The project is being led by Russia n scientists Sergey Zimov and Nikita Zimov,[3][4][5][6][7] testing the hypothesis that repopulating with large herbivores (and predators) can restore rich grasslands ecosystems, as expected if overhunting, and not climate change, was primarily responsible for the extinction of wildlife and the disappearance of the grasslands at the end of the Pleistocene epoch.[8][9]
The aim of the project is to research the climatic effects of the expected changes in the ecosystem. Here the hypothesis is that the change from tundra to grassland will result in a raised ratio of energy emission to energy absorption of the area, leading to less thawing of permafrost and thereby less emission of greenhouse gases.[8][9] It is also thought that removal of snow by large herbivores will further reduce the permafrost's insulation.
To study this, large herbivores have been released, and their effect on the local fauna is being monitored. Preliminary results point at the ecologically low-grade tundra biome being converted into a productive grassland biome and at the energy emission of the area being raised.[10]
Effects of large herbivores on the arctic tundra/grasslands ecosystem
The primary aim of Pleistocene Park is to recreate the mammoth steppe (ancient taiga/tundra grasslands that were widespread in the region during the last ice age). The key concept is that animals, rather than climate, maintained that ecosystem. Reintroducing large herbivores to Siberia would then initiate a positive feedback loop promoting the reestablishment of grassland ecosystems. This argument is the basis for rewilding Pleistocene Park's landscape with megafauna that were previously abundant in the area, as evidenced by the fossil record.[8][9][11]
The grassland-steppe ecosystem that dominated Siberia during the Pleistocene disappeared 10,000 years ago and was replaced by a mossy and forested tundra and taiga ecosystem.[8] Concurrently, most of the large herbivores that roamed Siberia during the Pleistocene have vanished from the region.[9] The mainstream explanation for this used to be that at the beginning of the Holocene the arid steppe climate changed into a humid one, and when the steppe vanished so did the steppe's animals.[8] Sergei Zimov points out that in contradiction to this scenario:
Similar climatic shifts occurred in previous interglacial periods without causing such massive environmental changes.[8][9][11]
Those large herbivores of the former steppe that survived until today (e.g. musk oxen, bison, horses) thrive in humid environments just as well as in arid ones.[8][9][11]
The climate (both temperatures and humidity) in today's northern Siberia is in fact similar to that of the mammoth steppe. The radiation aridity index for northern Siberia on Mikhail Budyko's scale is 2 (= steppe bordering on semi-desert).[8][9][11]Budyko's scale compares the ratio of the energy received by the earth's surface to the energy required for the evaporation of the total annual precipitation.
Zimov and colleagues argue for a reversed order of environmental change in the mammoth steppe. Humans, with their constantly improving technology, overhunted the large herbivores and led to their extinction and extirpation.[8][9][11][12] Without herbivores grazing and trampling over the land, mosses, shrubs and trees were able to take over and replace the grassland ecosystem.[8][9][11][12] If the grasslands were destroyed because herbivore populations were decimated by human hunting, then "it stands to reason that those landscapes can be reconstituted by the judicious return of appropriate herbivore communities."[8]
Effects of large herbivores on permafrost and global warming
A secondary aim is to research the climatic effects of the expected changes in the ecosystem. Here the key concept is that some of the effects of the large herbivores, such as eradicating trees and shrubs or trampling snow, will result in a stronger cooling of the ground in the winter, leading to less thawing of permafrost during summer and thereby less emission of greenhouse gases.[8][9][11]
Permafrost is a large global carbon reservoir that has remained frozen throughout much of the Holocene.[13] Due to recent climate change, the permafrost is beginning to thaw, releasing stored carbon and forming thermokarst lakes.[13][14] When the thawed permafrost enters the thermokarst lakes, its carbon is converted into carbon dioxide and methane and released into the atmosphere.[15][16][17]Methane is a potent greenhouse gas and the methane emissions from thermokarst lakes have the potential to initiate a positive feedback cycle in which increased atmospheric methane concentrations lead to amplified global climate change, which in turn leads to more permafrost thaw and more methane and carbon dioxide emissions.[16][17]
As the combined carbon stored in the world's permafrost (1670 Gt)[18] equals about twice the amount of the carbon currently released in the atmosphere (720 Gt),[19] the setting in motion of such a positive feedback cycle could potentially lead to a runaway climate change scenario. Even if the ecological situation of the arctic were as it was 400,000 years ago (i.e., grasslands instead of tundra), a global temperature rise of 1.5 °C (2.7 °F) relative to the pre-industrial level would be enough to start the thawing of permafrost in Siberia.[20] An increased cooling of the ground during winter would raise the current tipping point, potentially delaying such a scenario.
Implementation
Background: regional Pleistocene ecoregions
Saigas are extinct in Europe and are a critically endangered species.
It has been proposed that the introduction of a variety of large herbivores will recreate their ancient ecological niches in Siberia and regenerate the Pleistocene terrain with its different ecological habitats such as taiga, tundra, steppe and alpine terrain.
The main objective, however, is to recreate the extensive grasslands that covered the Beringia region in the late Pleistocene.
Proposed procedure
In present-day Siberia only a few of the former species of megafauna are left; and their population density is extremely low, too low to affect the environment. To reach the desired effects, the density has to be raised artificially by fencing in and concentrating the existing large herbivores. A large variety of species is important as each species affects the environment differently and as the overall stability of the ecosystem increases with the variety of species[8] (compare Biodiversity and ecological services). Their numbers will be raised by reintroducing species that became locally extinct (e.g., muskoxen). For species that became completely extinct, suitable replacements will be introduced if possible (e.g., wild Bactrian camels for the extinct Pleistocene camels of the genus Paracamelus). As the number of herbivores increases, the enclosure will be expanded.[8][9][21][22]
While this is taking place, the effects will be monitored. This concerns for example the effects on the flora (are the mosses being replaced by grasses, etc.), the effects on the atmosphere (changes in levels of methane, carbon dioxide, water vapor) and the effects on the permafrost.[10][23][24]
Finally, once a high density of herbivores over a vast area has been reached, predators larger than the wolves will have to be introduced to keep the megafauna in check.[8][9]
In 1996 a 50 ha (125 acre) enclosure was built in Pleistocene Park.[9] As a first step in recreating the ancient landscape, the Yakutian horses were introduced, as horses had been the most abundant ungulates on the northeastern Siberian mammoth steppe.[25] Of the first 40 horses, 15 were killed by predators and 12 died of eating poisonous plants. More horses were imported, and they learned to cope with the environment.[23] In 2006 approximately 20 horses lived in the park,[26] and by 2007 more horses were being born annually than died.[23] By 2013, the number had risen to about 30.[27] Moose, already present in the region, were also introduced.[28] The effects of large animals (mammoths and wisents) on nature were artificially created by using an engineering tank and an 8 wheel drive Argo all-terrain vehicle to crush pathways through the willow shrub.[12][29][30][31]
Restored grasslands in Pleistocene Park
The vegetation in the park started to change. In the areas where the horses grazed, the soil has been compacted[24] and mosses, weeds and willow shrub were replaced by grasses.[3][10][22][32] Flat grassland is now the dominating landscape inside the park.[31] The permafrost was also influenced by the grazers. When air temperature sank to −40 °C (−40 °F) in winter, the temperature of the ground was found to be only –5 °C (+23 °F) under an intact cover of snow, but −30 °C (−22 °F) where the animals had trampled down the snow. The grazers thus help keep permafrost intact, thereby lessening the amount of methane released by the tundra.[10][11]
2004–2011
In the years 2004–2005 a new fence was erected, creating an enclosure of 16 km2 (6 sq mi).[22][33]
The new enclosure finally allowed a more rapid development of the project.[22] After the fence was completed, reindeer were brought into the park from herds in the region and are now the most numerous ungulates in the park.[28][34] To increase moose density in the park, special constructions were added to the fence in several places that allow animals outside the fenced area to enter the park, while not allowing them to leave. Besides that, wild moose calves were caught in other regions and transported to the park.[35]
In 2007 a 32 meter (105 foot) high tower was erected in the park that constantly monitors the levels of methane, carbon dioxide and water vapor in the park's atmosphere.[23][36]
In September 2010, 6 male muskox from Wrangel Island were reintroduced,[6] but 2 muskoxen died in the first months: one from unknown causes, and the other from infighting among the muskoxen.[37][23][38] Seven months later, in April 2011, 6 Altai wapiti and 5 wisents arrived at the park, the wapiti were from the Altai mountains and the wisents from Prioksko-Terrasny Nature Reserve, near Moscow.[39][40] The enclosing fence proved too low for the wapiti, and by the end of 2012 all 6 had jumped the fence and run off.[41]
2011–2016
In the years 2011–2016 progress slowed down as most energy was put into the construction of a 150 ha (370 ac) branch of Pleistocene Park near the city of Tula in Tula Oblast in Europe,[27][42] see below (Wild Field section). A few more reindeer and moose were introduced into Pleistocene Park during this time,[42][43] and a monitoring system for measuring the energy balance (ratio of energy emission and energy absorption)[lower-alpha 2] of the pasture was installed.[44][45]
2017–2022
Attention has now been shifted back to the further development of Pleistocene Park. A successful crowdfunding effort in early 2017 provided funding for further animal acquisitions.[46][47][48] Later that year 12 domestic yak[49][50] and 30 domestic sheep[51][52] were brought to the park.[53][54] and the introduction of more muskoxen was planned for 2020.[55][better source needed]
For the near future the focus in animal introductions will generally be placed on browsers, not grazers, i.e., bison, muskoxen, horses, and domestic yaks. Their role in this phase will be to diminish the amount of shrubs and trees and enlarge the grassy areas. Only when these areas have sufficiently increased will grazers like saiga and wild Bactrian camels be introduced.[56][57]
2023
In 2023, 24 plains bison were brought to Pleistocene Park. The animals were sourced from Ditlevsdal Bison Farm, Denmark. Later that year, fourteen musk oxen were brought to the park.[citation needed]
Reception
Controversial aspects
Critics[who?] admonish that introducing alien species could damage the fragile ecosystem of the existing tundra. To this criticism Sergey Zimov replied: "The tundra is not an ecosystem. Such systems had not existed on the planet [before the disappearance of the megafauna], and there is nothing to cherish in the tundra. Of course, it would be silly to create a desert instead of the tundra, but if the same site would evolve into a steppe, then it certainly would improve the environment. If deer, foxes, bovines were more abundant, nature would only benefit from this. And people too. However, the danger still exists, of course, you have to be very careful. If it is a revival of the steppes, then, for example, small animals are really dangerous to release without control. As for large herbivores – no danger, as they are very easy to remove again."[58]
Another point of concern is doubt that the majority of species can be introduced in such harsh conditions. For example, according to some critics, the Yakutian horses, although they have been living in the park for several generations, would not have survived without human intervention. They normally tolerate –60 °C, but are said to cope poorly with an abundance of snow and possibly would have died of starvation in the first snowy winter. However, horses of much less primitive stock abandoned by the Japanese Army have been living feral on some uninhabited Kuril Islands since 1945. Despite the deep snows (two to three times deeper than in Yakutia), they have successfully survived all the winters without feeding. And in Pleistocene Park, while some of the Yakutian horses accept supplementary feeding, others keep away and survive on their own.[23]
Positive reception
The Zimovs' concept of Pleistocene Park and repopulating the mammoth steppe is listed as one of the "100 most substantive solutions to global warming" by Project Drawdown.[59] The list, encompassing only technologically viable, existing solutions, was compiled by a team of over 200 scholars, scientists, policymakers, business leaders and activists;[60][61] for each solution the carbon impact through the year 2050, the total and net cost to society, and the total lifetime savings were measured and modeled.[62][63]
In January 2020, a study co-authored by Nikita Zimov and three University of Oxford researchers assessed the viability of the park's goals when implemented on a larger scale. It was estimated that if three large-scale experimental areas were set up, each containing 1000 animals and costing 114 million US dollars over a ten year period, that 72,000 metric tons of carbon could be held and generate 360,000 US dollars in carbon revenues.[64]
Visitors
The park is a hub for international scientists and students, who come from around the world to conduct their own ecological research and experiments.[10] The Polaris Project was a yearly visitor from 2009 to 2015, sending American students on excursions to the park each summer.[65]
Another group of visitors are journalists. The park is steadily gaining more media attention and while most journalists do not come to the park itself the number of visitors is increasing. In 2016 for example, the park was visited by a filmmaker, two print media (Swiss 24 Heures and American The Atlantic), and two TV broadcasting companies (German ARD and American HBO).[66]
The total of visitors for 2016 (summer months only) was 45.[67]
Size and administration
Pleistocene Park is a 160 km2 scientific nature reserve (zakaznik) consisting of willow brush, grasslands, swamps, forests and a multitude of lakes.[8][68][lower-alpha 3] The average temperature in January is about –33 °C and in July +12 °C; annual precipitation is 200–250 mm.[9]
Pleistocene Park is owned and administered by a non-profit corporation, the Pleistocene Park Association, consisting of the ecologists from the Northeast Science Station in Chersky and the Grassland Institute in Yakutsk.[68] The present park area was signed over to the association by the state and is exempt from land tax.[5] The reserve is surrounded by a 600 km2 buffer zone that will be added to the park by the regional government once the animals have successfully established themselves.[68]
In July 2015 the "Pleistocene Park Foundation". http://pleistocenepark.org/. was founded, a non-profit organization (registered in Pennsylvania, US, with 501(c)(3) status)[69] dedicated to acquiring private donations for funding Pleistocene Park.[70] Hitherto Pleistocene Park had been financed solely through the funds of the founders, a practice that grew increasingly insufficient.[70]
Reindeer (Rangifer tarandus):[34] Present before the project started (although more are being brought to help simulate Pleistocene conditions). They mainly graze in the southern highlands of the park. This territory is not affected by spring flooding and dominated by larch forests and shrubland. Reindeer rarely visit the flood plain. Besides actively grazing (especially in winter) they browse on willow shrubs, tree moss, and lichens. (Numbers in park in November 2021: 20–30)[71]
Elk[BE]/moose[AE] (Alces alces):[35] Present before the project started, although in low numbers. Immigration from neighboring areas is stimulated. Due to poaching the density of moose in the region has substantially decreased in the last 20 years. To increase moose density in the park, special constructions were added to the fence in several places that allow animals outside the fenced area to enter the park, while not allowing them to leave. Besides that, wild moose calves are being caught in other regions and transported to the park.[35] It is the largest extant species of the deer family and one of the largest herbivores in the park today. (Numbers in park in November 2021: 5–15)[72]
Yakutian horse (a domestic breed of horse):[73] The first species to be introduced for the project, they were imported from the surrounding Srednekolymsk region beginning in 1988.[73] Yakutian horses have developed a range of remarkable morphologic, metabolic and physiologic adaptions to the harsh environment of Siberia, including an extremely dense and long winter coat, a compact build, a metabolism adjusted to seasonal needs, and an increased production of antifreezing compounds.[74][75] In summer they grow very large hooves, which they wear down in winter scraping away snow to get at food. Despite their size, they proved to be dominant over the wisents, who often fled from them. Yakutian horses are purely grazing animals – they eat only grass species and visit the park's forests only during the spring flood. In the spring of 2015, ten more Yakutian horses were acquired to increase genetic diversity.[76] (Numbers in park in November 2021: approximately 40)[77]
Muskoxen family
Muskox (Ovibos moschatus):[78] Muskoxen arrived at the park in September 2010. They were brought from Wrangel Island[78] (itself repopulated with animals from Canada ). They are doing well and are now fully grown. Unfortunately only males could be acquired, after an attempt to get both males and females was thwarted during the expedition when a polar bear broke the fence to eat one of them,[37] and the Zimovs are now urgently looking for females.[38] The introduction of more muskoxen was planned for 2019.[55][79] A new expedition to go to Wrangel Island was planned to take place in late 2020, but ultimately cancelled due to various delays by the time they had the boats ready, including by the COVID-19 pandemic.[80] The original muskoxen managed to escape the park several times, eventually escaping it for good, but in July 2023, they would retrieve 14 young muskoxen from the Yamal Peninsula in exchange for several plains bison. (Numbers in park in September 2023: approximately 14)[81]
Wisent (AKA European bison, Bison bonasus):[82] During the last ice age, wisents were the most cold-adapted of the Bison species and thrived in the glacial grassland-steppe biome.[83][lower-alpha 4] Their dietary needs are very different from the American bison. Year-round 10% of their diet necessarily consists of trees and shrubs, and they will ignore their main forage (grasses, sedges and forbs) in favour of woody forage to reach this quota.[84] Without supplementary feeding in winter, the yearly average may rise to 20% even in countries with mild winters.[85] Five wisents, one adult male and four juvenile females, were introduced in the park in April 2011. The wisents were brought to the park from the Prioksko-Terrasny Nature Reserve near Moscow.[40][82] The transportation was more complicated and took a longer time than originally thought, but all the animals recovered rapidly after the trip. Unfortunately, the wisents did not sufficiently acclimatize in the first months. They started to moult in November, when temperatures already were down to –30 °C (–35 °F) in Cherskii. The four juveniles died; only the adult bull survived. He is now fully acclimatized.[27][86] (Numbers in park in November 2021: 1 male)[79] The park announced via an Instagram comment that after 12 years of residence, the remaining wisent died sometime during the winter of 2022.[87]
Domestic yak in the Altai Mountains
Domestic yak (Bos mutus grunniens): Ten domestic yaks acquired in Irkutsk Oblast were introduced in Pleistocene Park in June 2017; two calves were born a few days after the arrival.[49] Another calf was born after that.[88] Yaks are adapted to extreme cold, short growing seasons for grazing herbage, and rough grazing conditions with sedges and shrubby plants. Wild yaks once lived in western Beringia.[citation needed] (Numbers in park in November 2021: approximately 8)[49][50][88]
Edilbaevskaya sheep (a domestic breed of sheep):[89] 30 domestic sheep acquired in Irkutsk Oblast were introduced in Pleistocene Park in October 2017.[51][52] The sheep are from a breed that is adapted to the Siberian cold.[51] They belong to the breed group of fat-tailed sheep; their fatty rump evolved to store fat as a reserve for lean seasons,[90] analogous to a camel's humps.[91] (Numbers in park in November 2021: 18)[92]
Kalmykian cattle (a domestic breed of cattle adapted for the Mongolian steppe):[93] A population was introduced to the park in October 2018.[94] (Numbers in park in November 2021: 15)[95]
Plains bison (Bison bison bison): Twelve yearling plains bison, nine males and three females,[96] were acquired and would have been introduced in the park once the United States' FAA gave clearance for the flight.[4][97] The plains bison were bought from the Stevens Village Bison Reserve[lower-alpha 5] near Delta Junction in Alaska; as the climate there is comparable to that of Siberia, the young bison were expected to thrive.[101] Plains bison are grazers of grasses and sedges. Unlike wisents, plains bison are almost pure grazers, which will consume other plant material mainly in time of need.[102][103][104] While wood bison were the preferred choice of subspecies, they are not easy to acquire;[86][105] plains bison simply are the subspecies that could be brought to the Park most easily.[47][106] They got bison from Denmark, from the Ditlevsdal bison farm. The bison began traveling on 7 May, and officially arrived safely in the park on 9 June. A second expedition to the Ditlevsdal bison farm allowed for another herd to be brought to the park. (Numbers in park in September 2023: 35)[96]
Orenburg fur goat (Capra aegagrus hircus): Its presence is necessary due to their ability to eat anything, including plant poisonous to other herbivores.[37] Only difficulty with acquiring them is due to them being only found in Orenburg, due to veterinary services not allowing shipping out of that region. Current plans involve bringing the goats from a farm belonging to a park ranger that formerly worked for Pleistocene Park into the park around May 2021.[107] The trip to acquire them began on May 5, with the goats being loaded on May 8, then the long trek to bring them to Pleistocene Park finished with their arrival at the park on June 18. (Numbers in park in November 2021: 35)[108]
Bactrian camel (Camelus bactrianus): Either of the two-humped camel species could act as a proxy for extinct Pleistocene camel species, whose fossils have been found in areas that once formed part of Beringia.[109][110] The camel evolved in the high arctic as a large boreal browser; its hump presumably evolved to store fat as a resource for the long winter.[91] Bactrian camels will eat almost anything, preferably any plant material such as grass, shrubs, bark, etc., but in times of need also carrion.[111][112] In the winter they will dig under snow to get at forage.[111] Camels are not suitable for wet environments, preferring uplands, and are mainly sought out in order to browse away at plants like willow shrubs, though they do sometimes eat the wet grasses. Domesticated Bactrian camels are currently set to be brought to the park around May 2021 from a farm in Orsk.[107] The trip to acquire them began on May 5, with the camels being loaded on May 8, and then the expedition would wrap up with the transport truck carrying the camels arriving at Pleistocene Park on June 18. (Numbers in park in November 2021: 10)[108]
Several non-ungulate herbivores were already present before establishment of the park and remain resident; these include the mountain hare (Lepus timidus), the black-capped marmot (Marmota camtschatica), the Arctic ground squirrel (Spermophilus parryii),[8][9] the muskrat (Ondatra zibethicus), and diverse species of voles.[113]
Carnivores
Eurasian lynx (Lynx lynx): Resident before the project started.[8] It is an important predator of medium-sized herbivores like hares and roe deer.
Tundra wolf (Canis lupus albus): Before the project started the area was already home to a family of wolves,[114] despite the originally low concentration of prey ungulates.[8]
Arctic fox (Vulpes lagopus): Resident before the project started.[8]
Wood bison (Bison bison athabascae): Better adapted to life in the Far North than the plains bison.[47] Mainly a grazer of grasses and sedges,[102][115] seasonally supplements this diet with other plant material like forbs, lichen, and silverberry and willow leaves.[115][116]Wet meadows in bottomlands (like the Kolyma river plain) are an important habitat for wood bison.[115] The original plans for the rewilding of Bison had called for the introduction of wood bison as an ecological proxy for the extinct steppe wisent, Bison priscus.[114][117] These plans did not work out[118] and wisents were acquired instead.
Altai maral
Altai wapiti or Altai maral (Cervus canadensis sibiricus): Had been introduced in April 2011.[119] The wapiti made their way to the park all the way from the mountainous regions of Altai in central southern Siberia.[119] Wapiti are very good jumpers and all six escaped within the first two years. The fence has been strengthened to cope with future introductions.[43]
Wild Bactrian camel (Camelus ferus): Like the domesticated Bactrian camel, could act as a proxy for extinct Pleistocene camel species, whose fossils have been found in areas that once formed part of Beringia.[120]
Siberian roe deer (Capreolus pygargus): Immigration from neighboring areas is encouraged.[citation needed]
Siberian tiger (Panthera tigris tigris): Introduction planned for a later stage, when herbivores have multiplied.[8][9][23]
Animals that can be placed in the park if revived from extinction
Woolly mammoth model at the Royal BC Museum, Victoria, British Columbia
Woolly mammoth (Mammuthus primigenius): In January 2011, the Yomiuri Shimbun reported that a team of scientists from Kyoto University were planning to extract DNA from a mammoth carcass preserved in a Russian laboratory and insert it into egg cells of Asian elephants in hope of creating a mammoth embryo. If the experiment succeeded, the calf would be taken to the park along with others to form a wild population. The researchers claimed that their aim was to produce the first mammoth within six years.[121][122][123][124]
Cave lion (Panthera spelaea): The discovery of two well-preserved cubs in the Sakha Republic ignited a project to clone the animal.[125]
Steppe bison (Bison priscus): The discovery of the mummified steppe bison of 9,000 years ago could help people clone the ancient bison species back, even though the steppe bison would not be the first to be "resurrected".[126]
Woolly rhinoceros (Coelodonta antiquitatis): Similar reasons to those for bringing back as the woolly mammoth.
In 2012 to 2014 a branch of Pleistocene Park named "Wild Field" (Russian: Дикое поле, Dikoe pole) was constructed near the city of Tula in Tula Oblast in the European part of Russia, approximately 250 km (150 mi) south of Moscow.[27][128]
Unlike Pleistocene Park, Wild Field's primary purpose is not scientific research but public outreach, i.e., it will provide a model of what an unregulated steppe ecosystem looked like before the advent of humans. It is situated near a federal road and a railway station and will be accessible to the general public.[128]
Wild Field comprises 300 ha (740 ac)[128] of which 280 ha have been fenced off and stocked with animals.[129] Already present in the park are nine species of large herbivores and one omnivore species: Bashkir horses (a strain of Equus ferus caballus) from the southern part of the Ural Mountains,[130][131] Altai maral/Altai wapiti (Cervus canadensis sibiricus),[131] Edilbaevskaya sheep (a strain of Ovis orientalis aries),[citation needed]roe deer (Capreolus spec.),[lower-alpha 6][128][133] Kalmykian cattle (a strain of Bos primigenius taurus),[7][134]domestic yaks (Bos mutus grunniens),[7][134][135] wild boar (Sus scrofa),[135] one female elk[BE]/moose[AE] (Alces alces),[135] four reindeer (Rangifer tarandus)[136] and 73 domestic Pridonskaya goats (a strain of Capra aegagrus hircus).[129]
↑During the last ice age northeastern Siberia remained a grassy refuge for scores of animals, including bison and woolly mammoths. Then, about 10,000 years ago, this vast ecosystem disappeared as the Ice Age ended. Now, though, the Ice Age landscape is on its way back, with a little help from the Russian scientists who have established "Pleistocene Park".[2]
↑Wikipedia has no good basic article, or at least article section on the energy balance (ratio of energy emission and energy absorption) of land surfaces: What it is, what affects it, etc. Some information may be gleaned from the articles
Earth's energy budget, though this article deals with the geological energy balance of the whole earth and not of individual areas,
Albedo, which is the scientific term for the fraction of the Sun's radiation reflected from a surface, though this article deals with geological albedo only in passing and more from a physical than from a geological or ecological point of view, and it is one of those articles written in such a way that, if you do not already know the topic beforehand, the introductory paragraph may stymie you.
↑A newer source talks of "around 14 thousand hectares" (140 km2),[5] but as the two older references[8][68] were written by Sergey Zimov himself, while the newer source was written by a journalist, 160 km2 is more likely to be the correct number.
↑Two bison species are known to have co-existed during that period in Eurasia, the steppe bison (Bison priscus, the ancestor of today's American bison) and the ancestral form of today's wisent. A study on the distribution of these two species in the Urals, the Caucasus and Western Europe found that population replacements between steppe bison and wisent occurred regularly in correlation "with major palaeoenvironmental shifts", with the wisent being "associated with colder, more tundra-like landscapes and absence of a warm summer" while the steppe bison dominated during the warmer interstadials. During the Last Glacial Maximum the steppe bison disappeared from all of the area covered by the study, leaving only the wisent.[83]
↑For information on the Stevens Village Bison Reserve see for example the website of the Stevens Village Community Improvement Corporation, subpage "Stevens Village Bison Reserve";[98] the 2006 article "Stevens Village council launches bison project" in the Juneau Empire;[99] and the 2010 article "Other tribes restore buffalo ties" in the Casper Star-Tribune.[100]
↑These are the roe deer of the Tula region, which were already present on the site of Wild Field reserve. The species is not certain, as roe deer were absent in much of European Russia throughout the 20th century and only reoccupied the area in the last decades. Judging by the IUCN distribution maps,[132] the roe deer of the Tula region should be European roe deer (Capreolus capreolus), with the westernmost extension of the range of the Siberian roe deer (Capreolus pygargus) ending approximately 500 km (300 mi) to the east.
↑ 13.013.1Sergey A. Zimov; Edward A. G. Schuur; F.S. Chapin III (2006). "Permafrost and the global carbon budget". Science312 (5780): 1612–1613. doi:10.1126/science.1128908. PMID16778046.
↑K. M. Walter; M. E. Edwards; G. Grosse; S. A. Zimov; F.S. Chapin III (26 October 2007). "Thermokarst lakes as a source of atmospheric CH4 during the last deglaciation". Science318 (5850): 633–636. doi:10.1126/science.1142924. PMID17962561. Bibcode: 2007Sci...318..633W.
↑ 16.016.1K. M. Walter; S. A. Zimov; J. P. Chanton; D. Verbyla; F.S. Chapin III (7 September 2006). "Methane bubbling from Siberian thaw lakes as a positive feedback to climate warming". Nature443 (7107): 71–75. doi:10.1038/nature05040. PMID16957728. Bibcode: 2006Natur.443...71W.
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