Английская Википедия:Greenland ice sheet

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Шаблон:Short description Шаблон:Use dmy dates Шаблон:Infobox glacier

Файл:Greenland ice sheet USGS.jpg
Greenland ice sheet as seen from space

The Greenland ice sheet is an ice sheet about Шаблон:Convert thick on average, and almost Шаблон:Convert at its thickest point.[1] It is almost Шаблон:Convert long in a north–south direction, with the greatest width of Шаблон:Convert at a latitude of 77°N, near its northern edge.[2] It covers Шаблон:Convert, around 80% of the surface of Greenland, and is the second largest body of ice in the world, after the East Antarctic ice sheet.[1] The acronyms GIS or GrIS are also frequently used in the scientific literature.[3][4][5][6]

While Greenland has had major glaciers and ice caps for at least 18 million years,[7] a single ice sheet first covered most of the island some 2.6 million years ago.[8] Since then, it has both grown, sometimes significantly larger than now,[9][10] and shrunk to less than 10% of its volume on at least one occasion.[11][12][13] Its oldest known ice is about 1 million years old.[14] Due to greenhouse gas emissions by humans, the ice sheet is now the warmest it has been in at least the past 1000 years,[15] and is losing ice at the fastest rate in at least the past 12,000 years.[16]

Every summer parts of the surface melt, and ice cliffs calve into the sea. Normally the ice sheet would be completely replenished by the vast winter snowfall.[4] But global warming is melting it two to five times faster than before 1850,[17] and snowfall has not kept up since 1996.[18] If the less stringent Paris Agreement goal of staying below Шаблон:Convert is achieved, then the melting of Greenland ice alone would add around Шаблон:Cvt to global sea level rise by the end of the century. If there are no efforts to reduce emissions, it would add around Шаблон:Cvt by 2100,[19]Шаблон:Rp with the worst-case of about Шаблон:Cvt.[20] For comparison, it has so far contributed Шаблон:Cvt since 1972,[21] while the sea level rise from all sources was Шаблон:Cvt) between 1901 and 2018.[22]Шаблон:Rp

Файл:NASA scientist Eric Rignot provides a narrated tour of Greenland’s moving ice sheet.ogv
A narrated tour about Greenland's ice sheet.

If all Шаблон:Convert of the ice sheet's volume were to melt, it would increase the global sea levels by ~Шаблон:Convert all on its own.[1] Global warming between Шаблон:Convert and Шаблон:Convert would likely make this melting inevitable, unless it is then reduced to Шаблон:Convert above preindustrial levels or lower (i.e. through large-scale carbon dioxide removal)[6] However, Шаблон:Convert still causes ice loss equivalent to Шаблон:Cvt of sea level rise,[23] and more ice will be lost if the temperatures first exceed that level before coming down.[6] If the temperatures do not decline, the ice sheet will disappear in 1,000 years with very high warming,[20] and in around 10,000 years otherwise.[24][25]

Description

Шаблон:See also Ice sheets are formed through a process of glaciation, when the local climate is so cold that snow regularly falls yet never melts entirely, causing its layers to pile up onto each other, the pressure of this steadily growing weight compressing snow into solid ice over thousands of years.[13] Once the ice sheet was formed in Greenland, its size had generally remained similar to its current state.[26] However, there were 11 times in Greenland's history when the ice sheet extended up to Шаблон:Cvt past its current boundaries, with the last one occurring around 1 million years ago.[9][10]

Файл:Aschwanden 2016 greenland ice flows.jpg
The pattern of ice flows at the Greenland ice sheet, with arrows pointing to its outlet glaciers where ice calving occurs[27]

The massive combined weight of causes it to slowly "flow", unless it is stopped by a sufficiently large obstacle, such as a mountain.[13] The terrain of Greenland has many mountains near its coastline, and they normally prevent the ice sheet from flowing further into the Arctic Ocean. The 11 periods of strong glaciation are notable because the ice sheet grew large enough to flow over those mountains.[9][10] Nowadays, northwest and southeast of the ice sheet are the main areas where there are sufficient gaps in the mountains to enable the ice sheet to flow out to the ocean through the so-called outlet glaciers. These glaciers regularly shed ice in what is known as ice calving.[28] Some of that calved ice sinks into the sediment, and can be preserved for a very long time, with sediment cores from places such as the Fram Strait providing some of the longest record of glaciation at Greenland.[7]

In geologic timescales

Файл:Tan 2018 GrIS formation.png
Timeline of the ice sheet's formation from 2.9 to 2.6 million years ago[3]

While there is evidence of large glaciers in Greenland for most of the past 18 million years,[7] they were more similar to various smaller modern formations, such as Maniitsoq and Flade Isblink, which cover Шаблон:Convert around the periphery. The conditions in Greenland were not initially suitable to enable the presence of a single cohesive ice sheet, but this began to change around 10 million years ago, during the middle Miocene, when the two passive continental margins which now form the uplands of West and East Greenland had experienced uplift for the first time, which ultimately formed the Upper Planation Surface at a 2000 to 3000 meter height above mean sea level.[29][30]

Later, during the Pliocene, a Lower Planation Surface, with the 500 to 1000 meter height above sea level, was formed during the second stage of uplift 5 million years ago, and the third stage had created multiple valleys and fjords below the planation surfaces. These increases in height had intensified glaciation due to increased orographic precipitation and cooler surface temperatures, which made it easier for ice to accumulate during colder periods and persist through higher temperature fluctuations.[29][30] While as recently as 3 million years ago, during the Pliocene warm period, Greenland's ice was limited to the highest peaks in the east and the south,[31] ice cover had gradually expanded since then,[8] until the atmospheric CO2 levels dropped to between 280 and 320 ppm 2.7–2.6 million years ago, which had reduced the temperatures sufficiently for the disparate ice caps build up in the meantime to connect and cover most of the island.[3]

Файл:Yang 2022 GrIS trends 120k.png
For much of the past 120,000 years, the climate in and around Greenland had been colder than in the last few millennia of recorded history (upper half), allowing the ice sheet to become considerably larger than it is now (lower half).[32]

Often, the base of ice sheet is warm enough due to geothermal activity to have some liquid water beneath it.[33] This liquid water, subject to great pressure from the continued movement of massive layers of ice above it, becomes a tool of intense water erosion, which eventually leaves nothing but bedrock below the ice sheet. However, there are parts of the Greenland ice sheet, near the summit, where the upper layers of the ice sheet slide above the lowest layer of ice which had frozen solid to the ground, preserving ancient soil, which can then be discovered when scientists drill ice cores, up to Шаблон:Convert deep. The oldest such soil had been continuously covered by ice for around 2.7 million years,[13] while another, Шаблон:Convert deep ice core from the summit reveals ice that is around ~1,000,000 years old.[14]

On the other hand, ocean sediment samples from the Labrador Sea provide evidence that nearly all of south Greenland had melted around 400,000 years ago, during the Marine Isotope Stage 11,[11][34] and other ice core samples, taken from Camp Century in northwestern Greenland at a depth of Шаблон:Cvt, demonstrate that the ice there melted at least once during the past 1.4 million years, during the Pleistocene, and that it did not return for at least 280,000 years.[12] Taken together, these findings suggest less than 10% of the current ice sheet's volume was left during those geologically recent periods, when the temperatures were less than Шаблон:Convert warmer than preindustrial, which contradicts how climate models typically simulate continuous presence of solid ice under those conditions.[35][13]

Файл:Radar reflector installation Greenland.jpg
Glaciologist at work

Besides providing crucial information about the past states of the ice sheet and its impact on sea level rise, ice cores are invaluable for other kinds of paleoclimate research as well. The subtle differences in isotope distributions of ice core's water molecules can reveal important information about the water cycle at the time,[36] and air bubbles frozen within the ice core provide a snapshot of the lower atmosphere, detailing the gas and particulate composition it used to have.[37][38]When properly analyzed, ice cores provide a wealth of proxies suitable for reconstructing the past temperature record,[36] precipitation patterns,[39] volcanic eruptions,[40] solar variation,[37] ocean primary production,[38] and even changes in soil vegetation cover and the associated wildfire frequency.[41] The ice cores from Greenland also record human impact, such as lead production during the time of Ancient Greece[42] and the Roman Empire.[43]

Recent melting

Файл:Arctic Temperature Trend 1987-2007.jpg
Arctic temperature trend, 1981–2007

In the earlier decades, an area in the North Atlantic which included southern Greenland was one of the only locations in the world which showed cooling rather than warming,[44][45] as it was already unusually warm in the 1930s and 1940s than it was in the decades immediately before and after.[46] However, later and more complete data sets have established both a trend of warming and ice loss starting from 1900[47](well after the start of the Industrial Revolution and its impact on global temperatures[48]) and a trend of strong warming starting around 1979, in line with the concurrently observed Arctic sea ice decline and its role in arctic amplification due to ice-albedo feedback.[49] Consistent with this warming, 1970s were the last decade when the Greenland ice sheet had grown, gaining about 47 gigatonnes per year, while the 1980–1990 period already had an average annual mass loss of ~51 Gt/y.[21] 1990–2000 period had smaller average annual loss of 41 Gt/y,[21] as 1996 was the last time when the Greenland ice sheet saw net mass gain. As of 2022, it had been losing ice for 26 years in a row,[18] and the temperatures there had been the highest in the entire past last millennium – about Шаблон:Convert warmer than the average of the 20th century.[15]

Файл:Cambios en la capa de hielo de Groenlandia.jpg
Until 2007, rate of decrease in ice sheet height in cm per year

Several factors determine the net rate of ice sheet growth or decline. These are:

  • Accumulation and melting rates of snow in and around the centre
  • Melting of ice along the sheet's margins, where it then runs off into the sea before it can refreeze during the winter
  • Ice calving into the sea from outlet glaciers also along the sheet's edges

When the IPCC Third Assessment Report was published in 2001, its analysis of observations to date had shown that the ice accumulation of 520 ± 26 gigatonnes per year was getting offset by the runoff and bottom melting equivalent to ice losses of 297±32 Gt/yr and 32±3 Gt/yr, as well as iceberg production of 235±33 Gt/yr, with the net loss of −44 ± 53 gigatonnes per year.[50]

Annual ice losses from the Greenland ice sheet had more than quadrupled in 2000s, going from 41 Gt/y in the 1980–1990 to ~187 Gt/y in 2000–2010. The losses worsened at a slower rate in 2010s: the average mass loss during 2010–2018 of 286 Gt per year – which meant that half of the ice sheet's observed net loss (3,902 gigatons (Gt) of ice between 1992 and 2018, or approximately 0.13% of its total mass[51]) happened during those 8 years. When these losses are converted to sea level rise equivalent, Greenland Ice Sheet contributed about 13.7 mm since 1972, with 4.4 mm from its northwest, 3 mm from its southeast and 2 mm from central west.[21]

Файл:Mass changes of the Greenland Ice Sheet between 2002 and 2019.webp
Trends of ice loss between 2002 and 2019[52]

Between 2012 and 2017, it had contributed 0.68 mm per year, as opposed to 0.07 mm per year between 1992 and 1997.[51] Its net contribution for the 2012–2016 period was also equivalent to 37% of sea level rise from land ice sources (excluding thermal expansion).[53] These melt rates are comparable to the largest experienced by the ice sheet over the past 12,000 years of its Holocene history, and they will inevitably be exceeded later in this century.[16]

Currently, the Greenland ice sheet is losing more mass every year than the Antarctic ice sheet, because of its position in the Arctic, where it is subject to far more intense regional amplification of warming.[44][54][55] However, ice losses from the West Antarctic Ice Sheet have been accelerating at a greater rate due to its uniquely vulnerable Thwaites and Pine Island Glaciers, and its contribution to sea level rise is expected to overtake that of Greenland later this century.[17][19]

Observed glacier retreat

Файл:Measuring Elevation Changes on the Greenland Ice Sheet.ogg
This narrated animation shows the overall change in the elevation of the Greenland ice sheet between 2003 and 2012. It can be seen that the coastal areas of the ice sheet had lost far more height, or "thinned", compared to the more inland regions.
Файл:Choi 2021 GIS glacier map.png
Greenland ice sheet has 215 marine-terminating glaciers whose retreat directly impacts sea level rise. As of 2021, 115 accounted for 79% of ice flow and could be simulated with good accuracy, 25 had their retreat underestimated and accounted for 13%, 67 lacked sufficient bathymetry surveys while accounting for 5% of the flow, and 8 had their retreat overestimated, accounting for the remaining 3%.[56]

Retreat of outlet glaciers as they shed more and more ice into the arctic waters is a large, or even dominant, factor in the decline of Greenland's ice sheet. Some analyses estimate that losses from glaciers explain 66.8% of the observed ice loss since the 1980s,[21] but others place it at 49%, with the rest accounted for by surface melting.[51] Net loss of ice was already observed across 70% of the ice sheet's coasts in the 1990s: scientific literature commonly described it as "thinning", since the glaciers started to lose height, and thus form a thinner layer over the bedrock.[57] Between 1998 and 2006, thinning occurred four times faster for coastal glaciers compared to the early 1990s,[58] falling at rates between Шаблон:Cvt and Шаблон:Cvt per year,[59] while the landlocked glaciers experienced almost no such acceleration.[58]

One of the most dramatic examples of such thinning took place in the southeast, at Kangerlussuaq Glacier. It is over Шаблон:Cvt long, Шаблон:Cvt wide and around Шаблон:Cvt thick, which makes it the third largest glacier in Greenland.[60] Between 1993 and 1998, parts of the glacier within Шаблон:Cvt of the coast lost Шаблон:Cvt in height.[61] Later, its observed ice flow speed went from Шаблон:Cvt per year for 1988–1995 to Шаблон:Cvt In 2005, which was then the fastest known flow of any glacier.[60] The retreat of Kangerlussuaq slowed down by 2008,[62] and its position even experienced some recovery until 2016–2018, when even more rapid ice loss had occurred.[63]

Greenland's other major outlet glaciers had also experienced rapid and dramatic change in the recent decades. Its single largest outlet glacier is Jakobshavn Isbræ (Шаблон:Lang-kl) in west Greenland, which has been observed by glaciologists for many decades,[64] as it historically sheds ice outflow from 6.5% of the ice sheet[65] (compared to 4% for Kangerlussuaq[60]), at speeds of ~Шаблон:Convert per day.[66] While it had already lost enough ice to retreat around Шаблон:Convert between 1850 and 1964, its mass gain increased sufficiently to keep it in balance for the next 35 years,[66] only to switch to rapid mass loss after 1997.[67][65] By 2003, its average annual ice flow speed had almost doubled since 1997, as the ice tongue in front of the glacier which used to impede ice flows had disintegrated,[67] and the glacier shed Шаблон:Convert of ice between 2001 and 2005.[68] The ice flow hit a record of Шаблон:Convert per day in 2012,[69] but slowed down substantially afterwards, to the point of experiencing mass gain between 2016 and 2019.[70][71]

On the other hand, northern Greenland's Petermann Glacier is smaller in absolute terms, yet it had experienced some of the most rapid degradation in recent decades: a loss of Шаблон:Convert of floating ice in 2000–2001, followed by a Шаблон:Convert iceberg breaking off in 2008, and then a Шаблон:Convert iceberg calving from ice shelf in August 2010, which became the largest Arctic iceberg since 1962, and amounted to a quarter of the shelf's size.[72] In July 2012, Petermann glacier had experienced the loss of another major iceberg measuring Шаблон:Convert, or twice the area of Manhattan.[73] As of 2023, the glacier's ice shelf lost around 40% of its pre-2010 state, and it is considered unlikely to recover from further ice loss.[74]

In the early 2010s, some estimates suggested that tracking the largest glaciers would be suffficient to account for most of the ice loss.[75] However, their dynamics can be hard to predict, like with the ice sheet's second largest glacier, Helheim Glacier. Its ice loss culminated in rapid retreat in 2005,[76] and was also associated with a marked increase in glacial earthquakes between 1993 and 2005.[77] Since then, it had remained comparatively stable near its 2005 position and lost relatively little mass in comparison to Jakobshavn and Kangerlussuaq,[78] although it might have eroded sufficiently by 2021 to experience another rapid retreat in the near future.[79] Meanwhile, smaller glaciers had been consistently losing mass at an accelerating rate,[80] and later research concluded that total glacier retreat is underestimated when the dynamics of largest glaciers are extrapolated without explicitly calculating the smaller glaciers.[21] By 2023, the rate of ice loss across Greenland's coasts had doubled in the two decades since 2000, in large part due to the accelerated losses from smaller glaciers.[81][82]

Processes accelerating glacier retreat

Файл:Ciraci 2023 Petermann fluctuations.jpg
Petermann Glacier experiences notable shifts from year to year not just at its calving front, but also at its grounding line, which renders it less stable. If such behaviour turns out to be widespread at other glaciers, this could potentially double their rates of ice loss.[83]

Starting from the early 2000s, glaciologists have concluded that glacier retreat in Greenland was accelerating too quickly to be explained by a linear increase in melting in response to greater surface temperatures alone, and that additional non-linear mechanisms must also be at work.[84][85][86] The rapid calving events at the largest glaciers match what was first described as the "Jakobshavn effect" in 1986:[87] thinning causes the glacier to be more buoyant, reducing friction that would otherwise impede its retreat, and also results in a force imbalance at the calving front, with the increase in velocity spread across the mass of the glacier.[88][89][65] The overall acceleration of Jakobshavn Isbrae and other glaciers from 1997 onwards had been attributed to the warming of North Atlantic waters which melt the glacier fronts from underneath: while this warming had been going on since the 1950s,[90] 1997 also saw a shift in circulation which brought relatively warmer currents from the Irminger Sea into closer contact with the glaciers of West Greenland.[91] By 2016, waters across much of West Greenland's coastline had warmed by Шаблон:Convert relative to 1990s, and some of the smaller glaciers were losing more ice to such melting than normal calving processes, leading to rapid retreat.[92]

Conversely, Jakobshavn Isbrae is sensitive to changes in ocean temperature as it experiences elevated exposure through a deep subglacial trench,[93][94] yet this sensitivity also meant that a sudden influx of cooler currents to its location had been responsible for its equally sudden slowdown after 2015,[71] in large part because the sea ice and icebergs immediately off-shore were able to survive for longer and thus help to stabilize the glacier.[95] Likewise, rapid retreat, then slowdown of Helheim in northwest and Kangerdlugssuaq in the east had also been connected to the respective warming and cooling of nearby currents.[96] At Petermann Glacier, its rapid rate of retreat had been linked to the topography of its grounding line, which appears to shift back and forth by around a kilometer with the tide: it has been suggested that if similar processes can occur at the other glaciers, then their eventual rate of mass loss could be doubled.[97][83]

Файл:Inlandsis moulin Groenland 2009 Expédition ACarré.JPG
Meltwater rivers may flow down into moulins and reach the base of the ice sheet

Research has shown that there are also several ways in which increased melting at the surface of the ice sheet can also accelerate lateral retreat of outlet glaciers. Firstly, the increase in meltwater at the surface causes larger amounts to flow all the way through the ice sheet down to bedrock via moulins. There, its presence lubricates the base of glaciers and generates higher basal pressure, which collectively reduces friction and accelerates glacial motion, including the rate of ice calving. This mechanism was observed at Sermeq Kujalleq in 1998 and 1999, where its flow was accelerated by up to 20% for two-three months.[98][99] However, subsequent research had shown that this mechanism only applies to certain small glaciers, rather than to the largest outlet glaciers,[100] and has only a "marginal" impact on ice loss trends.[101]

Файл:Slater 2022 meltwater plumes.png
An illustration of how meltwater forms a plume once it flows out into the ocean

Secondly, once meltwater flows into the ocean, it can still impact the glaciers by interacting with ocean water and altering its local circulation - even in the absence of any ocean warming.[102] In certain fjords, large meltwater flows from beneath the ice may mix with ocean water to create turbulent plumes that can be very damaging to the calving front.[103] While the models generally consider such the impact from meltwater run-off deeply secondary to ocean warming,[104] observations of 13 glaciers found that meltwater plumes play a greater role for glaciers with shallow grounding lines.[105] Further, 2022 research suggests that the warming from plumes had a greater impact on underwater melting across the entire northwest Greenland, with only south Greenland definitely affected by changes in ocean currents more than by the impact of local warming on its own meltwater.[102]

Finally, it has been shown that in addition to major moulins, meltwater can also flow through a large number of cracks that are too small to be picked up by most research tools - only Шаблон:Cvt wide. Such cracks do not connect to bedrock through the entire ice sheet but may still reach several hundred meters down from the surface.[106] Their presence is important, as it weakens the ice sheet, and the meltwater inside them also conducts more heat directly through the ice, making it more viscous and thus allowing it to flow faster.[107] As this research is recent, it is not currently captured in the models. One of the scientists behind these findings, Alun Hubbard, described finding moulins where "current scientific understanding doesn’t accommodate" their presence, because it disregards how they may evolve from such hairline cracks even in the absence of existing large crevasses that are normally thought to be necessary for their formation.[108]

Observed surface melting

Шаблон:Multiple image Currently, the total accumulation of ice on the surface of Greenland ice sheet remains larger than either outlet glacier losses individually or surface melting during the summer, and it is the combination of both which causes net annual loss.[4] Every summer, a so-called snow line separates the ice sheet's surface into areas above it, where snow continues to accumulate even then, with the areas below the line where summer melting occurs.[109] Notably, the exact position of the snow line moves around every summer, and if it moves away from some areas it covered the previous year, then those tend to experience substantially greater melt as their darker ice is exposed. In this way, the uncertainty about the snow line is one of the factors making it hard to predict each melting season in advance.[110]

Файл:Melt Ponds on the Greenland Ice Sheet.jpg
Satellite image of dark melt ponds

A notable example of ice accumulation rates above the snow line is provided by Glacier Girl, a Lockheed P-38 Lightning fighter plane which had crashed early in World War II and was recovered in 1992, by which point it had been buried under Шаблон:Cvt of ice.[111] Another example occurred in 2017, when an Airbus A380 had to make an emergency landing in Canada after one of its jet engines exploded while it was above Greenland; the engine's massive air intake fan was recovered from the ice sheet two years later, when it was already buried beneath Шаблон:Cvtof ice and snow.[112]

While summer surface melting had been increasing, it is still expected that it'll be decades before it will consistently exceed snow accumulation on its own.[4] It had also been hypothesized that the increase in global precipitation associated with the effects of climate change on the water cycle would also increase snowfall over Greenland, and thus further delay this transition.[113] This hypothethis had been difficult to test in the 2000s due to the poor state of long-term precipitation records over the ice sheet.[114] By 2019, it was found that while there was an increase in snowfall over southwest Greenland,[115] there had been a substantial decrease in precipitation over western Greenland as a whole.[113] Further, more precipitation in the northwest had been falling as rain instead of snow, with a fourfold increase in rain since 1980.[116] Rain is warmer than snow and forms darker and less thermally insulating ice layer once it does freeze on the ice sheet. It is particularly damaging when it falls due to late-summer cyclones, whose increasing occurrence had been overlooked by the earlier models.[117] There had also been an increase in water vapor, which paradoxically increases melting by making it easier for heat to radiate downwards through moist, as opposed to dry, air.[118]

Файл:Greenland Meltdown 08072012 12072012.jpg
NASA graphics show the extent of the then-record melting event in July 2012.

Altogether, the melt zone below the snow line, where summer warmth turns snow and ice into slush and melt ponds, has been expanding at an accelerating rate since the beginning of detailed measurements in 1979. By 2002, its area was found to have increased by 16% since 1979, and the annual melting season broke all previous records.[44] Another record was set in July 2012, when the melt zone extended to 97% of the ice sheet's cover,[119] and the ice sheet lost approximately 0.1% of its total mass (2900 Gt) during that year's melting season, with the net loss (464 Gt) setting another record.[120] It became the first directly observed example of a "massive melting event", when the melting took place across practically the entire ice sheet surface, rather than specific areas.[121] That event led to the counterintuitive discovery that cloud cover, which normally results in cooler temperature due to their albedo, actually interferes with meltwater refreezing in the firn layer at night, which can increase total meltwater runoff by over 30%.[122][123] Thin, water-rich clouds have the worst impact, and they were the most prominent in July 2012.[124]

Файл:Greenland river July 2012.png
Rivers of meltwater flowing on 21 July 2012.

Ice cores had also shown that the last time a melting event of the same magnitude as in 2012 took place was in 1889, and some glaciologists had expressed hope that 2012 was part of a 150-year cycle.[125][126] This was disproven in 2019, when a combination of high temperatures and unsuitable cloud cover led to an even larger mass melting event over both June and July, which ultimately covered over Шаблон:Convert at its greatest extent. Predictably, 2019 set a new record of 586 Gt net mass loss.[52][127] In July 2021, another record mass melting event occurred. At its peak, it covered Шаблон:Convert, and led to daily ice losses of 88 Gt across several days.[128][129] High temperatures continued in August 2021, with the melt extent staying at Шаблон:Convert. At that time, rain fell for 13 hours at Greenland's Summit Station, located at Шаблон:Convert elevation.[130] Researchers had no rain gauges to measure the rainfall, because temperatures at the summit have risen above freezing only three times since 1989 and it had never rained there before.[131]

Due to the enormous thickness of the central Greenland ice sheet, even the most extensive melting event can only affect a small fraction of it before the start of the freezing season, and so they are considered "short-term variability" in the scientific literature. Nevertheless, their existence is important: the fact that the current models underestimate the extent and frequency of such events is considered to be one of the main reasons why the observed ice sheet decline in Greenland and Antarctica tracks the worst-case rather than the moderate scenarios of the IPCC Fifth Assessment Report's sea-level rise projections.[132][133][134] Some of the most recent scientific projections of Greenland melt now include an extreme scenario where a massive melting event occurs every year across the studied period (i.e. every year between now and 2100 or between now and 2300), to illustrate that such a hypothetical future would greatly increase ice loss, but still wouldn't melt the entire ice sheet within the study period.[135][136]

Changes in albedo

Файл:Greenland Albedo Change.png
Albedo change in Greenland

On the ice sheet, annual temperatures are generally substantially lower than elsewhere in Greenland: about Шаблон:Convert at the south dome (latitudes 63°65°N) and Шаблон:Convert near the center of the north dome (latitude 72°N (the fourth highest "summit" of Greenland).[2] On 22 December 1991, a temperature of Шаблон:Convert was recorded at an automatic weather station near the topographic summit of the Greenland Ice Sheet, making it the lowest temperature ever recorded in the Northern Hemisphere. The record went unnoticed for more than 28 years and was finally recognized in 2020.[137] These low temperatures are in part caused by the high albedo of the ice sheet, as its bright white surface is very effective at reflecting sunlight. Ice-albedo feedback means that as the temperatures increase, this causes more ice to melt and either reveal bare ground or even just to form darker melt ponds, both of which act to reduce albedo, which accelerates the warming and contributes to further melting. This is taken into account by the climate models, which estimate that a total loss of the ice sheet would increase global temperature by Шаблон:Convert, while Greenland's local temperatures would increase by between Шаблон:Convert and Шаблон:Convert.[138][24][25]

Even incomplete melting already has some impact on the ice-albedo feedback. Besides the formation of darker melt ponds, warmer temperatures enable increasing growth of algae on the ice sheet's surface. Mats of algae are darker in colour than the surface of the ice, so they absorb more thermal radiation and increase the rate of ice melt.[139] In 2018, it was found that the regions covered in dust, soot, and living microbes and algae altogether grew by 12% between 2000 and 2012.[140] In 2020, it was demonstrated that the presence of algae, which is not accounted for by ice sheet models unlike soot and dust, had already been increasing annual melting by 10–13%.[141] Additionally, as the ice sheet slowly gets lower due to melting, surface temperatures begin to increase and it becomes harder for snow to accumulate and turn to ice, in what is known as surface-elevation feedback.[142][143]

Файл:Hopwood 2018 runoff patterns.png
Meltwater runoff has the greatest positive effect on phytoplankton when it can force nitrate-rich waters to the surface (b), which will become more difficult as the glaciers retreat (d).[144]

Geophysical and biochemical role of Greenland's meltwater

Шаблон:See also Even in 1993, Greenland's melt resulted in 300 cubic kilometers of fresh meltwater entering the seas annually, which was substantially larger than the liquid meltwater input from the Antarctic ice sheet, and equivalent to 0.7% of freshwater entering the oceans from all of the world's rivers.[145] This meltwater is not pure, and contains a range of elements - most notably iron, about half of which (around 0.3 million tons every year) is bioavailable as a nutrient for phytoplankton.[146] Thus, meltwater from Greenland enhances ocean primary production, both in the local fjords,[147] and further out in the Labrador Sea, where 40% of the total primary production had been attributed to nutrients from meltwater.[148] Since the 1950s, the acceleration of Greenland melt caused by climate change has already been increasing productivity in waters off the North Icelandic Shelf,[149] while productivity in Greenland's fjords is also higher than it had been at any point in the historical record, which spans from late 19th century to present.[150] However, some research suggests that Greenland's meltwater mainly benefits marine productivity not by adding its carbon and iron, but through stirring up lower water layers that are rich in nitrates and thus bringing more of those crucial nutrients to phytoplankton on the surface. As the outlet glaciers retreat inland, their meltwater will be less able to impact the lower layers, which implies that benefit from their meltwater will diminish even as its volume will grow in absolute terms.[144]

Файл:Christiansen 2018 GrIS meltwater flow.png
A photo of a meltwater flow at Russell Glacier. Water emerging through the small crack comes from the melting of underground ice and is particularly rich in carbon.[151]

The impact of meltwater from Greenland goes beyond nutrient transport. For instance, meltwater also contains dissolved organic carbon, which comes from the microbial activity on the ice sheet's surface, and, to a lesser extent, from the remnants of ancient soil and vegetation beneath the ice.[152] There is about 0.5-27 billion tonnes of pure carbon underneath the entire ice sheet, and much less within it.[153] This is much less than the 1400–1650 billion tonnes contained within the Arctic permafrost,[154] or the annual anthropogenic emissions of around 40 billion tonnes of Шаблон:CO2.[19]Шаблон:Rp) Yet, the release of this carbon through meltwater can still act as a climate change feedback if it increases overall carbon dioxide emissions.[155] There is one known area, at Russell Glacier, where meltwater carbon is released into the atmosphere as methane, which has a much larger global warming potential than carbon dioxide:[151] however, it also harbours large numbers of methanotrophic bacteria, which limit those emissions.[156][157]

In 2021, research claimed that there must be mineral deposits of mercury (a highly toxic heavy metal) beneath the southwestern ice sheet, because of the exceptional concentrations in meltwater entering the local fjords. If confirmed, these concentrations would have equalled up to 10% of mercury in all of the world's rivers.[158][159] In 2024, a follow-up study found only "very low" concentrations in meltwater from 21 locations. It concluded that the 2021 findings were best explained by accidental sample contamination with mercury(II) chloride, used by the first team of researchers as a reagent.[160] However, there is still a risk of toxic waste being released from Camp Century, formerly a United States military site secretly built to carry nuclear weapons for the Project Iceworm. The project was cancelled, but the site was never cleaned up, and it now threatens to eventually pollute the meltwater with nuclear waste, 20,000 liters of chemical waste and 24 million liters of untreated sewage as the melt progresses.[161][162]

Файл:16-008-NASA-2015RecordWarmGlobalYearSince1880-20160120.png
The cold blob visible on NASA's global mean temperatures for 2015, the warmest year on record up to 2015 (since 1880). Colors indicate temperature evolution (NASA/NOAA; 20 January 2016).[163]

Finally, increased quantities of fresh meltwater can affect ocean circulation.[44] Some scientists have connected this increased discharge from Greenland with the so-called cold blob in the North Atlantic, which is in turn connected to Atlantic meridional overturning circulation, or AMOC, and its apparent slowdown.[164][165][166][167] In 2016, a study attempted to improve forecasts of future AMOC changes by incorporating better simulation of Greenland trends into projections from eight state-of-the-art climate models. That research found that by 2090–2100, the AMOC would weaken by around 18% (with a range of potential weakening between 3% and 34%) under Representative Concentration Pathway 4.5, which is most akin to the current trajectory,[168][169] while it would weaken by 37% (with a range between 15% and 65%) under Representative Concentration Pathway 8.5, which assumes continually increasing emissions. If the two scenarios are extended past 2100, then the AMOC ultimately stabilizes under RCP 4.5, but it continues to decline under RCP 8.5: the average decline by 2290–2300 is 74%, and there is 44% likelihood of an outright collapse in that scenario, with a wide range of adverse effects.[170]

Future ice loss

Near-term

Шаблон:Multiple image In 2021, the IPCC Sixth Assessment Report estimated that under SSP5-8.5, the scenario associated with the highest global warming, Greenland ice sheet melt would add around Шаблон:Cvt to the global sea levels (with a likely (17%–83%) range of Шаблон:Cvt and a very likely range (5–95% confidence level) of Шаблон:Cvt), while the "moderate" SSP2-4.5 scenario adds Шаблон:Cvt with a likely and very likely range of Шаблон:Cvt and Шаблон:Cvt, respectively. The optimistic scenario which assumes that the Paris Agreement goals are largely fulfilled, SSP1-2.6, adds around Шаблон:Cvt and no more than Шаблон:Cvt, with a small chance of the ice sheet gaining mass and thus reducing the sea levels by around Шаблон:Cvt.[19]Шаблон:Rp

There are a few scientists, mainly led by James Hansen, who have long claimed that the ice sheets can disintegrate substantially faster than estimated by the ice sheet models,[171] but even their projections also have much of Greenland, whose total size amounts to Шаблон:Convert of sea level rise,[1] survive the 21st century. I.e. a 2016 paper from Hansen claimed that Greenland ice loss could add around Шаблон:Cvt by 2060, in addition to double that figure from the Antarctic ice sheet, if the Шаблон:CO2 concentration exceeded 600 parts per million,[172] which was immediately controversial amongst the scientific community,[173] while 2019 research from different scientists claimed a maximum of Шаблон:Cvt by 2100 under the worst-case climate change scenario.[20]

Файл:Choi 2021 GIS glacier trends.png
Projections of 21st century retreat for Greenland's largest glaciers[56]

As with the present losses, not all parts of the ice sheet would contribute to them equally. For instance, it is estimated that on its own, the Northeast Greenland Ice Stream would contribute 1.3–1.5 cm by 2100 under RCP 4.5 and RCP 8.5, respectively.[174] On the other hand, the three largest glaciers - Jakobshavn, Helheim, and Kangerlussuaq - are all located in the southern half of the ice sheet, and just the three of them are expected to add 9.1–14.9 mm under RCP 8.5.[28] Similarly, 2013 estimates suggested that by 2200, they and another large glacier would add 29 to 49 millimetres by 2200 under RCP 8.5, or 19 to 30 millimetres under RCP 4.5.[175] Altogether, the single largest contribution to 21st century ice loss in Greenland is expected to be from the northwest and central west streams (the latter including Jakobshavn), and glacier retreat will be responsible for at least half of the total ice loss, as opposed to earlier studies which suggested that surface melting would become dominant later this century.[56] If Greenland were to lose all of its coastal glaciers, though, then or not it will continue to shrink will be entirely determined by whether its surface melting in the summer consistently outweighs ice accumulation during winter. Under the highest-emission scenario, this could happen around 2055, well before the coastal glaciers are lost.[4]

It should also be noted that the sea level rise from Greenland does not affect every coast equally. The south of the ice sheet is much more vulnerable than the other parts, and the quantities of ice involved mean that there is an impact on the deformation of Earth's crust and on Earth's rotation. While this effect is subtle, it already causes East Coast of the United States to experience faster sea level rise than the global average.[176] At the same time, Greenland itself would experience isostatic rebound as its ice sheet shrinks and its ground pressure becomes lighter. Similarly, a reduced mass of ice would exert a lower gravitational pull on the coastal waters relative to the other land masses. These two processes would cause sea level around Greenland's own coasts to fall, even as it rises elsewhere.[177] The opposite of this phenomenon happened when the ice sheet gained mass during the Little Ice Age: increased weight attracted more water and flooded certain Viking settlements, likely playing a large role in the Viking abandonment soon afterwards.[178][179]

Long-term

Файл:Mean regional trends in ice thickness and front position.webp
These graphs indicate the switch of peripheral glaciers to a dynamic state of sustained mass loss after the widespread retreat in 2000–2005, making their disappearance inevitable.[180]
Файл:Beckmann 2023 Greenland 2300 RCP85 extent.png
2023 projections of how much the Greenland ice sheet may shrink from its present extent by the year 2300 under the worst possible climate change scenario (upper half) and of how much faster its remaining ice will be flowing in that case (lower half)[136]

Notably, the ice sheet's massive size simultaneously makes it insensitive to temperature changes in the short run, yet also commits it to enormous changes down the line, as demonstrated by paleoclimate evidence.[11][35][34] Polar amplification causes the Arctic, including Greenland, to warm three to four times more than the global average:[181][182][183] thus, while a period like the Eemian interglacial 130,000–115,000 years ago was not much warmer than today globally, the ice sheet was Шаблон:Convert warmer, and its northwest part was 130 ± 300 meters lower than it is at present.[184][185] Some estimates suggest that the most vulnerable and fastest-receding parts of the ice sheet have already passed "a point of no return" around 1997, and will be committed to disappearance even if the temperature stops rising.[186][180][187]

A 2022 paper found that the 2000–2019 climate would already result in the loss of ~3.3% volume of the entire ice sheet in the future, committing it to an eventual Шаблон:Cvt of SLR, independent of any future temperature change. They have additionally estimated that if the then-record melting seen on the ice sheet in 2012 were to become its new normal, then the ice sheet would be committed to around Шаблон:Cvt SLR.[135] Another paper suggested that paleoclimate evidence from 400,000 years ago is consistent with ice losses from Greenland equivalent to at least Шаблон:Cvt of sea level rise in a climate with temperatures close to Шаблон:Convert, which are now inevitable at least in the near future.[23]

It is also known that at a certain level of global warming, effectively the entirety of the Greenland's ice sheet will eventually melt. Its volume was initially estimated to amount to ~Шаблон:Convert, which would increase the global sea levels by Шаблон:Convert,[50] but later estimates increased its size to ~Шаблон:Convert, leading to ~Шаблон:Convert of sea level rise.[1]

Thresholds for total ice sheet loss

In 2006, it was estimated that the ice sheet is most likely to be committed to disappearance at Шаблон:Convert, with a plausible range between Шаблон:Convert and Шаблон:Convert.[188] However, these estimates were drastically reduced in 2012, with the suggestion that the threshold may lie anywhere between Шаблон:Convert and Шаблон:Convert, with Шаблон:Convert the most plausible global temperature for the ice sheet's disappearance.[189] That lowered temperature range had been widely used in the subsequent literature,[34][190] and in the year 2015, prominent NASA glaciologist Eric Rignot claimed that "even the most conservative people in our community" will agree that "Greenland’s ice is gone" after Шаблон:Convert or Шаблон:Convert of global warming.[142]

In 2022, a major review of scientific literature on tipping points in the climate system had barely modified these values: it suggested that the threshold would be most likely be at Шаблон:Convert, with the upper level at Шаблон:Convert and the worst-case threshold of Шаблон:Convert remained unchanged.[24][25] At the same time, it noted that the fastest plausible timeline for the ice sheet disintegration is 1000 years, which is based on research assuming the worst-case scenario of global temperatures exceeding Шаблон:Convert by 2500,[20] while its ice loss otherwise takes place over around 10,000 years after the threshold is crossed; the longest possible estimate is 15,000 years.[24][25]

Файл:Höning 2023 GIS thresholds.jpg
Potential equilibrium states of the ice sheet in response to different equilibrium carbon dioxide concentrations in parts per million. Second and third states would result in Шаблон:Convert and Шаблон:Convert of sea level rise, while the fourth state is equivalent to Шаблон:Convert.[5]

Model-based projections published in the year 2023 had indicated that the Greenland ice sheet could be a little more stable than suggested by the earlier estimates. One paper found that the threshold for ice sheet disintegration is more likely to lie between Шаблон:Convert and Шаблон:Convert. It also indicated that the ice sheet could still be saved, and its sustained collapse averted, if the warming were reduced to below Шаблон:Convert, up to a few centuries after the threshold was first breached. However, while that would avert the loss of the entire ice sheet, it would increase the overall sea level rise by up to several meters, as opposed to a scenario where the warming threshold was not breached in the first place.[6]

Another paper used a more complex ice sheet model with more detailed calculations than the previous, more abstracted studies, and it found that ever since the warming passed Шаблон:Convert degrees, ~Шаблон:Cvt of sea level rise became inevitable,[5] which closely matched the estimate derived from direct observation in 2022.[135] However, it had also found that Шаблон:Convert would likely only commit the ice sheet to Шаблон:Convert of long-term sea level rise, while near-complete melting of Шаблон:Convert worth of sea level rise would occur if the temperatures consistently stay above Шаблон:Convert. The paper also suggested that ice losses from Greenland may be reversed by reducing temperature to Шаблон:Convert or lower, up until the entirety of South Greenland ice melts, which would cause Шаблон:Convert of sea level rise and prevent any regrowth unless Шаблон:CO2 concentrations is reduced to 300 ppm. If the entire ice sheet were to melt, it would not begin to regrow until temperatures fall to below the preindustrial levels.[5]

Файл:Greenland-ice sheet hg.jpg
Aerial view of the ice sheet's eastern coast.

See also

References

Шаблон:Reflist

External links

Шаблон:Commons category

Шаблон:Greenland topics Шаблон:Arctic topics Шаблон:Climate change

Партнерские ресурсы
Криптовалюты
Магазины
Хостинг
Разное

  1. 1,0 1,1 1,2 1,3 1,4 Шаблон:Cite web
  2. 2,0 2,1 Шаблон:Cite encyclopedia
  3. 3,0 3,1 3,2 Шаблон:Cite journal
  4. 4,0 4,1 4,2 4,3 4,4 Шаблон:Cite journal
  5. 5,0 5,1 5,2 5,3 Шаблон:Cite journal
  6. 6,0 6,1 6,2 6,3 Шаблон:Cite journal
  7. 7,0 7,1 7,2 Шаблон:Cite journal
  8. 8,0 8,1 Шаблон:Cite journal
  9. 9,0 9,1 9,2 Шаблон:Cite journal
  10. 10,0 10,1 10,2 Шаблон:Cite web
  11. 11,0 11,1 11,2 Шаблон:Cite journal
  12. 12,0 12,1 Шаблон:Cite journal
  13. 13,0 13,1 13,2 13,3 13,4 Шаблон:Cite web
  14. 14,0 14,1 Шаблон:Cite journal
  15. 15,0 15,1 Шаблон:Cite journal
  16. 16,0 16,1 Шаблон:Cite journal
  17. 17,0 17,1 Шаблон:Cite web
  18. 18,0 18,1 Шаблон:Cite web
  19. 19,0 19,1 19,2 19,3 Шаблон:Cite journal
  20. 20,0 20,1 20,2 20,3 Шаблон:Cite journal
  21. 21,0 21,1 21,2 21,3 21,4 21,5 Шаблон:Cite journal
  22. IPCC, 2021: Summary for Policymakers Шаблон:Webarchive. In: Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change Шаблон:Webarchive [Masson-Delmotte, V., P. Zhai, A. Pirani, S.L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M.I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J.B.R. Matthews, T.K. Maycock, T. Waterfield, O. Yelekçi, R. Yu, and B. Zhou (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, US, pp. 3–32, doi:10.1017/9781009157896.001.
  23. 23,0 23,1 Шаблон:Cite journal
  24. 24,0 24,1 24,2 24,3 Шаблон:Cite journal
  25. 25,0 25,1 25,2 25,3 Шаблон:Cite web
  26. Шаблон:Cite journal
  27. Шаблон:Cite journal
  28. 28,0 28,1 Шаблон:Cite journal
  29. 29,0 29,1 Шаблон:Cite journal
  30. 30,0 30,1 Шаблон:Cite journal
  31. Шаблон:Cite journal
  32. Шаблон:Cite journal
  33. Шаблон:Cite web
  34. 34,0 34,1 34,2 Шаблон:Cite journal
  35. 35,0 35,1 Шаблон:Cite journal
  36. 36,0 36,1 Шаблон:Cite journal
  37. 37,0 37,1 Шаблон:Cite journal
  38. 38,0 38,1 Шаблон:Cite journal Файл:CC-BY icon.svg Text and images are available under a Creative Commons Attribution 4.0 International License Шаблон:Webarchive.
  39. Шаблон:Cite journal
  40. Шаблон:Cite journal
  41. Шаблон:Cite journal
  42. Шаблон:Cite journal
  43. Шаблон:Cite journal
  44. 44,0 44,1 44,2 44,3 Шаблон:Cite web
  45. Шаблон:Cite web
  46. Шаблон:Cite journal
  47. Шаблон:Cite journal
  48. Шаблон:Cite journal
  49. IPCC, 2007. Trenberth, K.E., P.D. Jones, P. Ambenje, R. Bojariu, D. Easterling, A. Klein Tank, D. Parker, F. Rahimzadeh, J.A. Renwick, M. Rusticucci, B. Soden and P. Zhai, 2007: Observations: Surface and Atmospheric Climate Change. In: Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change [Solomon, S., D. Qin, M. Manning, Z. Chen, M. Marquis, K.B. Averyt, M. Tignor and H.L. Miller (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA.[1] Шаблон:Webarchive
  50. 50,0 50,1 Climate Change 2001: The Scientific Basis. Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change (IPCC) [Houghton, J.T., Y. Ding, D.J. Griggs, M. Noguer, P.J. van der Linden, X. Dai, K. Maskell, and C.A. Johnson (eds.)]Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 881pp. [2] Шаблон:Webarchive, Шаблон:Cite web, and [3] Шаблон:Webarchive.
  51. 51,0 51,1 51,2 Шаблон:Cite journal
  52. 52,0 52,1 Шаблон:Cite news
  53. Шаблон:Cite journal
  54. Шаблон:Cite journal
  55. Шаблон:Cite journal
  56. 56,0 56,1 56,2 Шаблон:Cite journal Файл:CC-BY icon.svg Text and images are available under a Creative Commons Attribution 4.0 International License Шаблон:Webarchive.
  57. Шаблон:Cite journal
  58. 58,0 58,1 Шаблон:Cite journal
  59. Шаблон:Cite web
  60. 60,0 60,1 60,2 Шаблон:Cite news
  61. Шаблон:Cite journal
  62. Шаблон:Cite journal
  63. Шаблон:Cite journal
  64. Шаблон:Cite web
  65. 65,0 65,1 65,2 Шаблон:Cite journal
  66. 66,0 66,1 Шаблон:Cite journal
  67. 67,0 67,1 Шаблон:Cite web
  68. Шаблон:Cite web
  69. Шаблон:Cite web
  70. Шаблон:Cite web
  71. 71,0 71,1 Шаблон:Cite journal
  72. Шаблон:Cite news
  73. Шаблон:Cite news
  74. Шаблон:Cite journal
  75. Шаблон:Cite journal
  76. Шаблон:Cite journal
  77. Шаблон:Cite journal
  78. Шаблон:Cite journal
  79. Шаблон:Cite journal
  80. Шаблон:Cite journal
  81. Шаблон:Cite journal
  82. Шаблон:Cite web
  83. 83,0 83,1 Шаблон:Cite journal
  84. Шаблон:Cite journal
  85. Шаблон:Cite journal
  86. Шаблон:Cite journal
  87. Шаблон:Cite journal
  88. Шаблон:Cite journal
  89. Шаблон:Cite journal
  90. Шаблон:Cite journal
  91. Шаблон:Cite journal
  92. Шаблон:Cite journal
  93. Шаблон:Cite journal
  94. Шаблон:Cite journal
  95. Шаблон:Cite journal
  96. Шаблон:Cite journal
  97. Шаблон:Cite news
  98. Шаблон:Cite journal
  99. Шаблон:Cite web
  100. Шаблон:Cite journal
  101. Шаблон:Cite journal
  102. 102,0 102,1 Шаблон:Cite journal
  103. Шаблон:Cite journal
  104. Шаблон:Cite journal
  105. Шаблон:Cite journal
  106. Шаблон:Cite journal
  107. Шаблон:Cite journal
  108. Шаблон:Cite web
  109. Шаблон:Cite news
  110. Шаблон:Cite journal
  111. Шаблон:Cite web
  112. Шаблон:Cite web
  113. 113,0 113,1 Шаблон:Cite journal
  114. Шаблон:Cite journal
  115. Шаблон:Cite journal
  116. Шаблон:Cite journal
  117. Шаблон:Cite journal
  118. Шаблон:Cite journal
  119. Шаблон:Cite web
  120. Шаблон:Cite web
  121. Шаблон:Cite web
  122. Шаблон:Cite journal
  123. Шаблон:Cite journal
  124. Шаблон:Cite journal
  125. Шаблон:Cite web
  126. Шаблон:Cite journal
  127. Шаблон:Cite journal Файл:CC-BY icon.svg Text and images are available under a Creative Commons Attribution 4.0 International License Шаблон:Webarchive.
  128. Шаблон:Cite news
  129. Шаблон:Cite web
  130. Шаблон:Cite web
  131. Шаблон:Cite news
  132. Шаблон:Cite news
  133. Шаблон:Cite news
  134. Шаблон:Cite journal
  135. 135,0 135,1 135,2 Шаблон:Cite journal
  136. 136,0 136,1 Шаблон:Cite journal
  137. Шаблон:Cite web
  138. Шаблон:Cite journal
  139. Шаблон:Cite news
  140. Шаблон:Cite news
  141. Шаблон:Cite journal
  142. 142,0 142,1 Шаблон:Cite web
  143. Шаблон:Cite journal
  144. 144,0 144,1 Шаблон:Cite journal
  145. Шаблон:Cite journal
  146. Шаблон:Cite journal
  147. Шаблон:Cite journal
  148. Шаблон:Cite journal
  149. Шаблон:Cite journal
  150. Шаблон:Cite journal
  151. 151,0 151,1 Шаблон:Cite journal
  152. Шаблон:Cite journal
  153. Шаблон:Cite journal
  154. Шаблон:Cite journal
  155. Шаблон:Cite journal
  156. Шаблон:Cite journal
  157. Шаблон:Cite journal
  158. Шаблон:Cite journal
  159. Шаблон:Cite web
  160. Шаблон:Cite journal
  161. Шаблон:Cite journal
  162. Шаблон:Cite web
  163. Шаблон:Cite web
  164. Шаблон:Cite journal
  165. Шаблон:Cite web
  166. Шаблон:Cite journal
  167. Шаблон:Cite journal
  168. Ошибка цитирования Неверный тег <ref>; для сносок Schuur2022 не указан текст
  169. Ошибка цитирования Неверный тег <ref>; для сносок Phiddian2022 не указан текст
  170. Шаблон:Cite journal
  171. Шаблон:Cite journal
  172. Шаблон:Cite journal
  173. Шаблон:Cite news
  174. Шаблон:Cite journal
  175. Шаблон:Cite journal
  176. Шаблон:Cite journal
  177. Шаблон:Cite web
  178. Шаблон:Cite journal
  179. Шаблон:Cite web
  180. 180,0 180,1 Шаблон:Cite journal Файл:CC-BY icon.svg Text and images are available under a Creative Commons Attribution 4.0 International License.
  181. Шаблон:Cite web
  182. Шаблон:Cite journal
  183. Шаблон:Cite web
  184. Шаблон:Cite journal
  185. Шаблон:Cite journal
  186. Шаблон:Cite news
  187. Шаблон:Cite journal
  188. Шаблон:Cite journal
  189. Шаблон:Cite journal
  190. Шаблон:Cite journal
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