fbpx
Wikipedia

Megafauna

January 01, 1970

This article is about living or extinct large animals. For other uses, see Megafauna (disambiguation).

In zoology, megafauna (from Greek μέγας megas "large" and Neo-Latin fauna "animal life") are large animals. The most common thresholds to be a megafauna are weighing over 45 kg (99 lb) or weighing over 1,000 kg (2,200 lb). The first occurrence of the term was in 1876. After the Cretaceous–Paleogene extinction event wiped out all non-avian dinosaurs, mammals and other vertebrates experienced an expansion in size. Millions of years of evolution led to gigantism on every major land mass. During the Quaternary extinction event, many species of megafauna went extinct as part of a slowly progressing extinction wave that affected ecosystems worldwide.

The African bush elephant (foreground), Earth's largest extant land mammal, and the Masai ostrich (background), one of Earth's largest extant birds

In practice, the most common usage encountered in academic and popular writing describes land mammals roughly larger than a human that are not (solely) domesticated. The term is especially associated with the Pleistocene megafauna – the land animals that are considered archetypical of the last ice age, such as mammoths, the majority of which in northern Eurasia, Australia-New Guinea and the Americas became extinct within the last forty thousand years.

History edit

One of the earliest occurrences of the term "megafauna" is Alfred Russel Wallace's 1876 work The geographical distribution of animals. He described the animals as "the hugest, and fiercest, and strangest forms". In the later 20th and 21st centuries, the term usually refers to large animals. There are variations in thresholds used to define megafauna as a whole or certain groups of megafauna. Many scientific literature adopt Martin's threshold of (<45 kg) to classify animals under this group. However, for freshwater species, 30 kg is the preferred threshold. Some scientists define herbivorous terrestrial megafauna as having a weight exceeding 100 kg, and terrestrial carnivorous megafauna as more than 15 kg. Additionally, Owen-Smith coined the term megaherbivore to describe herbivores that weighed over a tonne.[1]

Among living animals, the term megafauna is most commonly used for the largest extant terrestrial mammals, which includes (but is not limited to) elephants, giraffes, hippopotamuses, rhinoceroses, and large bovines. Of these five categories of large herbivores, only bovines are presently found outside of Africa and southern Asia, but all the others were formerly more wide-ranging, with their ranges and populations continually shrinking and decreasing over time. Wild equines are another example of megafauna, but their current ranges are largely restricted to the Old World, specifically Africa and Asia. Megafaunal species may be categorized according to their dietary type: megaherbivores (e.g., elephants), megacarnivores (e.g., lions), and, more rarely, megaomnivores (e.g., bears).[2][3]

Ecological strategy edit

Megafauna animals – in the sense of the largest mammals and birds – are generally K-strategists, with high longevity, slow population growth rates, low mortality rates, and (at least for the largest) few or no natural predators capable of killing adults.[4] These characteristics, although not exclusive to such megafauna, make them vulnerable to human overexploitation, in part because of their slow population recovery rates.[5][6]

Evolution of large body size edit

One observation that has been made about the evolution of larger body size is that rapid rates of increase that are often seen over relatively short time intervals are not sustainable over much longer time periods. In an examination of mammal body mass changes over time, the maximum increase possible in a given time interval was found to scale with the interval length raised to the 0.25 power.[7] This is thought to reflect the emergence, during a trend of increasing maximum body size, of a series of anatomical, physiological, environmental, genetic and other constraints that must be overcome by evolutionary innovations before further size increases are possible. A strikingly faster rate of change was found for large decreases in body mass, such as may be associated with the phenomenon of insular dwarfism. When normalized to generation length, the maximum rate of body mass decrease was found to be over 30 times greater than the maximum rate of body mass increase for a ten-fold change.[7]

In terrestrial mammals edit

 
Large terrestrial mammals compared in size to one of the largest sauropod dinosaurs, Patagotitan

Subsequent to the Cretaceous–Paleogene extinction event that eliminated the non-avian dinosaurs about 66 Ma (million years) ago, terrestrial mammals underwent a nearly exponential increase in body size as they diversified to occupy the ecological niches left vacant.[8] Starting from just a few kg before the event, maximum size had reached ~50 kg a few million years later, and ~750 kg by the end of the Paleocene. This trend of increasing body mass appears to level off about 40 Ma ago (in the late Eocene), suggesting that physiological or ecological constraints had been reached, after an increase in body mass of over three orders of magnitude.[8] However, when considered from the standpoint of rate of size increase per generation, the exponential increase is found to have continued until the appearance of Indricotherium 30 Ma ago. (Since generation time scales with body mass0.259, increasing generation times with increasing size cause the log mass vs. time plot to curve downward from a linear fit.)[7]

Megaherbivores eventually attained a body mass of over 10,000 kg. The largest of these, indricotheres and proboscids, have been hindgut fermenters, which are believed to have an advantage over foregut fermenters in terms of being able to accelerate gastrointestinal transit in order to accommodate very large food intakes.[9] A similar trend emerges when rates of increase of maximum body mass per generation for different mammalian clades are compared (using rates averaged over macroevolutionary time scales). Among terrestrial mammals, the fastest rates of increase of body mass0.259 vs. time (in Ma) occurred in perissodactyls (a slope of 2.1), followed by rodents (1.2) and proboscids (1.1),[7] all of which are hindgut fermenters. The rate of increase for artiodactyls (0.74) was about a third that of perissodactyls. The rate for carnivorans (0.65) was slightly lower yet, while primates, perhaps constrained by their arboreal habits, had the lowest rate (0.39) among the mammalian groups studied.[7]

Terrestrial mammalian carnivores from several eutherian groups (the artiodactyl Andrewsarchus – formerly considered a mesonychid, the oxyaenid Sarkastodon, and the carnivorans Amphicyon and Arctodus) all reached a maximum size of about 1000 kg[8] (the carnivoran Arctotherium and the hyaenodontid Simbakubwa may have been somewhat larger). The largest known metatherian carnivore, Proborhyaena gigantea, apparently reached 600 kg, also close to this limit.[10] A similar theoretical maximum size for mammalian carnivores has been predicted based on the metabolic rate of mammals, the energetic cost of obtaining prey, and the maximum estimated rate coefficient of prey intake.[11] It has also been suggested that maximum size for mammalian carnivores is constrained by the stress the humerus can withstand at top running speed.[10]

Analysis of the variation of maximum body size over the last 40 Ma suggests that decreasing temperature and increasing continental land area are associated with increasing maximum body size. The former correlation would be consistent with Bergmann's rule,[12] and might be related to the thermoregulatory advantage of large body mass in cool climates,[8] better ability of larger organisms to cope with seasonality in food supply,[12] or other factors;[12] the latter correlation could be explained in terms of range and resource limitations.[8] However, the two parameters are interrelated (due to sea level drops accompanying increased glaciation), making the driver of the trends in maximum size more difficult to identify.[8]

In marine mammals edit

 
Baleen whale comparative sizes

Since tetrapods (first reptiles, later mammals) returned to the sea in the Late Permian, they have dominated the top end of the marine body size range, due to the more efficient intake of oxygen possible using lungs.[13][14] The ancestors of cetaceans are believed to have been the semiaquatic pakicetids, no larger than dogs, of about 53 million years (Ma) ago.[15] By 40 Ma ago, cetaceans had attained a length of 20 m or more in Basilosaurus, an elongated, serpentine whale that differed from modern whales in many respects and was not ancestral to them. Following this, the evolution of large body size in cetaceans appears to have come to a temporary halt, and then to have backtracked, although the available fossil records are limited. However, in the period from 31 Ma ago (in the Oligocene) to the present, cetaceans underwent a significantly more rapid sustained increase in body mass (a rate of increase in body mass0.259 of a factor of 3.2 per million years) than achieved by any group of terrestrial mammals.[7] This trend led to the largest animal of all time, the modern blue whale. Several reasons for the more rapid evolution of large body size in cetaceans are possible. Fewer biomechanical constraints on increases in body size may be associated with suspension in water as opposed to standing against the force of gravity, and with swimming movements as opposed to terrestrial locomotion. Also, the greater heat capacity and thermal conductivity of water compared to air may increase the thermoregulatory advantage of large body size in marine endotherms, although diminishing returns apply.[7]

Among toothed whales, maximum body size appears to be limited by food availability. Larger size, as in sperm and beaked whales, facilitates deeper diving to access relatively easily-caught, large cephalopod prey in a less competitive environment. Compared to odontocetes, the efficiency of baleen whales' filter feeding scales more favorably with increasing size when planktonic food is dense, making larger size more advantageous. The lunge feeding technique of rorquals appears to be more energy efficient than the ram feeding of balaenid whales; the latter technique is used with less dense and patchy plankton.[16] The cooling trend in Earth's recent history may have generated more localities of high plankton abundance via wind-driven upwellings, facilitating the evolution of gigantic whales.[16]

Cetaceans are not the only marine mammals to reach tremendous sizes.[17] The largest carnivorans of all time are marine pinnipeds, the largest of which is the southern elephant seal, which can reach more than 6 m (20 ft) in length and weigh up to 5,000 kg (11,000 lb). Other large pinnipeds include the northern elephant seal at 4,000 kg (8,800 lb), walrus at 2,000 kg (4,400 lb), and Steller sea lion at 1,135 kg (2,502 lb).[18][19] The sirenians are another group of marine mammals which adapted to fully aquatic life around the same time as the cetaceans did. Sirenians are closely related to elephants. The largest sirenian was the Steller's sea cow, which reached up to 10 m (33 ft) in length and weighed 8,000 to 10,000 kg (18,000 to 22,000 lb), and was hunted to extinction in the 18th century.[20]

In flightless birds edit

 
A size comparison between a human and 4 moa species:
1. Dinornis novaezealandiae
2. Emeus crassus
3. Anomalopteryx didiformis
4. Dinornis robustus

Because of the small initial size of all mammals following the extinction of the non-avian dinosaurs, nonmammalian vertebrates had a roughly ten-million-year-long window of opportunity (during the Paleocene) for evolution of gigantism without much competition.[21] During this interval, apex predator niches were often occupied by reptiles, such as terrestrial crocodilians (e.g. Pristichampsus), large snakes (e.g. Titanoboa) or varanid lizards, or by flightless birds[8] (e.g. Paleopsilopterus in South America). This is also the period when megafaunal flightless herbivorous gastornithid birds evolved in the Northern Hemisphere, while flightless paleognaths evolved to large size on Gondwanan land masses and Europe. Gastornithids and at least one lineage of flightless paleognath birds originated in Europe, both lineages dominating niches for large herbivores while mammals remained below 45 kg (in contrast with other landmasses like North America and Asia, which saw the earlier evolution of larger mammals) and were the largest European tetrapods in the Paleocene.[22]

Flightless paleognaths, termed ratites, have traditionally been viewed as representing a lineage separate from that of their small flighted relatives, the Neotropic tinamous. However, recent genetic studies have found that tinamous nest well within the ratite tree, and are the sister group of the extinct moa of New Zealand.[21][23][24] Similarly, the small kiwi of New Zealand have been found to be the sister group of the extinct elephant birds of Madagascar.[21] These findings indicate that flightlessness and gigantism arose independently multiple times among ratites via parallel evolution.[25]

Predatory megafaunal flightless birds were often able to compete with mammals in the early Cenozoic. Later in the Cenozoic, however, they were displaced by advanced carnivorans and died out. In North America, the bathornithids Paracrax and Bathornis were apex predators but became extinct by the Early Miocene. In South America, the related phorusrhacids shared the dominant predatory niches with metatherian sparassodonts during most of the Cenozoic but declined and ultimately went extinct after eutherian predators arrived from North America (as part of the Great American Interchange) during the Pliocene. In contrast, large herbivorous flightless ratites have survived to the present.[25]

However, none of the flightless birds of the Cenozoic, including the predatory Brontornis, possibly omnivorous Dromornis stirtoni[25] or herbivorous Aepyornis, ever grew to masses much above 500 kg, and thus never attained the size of the largest mammalian carnivores, let alone that of the largest mammalian herbivores. It has been suggested that the increasing thickness of avian eggshells in proportion to egg mass with increasing egg size places an upper limit on the size of birds.[26][note 1] The largest species of Dromornis, D. stirtoni, may have gone extinct after it attained the maximum avian body mass and was then outcompeted by marsupial diprotodonts that evolved to sizes several times larger.[29]

In giant turtles edit

Giant tortoises were important components of late Cenozoic megafaunas, being present in every nonpolar continent until the arrival of homininans.[30][31] The largest known terrestrial tortoise was Megalochelys atlas, an animal that probably weighed about 1,000 kg (2,200 lb).[32]

Some earlier aquatic Testudines, e.g. the marine Archelon of the Cretaceous[33] and freshwater Stupendemys of the Miocene, were considerably larger, weighing more than 2,000 kg (4,400 lb).[34]

Megafaunal mass extinctions edit

Timing and possible causes edit

 
Correlations between times of first appearance of humans and unique megafaunal extinction pulses on different land masses
 
Cyclical pattern of global climate change over the last 450,000 years (based on Antarctic temperatures and global ice volume), showing that there were no unique climatic events that would account for any of the megafaunal extinction pulses

The Quaternary extinction event occurred during the latter half of the last ice age glacial period when many giant ice age mammals, such as woolly mammoths, went extinct in the Americas, Australia-New Guinea, and northern Eurasia. An analysis of the extinction event in North America found it to be unique among Cenozoic extinction pulses in its selectivity for large animals.[35]: Fig. 10  Various theories have attributed the wave of extinctions to human hunting, climate change, disease, extraterrestrial impact, competition from other animals or other causes. However, this extinction near the end of the Pleistocene was just one of a series of megafaunal extinction pulses that have occurred during the last 50,000 years over much of the Earth's surface, with Africa and southern Asia (where the local megafauna had a chance to evolve alongside modern humans) being comparatively less affected. The latter areas did suffer gradual attrition of megafauna, particularly of the slower-moving species (a class of vulnerable megafauna epitomized by giant tortoises), over the last several million years.[36][37]

Outside the mainland of Afro-Eurasia, these megafaunal extinctions followed a highly distinctive landmass-by-landmass pattern that closely parallels the spread of humans into previously uninhabited regions of the world, and which shows no overall correlation with climatic history (which can be visualized with plots over recent geological time periods of climate markers such as marine oxygen isotopes or atmospheric carbon dioxide levels).[38][39] Australia[40] and nearby islands (e.g., Flores[41]) were struck first around 46,000 years ago, followed by Tasmania about 41,000 years ago (after formation of a land bridge to Australia about 43,000 years ago).[42][43][44] The role of humans in the extinction of Australia and New Guinea's megafauna has been disputed, with multiple studies showing a decline in the number of species prior to the arrival of humans on the continent and the absence of any evidence of human predation;[45][46][47][48] the impact of climate change has instead been cited for their decline.[49][45] Similarly, Japan lost most of its megafauna apparently about 30,000 years ago,[50] North America 13,000 years ago[note 2] and South America about 500 years later,[52][53] Cyprus 10,000 years ago,[54][55] the Antilles 6,000 years ago,[56][57] New Caledonia[58] and nearby islands[59] 3,000 years ago, Madagascar 2,000 years ago,[60] New Zealand 700 years ago,[61] the Mascarenes 400 years ago,[62] and the Commander Islands 250 years ago.[63] Nearly all of the world's isolated islands could furnish similar examples of extinctions occurring shortly after the arrival of humans, though most of these islands, such as the Hawaiian Islands, never had terrestrial megafauna, so their extinct fauna were smaller, but still displayed island gigantism.[38][39]

An analysis of the timing of Holarctic megafaunal extinctions and extirpations over the last 56,000 years has revealed a tendency for such events to cluster within interstadials, periods of abrupt warming, but only when humans were also present. Humans may have impeded processes of migration and recolonization that would otherwise have allowed the megafaunal species to adapt to the climate shift.[64] In at least some areas, interstadials were periods of expanding human populations.[65]

An analysis of Sporormiella fungal spores (which derive mainly from the dung of megaherbivores) in swamp sediment cores spanning the last 130,000 years from Lynch's Crater in Queensland, Australia, showed that the megafauna of that region virtually disappeared about 41,000 years ago, at a time when climate changes were minimal; the change was accompanied by an increase in charcoal, and was followed by a transition from rainforest to fire-tolerant sclerophyll vegetation. The high-resolution chronology of the changes supports the hypothesis that human hunting alone eliminated the megafauna, and that the subsequent change in flora was most likely a consequence of the elimination of browsers and an increase in fire.[66][67][68][69] The increase in fire lagged the disappearance of megafauna by about a century, and most likely resulted from accumulation of fuel once browsing stopped. Over the next several centuries grass increased; sclerophyll vegetation increased with a lag of another century, and a sclerophyll forest developed after about another thousand years.[68] During two periods of climate change about 120,000 and 75,000 years ago, sclerophyll vegetation had also increased at the site in response to a shift to cooler, drier conditions; neither of these episodes had a significant impact on megafaunal abundance.[68] Similar conclusions regarding the culpability of human hunters in the disappearance of Pleistocene megafauna were derived from high-resolution chronologies obtained via an analysis of a large collection of eggshell fragments of the flightless Australian bird Genyornis newtoni,[70][71][69] from analysis of Sporormiella fungal spores from a lake in eastern North America[72][73] and from study of deposits of Shasta ground sloth dung left in over half a dozen caves in the American Southwest.[74][75]

Continuing human hunting and environmental disturbance has led to additional megafaunal extinctions in the recent past, and has created a serious danger of further extinctions in the near future (see examples below). Direct killing by humans, primarily for meat or other body parts, is the most significant factor in contemporary megafaunal decline.[76][77]

A number of other mass extinctions occurred earlier in Earth's geologic history, in which some or all of the megafauna of the time also died out. Famously, in the Cretaceous–Paleogene extinction event the non-avian dinosaurs and most other giant reptiles were eliminated. However, the earlier mass extinctions were more global and not so selective for megafauna; i.e., many species of other types, including plants, marine invertebrates[78] and plankton, went extinct as well. Thus, the earlier events must have been caused by more generalized types of disturbances to the biosphere.[79]

Consequences of depletion of megafauna edit

Effect on nutrient transport edit

Megafauna play a significant role in the lateral transport of mineral nutrients in an ecosystem, tending to translocate them from areas of high to those of lower abundance. They do so by their movement between the time they consume the nutrient and the time they release it through elimination (or, to a much lesser extent, through decomposition after death).[80] In South America's Amazon Basin, it is estimated that such lateral diffusion was reduced over 98% following the megafaunal extinctions that occurred roughly 12,500 years ago.[81][82] Given that phosphorus availability is thought to limit productivity in much of the region, the decrease in its transport from the western part of the basin and from floodplains (both of which derive their supply from the uplift of the Andes) to other areas is thought to have significantly impacted the region's ecology, and the effects may not yet have reached their limits.[82] In the sea, cetaceans and pinnipeds that feed at depth are thought to translocate nitrogen from deep to shallow water, enhancing ocean productivity, and counteracting the activity of zooplankton, which tend to do the opposite.[83]

Effect on methane emissions edit

Large populations of megaherbivores have the potential to contribute greatly to the atmospheric concentration of methane, which is an important greenhouse gas. Modern ruminant herbivores produce methane as a byproduct of foregut fermentation in digestion, and release it through belching or flatulence. Today, around 20% of annual methane emissions come from livestock methane release. In the Mesozoic, it has been estimated that sauropods could have emitted 520 million tons of methane to the atmosphere annually,[84] contributing to the warmer climate of the time (up to 10 °C warmer than at present).[84][85] This large emission follows from the enormous estimated biomass of sauropods, and because methane production of individual herbivores is believed to be almost proportional to their mass.[84]

Recent studies have indicated that the extinction of megafaunal herbivores may have caused a reduction in atmospheric methane. This hypothesis is relatively new.[86] One study examined the methane emissions from the bison that occupied the Great Plains of North America before contact with European settlers. The study estimated that the removal of the bison caused a decrease of as much as 2.2 million tons per year.[87] Another study examined the change in the methane concentration in the atmosphere at the end of the Pleistocene epoch after the extinction of megafauna in the Americas. After early humans migrated to the Americas about 13,000 BP, their hunting and other associated ecological impacts led to the extinction of many megafaunal species there. Calculations suggest that this extinction decreased methane production by about 9.6 million tons per year. This suggests that the absence of megafaunal methane emissions may have contributed to the abrupt climatic cooling at the onset of the Younger Dryas.[86] The decrease in atmospheric methane that occurred at that time, as recorded in ice cores, was 2–4 times more rapid than any other decrease in the last half million years, suggesting that an unusual mechanism was at work.[86]

Gallery edit

Pleistocene extinct megafauna edit

Other extinct Cenozoic megafauna edit

Extant edit

See also edit

Notes edit

  1. ^ Nonavian dinosaur size was not similarly constrained because they had a different relationship between body mass and egg size than birds. The 400 kg Aepyornis had larger eggs than nearly all dinosaurs.[27][28]
  2. ^ Analysis indicates that 35 genera of North American mammals went extinct more or less simultaneously in this event.[51]

References edit

  1. ^ Moleón M, Sánchez-Zapata JA, Donázar JA, Revilla E, Martín-López B, Gutiérrez-Cánovas C, Getz WM, Morales-Reyes Z, Campos-Arceiz A, Crowder LB, Galetti M, González-Suárez M, He F, Jordano P, Lewison R (2020-03-11). "Rethinking megafauna". Proceedings of the Royal Society B: Biological Sciences. 287 (1922): 20192643. doi:10.1098/rspb.2019.2643. ISSN 0962-8452. PMC 7126068. PMID 32126954.
  2. ^ Malhi Y, Doughty CE, Galetti M, Smith FA, Svenning JC, Terborgh JW (2016-01-26). "Megafauna and ecosystem function from the Pleistocene to the Anthropocene". Proceedings of the National Academy of Sciences. 113 (4): 838–846. Bibcode:2016PNAS..113..838M. doi:10.1073/pnas.1502540113. ISSN 0027-8424. PMC 4743772. PMID 26811442.
  3. ^ McClenachan L, Cooper AB, Dulvy NK (2016-06-20). "Rethinking Trade-Driven Extinction Risk in Marine and Terrestrial Megafauna". Current Biology. 26 (12): 1640–1646. Bibcode:2016CBio...26.1640M. doi:10.1016/j.cub.2016.05.026. ISSN 1879-0445. PMID 27291051.
  4. ^ https://www.britannica.com/science/K-selected-species 2016-10-11 at the Wayback Machine. Britannica. Retrieved 2017-4-2.
  5. ^ Barnosky AD (2004-10-01). "Assessing the Causes of Late Pleistocene Extinctions on the Continents". Science. 306 (5693): 70–75. Bibcode:2004Sci...306...70B. CiteSeerX 10.1.1.574.332. doi:10.1126/science.1101476. PMID 15459379. S2CID 36156087.
  6. ^ Brook BW, Johnson CN (2006). "Selective hunting of juveniles as a cause of the imperceptible overkill of the Australian Pleistocene megafauna". Alcheringa: An Australasian Journal of Palaeontology. 30 (sup1): 39–48. Bibcode:2006Alch...30S..39B. doi:10.1080/03115510609506854. S2CID 84205755.
  7. ^ a b c d e f g Evans AR, Jones D, Boyer AG, Brown JH, Costa DP, Ernest SK, Fitzgerald EM, Fortelius M, Gittleman JL, Hamilton MJ, Harding LE, Lintulaakso K, Lyons SK, Okie JG, Saarinen JJ, Sibly RM, Smith FA, Stephens PR, Theodor JM, Uhen MD (2012-01-30). "The maximum rate of mammal evolution". PNAS. 109 (11): 4187–4190. Bibcode:2012PNAS..109.4187E. doi:10.1073/pnas.1120774109. PMC 3306709. PMID 22308461.
  8. ^ a b c d e f g Smith FA, Boyer AG, Brown JH, Costa DP, Dayan T, Ernest SK, Evans AR, Fortelius M, Gittleman JL, Hamilton MJ, Harding LE, Lintulaakso K, Lyons SK, McCain C, Okie JG, Saarinen JJ, Sibly RM, Stephens PR, Theodor J, Uhen MD (2010-11-26). "The Evolution of Maximum Body Size of Terrestrial Mammals". Science. 330 (6008): 1216–1219. Bibcode:2010Sci...330.1216S. CiteSeerX 10.1.1.383.8581. doi:10.1126/science.1194830. PMID 21109666. S2CID 17272200.
  9. ^ Clauss M, Frey, R., Kiefer, B., Lechner-Doll, M., Loehlein, W., Polster, C., Roessner, G. E., Streich, W. J. (2003-04-24). (PDF). Oecologia. 136 (1): 14–27. Bibcode:2003Oecol.136...14C. doi:10.1007/s00442-003-1254-z. PMID 12712314. S2CID 206989975. Archived from the original (PDF) on 2019-06-08. Retrieved 2019-07-13.
  10. ^ a b Sorkin B (2008-04-10). "A biomechanical constraint on body mass in terrestrial mammalian predators". Lethaia. 41 (4): 333–347. Bibcode:2008Letha..41..333S. doi:10.1111/j.1502-3931.2007.00091.x.
  11. ^ Carbone C, Teacher, A, Rowcliffe, J. M. (2007-01-16). "The Costs of Carnivory". PLOS Biology. 5 (2, e22): 363–368. doi:10.1371/journal.pbio.0050022. PMC 1769424. PMID 17227145.
  12. ^ a b c Ashton KG, Tracy, M. C., de Queiroz, A. (October 2000). "Is Bergmann's Rule Valid for Mammals?". The American Naturalist. 156 (4): 390–415. doi:10.1086/303400. JSTOR 10.1086/303400. PMID 29592141. S2CID 205983729.
  13. ^ Webb J (2015-02-19). "Evolution 'favours bigger sea creatures'". BBC News. BBC. from the original on 2015-02-22. Retrieved 2015-02-22.
  14. ^ Heim NA, Knope ML, Schaal EK, Wang SC, Payne JL (2015-02-20). "Cope's rule in the evolution of marine animals". Science. 347 (6224): 867–870. Bibcode:2015Sci...347..867H. doi:10.1126/science.1260065. PMID 25700517. from the original on 2019-07-05. Retrieved 2019-07-13.
  15. ^ Thewissen JG, Bajpai, S. (1 January 2001). "Whale Origins as a Poster Child for Macroevolution". BioScience. 51 (12): 1037–1049. doi:10.1641/0006-3568(2001)051[1037:WOAAPC]2.0.CO;2. ISSN 0006-3568.
  16. ^ a b Goldbogen JA, Cade DE, Wisniewska DM, Potvin J, Segre PS, Savoca MS, Hazen EL, Czapanskiy MF, Kahane-Rapport SR, DeRuiter SL, Gero S, Tønnesen P, Gough WT, Hanson MB, Holt MM, Jensen FH, Simon M, Stimpert AK, Arranz P, Johnston DW, Nowacek DP, Parks SE, Visser F, Friedlaender AS, Tyack PL, Madsen PT, Pyenson ND (2019). "Why whales are big but not bigger: Physiological drivers and ecological limits in the age of ocean giants". Science. 366 (6471): 1367–1372. Bibcode:2019Sci...366.1367G. doi:10.1126/science.aax9044. hdl:10023/19285. PMID 31831666. S2CID 209339266.
  17. ^ Baker J, Meade A, Pagel M, Venditti C (2015-04-21). "Adaptive evolution toward larger size in mammals". Proceedings of the National Academy of Sciences. 112 (16): 5093–5098. Bibcode:2015PNAS..112.5093B. doi:10.1073/pnas.1419823112. ISSN 0027-8424. PMC 4413265. PMID 25848031.
  18. ^ Churchill M, Clementz MT, Kohno N (2014-12-19). "Cope's rule and the evolution of body size in Pinnipedimorpha (Mammalia: Carnivora)". Evolution. 69 (1): 201–215. doi:10.1111/evo.12560. ISSN 0014-3820. PMID 25355195.
  19. ^ Haley MP, Deutsch CJ, Boeuf BJ (April 1991). "A method for estimating mass of large pinnipeds". Marine Mammal Science. 7 (2): 157–164. Bibcode:1991MMamS...7..157H. doi:10.1111/j.1748-7692.1991.tb00562.x. ISSN 0824-0469.
  20. ^ Goldbogen JA (2018-04-17). "Physiological constraints on marine mammal body size". Proceedings of the National Academy of Sciences. 115 (16): 3995–3997. Bibcode:2018PNAS..115.3995G. doi:10.1073/pnas.1804077115. ISSN 0027-8424. PMC 5910879. PMID 29618615.
  21. ^ a b c Mitchell KJ, Llamas B, Soubrier J, Rawlence NJ, Worthy TH, Wood J, Lee MS, Cooper A (2014-05-23). "Ancient DNA reveals elephant birds and kiwi are sister taxa and clarifies ratite bird evolution" (PDF). Science. 344 (6186): 898–900. Bibcode:2014Sci...344..898M. doi:10.1126/science.1251981. hdl:2328/35953. PMID 24855267. S2CID 206555952. (PDF) from the original on 2023-03-15. Retrieved 2019-09-24.
  22. ^ Buffetaut E, Angst D (November 2014). "Stratigraphic distribution of large flightless birds in the Palaeogene of Europe and its palaeobiological and palaeogeographical implications". Earth-Science Reviews. 138: 394–408. Bibcode:2014ESRv..138..394B. doi:10.1016/j.earscirev.2014.07.001.
  23. ^ Phillips MJ, Gibb GC, Crimp EA, Penny D (January 2010). "Tinamous and moa flock together: mitochondrial genome sequence analysis reveals independent losses of flight among ratites". Systematic Biology. 59 (1): 90–107. doi:10.1093/sysbio/syp079. PMID 20525622.
  24. ^ Baker AJ, Haddrath O, McPherson JD, Cloutier A (2014). "Genomic Support for a Moa-Tinamou Clade and Adaptive Morphological Convergence in Flightless Ratites". Molecular Biology and Evolution. 31 (7): 1686–1696. doi:10.1093/molbev/msu153. PMID 24825849.
  25. ^ a b c Murray PF, Vickers-Rich P (2004). Magnificent Mihirungs: The Colossal Flightless Birds of the Australian Dreamtime. Indiana University Press. pp. 51, 314. ISBN 978-0-253-34282-9. Retrieved 7 January 2012.
  26. ^ Ibid (2004). p. 212. Indiana University Press. ISBN 978-0-253-34282-9.
  27. ^ Kenneth Carpenter (1999). Eggs, Nests, and Baby Dinosaurs: A Look at Dinosaur Reproduction. Indiana University Press. p. 100. ISBN 978-0-253-33497-8. OCLC 42009424. Retrieved 6 May 2013.
  28. ^ Jackson FD, Varricchio DJ, Jackson RA, Vila B, Chiappe LM (2008). "Comparison of water vapor conductance in a titanosaur egg from the Upper Cretaceous of Argentina and a Megaloolithus siruguei egg from Spain". Paleobiology. 34 (2): 229–246. doi:10.1666/0094-8373(2008)034[0229:COWVCI]2.0.CO;2. ISSN 0094-8373. S2CID 85880201.
  29. ^ Ibid (2004). p. 277. Indiana University Press. ISBN 978-0-253-34282-9.
  30. ^ Hansen DM, Donlan, C. J., Griffiths, C. J., Campbell, K. J. (April 2010). (PDF). Ecography. 33 (2): 272–284. Bibcode:2010Ecogr..33..272H. doi:10.1111/j.1600-0587.2010.06305.x. Archived from the original (PDF) on July 24, 2011. Retrieved 2011-02-26.
  31. ^ Cione AL, Tonni, E. P., Soibelzon, L. (2003). "The Broken Zig-Zag: Late Cenozoic large mammal and tortoise extinction in South America". Rev. Mus. Argentino Cienc. Nat. Nueva Serie. 5 (1): 1–19. doi:10.22179/REVMACN.5.26. ISSN 1514-5158.
  32. ^ Gordon IJ, Prins HH, Mallon J, Puk LD, Miranda EB, Starling-Manne C, van der Wal R, Moore B, Foley W (2019), Gordon IJ, Prins HH (eds.), "The Ecology of Browsing and Grazing in Other Vertebrate Taxa", The Ecology of Browsing and Grazing II, Cham: Springer International Publishing, pp. 339–404, doi:10.1007/978-3-030-25865-8_15, ISBN 978-3-030-25865-8
  33. ^ Jaffe AL, Slater GJ, Alfaro ME (2011-08-23). "The evolution of island gigantism and body size variation in tortoises and turtles". Biology Letters. 7 (4): 558–561. doi:10.1098/rsbl.2010.1084. ISSN 1744-9561. PMC 3130210. PMID 21270022.
  34. ^ Cadena EA, Link A, Cooke SB, Stroik LK, Vanegas AF, Tallman M (December 2021). "New insights on the anatomy and ontogeny of the largest extinct freshwater turtles". Heliyon. 7 (12): e08591. Bibcode:2021Heliy...708591C. doi:10.1016/j.heliyon.2021.e08591. ISSN 2405-8440. PMC 8717240. PMID 35005268.
  35. ^ Alroy J (1999), "Putting North America's End-Pleistocene Megafaunal Extinction in Context: Large-Scale Analyses of Spatial Patterns, Extinction Rates, and Size Distributions", in MacPhee RD (ed.), Extinctions in Near Time: Causes, Contexts, and Consequences, Advances in Vertebrate Paleobiology, vol. 2, New York: Plenum, pp. 105–143, doi:10.1007/978-1-4757-5202-1_6, ISBN 978-1-4757-5202-1, OCLC 41368299, from the original on 2018-06-09
  36. ^ Corlett RT (2006). "Megafaunal extinctions in tropical Asia" (PDF). Tropinet. 17 (3): 1–3. (PDF) from the original on 2016-03-04. Retrieved 2010-10-04.
  37. ^ Edmeades B. . megafauna.com. (internet-published book with Foreword by Paul S. Martin). Archived from the original on 2014-12-25. Retrieved 2020-02-13.
  38. ^ a b Martin PS (2005). "Chapter 6. Deadly Syncopation". Twilight of the Mammoths: Ice Age Extinctions and the Rewilding of America. University of California Press. pp. 118–128. ISBN 978-0-520-23141-2. OCLC 58055404. from the original on 2024-03-27. Retrieved 2014-11-11.
  39. ^ a b Burney DA, Flannery TF (July 2005). (PDF). Trends in Ecology & Evolution. 20 (7): 395–401. doi:10.1016/j.tree.2005.04.022. PMID 16701402. Archived from the original (PDF) on 2010-06-10. Retrieved 2014-11-11.
  40. ^ Roberts RG, Flannery TF, Ayliffe LK, Yoshida H, Olley JM, Prideaux GJ, Laslett GM, Baynes A, Smith MA, Jones R, Smith BL (2001-06-08). "New Ages for the Last Australian Megafauna: Continent-Wide Extinction About 46,000 Years Ago" (PDF). Science. 292 (5523): 1888–1892. Bibcode:2001Sci...292.1888R. doi:10.1126/science.1060264. PMID 11397939. S2CID 45643228. (PDF) from the original on 2019-02-10. Retrieved 2011-08-26.
  41. ^ Callaway E (2016-09-21). "Human remains found in hobbit cave". Nature. doi:10.1038/nature.2016.20656. S2CID 89272546.
  42. ^ Diamond J (2008-08-13). "Palaeontology: The last giant kangaroo". Nature. 454 (7206): 835–836. Bibcode:2008Natur.454..835D. doi:10.1038/454835a. PMID 18704074. S2CID 36583693.
  43. ^ Turney CS, Flannery TF, Roberts RG, Reid C, Fifield LK, Higham TF, Jacobs Z, Kemp N, Colhoun EA, Kalin RM, Ogle N (2008-08-21). "Late-surviving megafauna in Tasmania, Australia, implicate human involvement in their extinction". PNAS. 105 (34): 12150–12153. Bibcode:2008PNAS..10512150T. doi:10.1073/pnas.0801360105. PMC 2527880. PMID 18719103.
  44. ^ Roberts R, Jacobs, Z. (October 2008). (PDF). Australasian Science. 29 (9): 14–17. Archived from the original (PDF) on 2011-09-27. Retrieved 2011-08-26.
  45. ^ a b Field J, Wroe S, Trueman CN, Garvey J, Wyatt-Spratt S (2013-02-08). "Looking for the archaeological signature in Australian Megafaunal extinctions". Quaternary International. Peopling the last new worlds: the first colonisation of Sahul and the Americas. 285: 76–88. Bibcode:2013QuInt.285...76F. doi:10.1016/j.quaint.2011.04.013. ISSN 1040-6182. from the original on 2012-12-18.
  46. ^ Dodson J, Field JH (2018). "What does the occurrence of Sporormiella (Preussia) spores mean in Australian fossil sequences?". Journal of Quaternary Science. 33 (4): 380–392. Bibcode:2018JQS....33..380D. doi:10.1002/jqs.3020. ISSN 1099-1417. S2CID 133737405. from the original on 2022-02-14.
  47. ^ Wroe S, Field JH, Archer M, Grayson DK, Price GJ, Louys J, Faith JT, Webb GE, Davidson I, Mooney SD (2013-09-03). "Reply to Brook et al: No empirical evidence for human overkill of megafauna in Sahul". Proceedings of the National Academy of Sciences. 110 (36): E3369. Bibcode:2013PNAS..110E3369W. doi:10.1073/pnas.1310440110. ISSN 0027-8424. PMC 3767508. PMID 24137797.
  48. ^ Dortch J, Cupper M, Grün R, Harpley B, Lee K, Field J (2016-08-01). "The timing and cause of megafauna mass deaths at Lancefield Swamp, south-eastern Australia". Quaternary Science Reviews. 145: 161–182. Bibcode:2016QSRv..145..161D. doi:10.1016/j.quascirev.2016.05.042. ISSN 0277-3791. from the original on 2024-03-27.
  49. ^ Wroe S, Field JH, Archer M, Grayson DK, Price GJ, Louys J, Faith JT, Webb GE, Davidson I, Mooney SD (2013-05-28). "Climate change frames debate over the extinction of megafauna in Sahul (Pleistocene Australia-New Guinea)". Proceedings of the National Academy of Sciences. 110 (22): 8777–8781. Bibcode:2013PNAS..110.8777W. doi:10.1073/pnas.1302698110. ISSN 0027-8424. PMC 3670326. PMID 23650401.
  50. ^ Norton CJ, Kondo, Y., Ono, A., Zhang, Y., Diab, M. C. (2009-05-23). "The nature of megafaunal extinctions during the MIS 3–2 transition in Japan". Quaternary International. 211 (1–2): 113–122. Bibcode:2010QuInt.211..113N. doi:10.1016/j.quaint.2009.05.002.
  51. ^ Faith JT, Surovell TA (2009-12-08). "Synchronous extinction of North America's Pleistocene mammals". Proceedings of the National Academy of Sciences. 106 (49): 20641–20645. Bibcode:2009PNAS..10620641F. doi:10.1073/pnas.0908153106. PMC 2791611. PMID 19934040.
  52. ^ Haynes G (2009). "Introduction to the Volume". In Haynes G (ed.). American Megafaunal Extinctions at the End of the Pleistocene. Vertebrate Paleobiology and Paleoanthropology. Springer. pp. 1–20. doi:10.1007/978-1-4020-8793-6_1. ISBN 978-1-4020-8792-9.[permanent dead link]
  53. ^ Fiedel S (2009). "Sudden Deaths: The Chronology of Terminal Pleistocene Megafaunal Extinction". In Haynes G (ed.). American Megafaunal Extinctions at the End of the Pleistocene. Vertebrate Paleobiology and Paleoanthropology. Springer. pp. 21–37. doi:10.1007/978-1-4020-8793-6_2. ISBN 978-1-4020-8792-9.
  54. ^ Simmons AH (1999). Faunal extinction in an island society: pygmy hippopotamus hunters of Cyprus. Interdisciplinary Contributions to Archaeology. Kluwer Academic/Plenum Publishers. p. 382. doi:10.1007/b109876. ISBN 978-0-306-46088-3. OCLC 41712246. from the original on 2024-03-27. Retrieved 2016-05-07.
  55. ^ Simmons AH, Mandel, R. D. (December 2007). "Not Such a New Light: A Response to Ammerman and Noller". World Archaeology. 39 (4): 475–482. doi:10.1080/00438240701676169. JSTOR 40026143. S2CID 161791746.
  56. ^ Steadman DW, Martin PS, MacPhee RD, Jull AJ, McDonald HG, Woods CA, Iturralde-Vinent M, Hodgins GW (2005-08-16). "Asynchronous extinction of late Quaternary sloths on continents and islands". Proc. Natl. Acad. Sci. USA. 102 (33): 11763–11768. Bibcode:2005PNAS..10211763S. doi:10.1073/pnas.0502777102. PMC 1187974. PMID 16085711.
  57. ^ Cooke SB, Dávalos LM, Mychajliw AM, Turvey ST, Upham NS (2017). "Anthropogenic Extinction Dominates Holocene Declines of West Indian Mammals". Annual Review of Ecology, Evolution, and Systematics. 48 (1): 301–327. doi:10.1146/annurev-ecolsys-110316-022754. S2CID 90558542.
  58. ^ Anderson A, Sand, C., Petchey, F., Worthy, T. H. (2010). "Faunal extinction and human habitation in New Caledonia: Initial results and implications of new research at the Pindai Caves". Journal of Pacific Archaeology. 1 (1): 89–109. hdl:10289/5404.
  59. ^ White AW, Worthy, T. H., Hawkins, S., Bedford, S., Spriggs, M. (2010-08-16). "Megafaunal meiolaniid horned turtles survived until early human settlement in Vanuatu, Southwest Pacific". Proc. Natl. Acad. Sci. USA. 107 (35): 15512–15516. Bibcode:2010PNAS..10715512W. doi:10.1073/pnas.1005780107. PMC 2932593. PMID 20713711.
  60. ^ Burney DA, Burney, L. P., Godfrey, L. R., Jungers, W. L., Goodman, S. M., Wright, H. T., Jull. A. J. T. (July 2004). "A chronology for late prehistoric Madagascar". Journal of Human Evolution. 47 (1–2): 25–63. doi:10.1016/j.jhevol.2004.05.005. PMID 15288523.
  61. ^ Holdaway RN, Jacomb, C. (2000-03-24). "Rapid Extinction of the Moas (Aves: Dinornithiformes): Model, Test, and Implications". Science. 287 (5461): 2250–2254. Bibcode:2000Sci...287.2250H. doi:10.1126/science.287.5461.2250. PMID 10731144.
  62. ^ Janoo A (April 2005). "Discovery of isolated dodo bones (Raphus cucullatus (L.), Aves, Columbiformes) from Mauritius cave shelters highlights human predation, with a comment on the status of the family Raphidae Wetmore, 1930". Annales de Paléontologie. 91 (2): 167–180. Bibcode:2005AnPal..91..167J. doi:10.1016/j.annpal.2004.12.002.
  63. ^ Anderson PK (July 1995). "Competition, Predation, and the Evolution and Extinction of Steller's Sea Cow, Hydrodamalis gigas". Marine Mammal Science. 11 (3): 391–394. Bibcode:1995MMamS..11..391A. doi:10.1111/j.1748-7692.1995.tb00294.x. Archived from the original on 2011-05-11. Retrieved 2011-08-30.
  64. ^ Cooper A, Turney C, Hughen KA, Brook BW, McDonald HG, Bradshaw CJ (2015-07-23). "Abrupt warming events drove Late Pleistocene Holarctic megafaunal turnover". Science. 349 (6248): 602–6. Bibcode:2015Sci...349..602C. doi:10.1126/science.aac4315. PMID 26250679. S2CID 31686497.
  65. ^ Müller UC, Pross J, Tzedakis PC, Gamble C, Kotthoff U, Schmiedl G, Wulf S, Christanis K (February 2011). "The role of climate in the spread of modern humans into Europe". Quaternary Science Reviews. 30 (3–4): 273–279. Bibcode:2011QSRv...30..273M. doi:10.1016/j.quascirev.2010.11.016.
  66. ^ Biello D (2012-03-22). "Big Kill, Not Big Chill, Finished Off Giant Kangaroos". Scientific American news. from the original on 2012-03-23. Retrieved 2012-03-25.
  67. ^ McGlone M (2012-03-23). "The Hunters Did It". Science. 335 (6075): 1452–1453. Bibcode:2012Sci...335.1452M. doi:10.1126/science.1220176. PMID 22442471. S2CID 36914192.
  68. ^ a b c Rule S, Brook, B. W., Haberle, S. G., Turney, C. S. M., Kershaw, A. P. (2012-03-23). "The Aftermath of Megafaunal Extinction: Ecosystem Transformation in Pleistocene Australia". Science. 335 (6075): 1483–1486. Bibcode:2012Sci...335.1483R. doi:10.1126/science.1214261. PMID 22442481. S2CID 26675232.
  69. ^ a b Johnson CN, Alroy J, Beeton NJ, Bird MI, Brook BW, Cooper A, Gillespie R, Herrando-Pérez S, Jacobs Z, Miller GH, Prideaux GJ, Roberts RG, Rodríguez-Rey M, Saltré F, Turney CS, Bradshaw CJ (10 February 2016). "What caused extinction of the Pleistocene megafauna of Sahul?". Proceedings of the Royal Society B: Biological Sciences. 283 (1824): 20152399. doi:10.1098/rspb.2015.2399. PMC 4760161. PMID 26865301.
  70. ^ Miller GH, Magee JW, Johnson BJ, Fogel ML, Spooner NA, McCulloch MT, Ayliffe LK (1999-01-08). "Pleistocene Extinction of Genyornis newtoni: Human Impact on Australian Megafauna". Science. 283 (5399): 205–208. doi:10.1126/science.283.5399.205. PMID 9880249.
  71. ^ Miller G, Magee J, Smith M, Spooner N, Baynes A, Lehman S, Fogel M, Johnston H, Williams D, Clark P, Florian C, Holst R, DeVogel S (2016-01-29). "Human predation contributed to the extinction of the Australian megafaunal bird Genyornis newtoni ~47 ka". Nature Communications. 7: 10496. Bibcode:2016NatCo...710496M. doi:10.1038/ncomms10496. PMC 4740177. PMID 26823193.
  72. ^ Johnson C (2009-11-20). "Megafaunal Decline and Fall". Science. 326 (5956): 1072–1073. Bibcode:2009Sci...326.1072J. doi:10.1126/science.1182770. PMID 19965418. S2CID 206523763.
  73. ^ Gill JL, Williams JW, Jackson ST, Lininger KB, Robinson GS (2009-11-20). "Pleistocene Megafaunal Collapse, Novel Plant Communities, and Enhanced Fire Regimes in North America" (PDF). Science. 326 (5956): 1100–1103. Bibcode:2009Sci...326.1100G. doi:10.1126/science.1179504. PMID 19965426. S2CID 206522597. (PDF) from the original on 2017-09-22. Retrieved 2018-11-09.
  74. ^ Fiedal S (2009). "Sudden Deaths: The Chronology of Terminal Pleistocene Megafaunal Extinction". In Haynes G (ed.). American Megafaunal Extinctions at the End of the Pleistocene. Vertebrate Paleobiology and Paleoanthropology. Springer. pp. 21–37. doi:10.1007/978-1-4020-8793-6_2. ISBN 978-1-4020-8792-9.
  75. ^ Martin PS (2005). "Chapter 4. Ground Sloths at Home". Twilight of the Mammoths: Ice Age Extinctions and the Rewilding of America. University of California Press. pp. 78–99. ISBN 978-0-520-23141-2. OCLC 58055404. from the original on 2024-03-27. Retrieved 2014-11-11.
  76. ^ Milman O (February 6, 2019). "The killing of large species is pushing them towards extinction, study finds". The Guardian. from the original on February 7, 2019. Retrieved February 13, 2019.
  77. ^ Ripple WJ, et al. (2019). "Are we eating the world's megafauna to extinction?". Conservation Letters. 12 (3): e12627. Bibcode:2019ConL...12E2627R. doi:10.1111/conl.12627.
  78. ^ Alroy J (2008-08-12). "Dynamics of origination and extinction in the marine fossil record". PNAS. 105 Suppl 1 (Supplement_1): 11536–11542. Bibcode:2008PNAS..10511536A. doi:10.1073/pnas.0802597105. PMC 2556405. PMID 18695240.
  79. ^ D'Hondt S (2005-12-01). "Consequences of the Cretaceous/Paleogene Mass Extinction for Marine Ecosystems". Annual Review of Ecology, Evolution, and Systematics. 36 (1): 295–317. doi:10.1146/annurev.ecolsys.35.021103.105715. ISSN 1543-592X.
  80. ^ Wolf A, Doughty CE, Malhi Y (2013). "Lateral Diffusion of Nutrients by Mammalian Herbivores in Terrestrial Ecosystems". PLoS ONE. 8 (8): e71352. Bibcode:2013PLoSO...871352W. doi:10.1371/journal.pone.0071352. PMC 3739793. PMID 23951141.
  81. ^ Marshall M (2013-08-11). "Ecosystems still feel the pain of ancient extinctions". New Scientist. from the original on 2015-07-04. Retrieved 2013-08-12.
  82. ^ a b Doughty CE, Wolf A, Malhi Y (2013-08-11). "The legacy of the Pleistocene megafauna extinctions on nutrient availability in Amazonia". Nature Geoscience. 6 (9): 761–764. Bibcode:2013NatGe...6..761D. doi:10.1038/ngeo1895.
  83. ^ Roman J, McCarthy J (2010). "The Whale Pump: Marine Mammals Enhance Primary Productivity in a Coastal Basin". PLOS ONE. 5 (10): e13255. Bibcode:2010PLoSO...513255R. doi:10.1371/journal.pone.0013255. PMC 2952594. PMID 20949007.
  84. ^ a b c Wilkinson DM, Nisbet, E. G., Ruxton, G. D. (2012-05-08). "Could methane produced by sauropod dinosaurs have helped drive Mesozoic climate warmth?". Current Biology. 22 (9): R292–R293. Bibcode:2012CBio...22.R292W. doi:10.1016/j.cub.2012.03.042. PMID 22575462.
  85. ^ "Dinosaur gases 'warmed the Earth'". BBC Nature News. 2012-05-07. from the original on 2015-12-01. Retrieved 2012-05-08.
  86. ^ a b c Smith FA, Elliot, S. M., Lyons, S. K. (2010-05-23). "Methane emissions from extinct megafauna". Nature Geoscience. 3 (6): 374–375. Bibcode:2010NatGe...3..374S. doi:10.1038/ngeo877.
  87. ^ Kelliher FM, Clark, H. (2010-03-15). "Methane emissions from bison—An historic herd estimate for the North American Great Plains". Agricultural and Forest Meteorology. 150 (3): 473–577. Bibcode:2010AgFM..150..473K. doi:10.1016/j.agrformet.2009.11.019.
  88. ^ Palmer, D., ed. (1999). The Marshall Illustrated Encyclopedia of Dinosaurs and Prehistoric Animals. London: Marshall Editions. p. 248. ISBN 978-1-84028-152-1.
  89. ^ Moyano S, Giannini N (2018-10-10). "Cranial characters associated with the proboscis postnatal-development in Tapirus (Perissodactyla: Tapiridae) and comparisons with other extant and fossil hoofed mammals". Zoologischer Anzeiger. 277 (7554): 143–147. doi:10.1016/j.jcz.2018.08.005. ISSN 0044-5231. S2CID 92143497.
  90. ^ Tsubamoto T (2012). "Estimating body mass from the astragalus in mammals". Acta Palaeontologica Polonica: 259–265. doi:10.4202/app.2011.0067. S2CID 54686160.
  91. ^ Stuart AJ (November 1991). "Mammalian extinctions in the Late Pleistocene of northern Eurasia and North America". Biological Reviews. 66 (4): 453–562. doi:10.1111/j.1469-185X.1991.tb01149.x. PMID 1801948. S2CID 41295526.
  92. ^ Sample, Ian (19 February 2010). "Great white shark is more endangered than tiger, claims scientist". The Guardian. from the original on 9 September 2013. Retrieved 14 August 2013.

External links edit

    January 01, 1970
    megafauna, this, article, about, living, extinct, large, animals, other, uses, disambiguation, zoology, megafauna, from, greek, μέγας, megas, large, latin, fauna, animal, life, large, animals, most, common, thresholds, megafauna, weighing, over, weighing, over. This article is about living or extinct large animals For other uses see Megafauna disambiguation In zoology megafauna from Greek megas megas large and Neo Latin fauna animal life are large animals The most common thresholds to be a megafauna are weighing over 45 kg 99 lb or weighing over 1 000 kg 2 200 lb The first occurrence of the term was in 1876 After the Cretaceous Paleogene extinction event wiped out all non avian dinosaurs mammals and other vertebrates experienced an expansion in size Millions of years of evolution led to gigantism on every major land mass During the Quaternary extinction event many species of megafauna went extinct as part of a slowly progressing extinction wave that affected ecosystems worldwide The African bush elephant foreground Earth s largest extant land mammal and the Masai ostrich background one of Earth s largest extant birds In practice the most common usage encountered in academic and popular writing describes land mammals roughly larger than a human that are not solely domesticated The term is especially associated with the Pleistocene megafauna the land animals that are considered archetypical of the last ice age such as mammoths the majority of which in northern Eurasia Australia New Guinea and the Americas became extinct within the last forty thousand years Contents 1 History 2 Ecological strategy 3 Evolution of large body size 3 1 In terrestrial mammals 3 2 In marine mammals 3 3 In flightless birds 3 4 In giant turtles 4 Megafaunal mass extinctions 4 1 Timing and possible causes 4 2 Consequences of depletion of megafauna 4 2 1 Effect on nutrient transport 4 2 2 Effect on methane emissions 5 Gallery 5 1 Pleistocene extinct megafauna 5 2 Other extinct Cenozoic megafauna 5 3 Extant 6 See also 7 Notes 8 References 9 External linksHistory editOne of the earliest occurrences of the term megafauna is Alfred Russel Wallace s 1876 work The geographical distribution of animals He described the animals as the hugest and fiercest and strangest forms In the later 20th and 21st centuries the term usually refers to large animals There are variations in thresholds used to define megafauna as a whole or certain groups of megafauna Many scientific literature adopt Martin s threshold of lt 45 kg to classify animals under this group However for freshwater species 30 kg is the preferred threshold Some scientists define herbivorous terrestrial megafauna as having a weight exceeding 100 kg and terrestrial carnivorous megafauna as more than 15 kg Additionally Owen Smith coined the term megaherbivore to describe herbivores that weighed over a tonne 1 Among living animals the term megafauna is most commonly used for the largest extant terrestrial mammals which includes but is not limited to elephants giraffes hippopotamuses rhinoceroses and large bovines Of these five categories of large herbivores only bovines are presently found outside of Africa and southern Asia but all the others were formerly more wide ranging with their ranges and populations continually shrinking and decreasing over time Wild equines are another example of megafauna but their current ranges are largely restricted to the Old World specifically Africa and Asia Megafaunal species may be categorized according to their dietary type megaherbivores e g elephants megacarnivores e g lions and more rarely megaomnivores e g bears 2 3 Ecological strategy editMegafauna animals in the sense of the largest mammals and birds are generally K strategists with high longevity slow population growth rates low mortality rates and at least for the largest few or no natural predators capable of killing adults 4 These characteristics although not exclusive to such megafauna make them vulnerable to human overexploitation in part because of their slow population recovery rates 5 6 Evolution of large body size editOne observation that has been made about the evolution of larger body size is that rapid rates of increase that are often seen over relatively short time intervals are not sustainable over much longer time periods In an examination of mammal body mass changes over time the maximum increase possible in a given time interval was found to scale with the interval length raised to the 0 25 power 7 This is thought to reflect the emergence during a trend of increasing maximum body size of a series of anatomical physiological environmental genetic and other constraints that must be overcome by evolutionary innovations before further size increases are possible A strikingly faster rate of change was found for large decreases in body mass such as may be associated with the phenomenon of insular dwarfism When normalized to generation length the maximum rate of body mass decrease was found to be over 30 times greater than the maximum rate of body mass increase for a ten fold change 7 In terrestrial mammals edit nbsp Large terrestrial mammals compared in size to one of the largest sauropod dinosaurs Patagotitan Subsequent to the Cretaceous Paleogene extinction event that eliminated the non avian dinosaurs about 66 Ma million years ago terrestrial mammals underwent a nearly exponential increase in body size as they diversified to occupy the ecological niches left vacant 8 Starting from just a few kg before the event maximum size had reached 50 kg a few million years later and 750 kg by the end of the Paleocene This trend of increasing body mass appears to level off about 40 Ma ago in the late Eocene suggesting that physiological or ecological constraints had been reached after an increase in body mass of over three orders of magnitude 8 However when considered from the standpoint of rate of size increase per generation the exponential increase is found to have continued until the appearance of Indricotherium 30 Ma ago Since generation time scales with body mass0 259 increasing generation times with increasing size cause the log mass vs time plot to curve downward from a linear fit 7 Megaherbivores eventually attained a body mass of over 10 000 kg The largest of these indricotheres and proboscids have been hindgut fermenters which are believed to have an advantage over foregut fermenters in terms of being able to accelerate gastrointestinal transit in order to accommodate very large food intakes 9 A similar trend emerges when rates of increase of maximum body mass per generation for different mammalian clades are compared using rates averaged over macroevolutionary time scales Among terrestrial mammals the fastest rates of increase of body mass0 259 vs time in Ma occurred in perissodactyls a slope of 2 1 followed by rodents 1 2 and proboscids 1 1 7 all of which are hindgut fermenters The rate of increase for artiodactyls 0 74 was about a third that of perissodactyls The rate for carnivorans 0 65 was slightly lower yet while primates perhaps constrained by their arboreal habits had the lowest rate 0 39 among the mammalian groups studied 7 Terrestrial mammalian carnivores from several eutherian groups the artiodactyl Andrewsarchus formerly considered a mesonychid the oxyaenid Sarkastodon and the carnivorans Amphicyon and Arctodus all reached a maximum size of about 1000 kg 8 the carnivoran Arctotherium and the hyaenodontid Simbakubwa may have been somewhat larger The largest known metatherian carnivore Proborhyaena gigantea apparently reached 600 kg also close to this limit 10 A similar theoretical maximum size for mammalian carnivores has been predicted based on the metabolic rate of mammals the energetic cost of obtaining prey and the maximum estimated rate coefficient of prey intake 11 It has also been suggested that maximum size for mammalian carnivores is constrained by the stress the humerus can withstand at top running speed 10 Analysis of the variation of maximum body size over the last 40 Ma suggests that decreasing temperature and increasing continental land area are associated with increasing maximum body size The former correlation would be consistent with Bergmann s rule 12 and might be related to the thermoregulatory advantage of large body mass in cool climates 8 better ability of larger organisms to cope with seasonality in food supply 12 or other factors 12 the latter correlation could be explained in terms of range and resource limitations 8 However the two parameters are interrelated due to sea level drops accompanying increased glaciation making the driver of the trends in maximum size more difficult to identify 8 In marine mammals edit nbsp Baleen whale comparative sizes Since tetrapods first reptiles later mammals returned to the sea in the Late Permian they have dominated the top end of the marine body size range due to the more efficient intake of oxygen possible using lungs 13 14 The ancestors of cetaceans are believed to have been the semiaquatic pakicetids no larger than dogs of about 53 million years Ma ago 15 By 40 Ma ago cetaceans had attained a length of 20 m or more in Basilosaurus an elongated serpentine whale that differed from modern whales in many respects and was not ancestral to them Following this the evolution of large body size in cetaceans appears to have come to a temporary halt and then to have backtracked although the available fossil records are limited However in the period from 31 Ma ago in the Oligocene to the present cetaceans underwent a significantly more rapid sustained increase in body mass a rate of increase in body mass0 259 of a factor of 3 2 per million years than achieved by any group of terrestrial mammals 7 This trend led to the largest animal of all time the modern blue whale Several reasons for the more rapid evolution of large body size in cetaceans are possible Fewer biomechanical constraints on increases in body size may be associated with suspension in water as opposed to standing against the force of gravity and with swimming movements as opposed to terrestrial locomotion Also the greater heat capacity and thermal conductivity of water compared to air may increase the thermoregulatory advantage of large body size in marine endotherms although diminishing returns apply 7 Among toothed whales maximum body size appears to be limited by food availability Larger size as in sperm and beaked whales facilitates deeper diving to access relatively easily caught large cephalopod prey in a less competitive environment Compared to odontocetes the efficiency of baleen whales filter feeding scales more favorably with increasing size when planktonic food is dense making larger size more advantageous The lunge feeding technique of rorquals appears to be more energy efficient than the ram feeding of balaenid whales the latter technique is used with less dense and patchy plankton 16 The cooling trend in Earth s recent history may have generated more localities of high plankton abundance via wind driven upwellings facilitating the evolution of gigantic whales 16 Cetaceans are not the only marine mammals to reach tremendous sizes 17 The largest carnivorans of all time are marine pinnipeds the largest of which is the southern elephant seal which can reach more than 6 m 20 ft in length and weigh up to 5 000 kg 11 000 lb Other large pinnipeds include the northern elephant seal at 4 000 kg 8 800 lb walrus at 2 000 kg 4 400 lb and Steller sea lion at 1 135 kg 2 502 lb 18 19 The sirenians are another group of marine mammals which adapted to fully aquatic life around the same time as the cetaceans did Sirenians are closely related to elephants The largest sirenian was the Steller s sea cow which reached up to 10 m 33 ft in length and weighed 8 000 to 10 000 kg 18 000 to 22 000 lb and was hunted to extinction in the 18th century 20 In flightless birds edit nbsp A size comparison between a human and 4 moa species 1 Dinornis novaezealandiae 2 Emeus crassus 3 Anomalopteryx didiformis 4 Dinornis robustus Because of the small initial size of all mammals following the extinction of the non avian dinosaurs nonmammalian vertebrates had a roughly ten million year long window of opportunity during the Paleocene for evolution of gigantism without much competition 21 During this interval apex predator niches were often occupied by reptiles such as terrestrial crocodilians e g Pristichampsus large snakes e g Titanoboa or varanid lizards or by flightless birds 8 e g Paleopsilopterus in South America This is also the period when megafaunal flightless herbivorous gastornithid birds evolved in the Northern Hemisphere while flightless paleognaths evolved to large size on Gondwanan land masses and Europe Gastornithids and at least one lineage of flightless paleognath birds originated in Europe both lineages dominating niches for large herbivores while mammals remained below 45 kg in contrast with other landmasses like North America and Asia which saw the earlier evolution of larger mammals and were the largest European tetrapods in the Paleocene 22 Flightless paleognaths termed ratites have traditionally been viewed as representing a lineage separate from that of their small flighted relatives the Neotropic tinamous However recent genetic studies have found that tinamous nest well within the ratite tree and are the sister group of the extinct moa of New Zealand 21 23 24 Similarly the small kiwi of New Zealand have been found to be the sister group of the extinct elephant birds of Madagascar 21 These findings indicate that flightlessness and gigantism arose independently multiple times among ratites via parallel evolution 25 Predatory megafaunal flightless birds were often able to compete with mammals in the early Cenozoic Later in the Cenozoic however they were displaced by advanced carnivorans and died out In North America the bathornithids Paracrax and Bathornis were apex predators but became extinct by the Early Miocene In South America the related phorusrhacids shared the dominant predatory niches with metatherian sparassodonts during most of the Cenozoic but declined and ultimately went extinct after eutherian predators arrived from North America as part of the Great American Interchange during the Pliocene In contrast large herbivorous flightless ratites have survived to the present 25 However none of the flightless birds of the Cenozoic including the predatory Brontornis possibly omnivorous Dromornis stirtoni 25 or herbivorous Aepyornis ever grew to masses much above 500 kg and thus never attained the size of the largest mammalian carnivores let alone that of the largest mammalian herbivores It has been suggested that the increasing thickness of avian eggshells in proportion to egg mass with increasing egg size places an upper limit on the size of birds 26 note 1 The largest species of Dromornis D stirtoni may have gone extinct after it attained the maximum avian body mass and was then outcompeted by marsupial diprotodonts that evolved to sizes several times larger 29 In giant turtles edit Giant tortoises were important components of late Cenozoic megafaunas being present in every nonpolar continent until the arrival of homininans 30 31 The largest known terrestrial tortoise was Megalochelys atlas an animal that probably weighed about 1 000 kg 2 200 lb 32 Some earlier aquatic Testudines e g the marine Archelon of the Cretaceous 33 and freshwater Stupendemys of the Miocene were considerably larger weighing more than 2 000 kg 4 400 lb 34 Megafaunal mass extinctions editTiming and possible causes edit nbsp Correlations between times of first appearance of humans and unique megafaunal extinction pulses on different land masses nbsp Cyclical pattern of global climate change over the last 450 000 years based on Antarctic temperatures and global ice volume showing that there were no unique climatic events that would account for any of the megafaunal extinction pulses The Quaternary extinction event occurred during the latter half of the last ice age glacial period when many giant ice age mammals such as woolly mammoths went extinct in the Americas Australia New Guinea and northern Eurasia An analysis of the extinction event in North America found it to be unique among Cenozoic extinction pulses in its selectivity for large animals 35 Fig 10 Various theories have attributed the wave of extinctions to human hunting climate change disease extraterrestrial impact competition from other animals or other causes However this extinction near the end of the Pleistocene was just one of a series of megafaunal extinction pulses that have occurred during the last 50 000 years over much of the Earth s surface with Africa and southern Asia where the local megafauna had a chance to evolve alongside modern humans being comparatively less affected The latter areas did suffer gradual attrition of megafauna particularly of the slower moving species a class of vulnerable megafauna epitomized by giant tortoises over the last several million years 36 37 Outside the mainland of Afro Eurasia these megafaunal extinctions followed a highly distinctive landmass by landmass pattern that closely parallels the spread of humans into previously uninhabited regions of the world and which shows no overall correlation with climatic history which can be visualized with plots over recent geological time periods of climate markers such as marine oxygen isotopes or atmospheric carbon dioxide levels 38 39 Australia 40 and nearby islands e g Flores 41 were struck first around 46 000 years ago followed by Tasmania about 41 000 years ago after formation of a land bridge to Australia about 43 000 years ago 42 43 44 The role of humans in the extinction of Australia and New Guinea s megafauna has been disputed with multiple studies showing a decline in the number of species prior to the arrival of humans on the continent and the absence of any evidence of human predation 45 46 47 48 the impact of climate change has instead been cited for their decline 49 45 Similarly Japan lost most of its megafauna apparently about 30 000 years ago 50 North America 13 000 years ago note 2 and South America about 500 years later 52 53 Cyprus 10 000 years ago 54 55 the Antilles 6 000 years ago 56 57 New Caledonia 58 and nearby islands 59 3 000 years ago Madagascar 2 000 years ago 60 New Zealand 700 years ago 61 the Mascarenes 400 years ago 62 and the Commander Islands 250 years ago 63 Nearly all of the world s isolated islands could furnish similar examples of extinctions occurring shortly after the arrival of humans though most of these islands such as the Hawaiian Islands never had terrestrial megafauna so their extinct fauna were smaller but still displayed island gigantism 38 39 An analysis of the timing of Holarctic megafaunal extinctions and extirpations over the last 56 000 years has revealed a tendency for such events to cluster within interstadials periods of abrupt warming but only when humans were also present Humans may have impeded processes of migration and recolonization that would otherwise have allowed the megafaunal species to adapt to the climate shift 64 In at least some areas interstadials were periods of expanding human populations 65 An analysis of Sporormiella fungal spores which derive mainly from the dung of megaherbivores in swamp sediment cores spanning the last 130 000 years from Lynch s Crater in Queensland Australia showed that the megafauna of that region virtually disappeared about 41 000 years ago at a time when climate changes were minimal the change was accompanied by an increase in charcoal and was followed by a transition from rainforest to fire tolerant sclerophyll vegetation The high resolution chronology of the changes supports the hypothesis that human hunting alone eliminated the megafauna and that the subsequent change in flora was most likely a consequence of the elimination of browsers and an increase in fire 66 67 68 69 The increase in fire lagged the disappearance of megafauna by about a century and most likely resulted from accumulation of fuel once browsing stopped Over the next several centuries grass increased sclerophyll vegetation increased with a lag of another century and a sclerophyll forest developed after about another thousand years 68 During two periods of climate change about 120 000 and 75 000 years ago sclerophyll vegetation had also increased at the site in response to a shift to cooler drier conditions neither of these episodes had a significant impact on megafaunal abundance 68 Similar conclusions regarding the culpability of human hunters in the disappearance of Pleistocene megafauna were derived from high resolution chronologies obtained via an analysis of a large collection of eggshell fragments of the flightless Australian bird Genyornis newtoni 70 71 69 from analysis of Sporormiella fungal spores from a lake in eastern North America 72 73 and from study of deposits of Shasta ground sloth dung left in over half a dozen caves in the American Southwest 74 75 Continuing human hunting and environmental disturbance has led to additional megafaunal extinctions in the recent past and has created a serious danger of further extinctions in the near future see examples below Direct killing by humans primarily for meat or other body parts is the most significant factor in contemporary megafaunal decline 76 77 A number of other mass extinctions occurred earlier in Earth s geologic history in which some or all of the megafauna of the time also died out Famously in the Cretaceous Paleogene extinction event the non avian dinosaurs and most other giant reptiles were eliminated However the earlier mass extinctions were more global and not so selective for megafauna i e many species of other types including plants marine invertebrates 78 and plankton went extinct as well Thus the earlier events must have been caused by more generalized types of disturbances to the biosphere 79 Consequences of depletion of megafauna edit Effect on nutrient transport edit Megafauna play a significant role in the lateral transport of mineral nutrients in an ecosystem tending to translocate them from areas of high to those of lower abundance They do so by their movement between the time they consume the nutrient and the time they release it through elimination or to a much lesser extent through decomposition after death 80 In South America s Amazon Basin it is estimated that such lateral diffusion was reduced over 98 following the megafaunal extinctions that occurred roughly 12 500 years ago 81 82 Given that phosphorus availability is thought to limit productivity in much of the region the decrease in its transport from the western part of the basin and from floodplains both of which derive their supply from the uplift of the Andes to other areas is thought to have significantly impacted the region s ecology and the effects may not yet have reached their limits 82 In the sea cetaceans and pinnipeds that feed at depth are thought to translocate nitrogen from deep to shallow water enhancing ocean productivity and counteracting the activity of zooplankton which tend to do the opposite 83 Effect on methane emissions edit Large populations of megaherbivores have the potential to contribute greatly to the atmospheric concentration of methane which is an important greenhouse gas Modern ruminant herbivores produce methane as a byproduct of foregut fermentation in digestion and release it through belching or flatulence Today around 20 of annual methane emissions come from livestock methane release In the Mesozoic it has been estimated that sauropods could have emitted 520 million tons of methane to the atmosphere annually 84 contributing to the warmer climate of the time up to 10 C warmer than at present 84 85 This large emission follows from the enormous estimated biomass of sauropods and because methane production of individual herbivores is believed to be almost proportional to their mass 84 Recent studies have indicated that the extinction of megafaunal herbivores may have caused a reduction in atmospheric methane This hypothesis is relatively new 86 One study examined the methane emissions from the bison that occupied the Great Plains of North America before contact with European settlers The study estimated that the removal of the bison caused a decrease of as much as 2 2 million tons per year 87 Another study examined the change in the methane concentration in the atmosphere at the end of the Pleistocene epoch after the extinction of megafauna in the Americas After early humans migrated to the Americas about 13 000 BP their hunting and other associated ecological impacts led to the extinction of many megafaunal species there Calculations suggest that this extinction decreased methane production by about 9 6 million tons per year This suggests that the absence of megafaunal methane emissions may have contributed to the abrupt climatic cooling at the onset of the Younger Dryas 86 The decrease in atmospheric methane that occurred at that time as recorded in ice cores was 2 4 times more rapid than any other decrease in the last half million years suggesting that an unusual mechanism was at work 86 Gallery editPleistocene extinct megafauna edit nbsp Moa Dinornis pictured nbsp Diprotodon optatum nbsp Megalania Varanus priscus nbsp Glyptodon nbsp Macrauchenia was the last and largest litoptern an order of extinct South American native ungulates 88 89 nbsp American lions Panthera atrox nbsp Woolly mammoth nbsp The subfossil lemur Archaeoindris nbsp Haast s eagle Other extinct Cenozoic megafauna edit nbsp Dromornis stirtoni nbsp Asian indricothere and rhino relative Paraceratherium was among the largest land mammals 90 nbsp Reconstructed jaws of megalodon Otodus megalodon nbsp Deinotherium nbsp Kelenken guillermoi nbsp Gastornis gigantea Extant edit nbsp The greater rhea nbsp The eastern gorilla nbsp Bengal tigers nbsp Polar bears nbsp The black rhinoceros nbsp Unlike woolly rhinos and mammoths muskoxen narrowly survived the Quaternary extinctions 91 nbsp Hippopotamuses nbsp The sperm whale nbsp The orca nbsp The southern cassowary nbsp The common ostrich nbsp The saltwater crocodile nbsp The Komodo dragon nbsp The green anaconda nbsp The Chinese giant salamander nbsp The giant sunfish nbsp The Nile perch nbsp The great white shark the largest macropredatory fish and one of the largest carnivorous shark species is found worldwide 92 nbsp The manta nbsp Examination of a 9 m giant squidSee also editAustralian megafauna Bergmann s rule Charismatic megafauna Cope s rule Deep sea gigantism Island gigantism Largest organisms Largest prehistoric animals List of heaviest land mammals List of largest mammals List of megafauna discovered in modern times Megafauna mythology Megafaunal wolf Megaflora Megaherb New World Pleistocene extinctions Pleistocene megafauna Quaternary extinction eventNotes edit Nonavian dinosaur size was not similarly constrained because they had a different relationship between body mass and egg size than birds The 400 kg Aepyornis had larger eggs than nearly all dinosaurs 27 28 Analysis indicates that 35 genera of North American mammals went extinct more or less simultaneously in this event 51 References edit Moleon M Sanchez Zapata JA Donazar JA Revilla E Martin Lopez B Gutierrez Canovas C Getz WM Morales Reyes Z Campos Arceiz A Crowder LB Galetti M Gonzalez Suarez M He F Jordano P Lewison R 2020 03 11 Rethinking megafauna Proceedings of the Royal Society B Biological Sciences 287 1922 20192643 doi 10 1098 rspb 2019 2643 ISSN 0962 8452 PMC 7126068 PMID 32126954 Malhi Y Doughty CE Galetti M Smith FA Svenning JC Terborgh JW 2016 01 26 Megafauna and ecosystem function from the Pleistocene to the Anthropocene Proceedings of the National Academy of Sciences 113 4 838 846 Bibcode 2016PNAS 113 838M doi 10 1073 pnas 1502540113 ISSN 0027 8424 PMC 4743772 PMID 26811442 McClenachan L Cooper AB Dulvy NK 2016 06 20 Rethinking Trade Driven Extinction Risk in Marine and Terrestrial Megafauna Current Biology 26 12 1640 1646 Bibcode 2016CBio 26 1640M doi 10 1016 j cub 2016 05 026 ISSN 1879 0445 PMID 27291051 https www britannica com science K selected species Archived 2016 10 11 at the Wayback Machine Britannica Retrieved 2017 4 2 Barnosky AD 2004 10 01 Assessing the Causes of Late Pleistocene Extinctions on the Continents Science 306 5693 70 75 Bibcode 2004Sci 306 70B CiteSeerX 10 1 1 574 332 doi 10 1126 science 1101476 PMID 15459379 S2CID 36156087 Brook BW Johnson CN 2006 Selective hunting of juveniles as a cause of the imperceptible overkill of the Australian Pleistocene megafauna Alcheringa An Australasian Journal of Palaeontology 30 sup1 39 48 Bibcode 2006Alch 30S 39B doi 10 1080 03115510609506854 S2CID 84205755 a b c d e f g Evans AR Jones D Boyer AG Brown JH Costa DP Ernest SK Fitzgerald EM Fortelius M Gittleman JL Hamilton MJ Harding LE Lintulaakso K Lyons SK Okie JG Saarinen JJ Sibly RM Smith FA Stephens PR Theodor JM Uhen MD 2012 01 30 The maximum rate of mammal evolution PNAS 109 11 4187 4190 Bibcode 2012PNAS 109 4187E doi 10 1073 pnas 1120774109 PMC 3306709 PMID 22308461 a b c d e f g Smith FA Boyer AG Brown JH Costa DP Dayan T Ernest SK Evans AR Fortelius M Gittleman JL Hamilton MJ Harding LE Lintulaakso K Lyons SK McCain C Okie JG Saarinen JJ Sibly RM Stephens PR Theodor J Uhen MD 2010 11 26 The Evolution of Maximum Body Size of Terrestrial Mammals Science 330 6008 1216 1219 Bibcode 2010Sci 330 1216S CiteSeerX 10 1 1 383 8581 doi 10 1126 science 1194830 PMID 21109666 S2CID 17272200 Clauss M Frey R Kiefer B Lechner Doll M Loehlein W Polster C Roessner G E Streich W J 2003 04 24 The maximum attainable body size of herbivorous mammals morphophysiological constraints on foregut and adaptations of hindgut fermenters PDF Oecologia 136 1 14 27 Bibcode 2003Oecol 136 14C doi 10 1007 s00442 003 1254 z PMID 12712314 S2CID 206989975 Archived from the original PDF on 2019 06 08 Retrieved 2019 07 13 a b Sorkin B 2008 04 10 A biomechanical constraint on body mass in terrestrial mammalian predators Lethaia 41 4 333 347 Bibcode 2008Letha 41 333S doi 10 1111 j 1502 3931 2007 00091 x Carbone C Teacher A Rowcliffe J M 2007 01 16 The Costs of Carnivory PLOS Biology 5 2 e22 363 368 doi 10 1371 journal pbio 0050022 PMC 1769424 PMID 17227145 a b c Ashton KG Tracy M C de Queiroz A October 2000 Is Bergmann s Rule Valid for Mammals The American Naturalist 156 4 390 415 doi 10 1086 303400 JSTOR 10 1086 303400 PMID 29592141 S2CID 205983729 Webb J 2015 02 19 Evolution favours bigger sea creatures BBC News BBC Archived from the original on 2015 02 22 Retrieved 2015 02 22 Heim NA Knope ML Schaal EK Wang SC Payne JL 2015 02 20 Cope s rule in the evolution of marine animals Science 347 6224 867 870 Bibcode 2015Sci 347 867H doi 10 1126 science 1260065 PMID 25700517 Archived from the original on 2019 07 05 Retrieved 2019 07 13 Thewissen JG Bajpai S 1 January 2001 Whale Origins as a Poster Child for Macroevolution BioScience 51 12 1037 1049 doi 10 1641 0006 3568 2001 051 1037 WOAAPC 2 0 CO 2 ISSN 0006 3568 a b Goldbogen JA Cade DE Wisniewska DM Potvin J Segre PS Savoca MS Hazen EL Czapanskiy MF Kahane Rapport SR DeRuiter SL Gero S Tonnesen P Gough WT Hanson MB Holt MM Jensen FH Simon M Stimpert AK Arranz P Johnston DW Nowacek DP Parks SE Visser F Friedlaender AS Tyack PL Madsen PT Pyenson ND 2019 Why whales are big but not bigger Physiological drivers and ecological limits in the age of ocean giants Science 366 6471 1367 1372 Bibcode 2019Sci 366 1367G doi 10 1126 science aax9044 hdl 10023 19285 PMID 31831666 S2CID 209339266 Baker J Meade A Pagel M Venditti C 2015 04 21 Adaptive evolution toward larger size in mammals Proceedings of the National Academy of Sciences 112 16 5093 5098 Bibcode 2015PNAS 112 5093B doi 10 1073 pnas 1419823112 ISSN 0027 8424 PMC 4413265 PMID 25848031 Churchill M Clementz MT Kohno N 2014 12 19 Cope s rule and the evolution of body size in Pinnipedimorpha Mammalia Carnivora Evolution 69 1 201 215 doi 10 1111 evo 12560 ISSN 0014 3820 PMID 25355195 Haley MP Deutsch CJ Boeuf BJ April 1991 A method for estimating mass of large pinnipeds Marine Mammal Science 7 2 157 164 Bibcode 1991MMamS 7 157H doi 10 1111 j 1748 7692 1991 tb00562 x ISSN 0824 0469 Goldbogen JA 2018 04 17 Physiological constraints on marine mammal body size Proceedings of the National Academy of Sciences 115 16 3995 3997 Bibcode 2018PNAS 115 3995G doi 10 1073 pnas 1804077115 ISSN 0027 8424 PMC 5910879 PMID 29618615 a b c Mitchell KJ Llamas B Soubrier J Rawlence NJ Worthy TH Wood J Lee MS Cooper A 2014 05 23 Ancient DNA reveals elephant birds and kiwi are sister taxa and clarifies ratite bird evolution PDF Science 344 6186 898 900 Bibcode 2014Sci 344 898M doi 10 1126 science 1251981 hdl 2328 35953 PMID 24855267 S2CID 206555952 Archived PDF from the original on 2023 03 15 Retrieved 2019 09 24 Buffetaut E Angst D November 2014 Stratigraphic distribution of large flightless birds in the Palaeogene of Europe and its palaeobiological and palaeogeographical implications Earth Science Reviews 138 394 408 Bibcode 2014ESRv 138 394B doi 10 1016 j earscirev 2014 07 001 Phillips MJ Gibb GC Crimp EA Penny D January 2010 Tinamous and moa flock together mitochondrial genome sequence analysis reveals independent losses of flight among ratites Systematic Biology 59 1 90 107 doi 10 1093 sysbio syp079 PMID 20525622 Baker AJ Haddrath O McPherson JD Cloutier A 2014 Genomic Support for a Moa Tinamou Clade and Adaptive Morphological Convergence in Flightless Ratites Molecular Biology and Evolution 31 7 1686 1696 doi 10 1093 molbev msu153 PMID 24825849 a b c Murray PF Vickers Rich P 2004 Magnificent Mihirungs The Colossal Flightless Birds of the Australian Dreamtime Indiana University Press pp 51 314 ISBN 978 0 253 34282 9 Retrieved 7 January 2012 Ibid 2004 p 212 Indiana University Press ISBN 978 0 253 34282 9 Kenneth Carpenter 1999 Eggs Nests and Baby Dinosaurs A Look at Dinosaur Reproduction Indiana University Press p 100 ISBN 978 0 253 33497 8 OCLC 42009424 Retrieved 6 May 2013 Jackson FD Varricchio DJ Jackson RA Vila B Chiappe LM 2008 Comparison of water vapor conductance in a titanosaur egg from the Upper Cretaceous of Argentina and a Megaloolithus siruguei egg from Spain Paleobiology 34 2 229 246 doi 10 1666 0094 8373 2008 034 0229 COWVCI 2 0 CO 2 ISSN 0094 8373 S2CID 85880201 Ibid 2004 p 277 Indiana University Press ISBN 978 0 253 34282 9 Hansen DM Donlan C J Griffiths C J Campbell K J April 2010 Ecological history and latent conservation potential large and giant tortoises as a model for taxon substitutions PDF Ecography 33 2 272 284 Bibcode 2010Ecogr 33 272H doi 10 1111 j 1600 0587 2010 06305 x Archived from the original PDF on July 24 2011 Retrieved 2011 02 26 Cione AL Tonni E P Soibelzon L 2003 The Broken Zig Zag Late Cenozoic large mammal and tortoise extinction in South America Rev Mus Argentino Cienc Nat Nueva Serie 5 1 1 19 doi 10 22179 REVMACN 5 26 ISSN 1514 5158 Gordon IJ Prins HH Mallon J Puk LD Miranda EB Starling Manne C van der Wal R Moore B Foley W 2019 Gordon IJ Prins HH eds The Ecology of Browsing and Grazing in Other Vertebrate Taxa The Ecology of Browsing and Grazing II Cham Springer International Publishing pp 339 404 doi 10 1007 978 3 030 25865 8 15 ISBN 978 3 030 25865 8 Jaffe AL Slater GJ Alfaro ME 2011 08 23 The evolution of island gigantism and body size variation in tortoises and turtles Biology Letters 7 4 558 561 doi 10 1098 rsbl 2010 1084 ISSN 1744 9561 PMC 3130210 PMID 21270022 Cadena EA Link A Cooke SB Stroik LK Vanegas AF Tallman M December 2021 New insights on the anatomy and ontogeny of the largest extinct freshwater turtles Heliyon 7 12 e08591 Bibcode 2021Heliy 708591C doi 10 1016 j heliyon 2021 e08591 ISSN 2405 8440 PMC 8717240 PMID 35005268 Alroy J 1999 Putting North America s End Pleistocene Megafaunal Extinction in Context Large Scale Analyses of Spatial Patterns Extinction Rates and Size Distributions in MacPhee RD ed Extinctions in Near Time Causes Contexts and Consequences Advances in Vertebrate Paleobiology vol 2 New York Plenum pp 105 143 doi 10 1007 978 1 4757 5202 1 6 ISBN 978 1 4757 5202 1 OCLC 41368299 archived from the original on 2018 06 09 Corlett RT 2006 Megafaunal extinctions in tropical Asia PDF Tropinet 17 3 1 3 Archived PDF from the original on 2016 03 04 Retrieved 2010 10 04 Edmeades B Megafauna First Victims of the Human Caused Extinction megafauna com internet published book with Foreword by Paul S Martin Archived from the original on 2014 12 25 Retrieved 2020 02 13 a b Martin PS 2005 Chapter 6 Deadly Syncopation Twilight of the Mammoths Ice Age Extinctions and the Rewilding of America University of California Press pp 118 128 ISBN 978 0 520 23141 2 OCLC 58055404 Archived from the original on 2024 03 27 Retrieved 2014 11 11 a b Burney DA Flannery TF July 2005 Fifty millennia of catastrophic extinctions after human contact PDF Trends in Ecology amp Evolution 20 7 395 401 doi 10 1016 j tree 2005 04 022 PMID 16701402 Archived from the original PDF on 2010 06 10 Retrieved 2014 11 11 Roberts RG Flannery TF Ayliffe LK Yoshida H Olley JM Prideaux GJ Laslett GM Baynes A Smith MA Jones R Smith BL 2001 06 08 New Ages for the Last Australian Megafauna Continent Wide Extinction About 46 000 Years Ago PDF Science 292 5523 1888 1892 Bibcode 2001Sci 292 1888R doi 10 1126 science 1060264 PMID 11397939 S2CID 45643228 Archived PDF from the original on 2019 02 10 Retrieved 2011 08 26 Callaway E 2016 09 21 Human remains found in hobbit cave Nature doi 10 1038 nature 2016 20656 S2CID 89272546 Diamond J 2008 08 13 Palaeontology The last giant kangaroo Nature 454 7206 835 836 Bibcode 2008Natur 454 835D doi 10 1038 454835a PMID 18704074 S2CID 36583693 Turney CS Flannery TF Roberts RG Reid C Fifield LK Higham TF Jacobs Z Kemp N Colhoun EA Kalin RM Ogle N 2008 08 21 Late surviving megafauna in Tasmania Australia implicate human involvement in their extinction PNAS 105 34 12150 12153 Bibcode 2008PNAS 10512150T doi 10 1073 pnas 0801360105 PMC 2527880 PMID 18719103 Roberts R Jacobs Z October 2008 The Lost Giants of Tasmania PDF Australasian Science 29 9 14 17 Archived from the original PDF on 2011 09 27 Retrieved 2011 08 26 a b Field J Wroe S Trueman CN Garvey J Wyatt Spratt S 2013 02 08 Looking for the archaeological signature in Australian Megafaunal extinctions Quaternary International Peopling the last new worlds the first colonisation of Sahul and the Americas 285 76 88 Bibcode 2013QuInt 285 76F doi 10 1016 j quaint 2011 04 013 ISSN 1040 6182 Archived from the original on 2012 12 18 Dodson J Field JH 2018 What does the occurrence of Sporormiella Preussia spores mean in Australian fossil sequences Journal of Quaternary Science 33 4 380 392 Bibcode 2018JQS 33 380D doi 10 1002 jqs 3020 ISSN 1099 1417 S2CID 133737405 Archived from the original on 2022 02 14 Wroe S Field JH Archer M Grayson DK Price GJ Louys J Faith JT Webb GE Davidson I Mooney SD 2013 09 03 Reply to Brook et al No empirical evidence for human overkill of megafauna in Sahul Proceedings of the National Academy of Sciences 110 36 E3369 Bibcode 2013PNAS 110E3369W doi 10 1073 pnas 1310440110 ISSN 0027 8424 PMC 3767508 PMID 24137797 Dortch J Cupper M Grun R Harpley B Lee K Field J 2016 08 01 The timing and cause of megafauna mass deaths at Lancefield Swamp south eastern Australia Quaternary Science Reviews 145 161 182 Bibcode 2016QSRv 145 161D doi 10 1016 j quascirev 2016 05 042 ISSN 0277 3791 Archived from the original on 2024 03 27 Wroe S Field JH Archer M Grayson DK Price GJ Louys J Faith JT Webb GE Davidson I Mooney SD 2013 05 28 Climate change frames debate over the extinction of megafauna in Sahul Pleistocene Australia New Guinea Proceedings of the National Academy of Sciences 110 22 8777 8781 Bibcode 2013PNAS 110 8777W doi 10 1073 pnas 1302698110 ISSN 0027 8424 PMC 3670326 PMID 23650401 Norton CJ Kondo Y Ono A Zhang Y Diab M C 2009 05 23 The nature of megafaunal extinctions during the MIS 3 2 transition in Japan Quaternary International 211 1 2 113 122 Bibcode 2010QuInt 211 113N doi 10 1016 j quaint 2009 05 002 Faith JT Surovell TA 2009 12 08 Synchronous extinction of North America s Pleistocene mammals Proceedings of the National Academy of Sciences 106 49 20641 20645 Bibcode 2009PNAS 10620641F doi 10 1073 pnas 0908153106 PMC 2791611 PMID 19934040 Haynes G 2009 Introduction to the Volume In Haynes G ed American Megafaunal Extinctions at the End of the Pleistocene Vertebrate Paleobiology and Paleoanthropology Springer pp 1 20 doi 10 1007 978 1 4020 8793 6 1 ISBN 978 1 4020 8792 9 permanent dead link Fiedel S 2009 Sudden Deaths The Chronology of Terminal Pleistocene Megafaunal Extinction In Haynes G ed American Megafaunal Extinctions at the End of the Pleistocene Vertebrate Paleobiology and Paleoanthropology Springer pp 21 37 doi 10 1007 978 1 4020 8793 6 2 ISBN 978 1 4020 8792 9 Simmons AH 1999 Faunal extinction in an island society pygmy hippopotamus hunters of Cyprus Interdisciplinary Contributions to Archaeology Kluwer Academic Plenum Publishers p 382 doi 10 1007 b109876 ISBN 978 0 306 46088 3 OCLC 41712246 Archived from the original on 2024 03 27 Retrieved 2016 05 07 Simmons AH Mandel R D December 2007 Not Such a New Light A Response to Ammerman and Noller World Archaeology 39 4 475 482 doi 10 1080 00438240701676169 JSTOR 40026143 S2CID 161791746 Steadman DW Martin PS MacPhee RD Jull AJ McDonald HG Woods CA Iturralde Vinent M Hodgins GW 2005 08 16 Asynchronous extinction of late Quaternary sloths on continents and islands Proc Natl Acad Sci USA 102 33 11763 11768 Bibcode 2005PNAS 10211763S doi 10 1073 pnas 0502777102 PMC 1187974 PMID 16085711 Cooke SB Davalos LM Mychajliw AM Turvey ST Upham NS 2017 Anthropogenic Extinction Dominates Holocene Declines of West Indian Mammals Annual Review of Ecology Evolution and Systematics 48 1 301 327 doi 10 1146 annurev ecolsys 110316 022754 S2CID 90558542 Anderson A Sand C Petchey F Worthy T H 2010 Faunal extinction and human habitation in New Caledonia Initial results and implications of new research at the Pindai Caves Journal of Pacific Archaeology 1 1 89 109 hdl 10289 5404 White AW Worthy T H Hawkins S Bedford S Spriggs M 2010 08 16 Megafaunal meiolaniid horned turtles survived until early human settlement in Vanuatu Southwest Pacific Proc Natl Acad Sci USA 107 35 15512 15516 Bibcode 2010PNAS 10715512W doi 10 1073 pnas 1005780107 PMC 2932593 PMID 20713711 Burney DA Burney L P Godfrey L R Jungers W L Goodman S M Wright H T Jull A J T July 2004 A chronology for late prehistoric Madagascar Journal of Human Evolution 47 1 2 25 63 doi 10 1016 j jhevol 2004 05 005 PMID 15288523 Holdaway RN Jacomb C 2000 03 24 Rapid Extinction of the Moas Aves Dinornithiformes Model Test and Implications Science 287 5461 2250 2254 Bibcode 2000Sci 287 2250H doi 10 1126 science 287 5461 2250 PMID 10731144 Janoo A April 2005 Discovery of isolated dodo bones Raphus cucullatus L Aves Columbiformes from Mauritius cave shelters highlights human predation with a comment on the status of the family Raphidae Wetmore 1930 Annales de Paleontologie 91 2 167 180 Bibcode 2005AnPal 91 167J doi 10 1016 j annpal 2004 12 002 Anderson PK July 1995 Competition Predation and the Evolution and Extinction of Steller s Sea Cow Hydrodamalis gigas Marine Mammal Science 11 3 391 394 Bibcode 1995MMamS 11 391A doi 10 1111 j 1748 7692 1995 tb00294 x Archived from the original on 2011 05 11 Retrieved 2011 08 30 Cooper A Turney C Hughen KA Brook BW McDonald HG Bradshaw CJ 2015 07 23 Abrupt warming events drove Late Pleistocene Holarctic megafaunal turnover Science 349 6248 602 6 Bibcode 2015Sci 349 602C doi 10 1126 science aac4315 PMID 26250679 S2CID 31686497 Muller UC Pross J Tzedakis PC Gamble C Kotthoff U Schmiedl G Wulf S Christanis K February 2011 The role of climate in the spread of modern humans into Europe Quaternary Science Reviews 30 3 4 273 279 Bibcode 2011QSRv 30 273M doi 10 1016 j quascirev 2010 11 016 Biello D 2012 03 22 Big Kill Not Big Chill Finished Off Giant Kangaroos Scientific American news Archived from the original on 2012 03 23 Retrieved 2012 03 25 McGlone M 2012 03 23 The Hunters Did It Science 335 6075 1452 1453 Bibcode 2012Sci 335 1452M doi 10 1126 science 1220176 PMID 22442471 S2CID 36914192 a b c Rule S Brook B W Haberle S G Turney C S M Kershaw A P 2012 03 23 The Aftermath of Megafaunal Extinction Ecosystem Transformation in Pleistocene Australia Science 335 6075 1483 1486 Bibcode 2012Sci 335 1483R doi 10 1126 science 1214261 PMID 22442481 S2CID 26675232 a b Johnson CN Alroy J Beeton NJ Bird MI Brook BW Cooper A Gillespie R Herrando Perez S Jacobs Z Miller GH Prideaux GJ Roberts RG Rodriguez Rey M Saltre F Turney CS Bradshaw CJ 10 February 2016 What caused extinction of the Pleistocene megafauna of Sahul Proceedings of the Royal Society B Biological Sciences 283 1824 20152399 doi 10 1098 rspb 2015 2399 PMC 4760161 PMID 26865301 Miller GH Magee JW Johnson BJ Fogel ML Spooner NA McCulloch MT Ayliffe LK 1999 01 08 Pleistocene Extinction of Genyornis newtoni Human Impact on Australian Megafauna Science 283 5399 205 208 doi 10 1126 science 283 5399 205 PMID 9880249 Miller G Magee J Smith M Spooner N Baynes A Lehman S Fogel M Johnston H Williams D Clark P Florian C Holst R DeVogel S 2016 01 29 Human predation contributed to the extinction of the Australian megafaunal bird Genyornis newtoni 47 ka Nature Communications 7 10496 Bibcode 2016NatCo 710496M doi 10 1038 ncomms10496 PMC 4740177 PMID 26823193 Johnson C 2009 11 20 Megafaunal Decline and Fall Science 326 5956 1072 1073 Bibcode 2009Sci 326 1072J doi 10 1126 science 1182770 PMID 19965418 S2CID 206523763 Gill JL Williams JW Jackson ST Lininger KB Robinson GS 2009 11 20 Pleistocene Megafaunal Collapse Novel Plant Communities and Enhanced Fire Regimes in North America PDF Science 326 5956 1100 1103 Bibcode 2009Sci 326 1100G doi 10 1126 science 1179504 PMID 19965426 S2CID 206522597 Archived PDF from the original on 2017 09 22 Retrieved 2018 11 09 Fiedal S 2009 Sudden Deaths The Chronology of Terminal Pleistocene Megafaunal Extinction In Haynes G ed American Megafaunal Extinctions at the End of the Pleistocene Vertebrate Paleobiology and Paleoanthropology Springer pp 21 37 doi 10 1007 978 1 4020 8793 6 2 ISBN 978 1 4020 8792 9 Martin PS 2005 Chapter 4 Ground Sloths at Home Twilight of the Mammoths Ice Age Extinctions and the Rewilding of America University of California Press pp 78 99 ISBN 978 0 520 23141 2 OCLC 58055404 Archived from the original on 2024 03 27 Retrieved 2014 11 11 Milman O February 6 2019 The killing of large species is pushing them towards extinction study finds The Guardian Archived from the original on February 7 2019 Retrieved February 13 2019 Ripple WJ et al 2019 Are we eating the world s megafauna to extinction Conservation Letters 12 3 e12627 Bibcode 2019ConL 12E2627R doi 10 1111 conl 12627 Alroy J 2008 08 12 Dynamics of origination and extinction in the marine fossil record PNAS 105 Suppl 1 Supplement 1 11536 11542 Bibcode 2008PNAS 10511536A doi 10 1073 pnas 0802597105 PMC 2556405 PMID 18695240 D Hondt S 2005 12 01 Consequences of the Cretaceous Paleogene Mass Extinction for Marine Ecosystems Annual Review of Ecology Evolution and Systematics 36 1 295 317 doi 10 1146 annurev ecolsys 35 021103 105715 ISSN 1543 592X Wolf A Doughty CE Malhi Y 2013 Lateral Diffusion of Nutrients by Mammalian Herbivores in Terrestrial Ecosystems PLoS ONE 8 8 e71352 Bibcode 2013PLoSO 871352W doi 10 1371 journal pone 0071352 PMC 3739793 PMID 23951141 Marshall M 2013 08 11 Ecosystems still feel the pain of ancient extinctions New Scientist Archived from the original on 2015 07 04 Retrieved 2013 08 12 a b Doughty CE Wolf A Malhi Y 2013 08 11 The legacy of the Pleistocene megafauna extinctions on nutrient availability in Amazonia Nature Geoscience 6 9 761 764 Bibcode 2013NatGe 6 761D doi 10 1038 ngeo1895 Roman J McCarthy J 2010 The Whale Pump Marine Mammals Enhance Primary Productivity in a Coastal Basin PLOS ONE 5 10 e13255 Bibcode 2010PLoSO 513255R doi 10 1371 journal pone 0013255 PMC 2952594 PMID 20949007 a b c Wilkinson DM Nisbet E G Ruxton G D 2012 05 08 Could methane produced by sauropod dinosaurs have helped drive Mesozoic climate warmth Current Biology 22 9 R292 R293 Bibcode 2012CBio 22 R292W doi 10 1016 j cub 2012 03 042 PMID 22575462 Dinosaur gases warmed the Earth BBC Nature News 2012 05 07 Archived from the original on 2015 12 01 Retrieved 2012 05 08 a b c Smith FA Elliot S M Lyons S K 2010 05 23 Methane emissions from extinct megafauna Nature Geoscience 3 6 374 375 Bibcode 2010NatGe 3 374S doi 10 1038 ngeo877 Kelliher FM Clark H 2010 03 15 Methane emissions from bison An historic herd estimate for the North American Great Plains Agricultural and Forest Meteorology 150 3 473 577 Bibcode 2010AgFM 150 473K doi 10 1016 j agrformet 2009 11 019 Palmer D ed 1999 The Marshall Illustrated Encyclopedia of Dinosaurs and Prehistoric Animals London Marshall Editions p 248 ISBN 978 1 84028 152 1 Moyano S Giannini N 2018 10 10 Cranial characters associated with the proboscis postnatal development in Tapirus Perissodactyla Tapiridae and comparisons with other extant and fossil hoofed mammals Zoologischer Anzeiger 277 7554 143 147 doi 10 1016 j jcz 2018 08 005 ISSN 0044 5231 S2CID 92143497 Tsubamoto T 2012 Estimating body mass from the astragalus in mammals Acta Palaeontologica Polonica 259 265 doi 10 4202 app 2011 0067 S2CID 54686160 Stuart AJ November 1991 Mammalian extinctions in the Late Pleistocene of northern Eurasia and North America Biological Reviews 66 4 453 562 doi 10 1111 j 1469 185X 1991 tb01149 x PMID 1801948 S2CID 41295526 Sample Ian 19 February 2010 Great white shark is more endangered than tiger claims scientist The Guardian Archived from the original on 9 September 2013 Retrieved 14 August 2013 External links editMegafauna First Victims of the Human Caused Extinction Retrieved from https en wikipedia org w index php title Megafauna amp oldid 1221010302 Megafaunal mass extinctions, 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.