs were cooler than those of the preceding Late Cretaceous and the succeeding Eocene 83 The Paleocene foraminifera assemblage globally indicates a defined deep water thermocline a warmer mass of water closer to the surface sitting on top of a colder mass nearer the bottom persisting throughout the epoch 84 The Atlantic foraminifera indicate a general warming of sea surface temperature with tropical taxa present in higher latitude areas until the Late Paleocene when the thermocline became steeper and tropical foraminifera retreated back to lower latitudes 85 Early Paleocene atmospheric CO2 levels at what is now Castle Rock Colorado were calculated to be between 352 and 1 110 parts per million ppm with a median of 616 ppm Based on this and estimated plant gas exchange rates and global surface temperatures the climate sensitivity was calculated to be 3 C when CO2 levels doubled compared to 7 C following the formation of ice at the poles CO2 levels alone may have been insufficient in maintaining the greenhouse climate and some positive feedbacks must have been active such as some combination of cloud aerosol or vegetation related processes 86 A 2019 study identified changes in orbital eccentricity as the dominant drivers of climate between the late Cretaceous and the early Eocene 87 Climatic events edit The effects of the meteor impact and volcanism 66 mya and the climate across the K Pg boundary were likely fleeting and climate reverted to normal in a short time frame 88 The freezing temperatures probably reversed after three years 89 and returned to normal within decades 90 sulfuric acid aerosols causing acid rain probably dissipated after 10 years 91 and dust from the impact blocking out sunlight and inhibiting photosynthesis would have lasted up to a year 92 though potential global wildfires raging for several years would have released more particulates into the atmosphere 93 For the following half million years the carbon isotope gradient a difference in the 13C 12C ratio between surface and deep ocean water causing carbon to cycle into the deep sea may have shut down This termed a Strangelove ocean indicates low oceanic productivity 94 resultant decreased phytoplankton activity may have led to a reduction in cloud seeds and thus marine cloud brightening causing global temperatures to increase by 6 C CLAW hypothesis 95 The Dan C2 Event 65 2 mya in the early Danian spanned about 100 000 years and was characterized by an increase in carbon particularly in the deep sea Since the mid Maastrichtian more and more carbon had been sequestered in the deep sea possibly due to a global cooling trend and increased circulation into the deep sea The Dan C2 event may represent a release of this carbon after deep sea temperatures rose to a certain threshold as warmer water can dissolve a lesser amount of carbon 96 Savanna may have temporarily displaced forestland in this interval 97 Following the extreme disruptions in the aftermath of the K Pg extinction event the relatively cool though still greenhouse conditions of the Late Cretaceous Early Palaeogene Cool Interval LKEPCI that began in the Late Cretaceous continued 98 Around 62 2 mya in the late Danian there was a warming event and evidence of ocean acidification associated with an increase in carbon 99 at this time there was major seafloor spreading in the Atlantic and volcanic activity along the southeast margin of Greenland The Latest Danian Event also known as the Top Chron C27n Event lasted about 200 000 years and resulted in a 1 6 2 8 C increase in temperatures throughout the water column Though the temperature in the latest Danian varied at about the same magnitude this event coincides with an increase of carbon 100 About 60 5 mya at the Danian Selandian boundary there is evidence of anoxia spreading out into coastal waters and a drop in sea levels which is most likely explained as an increase in temperature and evaporation as there was no ice at the poles to lock up water 101 During the mid Palaeocene biotic event MPBE also known as the Early Late Palaeocene Event ELPE 102 103 around 59 Ma roughly 50 000 years before the Selandian Thanetian boundary the temperature spiked probably due to a mass release of the deep sea methane hydrate into the atmosphere and ocean systems Carbon was probably output for 10 11 000 years and the aftereffects likely subsided around 52 53 000 years later 104 There is also evidence this occurred again 300 000 years later in the early Thanetian dubbed MPBE 2 Respectively about 83 and 132 gigatons of methane derived carbon were ejected into the atmosphere which suggests a 2 3 C 3 6 5 4 F rise in temperature and likely caused heightened seasonality and less stable environmental conditions It may have also caused an increase of grass in some areas 28 From 59 7 to 58 1 Ma during the late Selandian and early Thanetian organic carbon burial resulted in a period of climatic cooling sea level fall and transient ice growth This interval saw the highest d18O values of the epoch 105 Paleocene Eocene Thermal Maximum edit Main article Paleocene Eocene Thermal Maximum The Paleocene Eocene Thermal Maximum was an approximately 200 000 year long event where the global average temperature rose by some 5 to 8 C 9 to 14 F 55 and mid latitude and polar areas may have exceeded modern tropical temperatures of 24 29 C 75 84 F 106 This was due to an ejection of 2 500 4 500 gigatons of carbon into the atmosphere most commonly explained as the perturbation and release of methane clathrate deposits in the North Atlantic from tectonic activity and resultant increase in bottom water temperatures 55 Other proposed hypotheses include methane release from the heating of organic matter at the seafloor rather than methane clathrates 107 108 or melting permafrost 109 The duration of carbon output is controversial but most likely about 2 500 years 110 This carbon also interfered with the carbon cycle and caused ocean acidification 111 112 and potentially altered 69 and slowed down ocean currents the latter leading to the expansion of oxygen minimum zones OMZs in the deep sea 113 In surface water OMZs could have also been caused from the formation of strong thermoclines preventing oxygen inflow and higher temperatures equated to higher productivity leading to higher oxygen usurpation 114 Further expanding OMZs could have caused the proliferation of sulfate reducing microorganisms which create highly toxic hydrogen sulfide H2S as a waste product During the event the volume of sulfidic water may have been 10 20 of total ocean volume in comparison to today s 1 This may have also caused chemocline upwellings along continents and the dispersal of H2S into the atmosphere 115 During the PETM there was a temporary dwarfing of mammals apparently caused by the upward excursion in temperature 116 Flora edit nbsp Restoration of a Patagonian landscape during the DanianThe warm wet climate supported tropical and subtropical forests worldwide mainly populated by conifers and broad leafed trees 117 78 In Patagonia the landscape supported tropical rainforests cloud rainforests mangrove forests swamp forests savannas and sclerophyllous forests 78 In the Colombian Cerrejon Formation fossil flora belong to the same families as modern day flora such as palm trees legumes aroids and malvales 118 and the same is true in the North Dakotan Almont Beicegel Creek such as Ochnaceae Cyclocarya and Ginkgo cranei 119 indicating the same floral families have characterized South American rainforests and the American Western Interior since the Paleocene 118 119 nbsp Reconstruction of the late Paleocene Ginkgo craneiThe extinction of large herbivorous dinosaurs may have allowed the forests to grow quite dense 74 and there is little evidence of wide open plains 117 Plants evolved several techniques to cope with high plant density such as buttressing to better absorb nutrients and compete with other plants increased height to reach sunlight larger diaspore in seeds to provide added nutrition on the dark forest floor and epiphytism where a plant grows on another plant in response to less space on the forest floor 117 Despite increasing density which could act as fuel wildfires decreased in frequency from the Cretaceous to the early Eocene as the atmospheric oxygen levels decreased to modern day levels though they may have been more intense 120 Recovery edit There was a major die off of plant species over the boundary for example in the Williston Basin of North Dakota an estimated 1 3 to 3 5 of plant species went extinct 121 The K Pg extinction event ushered in a floral turnover for example the once commonplace Araucariaceae conifers were almost fully replaced by Podocarpaceae conifers and the Cheirolepidiaceae a group of conifers that had dominated during most of the Mesozoic but had become rare during the Late Cretaceous became dominant trees in Patagonia before going extinct 122 117 123 Some plant communities such as those in eastern North America were already experiencing an extinction event in the late Maastrichtian particularly in the 1 million years before the K Pg extinction event 124 The disaster plants that refilled the emptied landscape crowded out many Cretaceous plants and resultantly many went extinct by the middle Paleocene 71 nbsp The conifer Glyptostrobus europaeus from the Canadian Paskapoo FormationThe strata immediately overlaying the K Pg extinction event are especially rich in fern fossils Ferns are often the first species to colonize areas damaged by forest fires so this fern spike may mark the recovery of the biosphere following the impact which caused blazing fires worldwide 125 126 The diversifying herb flora of the early Paleocene either represent pioneer species which re colonized the recently emptied landscape or a response to the increased amount of shade provided in a forested landscape 124 Lycopods ferns and angiosperm shrubs may have been important components of the Paleocene understory 117 In general the forests of the Paleocene were species poor and diversity did not fully recover until the end of the Paleocene 71 127 For example the floral diversity of what is now the Holarctic region comprising most of the Northern Hemisphere was mainly early members of Ginkgo Metasequoia Glyptostrobus Macginitiea Platanus Carya Ampelopsis and Cercidiphyllum 117 Patterns in plant recovery varied significantly with latitude climate and altitude For example what is now Castle Rock Colorado featured a rich rainforest only 1 4 million years after the event probably due to a rain shadow effect causing regular monsoon seasons 127 Conversely low plant diversity and a lack of specialization in insects in the Colombian Cerrejon Formation dated to 58 mya indicates the ecosystem was still recovering from the K Pg extinction event 7 million years later 118 Angiosperms edit nbsp Fossil Platanus fruit from the Canadian Paskapoo FormationFlowering plants angiosperms which had become dominant among forest taxa by the middle Cretaceous 110 90 mya 128 continued to develop and proliferate more so to take advantage of the recently emptied niches and an increase in rainfall 124 Along with them coevolved the insects that fed on these plants and pollinated them Predation by insects was especially high during the PETM 129 Many fruit bearing plants appeared in the Paleocene in particular probably to take advantage of the newly evolving birds and mammals for seed dispersal 130 In what is now the Gulf Coast angiosperm diversity increased slowly in the early Paleocene and more rapidly in the middle and late Paleocene This may have been because the effects of the K Pg extinction event were still to some extent felt in the early Paleocene the early Paleocene may not have had as many open niches early angiosperms may not have been able to evolve at such an accelerated rate as later angiosperms low diversity equates to lower evolution rates or there was not much angiosperm migration into the region in the early Paleocene 124 Over the K Pg extinction event angiosperms had a higher extinction rate than gymnosperms which include conifers cycads and relatives and pteridophytes ferns horsetails and relatives zoophilous angiosperms those that relied on animals for pollination had a higher rate than anemophilous angiosperms and evergreen angiosperms had a higher rate than deciduous angiosperms as deciduous plants can become dormant in harsh conditions 124 In the Gulf Coast angiosperms experienced another extinction event during the PETM which they recovered quickly from in the Eocene through immigration from the Caribbean and Europe During this time the climate became warmer and wetter and it is possible that angiosperms evolved to become stenotopic by this time able to inhabit a narrow range of temperature and moisture or since the dominant floral ecosystem was a highly integrated and complex closed canopy rainforest by the middle Paleocene the plant ecosystems were more vulnerable to climate change 124 There is some evidence that in the Gulf Coast there was an extinction event in the late Paleocene preceding the PETM which may have been due to the aforementioned vulnerability of complex rainforests and the ecosystem may have been disrupted by only a small change in climate 131 Polar forests edit nbsp Metasequoia occidentalis from the Canadian Scollard FormationThe warm Paleocene climate much like that of the Cretaceous allowed for diverse polar forests Whereas precipitation is a major factor in plant diversity nearer the equator polar plants had to adapt to varying light availability polar nights and midnight suns and temperatures Because of this plants from both poles independently evolved some similar characteristics such as broad leaves Plant diversity at both poles increased throughout the Paleocene especially at the end in tandem with the increasing global temperature 132 At the North Pole woody angiosperms had become the dominant plants a reversal from the Cretaceous where herbs proliferated The Iceberg Bay Formation on Ellesmere Island Nunavut latitude 75 80 N shows remains of a late Paleocene dawn redwood forest the canopy reaching around 32 m 105 ft and a climate similar to the Pacific Northwest 74 On the Alaska North Slope Metasequoia was the dominant conifer Much of the diversity represented migrants from nearer the equator Deciduousness was dominant probably to conserve energy by retroactively shedding leaves and retaining some energy rather than having them die from frostbite 132 At the South Pole due to the increasing isolation of Antarctica many plant taxa were endemic to the continent instead of migrating down Patagonian flora may have originated in Antarctica 132 133 The climate was much cooler than in the Late Cretaceous though frost probably was not common in at least coastal areas East Antarctica was likely warm and humid Because of this evergreen forests could proliferate as in the absence of frost and a low probability of leaves dying it was more energy efficient to retain leaves than to regrow them every year One possibility is that the interior of the continent favored deciduous trees though prevailing continental climates may have produced winters warm enough to support evergreen forests As in the Cretaceous podocarpaceous conifers Nothofagus and Proteaceae angiosperms were common 132 Fauna editIn the K Pg extinction event every land animal over 25 kg 55 lb was wiped out leaving open several niches at the beginning of the epoch 134 Mammals edit nbsp Restoration of the herbivorous late Paleocene pantodont Barylambda which could have weighed up to 650 kg 1 430 lb 135 Mammals had first appeared in the Late Triassic and remained small and nocturnal throughout the Mesozoic to avoid competition with dinosaurs nocturnal bottleneck 136 though by the Middle Jurassic they had branched out into several habitats such as subterranean arboreal and aquatic 137 and the largest known Mesozoic mammal Repenomamus robustus reached about 1 m 3 ft 3 in in length and 12 14 kg 26 31 lb in weight comparable to the modern day Virginia opossum 138 Though some mammals could sporadically venture out in daytime cathemerality by roughly 10 million years before the K Pg extinction event they only became strictly diurnal active in the daytime sometime after 136 In general Paleocene mammals retained this small size until near the end of the epoch and consequently early mammal bones are not well preserved in the fossil record and most of what is known comes from fossil teeth 50 Multituberculates a now extinct rodent like group not closely related to any modern mammal were the most successful group of mammals in the Mesozoic and they reached peak diversity in the early Paleocene During this time multituberculate taxa had a wide range of dental complexity which correlates to a broader range in diet for the group as a whole Multituberculates declined in the late Paleocene and went extinct at the end of the Eocene possibly due to competition from newly evolving rodents 139 nbsp The mesonychid Sinonyx at the Museo delle ScienzeNonetheless following the K Pg extinction event mammals very quickly diversified and filled the empty niches 140 141 Modern mammals are subdivided into therians modern members are placentals and marsupials and monotremes These three groups all originated in the Cretaceous 142 Paleocene marsupials include Peradectes 143 and monotremes Monotrematum 144 145 The epoch featured the rise of many crown placental groups groups that have living members in modern day such as the earliest afrotherian Ocepeia xenarthran Utaetus rodent Tribosphenomys and Paramys the forerunners of primates the Plesiadapiformes earliest carnivorans Ravenictis and Pristinictis possible pangolins Palaeanodonta possible forerunners of odd toed ungulates Phenacodontidae and eulipotyphlans Nyctitheriidae 146 Though therian mammals had probably already begun to diversify around 10 to 20 million years before the K Pg extinction event average mammal size increased greatly after the boundary and a radiation into frugivory fruit eating and omnivory began namely with the newly evolving large herbivores such as the Taeniodonta Tillodonta Pantodonta Polydolopimorphia and the Dinocerata 147 148 Large carnivores include the wolf like Mesonychia such as Ankalagon 149 and Sinonyx 150 Though there was an explosive diversification the affinities of most Paleocene mammals are unknown and only primates carnivorans and rodents have unambiguous Paleocene origins resulting in a 10 million year gap in the fossil record of other mammalian crown orders The most species rich order of Paleocene mammals is Condylarthra which is a wastebasket taxon for miscellaneous bunodont hoofed mammals Other ambiguous orders include the Leptictida Cimolesta and Creodonta This uncertainty blurs the early evolution of placentals 146 Birds edit nbsp Gastornis restorationAccording to DNA studies modern birds Neornithes rapidly diversified following the extinction of the other dinosaurs in the Paleocene and nearly all modern bird lineages can trace their origins to this epoch with the exception of fowl This was one of the fastest diversifications of any group 151 probably fueled by the diversification of fruit bearing trees and associated insects and the modern bird groups had likely already diverged within four million years of the K Pg extinction event However the fossil record of birds in the Paleocene is rather poor compared to other groups limited globally to mainly waterbirds such as the early penguin Waimanu The earliest arboreal crown group bird known is Tsidiiyazhi a mousebird dating to around 62 mya 152 The fossil record also includes early owls such as the large Berruornis from France 153 and the smaller Ogygoptynx from the United States 154 Almost all archaic birds any bird outside Neornithes went extinct during the K Pg extinction event although the archaic Qinornis is recorded in the Paleocene 152 Their extinction may have led to the proliferation of neornithine birds in the Paleocene and the only known Cretaceous neornithine bird is the waterbird Vegavis and possibly also the waterbird Teviornis 155 In the Mesozoic birds and pterosaurs exhibited size related niche partitioning no known Late Cretaceous flying bird had a wingspan greater than 2 m 6 ft 7 in nor exceeded a weight of 5 kg 11 lb whereas contemporary pterosaurs ranged from 2 10 m 6 ft 7 in 32 ft 10 in probably to avoid competition Their extinction allowed flying birds to attain greater size such as pelagornithids and pelecaniformes 156 The Paleocene pelagornithid Protodontopteryx was quite small compared to later members with a wingspan of about 1 m 3 3 ft comparable to a gull 157 On the archipelago continent of Europe the flightless bird Gastornis was the largest herbivore at 2 m 6 ft 7 in tall for the largest species possibly due to lack of competition from newly emerging large mammalian herbivores which were prevalent on the other continents 134 158 The carnivorous terror birds in South America have a contentious appearance in the Paleocene with Paleopsilopterus though the first definitive appearance is in the Eocene 159 Reptiles edit nbsp Borealosuchus at the Field Museum of Natural HistoryIt is generally believed all non avian dinosaurs went extinct at the K Pg extinction event 66 mya though there are a couple of controversial claims of Paleocene dinosaurs which would indicate a gradual decline of dinosaurs Contentious dates include remains from the Hell Creek Formation dated 40 000 years after the boundary 160 and a hadrosaur femur from the San Juan Basin dated to 64 5 mya 161 but such stray late forms may be zombie taxa that were washed out and moved to younger sediments 162 In the wake of the K Pg extinction event 83 of lizard and snake squamate species went extinct and the diversity did not fully recover until the end of the Paleocene However since the only major squamate lineages to disappear in the event were the mosasaurs and polyglyphanodontians the latter making up 40 of Maastrichtian lizard diversity and most major squamate groups had evolved by the Cretaceous the event probably did not greatly affect squamate evolution and newly evolving squamates did not seemingly branch out into new niches as mammals That is Cretaceous and Paleogene squamates filled the same niches Nonetheless there was a faunal turnover of squamates and groups that were dominant by the Eocene were not as abundant in the Cretaceous namely the anguids iguanas night lizards pythons colubrids boas and worm lizards Only small squamates are known from the early Paleocene the largest snake Helagras was 950 mm 37 in in length 163 but the late Paleocene snake Titanoboa grew to over 13 m 43 ft long the longest snake ever recorded 164 Kawasphenodon peligrensis from the early Paleocene of South America represents the youngest record of Rhynchocephalia outside of New Zealand where the only extant representative of the order the tuatara resides 165 Freshwater crocodilians and choristoderans were among the aquatic reptiles to have survived the K Pg extinction event probably because freshwater environments were not as impacted as marine ones 166 One example of a Paleocene crocodile is Borealosuchus which averaged 3 7 m 12 ft in length at the Wannagan Creek site 167 Among crocodyliformes the aquatic and terrestrial dyrosaurs and the fully terrestrial sebecids would also survive the K Pg extinction event and a late surviving member of Pholidosauridae is also known from the Danian of Morocco 168 Three choristoderans are known from the Paleocene The gharial like neochoristoderans Champsosaurus the largest is the Paleocene C gigas at 3 m 9 8 ft Simoedosaurus the largest specimen measuring 5 m 16 ft and an indeterminate species of the lizard like non neochoristoderan Lazarussuchus around 44 centimetres in length 169 The last known choristoderes belonging to the genus Lazarussuchus are known from the Miocene 170 Turtles experienced a decline in the Campanian Late Cretaceous during a cooling event and recovered during the PETM at the end of the Paleocene 171 Turtles were not greatly affected by the K Pg extinction event and around 80 of species survived 172 In Colombia a 60 million year old turtle with a 1 7 m 5 ft 7 in carapace Carbonemys was discovered 173 Amphibians edit There is little evidence amphibians were affected very much by the K Pg extinction event probably because the freshwater habitats they inhabited were not as greatly impacted as marine environments 174 In the Hell Creek Formation of eastern Montana a 1990 study found no extinction in amphibian species across the boundary 175 The true toads evolved during the Paleocene 176 The final record of albanerpetontids from North America and outside of Europe and Anatolia an unnamed species of Albanerpeton is known from the Paleocene aged Paskapoo Formation in Canada 177 Fish edit nbsp The early Paleocene trumpetfish Eekaulostomus from Palenque MexicoThe small pelagic fish population recovered rather quickly and there was a low extinction rate for sharks and rays Overall only 12 of fish species went extinct 178 During the Cretaceous fishes were not very abundant probably due to heightened predation by or competition with ammonites and squid although large predatory fish did exist including ichthyodectids pachycormids and pachyrhizodontids 179 Almost immediately following the K Pg extinction event ray finned fish today representing nearly half of all vertebrate taxa became much more numerous and increased in size and rose to dominate the open oceans Acanthomorphs a group of ray finned fish which today represent a third of all vertebrate life experienced a massive diversification following the K Pg extinction event dominating marine ecosystems by the end of the Paleocene refilling vacant open ocean predatory niches as well as spreading out into recovering reef systems In specific percomorphs diversified faster than any other vertebrate group at the time with the exception of birds Cretaceous percomorphs varied very little in body plan whereas by the Eocene percomorphs evolved into vastly varying creatures 180 such as early scombrids today tuna mackerels and bonitos 179 barracudas 181 jacks 180 billfish 182 flatfishes 183 and aulostomoid trumpetfish and cornetfish 184 180 185 However the discovery of the Cretaceous cusk eel Pastorius shows that the body plans of at least some percomorphs were already highly variable perhaps indicating an already diverse array of percomorph body plans before the Paleocene 186 nbsp Otodus obliquus shark tooth from Oued Zem MoroccoConversely sharks and rays appear to have been unable to exploit the vacant niches and recovered the same pre extinction abundance 178 187 There was a faunal turnover of sharks from mackerel sharks to ground sharks as ground sharks are more suited to hunting the rapidly diversifying ray finned fish whereas mackerel sharks target larger prey 188 The first megatoothed shark Otodus obliquus the ancestor of the giant megalodon is recorded from the Paleocene 189 Several Paleocene freshwater fish are recorded from North America including bowfins gars arowanas Gonorynchidae common catfish smelts and pike 190 Insects and arachnids edit nbsp Earwig from the late Paleocene Danish Fur FormationInsect recovery varied from place to place For example it may have taken until the PETM for insect diversity to recover in the western interior of North America whereas Patagonian insect diversity had recovered by four million years after the K Pg extinction event In some areas such as the Bighorn Basin in Wyoming there is a dramatic increase in plant predation during the PETM although this is probably not indicative of a diversification event in insects due to rising temperatures because plant predation decreases following the PETM More likely insects followed their host plant or plants which were expanding into mid latitude regions during the PETM and then retreated afterward 129 191 The middle to late Paleocene French Menat Formation shows an abundance of beetles making up 77 5 of the insect diversity especially weevils 50 of diversity jewel beetles leaf beetles and reticulated beetles as well as other true bugs such as pond skaters and cockroaches To a lesser degree there are also orthopterans hymenopterans butterflies and flies though planthoppers were more common than flies Representing less than 1 of fossil remains dragonflies caddisflies mayflies earwigs mantises net winged insects and possibly termites 192 The Wyoming Hanna Formation is the only known Paleocene formation to produce sizable pieces of amber as opposed to only small droplets The amber was formed by a single or a closely related group of either taxodiaceaen or pine tree s which produced cones similar to those of dammaras Only one insect a thrips has been identified 193 nbsp The ant Napakimyrma paskapooensis from the Canadian Paskapoo FormationThere is a gap in the ant fossil record from 78 to 55 mya except for the aneuretine Napakimyrma paskapooensis from the 62 56 million year old Canadian Paskapoo Formation 194 Given high abundance in the Eocene two of the modern dominant ant subfamilies Ponerinae and Myrmicinae likely originated and greatly diversified in the Paleocene acting as major hunters of arthropods and probably competed with each other for food and nesting grounds in the dense angiosperm leaf litter Myrmicines expanded their diets to seeds and formed trophobiotic symbiotic relationships with aphids mealybugs treehoppers and other honeydew secreting insects which were also successful in angiosperm forests allowing them to invade other biomes such as the canopy or temperate environments and achieve a worldwide distribution by the middle Eocene 195 About 80 of the butterfly and moth lepidopteran fossil record occurs in the early Paleogene specifically the late Paleocene and the middle to late Eocene Most Paleocene lepidopteran compression fossils come from the Danish Fur Formation Though there is low family level diversity in the Paleocene compared to later epochs this may be due to a largely incomplete fossil record 196 The evolution of bats had a profound effect on lepidopterans which feature several anti predator adaptations such as echolocation jamming and the ability to detect bat signals 197 Bees were likely heavily impacted by the K Pg extinction event and a die off of flowering plants though the bee fossil record is very limited 198 The oldest kleptoparasitic bee Paleoepeolus is known from the Paleocene 60 mya 199 Though the Eocene features by far the highest proportion of known fossil spider species the Paleocene spider assemblage is quite low 200 Some spider groups began to diversify around the PETM such as jumping spiders 201 and possibly coelotine spiders members of the funnel weaver family 202 The diversification of mammals had a profound effect on parasitic insects namely the evolution of bats which have more ectoparasites than any other known mammal or bird The PETM s effect on mammals greatly impacted the evolution of fleas ticks and oestroids 203 Marine invertebrates edit Among marine invertebrates plankton and those with a planktonic stage in their development meroplankton were most impacted by the K Pg extinction event and plankton populations crashed Nearly 90 of all calcifying plankton species perished This reverberated up and caused a global marine food chain collapse namely with the extinction of ammonites and large raptorial marine reptiles Nonetheless the rapid diversification of large fish species indicates a healthy plankton population through the Paleocene 178 Marine invertebrate diversity may have taken about 7 million years to recover though this may be a preservation artifact as anything smaller than 5 mm 0 20 in is unlikely to be fossilized and body size may have simply decreased across the boundary 204 A 2019 study found that in Seymour Island Antarctica the marine life assemblage consisted primarily of burrowing creatures such as burrowing clams and snails for around 320 000 years after the K Pg extinction event and it took around a million years for the marine diversity to return to previous levels Areas closer to the equator may have been more affected 88 Sand dollars first evolved in the late Paleocene 205 The Late Cretaceous decapod crustacean assemblage of James Ross Island appears to have been mainly pioneer species and the ancestors of modern fauna such as the first Antarctic crabs and the first appearance of the lobsters of the genera Linuparus Metanephrops and Munidopsis which still inhabit Antarctica today 206 nbsp A rudist the dominant reef building organism of the CretaceousIn the Cretaceous the main reef building creatures were the box like bivalve rudists instead of coral though a diverse Cretaceous coral assemblage did exist and rudists had collapsed by the time of the K Pg extinction event Some corals are known to have survived in higher latitudes in the Late Cretaceous and into the Paleogene and hard coral dominated reefs may have recovered by 8 million years after the K Pg extinction event though the coral fossil record of this time is rather sparse 207 Though there was a lack of extensive coral reefs in the Paleocene there were some colonies mainly dominated by zooxanthellate corals in shallow coastal neritic areas Starting in the latest Cretaceous and continuing until the early Eocene calcareous corals rapidly diversified Corals probably competed mainly with red and coralline algae for space on the seafloor Calcified dasycladalean green algae experienced the greatest diversity in their evolutionary history in the Paleocene 208 Though coral reef ecosystems do not become particularly abundant in the fossil record until the Miocene possibly due to preservation bias strong Paleocene coral reefs have been identified in what are now the Pyrenees emerging as early as 63 mya with some smaller Paleocene coral reefs identified across the Mediterranean region 209 See also editMoeraki BouldersNotes edit In Lyell s time epochs were divided into periods In modern geology periods are divided into epochs References edit International Chronostratigraphic Chart International Commission on Stratigraphy a b c Molina Eustoquio Alegret Laia Arenillas Ignacio Jose A Arz Gallala Njoud Hardenbol Jan Katharina von Salis Steurbaut Etienne Vandenberghe Noel Dalila Zaghibib Turki 2006 The Global Boundary Stratotype Section and Point for the base of the Danian Stage Paleocene Paleogene Tertiary Cenozoic at El Kef Tunisia Original definition and revision PDF Episodes 29 4 263 278 doi 10 18814 epiiugs 2006 v29i4 004 Archived from the original PDF on 7 December 2012 Retrieved 14 September 2012 a b c Aubry Marie Pierre Ouda Khaled Dupuis Christian William A Berggren John A Van Couvering Working Group on the Paleocene Eocene Boundary 2007 The Global Standard Stratotype section and Point GSSP for the base of the Eocene Series in the Dababiya section Egypt PDF Episodes 30 4 271 286 doi 10 18814 epiiugs 2007 v30i4 003 Jones Daniel 2003 1917 Peter Roach James Hartmann Jane Setter eds English Pronouncing Dictionary Cambridge Cambridge University Press ISBN 3 12 539683 2 Schimper W P 1874 Traite de Paleontologie Vegetale Treatise on Paleobotany in French Vol 3 Paris J G Bailliere pp 680 689 a b Pulvertaft T C R 1999 Paleocene or Palaeocene PDF Bulletin of the Geological Society of Denmark 46 52 doi 10 37570 bgsd 1999 46 17 S2CID 246504439 Archived PDF from the original on 20 June 2016 Desnoyers J 1829 Observations sur un ensemble de depots marins plus recents que les terrains tertiaires du bassin de la Seine et constituant une formation geologique distincte precedees d un apercu de la nonsimultaneite des bassins tertiares Observations on a set of marine deposits more recent than the tertiary terrains of the Seine basin and constitute a distinct geological formation preceded by an outline of the non simultaneity of tertiary basins Annales des Sciences Naturelles in French 16 171 214 Archived from the original on 10 September 2018 Retrieved 20 October 2019 Lyell C 1833 Principles of Geology Vol 3 Geological Society of London p 378 Phillips J 1840 Palaeozoic series Penny Cyclopaedia of the Society for the Diffusion of Useful Knowledge Vol 17 London England Charles Knight and Co pp 153 154 Hornes M 1853 Mittheilungen an Professor Bronn gerichtet Reports addressed to Professor Bronn Neues Jahrbuch fur Mineralogie Geognosie Geologie und Petrefaktenkunde in German 806 810 hdl 2027 hvd 32044106271273 George T N Harland W B 1969 Recommendations on stratigraphical usage Proceedings of the Geological Society of London 156 1 656 139 166 Odin G S Curry D Hunziker J Z 1978 Radiometric dates from NW European glauconites and the Palaeogene time scale Journal of the Geological Society 135 5 481 497 Bibcode 1978JGSoc 135 481O doi 10 1144 gsjgs 135 5 0481 S2CID 129095948 Knox R W O B Pearson P N Barry T L 2012 Examining the case for the use of the Tertiary as a formal period or informal unit PDF Proceedings of the Geologists Association 123 3 390 393 Bibcode 2012PrGA 123 390K doi 10 1016 j pgeola 2012 05 004 S2CID 56290221 ICS Chart Time Scale www stratigraphy org Archived from the original on 30 May 2014 Retrieved 28 August 2019 Schulte P 2010 The Chicxulub Asteroid Impact and Mass Extinction at the Cretaceous Paleogene Boundary PDF Science 327 5970 1214 1218 Bibcode 2010Sci 327 1214S doi 10 1126 science 1177265 PMID 20203042 S2CID 2659741 Archived PDF from the original on 21 September 2017 Retrieved 28 August 2019 Vellekoop J Sluijs A Smit J Schouten S Weijers J W H Sinninghe Damste J S Brinkhuis H 2014 Rapid short term cooling following the Chicxulub impact at the Cretaceous Paleogene boundary Proceedings of the National Academy of Sciences 111 21 7537 7541 Bibcode 2014PNAS 111 7537V doi 10 1073 pnas 1319253111 PMC 4040585 PMID 24821785 Jablonski D Chaloner W G 1994 Extinctions in the fossil record and discussion Philosophical Transactions of the Royal Society of London B 344 1307 11 17 doi 10 1098 rstb 1994 0045 Sprain C J Renne P R Vanderkluysen L 2019 The eruptive tempo of Deccan volcanism in relation to the Cretaceous Paleogene boundary Science 363 6429 866 870 Bibcode 2019Sci 363 866S doi 10 1126 science aav1446 PMID 30792301 S2CID 67876911 a b Turner S K Hull P M Ridgwell A 2017 A probabilistic assessment of the rapidity of PETM onset Nature Communications 8 353 353 Bibcode 2017NatCo 8 353K doi 10 1038 s41467 017 00292 2 PMC 5572461 PMID 28842564 Zhang Q Willems H Ding L Xu X 2019 Response of larger benthic foraminifera to the Paleocene Eocene thermal maximum and the position of the Paleocene Eocene boundary in the Tethyan shallow benthic zones Evidence from south Tibet GSA Bulletin 131 1 2 84 98 Bibcode 2019GSAB 131 84Z doi 10 1130 B31813 1 S2CID 134560025 a b Kennet J P Stott L D 1995 Terminal Paleocene Mass Extinction in the Deep Sea Association with Global Warming Effects of Past Global Change on Life Studies in Geophysics National Academy of Sciences Winguth C Thomas E 2012 Global decline in ocean ventilation oxygenation and productivity during the Paleocene Eocene Thermal Maximum Implications for the benthic extinction Geology 40 3 263 266 Bibcode 2012Geo 40 263W doi 10 1130 G32529 1 Schmidt G A Shindell D T 2003 Atmospheric composition radiative forcing and climate change as a consequence of a massive methane release from gas hydrates PDF Paleoceanography 18 1 n a Bibcode 2003PalOc 18 1004S doi 10 1029 2002PA000757 Archived from the original PDF on 20 October 2011 a b c d e Schmitz B Pujalte V Molina E 2011 The Global Stratotype Sections and Points for the bases of the Selandian Middle Paleocene and Thanetian Upper Paleocene Stages at Zumaia Spain PDF Episodes 34 4 220 243 doi 10 18814 epiiugs 2011 v34i4 002 Archived PDF from the original on 20 August 2018 Desor P J E Sur le terrain Danien nouvel etage de la craie Bulletin de la Societe Geologique de France in French 2 Harland W B Armstrong R L Cox A V Craig L E Smith A G Smith D G 1990 A Geologic Time Scale 1989 Cambridge University Press p 61 ISBN 978 0 521 38765 1 Molina E Alagret L Arenillas I 2006 The Global Boundary Stratotype Section and Point for the base of the Danian Stage Paleocene Paleogene Tertiary Cenozoic at El Kef Tunisia Original definition and revision PDF Episodes 29 4 263 273 doi 10 18814 epiiugs 2006 v29i4 004 Archived PDF from the original on 14 February 2019 a b Hyland E G Sheldon N D Cotton J M 2015 Terrestrial evidence for a two stage mid Paleocene biotic event PDF Palaeogeography Palaeoclimatology Palaeoecology 417 371 378 Bibcode 2015PPP 417 371H doi 10 1016 j palaeo 2014 09 031 Archived PDF from the original on 5 August 2016 Tauxe L Banerjee S K Butler R F van der Voo R 2018 The GPTS and magnetostratigraphy Essentials of Paleomagnetism Fifth Web Edition Scripps Institute of Oceanography Archived from the original on 8 October 2019 Flores R M Bader L R Fort Union coal in the Powder River Basin Wyoming and Montana a synthesis PDF US Geological Survey pp 1 30 Archived PDF from the original on 4 May 2017 Retrieved 3 November 2019 Sixteen mines in the Powder River Basin produce 43 of U S coal U S Energy Information Administration 16 August 2019 Archived from the original on 7 November 2019 Retrieved 7 November 2019 Hook R W Warwick P D San Felipo J R Schultz A C Nichols D J Swanson S M 2011 Paleocene coal deposits of the Wilcox group central Texas In Warwick P D Karlsen A K Merrill M D Valentine B J eds Geologic Assessment of Coal in the Gulf of Mexico Coastal Plain American Association of Petroleum Geologists doi 10 1306 13281367St621291 ISBN 978 1 62981 025 6 Jaramillo C A Bayona G Pardo Trujillo A Rueda M Torres V Harrington G J Mora G 2007 The Palynology of the Cerrejon Formation Upper Paleocene of Northern Colombia Palynology 31 1 159 183 Bibcode 2007Paly 31 153J doi 10 1080 01916122 2007 9989641 S2CID 220343205 Luthje C J Milan J Hurum J H 2009 Paleocene tracks of the mammal Pantodont genus Titanoides in coal bearing strata Svalbard Arctic Norway Journal of Vertebrate Paleontology 30 2 521 527 doi 10 1080 02724631003617449 hdl 1956 3854 S2CID 59125537 Kalkreuth W D Riediger C L McIntyre D J Richardson R J H Fowler M G Marchioni D 1996 Petrological palynological and geochemical characteristics of Eureka Sound Group coals Stenkul Fiord southern Ellesmere Island Arctic Canada International Journal of Coal Geology 30 1 2 151 182 Bibcode 1996IJCG 30 151K doi 10 1016 0166 5162 96 00005 5 Akhmetiev M A 2015 High latitude regions of Siberia and Northeast Russia in the Paleogene Stratigraphy flora climate coal accumulation Stratigraphy and Geological Correlation 23 4 421 435 Bibcode 2015SGC 23 421A doi 10 1134 S0869593815040024 S2CID 131114773 Bain J S 1993 Historical overview of exploration of Tertiary plays in the UK North Sea Petroleum Geology Conference 4 5 13 doi 10 1144 0040005 Garnit H Bouhlel S Jarvis I 2017 Geochemistry and depositional environments of Paleocene Eocene phosphorites Metlaoui Group Tunisia PDF Journal of African Earth Sciences 134 704 736 Bibcode 2017JAfES 134 704G doi 10 1016 j jafrearsci 2017 07 021 Archived PDF from the original on 29 April 2019 Retrieved 7 November 2019 a b Kenny Gavin G Hyde William R Storey Michael Garde Adam A Whitehouse Martin J Beck Pierre Johansson Leif Sondergaard Anne Sofie Bjork Anders A MacGregor Joseph A Khan Shfaqat A 11 March 2022 A Late Paleocene age for Greenland s Hiawatha impact structure Science Advances 8 10 eabm2434 Bibcode 2022SciA 8M2434K doi 10 1126 sciadv abm2434 ISSN 2375 2548 PMC 8906741 PMID 35263140 Connolly Basin Earth Impact Database Archived from the original on 12 April 2019 Retrieved 3 November 2019 Marquez Earth Impact Database Archived from the original on 12 April 2019 Retrieved 3 November 2019 Jebel Waqf as Suwwan Earth Impact Database Archived from the original on 8 June 2019 Retrieved 3 November 2019 Drake S M Beard A D Jones A P Brown D J Fortes A D Millar I L Carter A Baca J Downes H 2018 Discovery of a meteoritic ejecta layer containing unmelted impactor fragments at the base of Paleocene lavas Isle of Skye Scotland PDF Geology 46 2 171 174 Bibcode 2018Geo 46 171D doi 10 1130 G39452 1 S2CID 4807661 Renne Paul 2013 Time Scales of Critical Events Around the Cretaceous Paleogene Boundary PDF Science 339 6120 684 7 Bibcode 2013Sci 339 684R doi 10 1126 science 1230492 PMID 23393261 S2CID 6112274 Archived PDF from the original on 3 April 2018 Retrieved 4 November 2019 Pickersgill Annemarie E Mark Darren F Lee Martin R Kelley Simon P Jolley David W 1 June 2021 The Boltysh impact structure An early Danian impact event during recovery from the K Pg mass extinction Science Advances 7 25 eabe6530 Bibcode 2021SciA 7 6530P doi 10 1126 sciadv abe6530 ISSN 2375 2548 PMC 8213223 PMID 34144979 Eagle Butte Earth Impact Database Archived from the original on 12 May 2019 Retrieved 3 November 2019 Vista Alegre Earth Impact Database Archived from the original on 12 May 2019 Retrieved 4 November 2019 Vasconcelos M A R 2013 Update on the current knowledge of the Brazilian impact craters PDF 44th Lunar and Planetary Science Conference 1318 1318 Bibcode 2013LPI 44 1318C Archived PDF from the original on 8 October 2016 Retrieved 4 November 2019 Schaller M F Fung M K Wright J D Katz M E Kent D V 2016 Impact ejecta at the Paleocene Eocene boundary Science 354 6309 225 229 Bibcode 2016Sci 354 225S doi 10 1126 science aaf5466 PMID 27738171 S2CID 30852592 a b c Hooker J J 2005 Tertiary to Present Paleocene In Selley R C Cocks R Plimer I R eds Encyclopedia of Geology Vol 5 Elsevier Limited pp 459 465 ISBN 978 0 12 636380 7 Brikiatis L 2014 The De Geer Thulean and Beringia routes key concepts for understanding early Cenozoic biogeography Journal of Biogeography 41 6 1036 1054 Bibcode 2014JBiog 41 1036B doi 10 1111 jbi 12310 S2CID 84506301 Graham A 2018 The role of land bridges ancient environments and migrations in the assembly of the North American flora Journal of Systematics and Evolution 56 5 405 429 doi 10 1111 jse 12302 S2CID 90782505 English Joseph M Johnston Stephen T 2004 The Laramide Orogeny What Were the Driving Forces International Geology Review 46 9 833 838 Bibcode 2004IGRv 46 833E doi 10 2747 0020 6814 46 9 833 S2CID 129901811 Slattery J Cobban W A McKinney K C Harries P J Sandness A 2013 Early Cretaceous to Paleocene Paleogeography of the Western Interior Seaway The Interaction of Eustasy and Tectonism Wyoming Geological Association 68th Annual Field Conference doi 10 13140 RG 2 1 4439 8801 a b c d Jolley D W Bell B R 2002 The evolution of the North Atlantic Igneous Province and the opening of the NE Atlantic rift Geological Society of London 197 1 1 13 Bibcode 2002GSLSP 197 1J doi 10 1144 GSL SP 2002 197 01 01 S2CID 129653395 a b Rousse S M Ganerod M A Smethurst T H Torsvik T Prestvik 2007 The British Tertiary Volcanics Origin History and New Paleogeographic Constraints for the North Atlantic Geophysical Research Abstracts 9 Hansen J Jerram D A McCaffrey K Passey S R 2009 The onset of the North Atlantic Igneous Province in a rifting perspective Geological Magazine 146 3 309 325 Bibcode 2009GeoM 146 309H doi 10 1017 S0016756809006347 S2CID 130266576 Archived from the original on 7 October 2019 Torsvik T H Mosar J Eide E A 2001 Cretaceous Tertiary geodynamics a North Atlantic exercise PDF Geophysical Journal 146 3 850 866 Bibcode 2001GeoJI 146 850T doi 10 1046 j 0956 540x 2001 01511 x S2CID 129961946 White R S McKenzie D P 1989 Magmatism at rift zones The generation of volcanic continental margins and flood basalts PDF Journal of Geophysical Research Solid Earth 94 B6 7685 7729 Bibcode 1989JGR 94 7685W doi 10 1029 JB094iB06p07685 Archived PDF from the original on 15 December 2017 Retrieved 24 September 2019 Maclennan John Jones Stephen M 2006 Regional uplift gas hydrate dissociation and the origins of the Paleocene Eocene Thermal Maximum Earth and Planetary Science Letters 245 1 65 80 Bibcode 2006E amp PSL 245 65M doi 10 1016 j epsl 2006 01 069 Buchs David M Arculus Richard J Baumgartner Peter O Baumgartner Mora Claudia Ulianov Alexey July 2010 Late Cretaceous arc development on the SW margin of the Caribbean Plate Insights from the Golfito Costa Rica and Azuero Panama complexes PDF Geochemistry Geophysics Geosystems 11 7 n a Bibcode 2010GGG 11 7S24B doi 10 1029 2009GC002901 hdl 1885 55979 S2CID 12267720 Archived PDF from the original on 14 August 2017 Retrieved 24 October 2019 Escuder Viruete J Perez Estuan A Joubert M Weis D 2011 The Pelona Pico Duarte basalts Formation Central Hispaniola an on land section of Late Cretaceous volcanism related to the Caribbean large igneous province PDF Geologica Acta 9 3 4 307 328 doi 10 1344 105 000001716 Archived PDF from the original on 4 March 2016 O Dea A Lessios H A Coates A G Eytan R I Restrepo Moreno S A Cione R A 2016 Formation of the Isthmus of Panama Science Advances 2 8 e1600883 Bibcode 2016SciA 2E0883O doi 10 1126 sciadv 1600883 PMC 4988774 PMID 27540590 Hu Xiumian Garzanti Eduardo Moore Ted Raffi Isabella 1 October 2015 Direct stratigraphic dating of India Asia collision onset at the Selandian middle Paleocene 59 1 Ma Geology 43 10 859 862 Bibcode 2015Geo 43 859H doi 10 1130 G36872 1 hdl 10281 95315 ISSN 0091 7613 Retrieved 23 September 2023 Frederiksen N O 1994 Middle and Late Paleocene Angiosperm Pollen from Pakistan Palynology 18 1 91 137 Bibcode 1994Paly 18 91F doi 10 1080 01916122 1994 9989442 a b Vahlenkamp M Niezgodzki I Niezgodzki D Lohmann G Bickert T Palike H 2018 Ocean and climate response to North Atlantic seaway changes at the onset of long term Eocene cooling PDF Earth and Planetary Science Letters 498 185 195 Bibcode 2018E amp PSL 498 185V doi 10 1016 j epsl 2018 06 031 S2CID 135252669 a b c d Thomas D J 2004 Evidence for deep water production in the North Pacific Ocean during the early Cenozoic warm interval Nature 430 6995 65 68 Bibcode 2004Natur 430 65T doi 10 1038 nature02639 PMID 15229597 S2CID 4422834 a b c d e f g Kitchell J A Clark D L 1982 Late Cretaceous Paleogene paleogeography and paleocirculation Evidence of north polar upwelling Palaeogeography Palaeoclimatology Palaeoecology 40 1 3 135 165 Bibcode 1982PPP 40 135K doi 10 1016 0031 0182 82 90087 6 a b Nunes F Norris R D 2006 Abrupt reversal in ocean overturning during the Palaeocene Eocene warm period Nature 439 7072 60 63 Bibcode 2006Natur 439 60N doi 10 1038 nature04386 PMID 16397495 S2CID 4301227 Hassold N J C Rea D K van der Pluijm B A Pares J M 2009 A physical record of the Antarctic Circumpolar Current late Miocene to recent slowing of abyssal circulation PDF Palaeogeography Palaeoclimatology Palaeoecology 275 1 4 28 36 Bibcode 2009PPP 275 28H doi 10 1016 j palaeo 2009 01 011 Archived PDF from the original on 29 October 2015 Retrieved 10 September 2019 a b c Wilf P Johnson K R 2004 Land plant extinction at the end of the Cretaceous A quantitative analysis of the North Dakota megafloral record Paleobiology 30 3 347 368 doi 10 1666 0094 8373 2004 030 lt 0347 LPEATE gt 2 0 CO 2 S2CID 33880578 Retrieved 16 December 2023 Akhmetiev M A 2007 Paleocene and Eocene floras of Russia and adjacent regions Climatic conditions of their development Paleontological Journal 41 11 1032 1039 Bibcode 2007PalJ 41 1032A doi 10 1134 S0031030107110020 S2CID 128882063 Akhmetiev M A Beniamovsky V N 2009 Paleogene floral assemblages around epicontinental seas and straits in Northern Central Eurasia proxies for climatic and paleogeographic evolution Geologica Acta 7 1 297 309 doi 10 1344 105 000000278 a b c Williams C J LePage B A Johnson A H Vann D R 2009 Structure Biomass and Productivity of a Late Paleocene Arctic Forest Proceedings of the Academy of Natural Sciences of Philadelphia 158 1 107 127 doi 10 1635 053 158 0106 S2CID 130110536 Hansen J Sato M Russell G Kharecha P 2013 Climate sensitivity sea level and atmospheric carbon dioxide Philosophical Transactions of the Royal Society A 371 2001 20120294 arXiv 1211 4846 Bibcode 2013RSPTA 37120294H doi 10 1098 rsta 2012 0294 PMC 3785813 PMID 24043864 World of Change Global Temperatures NASA Earth Observatory 9 December 2010 Archived from the original on 3 September 2019 Retrieved 10 September 2019 Hao Hui Ferguson David K Feng Guang Ping Ablaev Albert Wang Yu Fei Li Cheng Sen 11 November 2009 Early Paleocene vegetation and climate in Jiayin NE China Climatic Change 99 3 4 547 566 doi 10 1007 s10584 009 9728 6 ISSN 0165 0009 S2CID 55815633 Retrieved 23 September 2023 a b c Brea M Matheos S D Raigemborn M S Iglesias A Zucol A F Pramparo M 2011 Paleoecology and paleoenvironments of Podocarp trees in the Ameghino Petrified forest Golfo San Jorge Basin Patagonia Argentina Constraints for Early Paleogene paleoclimate PDF Geologica Acta 9 1 13 28 doi 10 1344 105 000001647 Archived PDF from the original on 28 August 2017 Barr Iestyn D Spagnolo Matteo Rea Brice R Bingham Robert G Oien Rachel P Adamson Kathryn Ely Jeremy C Mullan Donal J Pellitero Ramon Tomkins Matt D 21 September 2022 60 million years of glaciation in the Transantarctic Mountains Nature Communications 13 1 5526 Bibcode 2022NatCo 13 5526B doi 10 1038 s41467 022 33310 z ISSN 2041 1723 PMC 9492669 PMID 36130952 Paleocene Climate PaleoMap Project Archived from the original on 4 April 2019 Retrieved 7 September 2019 Sewall Jacob O Sloan Lisa Cirbus 1 February 2006 Come a little bit closer A high resolution climate study of the early Paleogene Laramide foreland Geology 34 2 81 Bibcode 2006Geo 34 81S doi 10 1130 G22177 1 ISSN 0091 7613 Retrieved 23 September 2023 Bergman J 16 February 2011 Temperature of Ocean Water Windows to the Universe Archived from the original on 25 September 2019 Retrieved 4 October 2019 Buchardt Bjorn 1 October 1977 Oxygen isotope ratios from shell material from the Danish middle paleocene Selandian deposits and their interpretation as paleotemperature indicators Palaeogeography Palaeoclimatology Palaeoecology 22 3 209 230 Bibcode 1977PPP 22 209B doi 10 1016 0031 0182 77 90029 3 ISSN 0031 0182 Quillevere F Norris R D 2003 Ecological development of acarininids planktonic foraminifera and hydrographic evolution of Paleocene surface waters Geological Society of America 223 238 doi 10 1130 0 8137 2369 8 223 ISBN 9780813723693 Boersma A Silva I P 1991 Distribution of Paleogene planktonic foraminifera analogies with the Recent Palaeogeography Palaeoclimatology Palaeoecology 83 1 3 38 40 Bibcode 1991PPP 83 29B doi 10 1016 0031 0182 91 90074 2 Kowalczyk J B Royer D L Miller I M Anderson C W 2018 Multiple Proxy Estimates of Atmospheric CO2 From an Early Paleocene Rainforest Paleoceanography and Paleoclimatology 33 12 1 427 1 438 Bibcode 2018PaPa 33 1427K doi 10 1029 2018PA003356 S2CID 130296033 Archived from the original on 29 April 2019 Retrieved 7 November 2019 page needed Barnet J S K Littler K Westerhold T Kroon D Leng M J Bailey I Rohl U Zachos J C 3 April 2019 A High Fidelity Benthic Stable Isotope Record of Late Cretaceous Early Eocene Climate Change and Carbon Cycling Paleoceanography and Paleoclimatology 34 4 672 691 Bibcode 2019PaPa 34 672B doi 10 1029 2019PA003556 hdl 20 500 11820 71e8a0b8 eec2 46bd 8559 bfc98ee3d21c S2CID 134124572 a b Whittle Rowan Witts James Bowman Vanessa Crame Alistair Francis Jane Ineson Ion 2019 Mass extinction Data from Nature and timing of biotic recovery in Antarctic benthic marine ecosystems following the Cretaceous Palaeogene mass extinction Dryad Digital Repository doi 10 5061 dryad v1265j8 Brugger Julia Feulner Georg Petri Stefan 2016 Baby it s cold outside Climate model simulations of the effects of the asteroid impact at the end of the Cretaceous PDF Geophysical Research Letters 44 1 419 427 Bibcode 2017GeoRL 44 419B doi 10 1002 2016GL072241 S2CID 53631053 Vellekoop J Sluijs A Smit J Schouten S Weijers J W H Sinninghe Damste J S Brinkhuis H 12 May 2014 Rapid short term cooling following the Chicxulub impact at the Cretaceous Paleogene boundary Proceedings of the National Academy of Sciences 111 21 7537 7541 Bibcode 2014PNAS 111 7537V doi 10 1073 pnas 1319253111 PMC 4040585 PMID 24821785 Ohno S et al 2014 Production of sulphate rich vapour during the Chicxulub impact and implications for ocean acidification Nature Geoscience 7 4 279 282 Bibcode 2014NatGe 7 279O doi 10 1038 ngeo2095 Pope K O D Hondt S L Marshall C R 15 September 1998 Meteorite impact and the mass extinction of species at the Cretaceous Tertiary boundary Proceedings of the National Academy of Sciences 95 19 11028 11029 Bibcode 1998PNAS 9511028P doi 10 1073 pnas 95 19 11028 PMC 33889 PMID 9736679 Belcher C M 2009 Reigniting the Cretaceous Palaeogene firestorm debate Geology 37 12 1147 1148 Bibcode 2009Geo 37 1147B doi 10 1130 focus122009 1 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint ignored DOI errors link Zanthos J C Arthur M A Dean W E 1989 Geochemical evidence for suppression of pelagic marine productivity at the Cretaceous Tertiary boundary Nature 337 6202 61 64 Bibcode 1989Natur 337 61Z doi 10 1038 337061a0 S2CID 4307681 Archived from the original on 7 June 2017 Retrieved 19 November 2019 Rampino M R Volk T 1988 Mass extinctions atmospheric sulphur and climatic warming at the K T boundary Nature 332 6159 63 65 Bibcode 1988Natur 332 63R doi 10 1038 332063a0 S2CID 4343787 Quillevere F Norris R D Koon D Wilson P A 2007 Transient ocean warming and shifts in carbon reservoirs during the early Danian Earth and Planetary Science Letters 265 3 600 615 doi 10 1016 j epsl 2007 10 040 Jolley D W Gilmour I Gilmour M Kemp D B Kelley S P 2015 Long term resilience decline in plant ecosystems across the Danian Dan C2 hyperthermal event Boltysh crater Ukraine Journal of the Geological Society 172 4 491 498 Bibcode 2015JGSoc 172 491J doi 10 1144 jgs2014 130 hdl 2164 6186 S2CID 130611763 Scotese Christopher R Song Haijun Mills Benjamin J W van der Meer Douwe G April 2021 Phanerozoic paleotemperatures The earth s changing climate during the last 540 million years Earth Science Reviews 215 103503 Bibcode 2021ESRv 21503503S doi 10 1016 j earscirev 2021 103503 S2CID 233579194 Retrieved 23 September 2023 Jehle Sofie Bornemann Andre Lagel Anna Friederike Deprez Arne Speijer Robert P 1 July 2019 Paleoceanographic changes across the Latest Danian Event in the South Atlantic Ocean and planktic foraminiferal response Palaeogeography Palaeoclimatology Palaeoecology 525 1 13 Bibcode 2019PPP 525 1J doi 10 1016 j palaeo 2019 03 024 ISSN 0031 0182 S2CID 134929774 Retrieved 23 September 2023 Jehl S Bornemann A Deprez A Speijer R P 2015 The Impact of the Latest Danian Event on Planktic Foraminiferal Faunas at ODP Site 1210 Shatsky Rise Pacific Ocean PLOS ONE 10 11 e0141644 Bibcode 2015PLoSO 1041644J doi 10 1371 journal pone 0141644 PMC 4659543 PMID 26606656 Speijer R P 2003 Danian Selandian sea level change and biotic excursion on the southern Tethyan margin Egypt In Wing S L Gingerich P D Schmitz B Thomas E eds Causes and Consequences of Globally Warm Climates in the Early Paleogene Geological Society of America pp 275 290 doi 10 1130 0 8137 2369 8 275 ISBN 978 0 8137 2369 3 S2CID 130152164 Coccioni Rodolfo Frontalini Fabrizio Catanzariti Rita Jovane Luigi Rodelli Daniel Rodrigues Ianco M M Savian Jairo F Giorgioni Martino Galbrun Bruno 1 June 2019 Paleoenvironmental signature of the Selandian Thanetian Transition Event STTE and Early Late Paleocene Event ELPE in the Contessa Road section western Neo Tethys Palaeogeography Palaeoclimatology Palaeoecology 523 62 77 Bibcode 2019PPP 523 62C doi 10 1016 j palaeo 2019 03 023 ISSN 0031 0182 S2CID 134340748 Retrieved 23 September 2023 Faris Mahmoud Shabaan Manal Abdelhady Ahmed Awad Ahmed Mohamed S Shaker Fatma 4 July 2023 The Paleocene climate in west central Sinai Egypt insights from the calcareous nannofossils Arabian Journal of Geosciences 16 8 448 Bibcode 2023ArJG 16 448F doi 10 1007 s12517 023 11566 z ISSN 1866 7511 S2CID 259318736 Retrieved 23 September 2023 Bernoala G Baceta J I Orue Etxebarria X Alegret L 2008 The mid Paleocene biotic event at the Zumaia section western Pyrenees evidence of an abrupt environmental disruption Geophysical Research Abstracts 10 Hollis Christopher J Naeher Sebastian Clowes Christopher D Naafs B David A Pancost Richard D Taylor Kyle W R Dahl Jenny Li Xun Ventura G Todd Sykes Richard 20 June 2022 Late Paleocene CO lt sub gt 2 lt sub gt drawdown climatic cooling and terrestrial denudation in the southwest Pacific Climate of the Past 18 6 1295 1320 Bibcode 2022CliPa 18 1295H doi 10 5194 cp 18 1295 2022 hdl 1983 b43317da 8fdd 4f4d baf4 36a467a9d5cf ISSN 1814 9332 Retrieved 28 October 2023 Frieling J Gebhardt H Huber M 2017 Extreme warmth and heat stressed plankton in the tropics during the Paleocene Eocene Thermal Maximum Science Advances 3 3 e1600891 Bibcode 2017SciA 3E0891F doi 10 1126 sciadv 1600891 PMC 5336354 PMID 28275727 Gutjahr M Ridgewell A Sexton P F et al 2017 Very large release of mostly volcanic carbon during the Palaeocene Eocene Thermal Maximum Nature 538 7669 573 577 Bibcode 2017Natur 548 573G doi 10 1038 nature23646 PMC 5582631 PMID 28858305 Svensen H Planke S Malthe Sorrensen A et al 2004 Release of methane from a volcanic basin as a mechanism for initial Eocene global warming Nature 429 6991 542 545 Bibcode 2004Natur 429 542S doi 10 1038 nature02566 PMID 15175747 S2CID 4419088 DeConto R M et al 2012 Past extreme warming events linked to massive carbon release from thawing permafrost Nature 484 7392 87 91 Bibcode 2012Natur 484 87D doi 10 1038 nature10929 PMID 22481362 S2CID 3194604 Turner S K 2018 Constraints on the onset duration of the Paleocene Eocene Thermal Maximum Philosophical Transactions of the Royal Society B 376 2130 20170082 Bibcode 2018RSPTA 37670082T doi 10 1098 rsta 2017 0082 PMC 6127381 PMID 30177565 Bowen G J 2015 Two massive rapid releases of carbon during the onset of the Palaeocene Eocene thermal maximum Nature Geoscience 8 1 44 47 Bibcode 2015NatGe 8 44B doi 10 1038 ngeo2316 McInerney Francesca A Wing Scott L 30 May 2011 The Paleocene Eocene Thermal Maximum A Perturbation of Carbon Cycle Climate and Biosphere with Implications for the Future Annual Review of Earth and Planetary Sciences 39 1 489 516 Bibcode 2011AREPS 39 489M doi 10 1146 annurev earth 040610 133431 S2CID 39683046 Panchuk K Ridgwell A Kump L R 2008 Sedimentary response to Paleocene Eocene Thermal Maximum carbon release A model data comparison Geology 36 4 315 318 Bibcode 2008Geo 36 315P doi 10 1130 G24474A 1 Zhou X Thomas E Rickaby R E M Winguth A M E Lu Z 2014 I Ca evidence for upper ocean deoxygenation during the PETM Paleoceanography and Paleoclimatology 29 10 964 975 Bibcode 2014PalOc 29 964Z doi 10 1002 2014PA002702 Retrieved 17 October 2023 Yao W Paytan A Wortmann U G 2018 Large scale ocean deoxygenation during the Paleocene Eocene Thermal Maximum Science 361 6404 804 806 Bibcode 2018Sci 361 804Y doi 10 1126 science aar8658 PMID 30026315 S2CID 206666570 Secord R Bloch J I Chester S G B Boyer D M Wood A R Wing S L Kraus M J McInerney F A Krigbaum J 2012 Evolution of the Earliest Horses Driven by Climate Change in the Paleocene Eocene Thermal Maximum Science 335 6071 959 962 Bibcode 2012Sci 335 959S doi 10 1126 science 1213859 PMID 22363006 S2CID 4603597 Archived from the original on 9 April 2019 Retrieved 8 January 2020 a b c d e f Graham A 1999 Late Cretaceous and Cenozoic History of North American Vegetation PDF Oxford University Press pp 162 169 ISBN 978 0 19 511342 6 Archived PDF from the original on 1 October 2019 a b c Wing S L Herrera F Jaramillo C A Gomez Navarro C Wilf P Labandeira C C 2009 Late Paleocene fossils from the Cerrejon Formation Colombia are the earliest record of Neotropical rainforest Proceedings of the National Academy of Sciences of the United States of America 106 44 18627 18632 Bibcode 2009PNAS 10618627W doi 10 1073 pnas 0905130106 PMC 2762419 PMID 19833876 a b Ickert Bond S M Pigg K B DeVore M L 2015 Paleoochna tiffneyi gen et sp nov Ochnaceae from the Late Paleocene Almont Beicegel Creek Flora North Dakota USA International Journal of Plant Sciences 176 9 892 900 doi 10 1086 683275 S2CID 88105238 Robson B E Collinson M E Riegel W Wilde V Scott A C Pancost Richard D 2015 Early Paleogene wildfires in peat forming environments at Schoningen Germany PDF Palaeogeography Palaeoclimatology Palaeoecology 437 43 62 Bibcode 2015PPP 437 53R doi 10 1016 j palaeo 2015 07 016 S2CID 126619743 Retrieved 17 October 2023 Tschudy R H Tschudy B D 1986 Extinction and survival of plant life following the Cretaceous Tertiary boundary event Western Interior North America Geology 14 8 667 670 Bibcode 1986Geo 14 667T doi 10 1130 0091 7613 1986 14 lt 667 EASOPL gt 2 0 CO 2 Vajda V Bercovici A 2014 The global vegetation pattern across the Cretaceous Paleogene mass extinction interval A template for other extinction events Global and Planetary Change 122 24 49 Bibcode 2014GPC 122 29V doi 10 1016 j gloplacha 2014 07 014 Barreda Viviana D Cuneo Nestor R Wilf Peter Currano Ellen D Scasso Roberto A Brinkhuis Henk 17 December 2012 Newsom Lee A ed Cretaceous Paleogene Floral Turnover in Patagonia Drop in Diversity Low Extinction and a Classopollis Spike PLOS ONE 7 12 e52455 Bibcode 2012PLoSO 752455B doi 10 1371 journal pone 0052455 ISSN 1932 6203 PMC 3524134 PMID 23285049 a b c d e f Frederiksen N O 1994 Paleocene floral diversities and turnover events in eastern North America and their relation to diversity models Review of Palaeobotany and Palynology 82 3 4 225 238 Bibcode 1994RPaPa 82 225F doi 10 1016 0034 6667 94 90077 9 Vajda V Raine J I Hollis C J 2001 Indication of global deforestation at the Cretaceous Tertiary boundary by New Zealand fern spike Science 294 5547 1700 1702 Bibcode 2001Sci 294 1700V doi 10 1126 science 1064706 PMID 11721051 S2CID 40364945 Schultz P H D Hondt S 1996 Cretaceous Tertiary Chicxulub impact angle and its consequences Geology 24 11 963 967 Bibcode 1996Geo 24 963S doi 10 1130 0091 7613 1996 024 lt 0963 CTCIAA gt 2 3 CO 2 a b Johnson K R Ellis B 2002 A Tropical Rainforest in Colorado 1 4 Million Years After the Cretaceous Tertiary Boundary Science 296 5577 2379 2383 Bibcode 2002Sci 296 2379J doi 10 1126 science 1072102 PMID 12089439 S2CID 11207255 Wang W Lin L Xiang X 2016 The rise of angiosperm dominated herbaceous floras Insights from Ranunculaceae Scientific Reports 6 e27259 Bibcode 2016NatSR 627259W doi 10 1038 srep27259 PMC 4890112 PMID 27251635 a b Wilf P Labandeira C C 1999 Response of Plant Insect Associations to Paleocene Eocene Warming PDF Science 284 5423 2153 2156 CiteSeerX 10 1 1 304 8853 doi 10 1126 science 284 5423 2153 PMID 10381875 Dilcher D 2000 Toward a new synthesis Major evolutionary trends in the angiosperm fossil record Proceedings of the National Academy of Sciences of the United States of America 97 13 7030 7036 Bibcode 2000PNAS 97 7030D doi 10 1073 pnas 97 13 7030 PMC 34380 PMID 10860967 Frederiksen N O 1998 Upper Paleocene and Lowermost Eocene Angiosperm Pollen Biostratigraphy of the Eastern Gulf Coast and Virginia Micropaleontology 44 1 45 68 Bibcode 1998MiPal 44 45F doi 10 2307 1486084 JSTOR 1486084 a b c d Askin R A Spicer R A 1995 The Late Cretaceous and Cenozoic History of Vegetation and Climate at Northern and Southern High Latitudes A Comparison Effects of Past Global Change on Life National Academy Press pp 156 173 Tosolini A Cantrill D J Francis J E 2013 Paleocene flora from Seymour Island Antarctica Revision of Dusen s 1908 angiosperm taxa Alcheringa An Australasian Journal of Palaeontology 37 3 366 391 Bibcode 2013Alch 37 366T doi 10 1080 03115518 2013 764698 S2CID 87955445 a b Angst D Lecuyer C Amiot R Buffetaut E Fourel F Martineau F Legendre S Abourachid A Herrel A 2014 Isotopic and anatomical evidence of an herbivorous diet in the Early Tertiary giant bird Gastornis Implications for the structure of Paleocene terrestrial ecosystems Naturwissenschaften 101 4 313 322 Bibcode 2014NW 101 313A doi 10 1007 s00114 014 1158 2 PMID 24563098 S2CID 18518649 Lucas S G 1998 Pantodonta In Janis C M Scott K M Jacobs L L Gunnel G F Uhen M D eds Evolution of Mammals of North America Cambridge University Press p 274 ISBN 978 0 521 35519 3 a b Maor R Dayan T Ferguson Gow H Jones K E 2017 Temporal niche expansion in mammals from a nocturnal ancestor after dinosaur extinction Nature Ecology and Evolution 1 12 1889 1895 Bibcode 2017NatEE 1 1889M doi 10 1038 s41559 017 0366 5 PMID 29109469 S2CID 20732677 Close R A Friedman M Lloyd G T Benson R B J 2015 Evidence for a Mid Jurassic Adaptive Radiation in Mammals Current Biology 25 16 2 137 2 142 doi 10 1016 j cub 2015 06 047 PMID 26190074 S2CID 527196 Hu Y Meng J Wang Y Li C 2005 Large Mesozoic mammals fed on young dinosaurs PDF Nature 433 7022 149 152 Bibcode 2005Natur 433 149H doi 10 1038 nature03102 PMID 15650737 S2CID 2306428 Wilson G P Evans A R Corfe I J Smits P D Fortelius M Jernvall J 2012 Adaptive radiation of multituberculate mammals before the extinction of dinosaurs PDF Nature 483 7390 457 460 Bibcode 2012Natur 483 457W doi 10 1038 nature10880 PMID 22419156 S2CID 4419772 Archived PDF from the original on 12 August 2017 Hunter J P 1999 The radiation of Paleocene mammals with the demise of the dinosaurs Evidence from southwestern North Dakota Proceedings of the North Dakota Academy of Sciences 53 Alroy John Waddell P March 1999 The Fossil Record of North American Mammals Evidence for a Paleocene Evolutionary Radiation PDF Systematic Biology 48 1 107 118 doi 10 1080 106351599260472 PMID 12078635 Archived from the original PDF on 10 August 2017 Retrieved 8 January 2020 Luo Z X Ji Q Wible J R Yuan C X 2003 An early Cretaceous tribosphenic mammal and metatherian evolution Science 302 5652 1934 1940 Bibcode 2003Sci 302 1934L doi 10 1126 science 1090718 PMID 14671295 S2CID 18032860 Williamson T E Taylor L 2011 New species of Peradectes and Swaindelphys Mammalia Metatheria from the Early Paleocene Torrejonian Nacimiento Formation San Juan Basin New Mexico USA Palaeontologia Electronica 14 3 Pascual R Archer M Ortiz Jaureguizar E Prado J L Goldthep H Hand S J 1992 First discovery of monotremes in South America Nature 356 6371 704 706 Bibcode 1992Natur 356 704P doi 10 1038 356704a0 S2CID 4350045 Musser A M 2003 Review of the monotreme fossil record and comparison of palaeontological and molecular data Comparative Biochemistry and Physiology A 136 4 927 942 doi 10 1016 s1095 6433 03 00275 7 PMID 14667856 Archived from the original on 4 March 2016 a b Halliday T J D Upchurch P Goswami A 2017 Resolving the relationships of Paleocene placental mammals Biological Reviews 92 1 521 550 doi 10 1111 brv 12242 PMC 6849585 PMID 28075073 Grossnickle D M Newham E 2016 Therian mammals experience an ecomorphological radiation during the Late Cretaceous and selective extinction at the K Pg boundary Proceedings of the Royal Society B 283 1832 20160256 doi 10 1098 rspb 2016 0256 PMC 4920311 Janis C M 2005 Sues H ed Evolution of Herbivory in Terrestrial Vertebrates Perspectives from the Fossil Record Cambridge University Press p 182 ISBN 978 0 521 02119 7 O Leary M A Lucas S G Williamson T E 1999 A new specimen of Ankalagon Mammalia Mesonychia and evidence of sexual dimorphism in mesonychians Journal of Vertebrate Paleontology 20 2 387 393 doi 10 1671 0272 4634 2000 020 0387 ANSOAM 2 0 CO 2 S2CID 86542114 Zhou X Zhai R Gingerich P D Chen L 1995 Skull of a New Mesonychid Mammalia Mesonychia from the Late Paleocene of China PDF Journal of Vertebrate Paleontology 15 2 387 400 Bibcode 1995JVPal 15 387Z doi 10 1080 02724634 1995 10011237 Archived PDF from the original on 4 March 2016 Retrieved 27 August 2019 Suh A Smeds L Ellegren H 2015 The dynamics of incomplete lineage sorting across the ancient adaptive radiation of Neoavian birds PLOS Biology 13 8 e1002224 doi 10 1371 journal pbio 1002224 PMC 4540587 PMID 26284513 a b Ksepka D T Stidham T A Williamson T E 2017 Early Paleocene landbird supports rapid phylogenetic and morphological diversification of crown birds after the K Pg mass extinction Proceedings of the National Academy of Sciences 114 30 8047 8052 Bibcode 2017PNAS 114 8047K doi 10 1073 pnas 1700188114 PMC 5544281 PMID 28696285 Mourer Chauvire C 1994 A Large Owl from the Paleocene of France PDF Palaeontology 37 2 339 348 Archived PDF from the original on 25 August 2019 Rich P V Bohaska D J 1981 The Ogygoptyngidae a new family of owls from the Paleocene of North America Alcheringa An Australasian Journal of Palaeontology 5 2 95 102 Bibcode 1981Alch 5 95R doi 10 1080 03115518108565424 Longrich N R Tokaryk T Field D J 2011 Mass extinction of birds at the Cretaceous Paleogene K Pg boundary Proceedings of the National Academy of Sciences of the United States of America 108 37 15253 15257 Bibcode 2011PNAS 10815253L doi 10 1073 pnas 1110395108 PMC 3174646 PMID 21914849 Longrich N R Martill D M Andres B 2018 Late Maastrichtian pterosaurs from North Africa and mass extinction of Pterosauria at the Cretaceous Paleogene boundary PLOS Biology 16 3 e2001663 doi 10 1371 journal pbio 2001663 PMC 5849296 PMID 29534059 Mayr G Pietri V L D Love L Mannering A Scofield R P 2019 Oldest smallest and phylogenetically most basal pelagornithid from the early Paleocene of New Zealand sheds light on the evolutionary history of the largest flying birds Papers in Palaeontology 7 217 233 doi 10 1002 spp2 1284 S2CID 203884619 Witmer Lawrence M Rose Kenneth D 8 February 2016 Biomechanics of the jaw apparatus of the gigantic Eocene bird Diatryma implications for diet and mode of life Paleobiology 17 2 95 120 doi 10 1017 s0094837300010435 S2CID 18212799 Angst Delphine Buffetaut Eric Lecuyer Christophe Amiot Romain Farke Andrew A 27 November 2013 Terror Birds Phorusrhacidae from the Eocene of Europe Imply Trans Tethys Dispersal PLOS ONE 8 11 e80357 Bibcode 2013PLoSO 880357A doi 10 1371 journal pone 0080357 PMC 3842325 PMID 24312212 Sloan R E Rigby K Van Valen L M Gabriel D 2 May 1986 Gradual dinosaur extinction and simultaneous ungulate radiation in the Hell Creek formation Science 232 4750 629 633 Bibcode 1986Sci 232 629S doi 10 1126 science 232 4750 629 PMID 17781415 S2CID 31638639 Fassett JE Lucas SG Zielinski RA Budahn JR 2001 Compelling new evidence for Paleocene dinosaurs in the Ojo Alamo Sandstone San Juan Basin New Mexico and Colorado USA PDF Catastrophic Events and Mass Extinctions Lunar and Planetary Contribution 1053 45 46 Bibcode 2001caev conf 3139F Archived PDF from the original on 5 June 2011 Sullivan R M 2003 No Paleocene dinosaurs in the San Juan Basin New Mexico Geological Society of America Abstracts with Programs 35 5 15 Archived from the original on 8 April 2011 Longrich N R Bhullar B S Gauthier J A 2012 Mass extinction of lizards and snakes at the Cretaceous Paleogene boundary Proceedings of the National Academy of Sciences 109 52 21396 21401 Bibcode 2012PNAS 10921396L doi 10 1073 pnas 1211526110 PMC 3535637 PMID 23236177 Head J J Bloch J I Moreno Bernal J W Rincon A F 2013 Cranial osteology Body Size Systematics and Ecology of the giant Paleocene SnakeTitanoboa cerrejonensis 73nd Annual Meeting of the Society of Vertebrate Paleontology Los Angeles California Society of Vertebrate Paleontology pp 140 141 Apesteguia Sebastian Gomez Raul O Rougier Guillermo W 7 October 2014 The youngest South American rhynchocephalian a survivor of the K Pg extinction Proceedings of the Royal Society B Biological Sciences 281 1792 20140811 doi 10 1098 rspb 2014 0811 ISSN 0962 8452 PMC 4150314 PMID 25143041 MacLeod N Rawson P F Forey P L Banner F T Boudagher Fadel M K Bown P R Burnett J A Chambers P Culver S Evans S E Jeffery C Kaminski M A Lord A R Milner A C Milner A R Morris N Owen E Rosen B R Smith A B Taylor P D Urquhart E Young J R 1997 The Cretaceous Tertiary biotic transition Journal of the Geological Society 154 2 265 292 Bibcode 1997JGSoc 154 265M doi 10 1144 gsjgs 154 2 0265 S2CID 129654916 Archived from the original on 7 May 2019 Erickson B R 2007 Crocodile and Arthropod Tracks from the Late Paleocene Wannagan Creek Fauna of North Dakota USA Ichnos 12 4 303 308 doi 10 1080 1042094050031111 S2CID 129085761 Jouve Stephane Jalil Nour Eddine September 2020 Paleocene resurrection of a crocodylomorph taxon Biotic crises climatic and sea level fluctuations Gondwana Research 85 1 18 Bibcode 2020GondR 85 1J doi 10 1016 j gr 2020 03 010 S2CID 219451890 Matsumoto Ryoko Buffetaut Eric Escuillie Francois Hervet Sophie Evans Susan E March 2013 New material of the choristodere Lazarussuchus Diapsida Choristodera from the Paleocene of France Journal of Vertebrate Paleontology 33 2 319 339 Bibcode 2013JVPal 33 319M doi 10 1080 02724634 2012 716274 ISSN 0272 4634 S2CID 129438118 Retrieved 23 September 2023 Matsumoto R Evans S E 2010 Choristoderes and the freshwater assemblages of Laurasia Journal of Iberian Geology 36 2 253 274 Bibcode 2010JIbG 36 253M doi 10 5209 rev JIGE 2010 v36 n2 11 Weems R E 1988 Paleocene turtles from the Aquia and Brightseat Formations with a discussion of their bearing on sea turtle evolution and phylogeny Proceedings of the Biological Society of Washington 101 1 109 145 Novacek M J 1999 100 Million Years of Land Vertebrate Evolution The Cretaceous Early Tertiary Transition Annals of the Missouri Botanical Garden 86 2 230 258 doi 10 2307 2666178 JSTOR 2666178 Cadena E A Ksepka D T Jaramillo C A Bloch J I 2012 New pelomedusoid turtles from the late Palaeocene Cerrejon Formation of Colombia and their implications for phylogeny and body size evolution Journal of Systematic Palaeontology 10 2 313 Bibcode 2012JSPal 10 313C doi 10 1080 14772019 2011 569031 S2CID 59406495 Sheehan P M Fastovsky D E 1992 Major extinctions of land dwelling vertebrates at the Cretaceous Tertiary boundary Eastern Montana Geology 20 6 556 560 Bibcode 1992Geo 20 556S doi 10 1130 0091 7613 1992 020 lt 0556 meoldv gt 2 3 co 2 Archibald J D Bryant L J 1990 Differential Cretaceous Tertiary extinction of nonmarine vertebrates evidence from northeastern Montana In Sharpton V L Ward P D eds Global Catastrophes in Earth History an Interdisciplinary Conference on Impacts Volcanism and Mass Mortality Geological Society of America Special Paper Vol 247 pp 549 562 doi 10 1130 spe247 p549 ISBN 978 0 8137 2247 4 Rage J 2001 Oldest Bufonidae Amphibia Anura from the Old World a bufonid from the Paleocene of France PDF Journal of Vertebrate Paleontology 23 2 462 463 doi 10 1671 0272 4634 2003 023 0462 OBAAFT 2 0 CO 2 S2CID 86030507 Gardner JD Revised taxonomy of albanerpetontid amphibians Acta Palaeontol Pol 2000 45 55 70 a b c Sibert E C Norris R D 2015 New Age of Fishes initiated by the Cretaceous Paleogene mass extinction Proceedings of the National Academy of Sciences 112 28 8537 8542 Bibcode 2015PNAS 112 8537S doi 10 1073 pnas 1504985112 PMC 4507219 PMID 26124114 a b Miya M Friedman M Satoh T P 2013 Evolutionary origin of the Scombridae tunas and mackerels members of a paleogene adaptive radiation with 14 other pelagic fish families PLOS ONE 8 9 e73535 Bibcode 2013PLoSO 873535M doi 10 1371 journal pone 0073535 PMC 3762723 PMID 24023883 a b c Friedman M 2010 Explosive morphological diversification of spiny finned teleost fishes in the aftermath of the end Cretaceous extinction Proceedings of the Royal Society B 277 1688 1675 1683 doi 10 1098 rspb 2009 2177 PMC 2871855 PMID 20133356 Santini F Carnevale G Sorenson L 2015 First timetree of Sphyraenidae Percomorpha reveals a Middle Eocene crown age and an Oligo Miocene radiation of barracudas Italian Journal of Zoology 82 1 133 142 doi 10 1080 11250003 2014 962630 S2CID 86305952 Wilson A B Orr J W June 2011 The evolutionary origins of Syngnathidae pipefishes and seahorses Journal of Fish Biology 78 6 1603 1623 Bibcode 2011JFBio 78 1603W doi 10 1111 j 1095 8649 2011 02988 x PMID 21651519 Harrington R C Faircloth B C Eytan R I Smith W L Near T J Alfaro M E Friedman M 2016 Phylogenomic analysis of carangimorph fishes reveals flatfish asymmetry arose in a blink of the evolutionary eye BMC Evolutionary Biology 16 1 224 Bibcode 2016BMCEE 16 224H doi 10 1186 s12862 016 0786 x PMC 5073739 PMID 27769164 Cantalice K Alvarado Ortega J 2016 Eekaulostomus cuevasae gen and sp nov an ancient armored trumpet fish Aulostomoidea from Danian Paleocene marine deposits of Belisario Dominguez Chiapas southeastern Mexico Palaeontologia Electronica 19 doi 10 26879 682 Near T J 2013 Phylogeny and tempo of diversification in the superradiation of spiny rayed fishes Proceedings of the National Academy of Sciences 110 31 12738 12743 Bibcode 2013PNAS 11012738N doi 10 1073 pnas 1304661110 PMC 3732986 PMID 23858462 Carnevale G Johnson G D 2015 A Cretaceous Cusk Eel Teleostei Ophidiiformes from Italy and the Mesozoic Diversification of Percomorph Fishes Copeia 103 4 771 791 doi 10 1643 CI 15 236 S2CID 86033746 Adolfssen J S Ward D J 2013 Neoselachians from the Danian Early Paleocene of Denmark PDF Acta Palaeontologica Polonica 60 2 313 338 doi 10 4202 app 2012 0123 S2CID 128949365 Bazzi M Kear B P Blom H Ahlberg P E Campione N E 2018 Static Dental Disparity and Morphological Turnover in Sharks across the End Cretaceous Mass Extinction Current Biology 28 16 2607 2615 doi 10 1016 j cub 2018 05 093 PMID 30078565 S2CID 51893337 Ehret D J Ebersole J 2014 Occurrence of the megatoothed sharks Lamniformes Otodontidae in Alabama USA PeerJ 2 e625 doi 10 7717 peerj 625 PMC 4201945 PMID 25332848 Cavender T M 1998 Development of the North American Tertiary freshwater fish fauna with a look at parallel trends found in the European record Italian Journal of Palaeontology 36 1 149 161 doi 10 1080 11250009809386807 Currano E D Wilf P Wing S C Labandeira C C Lovelock E C Royer D L 2008 Sharply increased insect herbivory during the Paleocene Eocene Thermal Maximum Proceedings of the National Academy of Sciences 105 6 1960 1964 Bibcode 2008PNAS 105 1960C doi 10 1073 pnas 0708646105 PMC 2538865 PMID 18268338 Wedmann S Uhl D Lehmann T Garrouste R Nel A Gomez B Smith K Schaal S F K 2018 The Konservat Lagerstatte Menat Paleocene France an overview and new insights PDF Geologica Acta 16 2 189 213 doi 10 1344 GeologicaActa2018 16 2 5 Archived PDF from the original on 6 November 2019 Retrieved 6 November 2019 Grimaldi D A Lillegraven J A Wampler T W Bookwalter D Shredrinsky A 2000 Amber from Upper Cretaceous through Paleocene strata of the Hanna Basin Wyoming with evidence for source and taphonomy of fossil resins Rocky Mountain Geology 35 2 163 204 Bibcode 2000RMGeo 35 163G doi 10 2113 35 2 163 Lapolla J S Barden P 2018 A new aneuretine ant from the Paleocene Paskapoo Formation of Canada PDF Acta Palaeontologica Polonica 63 3 435 440 doi 10 4202 app 00478 2018 S2CID 55921254 Archived PDF from the original on 5 October 2019 Wilson E O Holldobler B 2005 The rise of the ants A phylogenetic and ecological explanation Proceedings of the National Academy of Sciences of the United States of America 102 21 7411 7414 Bibcode 2005PNAS 102 7411W doi 10 1073 pnas 0502264102 PMC 1140440 PMID 15899976 Sohn J Labandeira C C Davis D R 2015 The fossil record and taphonomy of butterflies and moths Insecta Lepidoptera implications for evolutionary diversity and divergence time estimates BMC Evolutionary Biology 15 12 12 Bibcode 2015BMCEE 15 12S doi 10 1186 s12862 015 0290 8 PMC 4326409 PMID 25649001 ter Hofstede H M Ratcliffe J M 2016 Evolutionary escalation the bat moth arms race PDF Journal of Experimental Biology 219 11 1589 1902 doi 10 1242 jeb 086686 PMID 27252453 S2CID 13590132 Archived from the original PDF on 16 February 2020 Rehan S M Reys R Schwarz M P 2013 First Evidence for a Massive Extinction Event Affecting Bees Close to the K T Boundary PLOS ONE 8 10 e76683 Bibcode 2013PLoSO 876683R doi 10 1371 journal pone 0076683 PMC 3806776 PMID 24194843 Dehon M Perrard A Engel M S Nel A Michez D 2017 Antiquity of cleptoparasitism among bees revealed by morphometric and phylogenetic analysis of a Paleocene fossil nomadine Hymenoptera Apidae Systematic Entomology 42 3 543 554 Bibcode 2017SysEn 42 543D doi 10 1111 syen 12230 S2CID 73595252 Pen, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.