Snowball Earth

Proterozoic snowball periods
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Neoproterozoic era
Snowball Earth
A recent estimate of the timing and duration of Proterozoic glacial periods. Note that great uncertainty surrounds the dating of pre-Gaskiers glaciations. The status of the Kaigas is not clear; its dating is very insecure and many workers do not recognise it as a glaciation. From Smith 2009,[2] modified with updated info from Pu et al 2016.[1] An earlier and longer possible snowball phase, the Huronian glaciation, is not shown.

The Snowball Earth hypothesis proposes that Earth's surface became entirely or nearly entirely frozen at least once, sometime earlier than 650 Mya (million years ago). Proponents of the hypothesis argue that it best explains sedimentary deposits generally regarded as of glacial origin at tropical palaeolatitudes and other enigmatic features in the geological record. Opponents of the hypothesis contest the implications of the geological evidence for global glaciation and the geophysical feasibility of an ice- or slush-covered ocean[3][4] and emphasize the difficulty of escaping an all-frozen condition. A number of unanswered questions remain, including whether the Earth was a full snowball, or a "slushball" with a thin equatorial band of open (or seasonally open) water.

The snowball-Earth episodes occurred before the sudden radiation of multicellular bioforms, known as the Cambrian explosion. The most recent snowball episode may have triggered the evolution of multicellularity. Another, much earlier and longer snowball episode, the Huronian glaciation, which occurred 2400 to 2100 Mya, may have been triggered by the first appearance of oxygen in the atmosphere, the "Great Oxygenation Event".

History

Evidence for ancient glaciation mounts

Long before the idea of a global glaciation was established, a series of discoveries began to accumulate evidence for ancient Precambrian glaciations. The first of these discoveries was published in 1871 by J. Thomson who found ancient glacier-reworked material (tillite) in Islay, Scotland. Similar findings followed in Australia (1884) and India (1887). A fourth and very illustrative finding that came to be known as "Reusch's Moraine" was reported by Hans Reusch in northern Norway in 1891. Many other findings followed, but their understanding was hampered by the rejection of continental drift.[5]

Global glaciation proposed

Sir Douglas Mawson (1882–1958), an Australian geologist and Antarctic explorer, spent much of his career studying the Neoproterozoic stratigraphy of South Australia, where he identified thick and extensive glacial sediments and late in his career speculated about the possibility of global glaciation.[6]

Mawson's ideas of global glaciation, however, were based on the mistaken assumption that the geographic position of Australia, and that of other continents where low-latitude glacial deposits are found, has remained constant through time. With the advancement of the continental drift hypothesis, and eventually plate tectonic theory, came an easier explanation for the glaciogenic sediments — they were deposited at a point in time when the continents were at higher latitudes.

In 1964, the idea of global-scale glaciation reemerged when W. Brian Harland published a paper in which he presented palaeomagnetic data showing that glacial tillites in Svalbard and Greenland were deposited at tropical latitudes.[7] From this palaeomagnetic data, and the sedimentological evidence that the glacial sediments interrupt successions of rocks commonly associated with tropical to temperate latitudes, he argued for an ice age that was so extreme that it resulted in the deposition of marine glacial rocks in the tropics.

In the 1960s, Mikhail Budyko, a Russian climatologist, developed a simple energy-balance climate model to investigate the effect of ice cover on global climate. Using this model, Budyko found that if ice sheets advanced far enough out of the polar regions, a feedback loop ensued where the increased reflectiveness (albedo) of the ice led to further cooling and the formation of more ice, until the entire Earth was covered in ice and stabilized in a new ice-covered equilibrium.[8] While Budyko's model showed that this ice-albedo stability could happen, he concluded that it had in fact never happened, because his model offered no way to escape from such a feedback loop. In 1971, Aron Faegre, an American physicist, showed that a similar energy-balance model predicted three stable global climates, one of which was snowball earth.[9] This model introduced Edward Norton Lorenz's concept of intransitivity indicating that there could be a major jump from one climate to another, including to snowball earth.

The term "snowball Earth" was coined by Joseph Kirschvink in a short paper published in 1992 within a lengthy volume concerning the biology of the Proterozoic eon.[10] The major contributions from this work were: (1) the recognition that the presence of banded iron formations is consistent with such a global glacial episode, and (2) the introduction of a mechanism by which to escape from a completely ice-covered Earth — specifically, the accumulation of CO2 from volcanic outgassing leading to an ultra-greenhouse effect.

Franklyn Van Houten's discovery of a consistent geological pattern in which lake levels rose and fell is now known as the "Van Houten cycle." His studies of phosphorus deposits and banded iron formations in sedimentary rocks made him an early adherent of the "snowball Earth" hypothesis postulating that the planet's surface froze more than 650 million years ago.[11]

Interest in the notion of a snowball Earth increased dramatically after Paul F. Hoffman and his co-workers applied Kirschvink's ideas to a succession of Neoproterozoic sedimentary rocks in Namibia and elaborated upon the hypothesis in the journal Science in 1998 by incorporating such observations as the occurrence of cap carbonates.[12]

In 2010, Francis MacDonald reported evidence that Rodinia was at equatorial latitude during the Cryogenian period with glacial ice at or below sea level, and that the associated Sturtian glaciation was global.[13][14]

Evidence

The snowball Earth hypothesis was originally devised to explain geological evidence for the apparent presence of glaciers at tropical latitudes.[15] According to modelling, an ice-albedo feedback would result in glacial ice rapidly advancing to the equator once the glaciers spread to within 25°[16] to 30°[17] of the equator. Therefore, the presence of glacial deposits within the tropics suggests global ice cover.

Critical to an assessment of the validity of the theory, therefore, is an understanding of the reliability and significance of the evidence that led to the belief that ice ever reached the tropics. This evidence must prove two things:

  1. that a bed contains sedimentary structures that could have been created only by glacial activity;
  2. that the bed lay within the tropics when it was deposited.

During a period of global glaciation, it must also be demonstrated that glaciers were active at different global locations at the same time, and that no other deposits of the same age are in existence.

This last point is very difficult to prove. Before the Ediacaran, the biostratigraphic markers usually used to correlate rocks are absent; therefore there is no way to prove that rocks in different places across the globe were deposited at precisely the same time. The best that can be done is to estimate the age of the rocks using radiometric methods, which are rarely accurate to better than a million years or so.[18]

The first two points are often the source of contention on a case-to-case basis. Many glacial features can also be created by non-glacial means, and estimating the approximate latitudes of landmasses even as recently as 200 million years ago can be riddled with difficulties.[19]

Palaeomagnetism

The snowball Earth hypothesis was first posited to explain what were then considered to be glacial deposits near the equator. Since tectonic plates move slowly over time, ascertaining their position at a given point in Earth's long history is not easy. In addition to considerations of how the recognizable landmasses could have fit together, the latitude at which a rock was deposited can be constrained by palaeomagnetism.

When sedimentary rocks form, magnetic minerals within them tend to align themselves with the Earth's magnetic field. Through the precise measurement of this palaeomagnetism, it is possible to estimate the latitude (but not the longitude) where the rock matrix was formed. Palaeomagnetic measurements have indicated that some sediments of glacial origin in the Neoproterozoic rock record were deposited within 10 degrees of the equator,[20] although the accuracy of this reconstruction is in question.[18] This palaeomagnetic location of apparently glacial sediments (such as dropstones) has been taken to suggest that glaciers extended from land to sea level in tropical latitudes at the time the sediments were deposited. It is not clear whether this implies a global glaciation, or the existence of localized, possibly land-locked, glacial regimes.[21] Others have even suggested that most data do not constrain any glacial deposits to within 25° of the equator.[22]

Skeptics suggest that the palaeomagnetic data could be corrupted if Earth's ancient magnetic field was substantially different from today's. Depending on the rate of cooling of Earth's core, it is possible that during the Proterozoic, the magnetic field did not approximate a simple dipolar distribution, with north and south magnetic poles roughly aligning with the planet's axis as they do today. Instead, a hotter core may have circulated more vigorously and given rise to 4, 8 or more poles. Palaeomagnetic data would then have to be re-interpreted, as the sedimentary minerals could have aligned pointing to a 'West Pole' rather than the North Pole. Alternatively, Earth's dipolar field could have been oriented such that the poles were close to the equator. This hypothesis has been posited to explain the extraordinarily rapid motion of the magnetic poles implied by the Ediacaran palaeomagnetic record; the alleged motion of the north pole would occur around the same time as the Gaskiers glaciation.[23]

Another weakness of reliance on palaeomagnetic data is the difficulty in determining whether the magnetic signal recorded is original, or whether it has been reset by later activity. For example, a mountain-building orogeny releases hot water as a by-product of metamorphic reactions; this water can circulate to rocks thousands of kilometers away and reset their magnetic signature. This makes the authenticity of rocks older than a few million years difficult to determine without painstaking mineralogical observations.[16] Moreover, further evidence is accumulating that large-scale remagnetization events have taken place which may necessitate revision of the estimated positions of the palaeomagnetic poles.[24][25]

There is currently only one deposit, the Elatina deposit of Australia, that was indubitably deposited at low latitudes; its depositional date is well-constrained, and the signal is demonstrably original.[26]

Low-latitude glacial deposits

Diamictite of the Neoproterozoic Pocatello Formation, a "snowball Earth"–type deposit
Elatina Fm diamictite below Ediacaran GSSP site in the Flinders Ranges NP, South Australia. A$1 coin for scale.

Sedimentary rocks that are deposited by glaciers have distinctive features that enable their identification. Long before the advent of the snowball Earth hypothesis many Neoproterozoic sediments had been interpreted as having a glacial origin, including some apparently at tropical latitudes at the time of their deposition. However, it is worth remembering that many sedimentary features traditionally associated with glaciers can also be formed by other means.[27] Thus the glacial origin of many of the key occurrences for snowball Earth has been contested.[18] As of 2007, there was only one "very reliable" – still challenged[18] – datum point identifying tropical tillites,[20] which makes statements of equatorial ice cover somewhat presumptuous. However evidence of sea-level glaciation in the tropics during the Sturtian is accumulating.[28] Evidence of possible glacial origin of sediment includes:

Open-water deposits

It appears that some deposits formed during the snowball period could only have formed in the presence of an active hydrological cycle. Bands of glacial deposits up to 5,500 meters thick, separated by small (meters) bands of non-glacial sediments, demonstrate that glaciers melted and re-formed repeatedly for tens of millions of years; solid oceans would not permit this scale of deposition.[32] It is considered possible that ice streams such as seen in Antarctica today could have caused these sequences. Further, sedimentary features that could only form in open water (for example: wave-formed ripples, far-traveled ice-rafted debris and indicators of photosynthetic activity) can be found throughout sediments dating from the snowball-Earth periods. While these may represent "oases" of meltwater on a completely frozen Earth,[33] computer modelling suggests that large areas of the ocean must have remained ice-free; arguing that a "hard" snowball is not plausible in terms of energy balance and general circulation models.[34]

Carbon isotope ratios

There are two stable isotopes of carbon in sea water: carbon-12 (12C) and the rare carbon-13 (13C), which makes up about 1.109 percent of carbon atoms.

Biochemical processes, of which photosynthesis is one, tend to preferentially incorporate the lighter 12C isotope. Thus ocean-dwelling photosynthesizers, both protists and algae, tend to be very slightly depleted in 13C, relative to the abundance found in the primary volcanic sources of Earth's carbon. Therefore, an ocean with photosynthetic life will have a lower 13C/12C ratio within organic remains, and a higher ratio in corresponding ocean water. The organic component of the lithified sediments will forever remain very slightly, but measurably, depleted in 13C.

During the proposed episode of snowball Earth, there are rapid and extreme negative excursions in the ratio of 13C to 12C.[35] This is consistent with a deep freeze that killed off most or nearly all photosynthetic life – although other mechanisms, such as clathrate release, can also cause such perturbations. Close analysis of the timing of 13C 'spikes' in deposits across the globe allows the recognition of four, possibly five, glacial events in the late Neoproterozoic.[36]

Banded iron formations

2.1 billion-year-old rock with black-band ironstone

Banded iron formations (BIF) are sedimentary rocks of layered iron oxide and iron-poor chert. In the presence of oxygen, iron naturally rusts and becomes insoluble in water. The banded iron formations are commonly very old and their deposition is often related to the oxidation of the Earth's atmosphere during the Palaeoproterozoic era, when dissolved iron in the ocean came in contact with photosynthetically produced oxygen and precipitated out as iron oxide.

The bands were produced at the tipping point between an anoxic and an oxygenated ocean. Since today's atmosphere is oxygen-rich (nearly 21% by volume) and in contact with the oceans, it is not possible to accumulate enough iron oxide to deposit a banded formation. The only extensive iron formations that were deposited after the Palaeoproterozoic (after 1.8 billion years ago) are associated with Cryogenian glacial deposits.

For such iron-rich rocks to be deposited there would have to be anoxia in the ocean, so that much dissolved iron (as ferrous oxide) could accumulate before it met an oxidant that would precipitate it as ferric oxide. For the ocean to become anoxic it must have limited gas exchange with the oxygenated atmosphere. Proponents of the hypothesis argue that the reappearance of BIF in the sedimentary record is a result of limited oxygen levels in an ocean sealed by sea-ice,[10] while opponents suggest that the rarity of the BIF deposits may indicate that they formed in inland seas.

Being isolated from the oceans, such lakes could have been stagnant and anoxic at depth, much like today's Black Sea; a sufficient input of iron could provide the necessary conditions for BIF formation.[18] A further difficulty in suggesting that BIFs marked the end of the glaciation is that they are found interbedded with glacial sediments.[21] BIFs are also strikingly absent during the Marinoan glaciation.

Cap carbonate rocks

A present-day glacier
Volcanoes may have had a role in replenishing CO2, possibly ending the global ice age that was the snowball Earth during the Cryogenian Period.

Around the top of Neoproterozoic glacial deposits there is commonly a sharp transition into a chemically precipitated sedimentary limestone or dolostone metres to tens of metres thick.[37] These cap carbonates sometimes occur in sedimentary successions that have no other carbonate rocks, suggesting that their deposition is result of a profound aberration in ocean chemistry.[38]

These cap carbonates have unusual chemical composition, as well as strange sedimentary structures that are often interpreted as large ripples.[39] The formation of such sedimentary rocks could be caused by a large influx of positively charged ions, as would be produced by rapid weathering during the extreme greenhouse following a snowball Earth event. The δ13C isotopic signature of the cap carbonates is near −5 ‰, consistent with the value of the mantle — such a low value is usually/could be taken to signify an absence of life, since photosynthesis usually acts to raise the value; alternatively the release of methane deposits could have lowered it from a higher value, and counterbalance the effects of photosynthesis.

The precise mechanism involved in the formation of cap carbonates is not clear, but the most cited explanation suggests that at the melting of a snowball Earth, water would dissolve the abundant CO2 from the atmosphere to form carbonic acid, which would fall as acid rain. This would weather exposed silicate and carbonate rock (including readily attacked glacial debris), releasing large amounts of calcium, which when washed into the ocean would form distinctively textured layers of carbonate sedimentary rock. Such an abiotic "cap carbonate" sediment can be found on top of the glacial till that gave rise to the snowball Earth hypothesis.

However, there are some problems with the designation of a glacial origin to cap carbonates. Firstly, the high carbon dioxide concentration in the atmosphere would cause the oceans to become acidic, and dissolve any carbonates contained within — starkly at odds with the deposition of cap carbonates. Further, the thickness of some cap carbonates is far above what could reasonably be produced in the relatively quick deglaciations. The cause is further weakened by the lack of cap carbonates above many sequences of clear glacial origin at a similar time and the occurrence of similar carbonates within the sequences of proposed glacial origin.[18] An alternative mechanism, which may have produced the Doushantuo cap carbonate at least, is the rapid, widespread release of methane. This accounts for incredibly low — as low as −48 ‰ — δ13C values — as well as unusual sedimentary features which appear to have been formed by the flow of gas through the sediments.[40]

Changing acidity

Isotopes of the element boron suggest that the pH of the oceans dropped dramatically before and after the Marinoan glaciation.[41] This may indicate a buildup of carbon dioxide in the atmosphere, some of which would dissolve into the oceans to form carbonic acid. Although the boron variations may be evidence of extreme climate change, they need not imply a global glaciation.

Space dust

Earth's surface is very depleted in the element iridium, which primarily resides in the Earth's core. The only significant source of the element at the surface is cosmic particles that reach Earth. During a snowball Earth, iridium would accumulate on the ice sheets, and when the ice melted the resulting layer of sediment would be rich in iridium. An iridium anomaly has been discovered at the base of the cap carbonate formations, and has been used to suggest that the glacial episode lasted for at least 3 million years,[42] but this does not necessarily imply a global extent to the glaciation; indeed, a similar anomaly could be explained by the impact of a large meteorite.[43]

Cyclic climate fluctuations

Using the ratio of mobile cations to those that remain in soils during chemical weathering (the chemical index of alteration), it has been shown that chemical weathering varied in a cyclic fashion within a glacial succession, increasing during interglacial periods and decreasing during cold and arid glacial periods.[44] This pattern, if a true reflection of events, suggests that the "snowball Earths" bore a stronger resemblance to Pleistocene ice age cycles than to a completely frozen Earth.

In addition, glacial sediments of the Port Askaig Tillite Formation in Scotland clearly show interbedded cycles of glacial and shallow marine sediments.[45] The significance of these deposits is highly reliant upon their dating. Glacial sediments are difficult to date, and the closest dated bed to the Portaskaig group is 8 km stratigraphically above the beds of interest. Its dating to 600 Ma means the beds can be tentatively correlated to the Sturtian glaciation, but they may represent the advance or retreat of a snowball Earth.

Mechanisms

One computer simulation of conditions during a snowball Earth period[46]

The initiation of a snowball Earth event would involve some initial cooling mechanism, which would result in an increase in Earth's coverage of snow and ice. The increase in Earth's coverage of snow and ice would in turn increase Earth's albedo, which would result in positive feedback for cooling. If enough snow and ice accumulates, run-away cooling would result. This positive feedback is facilitated by an equatorial continental distribution, which would allow ice to accumulate in the regions closer to the equator, where solar radiation is most direct.

Many possible triggering mechanisms could account for the beginning of a snowball Earth, such as the eruption of a supervolcano, a reduction in the atmospheric concentration of greenhouse gases such as methane and/or carbon dioxide, changes in Solar energy output, or perturbations of Earth's orbit. Regardless of the trigger, initial cooling results in an increase in the area of Earth's surface covered by ice and snow, and the additional ice and snow reflects more Solar energy back to space, further cooling Earth and further increasing the area of Earth's surface covered by ice and snow. This positive feedback loop could eventually produce a frozen equator as cold as modern Antarctica.

Global warming associated with large accumulations of carbon dioxide in the atmosphere over millions of years, emitted primarily by volcanic activity, is the proposed trigger for melting a snowball Earth. Due to positive feedback for melting, the eventual melting of the snow and ice covering most of Earth's surface would require as little as a millennium.

Continental distribution

A tropical distribution of the continents is, perhaps counter-intuitively, necessary to allow the initiation of a snowball Earth.[47] Firstly, tropical continents are more reflective than open ocean, and so absorb less of the Sun's heat: most absorption of Solar energy on Earth today occurs in tropical oceans.[48]

Further, tropical continents are subject to more rainfall, which leads to increased river discharge — and erosion. When exposed to air, silicate rocks undergo weathering reactions which remove carbon dioxide from the atmosphere. These reactions proceed in the general form: Rock-forming mineral + CO2 + H2O → cations + bicarbonate + SiO2. An example of such a reaction is the weathering of wollastonite:

CaSiO3 + 2CO2 + H2O → Ca2+ + SiO2 + 2HCO3

The released calcium cations react with the dissolved bicarbonate in the ocean to form calcium carbonate as a chemically precipitated sedimentary rock. This transfers carbon dioxide, a greenhouse gas, from the air into the geosphere, and, in steady-state on geologic time scales, offsets the carbon dioxide emitted from volcanoes into the atmosphere.

A paucity of suitable sediments for analysis makes precise continental distribution during the Neoproterozoic difficult to establish.[49] Some reconstructions point towards polar continents — which have been a feature of all other major glaciations, providing a point upon which ice can nucleate. Changes in ocean circulation patterns may then have provided the trigger of snowball Earth.[50]

Additional factors that may have contributed to the onset of the Neoproterozoic snowball include the introduction of atmospheric free oxygen, which may have reached sufficient quantities to react with methane in the atmosphere, oxidizing it to carbon dioxide, a much weaker greenhouse gas,[51] and a younger — thus fainter — Sun, which would have emitted 6 percent less radiation in the Neoproterozoic.[18]

Normally, as Earth gets colder due to natural climatic fluctuations and changes in incoming solar radiation, the cooling slows these weathering reactions. As a result, less carbon dioxide is removed from the atmosphere and Earth warms as this greenhouse gas accumulates — this 'negative feedback' process limits the magnitude of cooling. During the Cryogenian period, however, Earth's continents were all at tropical latitudes, which made this moderating process less effective, as high weathering rates continued on land even as Earth cooled. This let ice advance beyond the polar regions. Once ice advanced to within 30° of the equator,[52] a positive feedback could ensue such that the increased reflectiveness (albedo) of the ice led to further cooling and the formation of more ice, until the whole Earth is ice-covered.

Polar continents, due to low rates of evaporation, are too dry to allow substantial carbon deposition — restricting the amount of atmospheric carbon dioxide that can be removed from the carbon cycle. A gradual rise of the proportion of the isotope carbon-13 relative to carbon-12 in sediments pre-dating "global" glaciation indicates that CO2 draw-down before snowball Earths was a slow and continuous process.[53]

The start of snowball Earths are always marked by a sharp downturn in the δ13C value of sediments,[54] a hallmark that may be attributed to a crash in biological productivity as a result of the cold temperatures and ice-covered oceans.

In January 2016, Gernon et al. proposed a "shallow-ridge hypothesis" involving the breakup of the supercontinent Rodinia, linking the eruption and rapid alteration of hyaloclastites along shallow ridges to massive increases in alkalinity in an ocean with thick ice cover. Gernon et al. demonstrated that the increase in alkalinity over the course of glaciation is sufficient to explain the thickness of cap carbonates formed in the aftermath of Snowball Earth events. [55]

During the frozen period

Global ice sheets may have created the bottleneck required for the evolution of multicellular life.[3]

Global temperature fell so low that the equator was as cold as modern-day Antarctica.[56] This low temperature was maintained by the high albedo of the ice sheets, which reflected most incoming solar energy into space. A lack of heat-retaining clouds, caused by water vapor freezing out of the atmosphere, amplified this effect.

Breaking out of global glaciation

The carbon dioxide levels necessary to unfreeze Earth have been estimated as being 350 times what they are today, about 13% of the atmosphere.[57] Since the Earth was almost completely covered with ice, carbon dioxide could not be withdrawn from the atmosphere by release of alkaline metal ions weathering out of siliceous rocks. Over 4 to 30 million years, enough CO2 and methane, mainly emitted by volcanoes but also produced by microbes converting organic carbon trapped under the ice into the gas,[58] would accumulate to finally cause enough greenhouse effect to make surface ice melt in the tropics until a band of permanently ice-free land and water developed;[59] this would be darker than the ice, and thus absorb more energy from the Sun — initiating a "positive feedback".

Destabilization of substantial deposits of methane hydrates locked up in low-latitude permafrost may also have acted as a trigger and/or strong positive feedback for deglaciation and warming.[60]

On the continents, the melting of glaciers would release massive amounts of glacial deposit, which would erode and weather. The resulting sediments supplied to the ocean would be high in nutrients such as phosphorus, which combined with the abundance of CO2 would trigger a cyanobacteria population explosion, which would cause a relatively rapid reoxygenation of the atmosphere, which may have contributed to the rise of the Ediacaran biota and the subsequent Cambrian explosion — a higher oxygen concentration allowing large multicellular lifeforms to develop. Although the positive feedback loop would melt the ice in geological short order, perhaps less than 1,000 years, replenishment of atmospheric oxygen and depletion of the CO2 levels would take further millennia.

It is possible that carbon dioxide levels fell enough for Earth to freeze again; this cycle may have repeated until the continents had drifted to more polar latitudes.[61]

More recent evidence suggests that with colder oceanic temperatures, the resulting higher ability of the oceans to dissolve gases led to the carbon content of sea water being more quickly oxidized to carbon dioxide. This leads directly to an increase of atmospheric carbon dioxide, enhanced greenhouse warming of Earth's surface, and the prevention of a total snowball state.[62]

During millions of years, cryoconite would have accumulated on and inside the ice. Psychrophilic microorganisms, volcanic ash and dust from ice-free locations would settle on ice covering several million km2. Once the ice started to melt, these layers would become visible and coloring the icy surfaces dark, helping to accelerate the process.[63]

Ultraviolet light from the Sun would also produce hydrogen peroxide (H2O2) when it hits water molecules. Normally hydrogen peroxide is broken down by sunlight, but some would have been trapped inside the ice. When the glaciers started to melt, it would have been released in both the ocean and the atmosphere, where it was split into water and oxygen molecules, leading to an increase in atmospheric oxygen.[64]

Slushball Earth hypothesis

While the presence of glaciers is not disputed, the idea that the entire planet was covered in ice is more contentious, leading some scientists to posit a "slushball Earth", in which a band of ice-free, or ice-thin, waters remains around the equator, allowing for a continued hydrologic cycle.

This hypothesis appeals to scientists who observe certain features of the sedimentary record that can only be formed under open water, or rapidly moving ice (which would require somewhere ice-free to move to). Recent research observed geochemical cyclicity in clastic rocks, showing that the "snowball" periods were punctuated by warm spells, similar to ice age cycles in recent Earth history. Attempts to construct computer models of a snowball Earth have also struggled to accommodate global ice cover without fundamental changes in the laws and constants which govern the planet.

A less extreme snowball Earth hypothesis involves continually evolving continental configurations and changes in ocean circulation.[65] Synthesised evidence has produced models indicating a "slushball Earth",[66] where the stratigraphic record does not permit postulating complete global glaciations.[65] Kirschivink's original hypothesis[10] had recognised that warm tropical puddles would be expected to exist in a snowball earth.

The snowball Earth hypothesis does not explain the alternation of glacial and interglacial events, nor the oscillation of glacial sheet margins.[67]

Scientific dispute

The argument against the hypothesis is evidence of fluctuation in ice cover and melting during "snowball Earth" deposits. Evidence for such melting comes from evidence of glacial dropstones,[32] geochemical evidence of climate cyclicity,[44] and interbedded glacial and shallow marine sediments.[45] A longer record from Oman, constrained to 13°N, covers the period from 712 to 545 million years ago — a time span containing the Sturtian and Marinoan glaciations — and shows both glacial and ice-free deposition.[68]

There have been difficulties in recreating a snowball Earth with global climate models. Simple GCMs with mixed-layer oceans can be made to freeze to the equator; a more sophisticated model with a full dynamic ocean (though only a primitive sea ice model) failed to form sea ice to the equator.[69] In addition, the levels of CO2 necessary to melt a global ice cover have been calculated to be 130,000 ppm,[57] which is considered by some to be unreasonably large.

Strontium isotopic data have been found to be at odds with proposed snowball Earth models of silicate weathering shutdown during glaciation and rapid rates immediately post-glaciation. Therefore, methane release from permafrost during marine transgression was proposed to be the source of the large measured carbon excursion in the time immediately after glaciation.[70]

"Zipper rift" hypothesis

Nick Eyles suggest that the Neoproterozoic Snowball Earth was in fact no different from any other glaciation in Earth's history, and that efforts to find a single cause are likely to end in failure.[18] The "Zipper rift" hypothesis proposes two pulses of continental "unzipping" — first, the breakup of the supercontinent Rodinia, forming the proto-Pacific Ocean; then the splitting of the continent Baltica from Laurentia, forming the proto-Atlantic — coincided with the glaciated periods. The associated tectonic uplift would form high plateaus, just as the East African Rift is responsible for high topography; this high ground could then host glaciers.

Banded iron formations have been taken as unavoidable evidence for global ice cover, since they require dissolved iron ions and anoxic waters to form; however, the limited extent of the Neoproterozoic banded iron deposits means that they may not have formed in frozen oceans, but instead in inland seas. Such seas can experience a wide range of chemistries; high rates of evaporation could concentrate iron ions, and a periodic lack of circulation could allow anoxic bottom water to form.

Continental rifting, with associated subsidence, tends to produce such landlocked water bodies. This rifting, and associated subsidence, would produce the space for the fast deposition of sediments, negating the need for an immense and rapid melting to raise the global sea levels.

High-obliquity hypothesis

A competing hypothesis to explain the presence of ice on the equatorial continents was that Earth's axial tilt was quite high, in the vicinity of 60°, which would place Earth's land in high "latitudes", although supporting evidence is scarce.[71] A less extreme possibility would be that it was merely Earth's magnetic pole that wandered to this inclination, as the magnetic readings which suggested ice-filled continents depends on the magnetic and rotational poles being relatively similar. In either of these two situations, the freeze would be limited to relatively small areas, as is the case today; severe changes to Earth's climate are not necessary.

Inertial interchange true polar wander

The evidence for low-latitude glacial deposits during the supposed snowball Earth episodes has been reinterpreted via the concept of inertial interchange true polar wander (IITPW).[72][73] This hypothesis, created to explain palaeomagnetic data, suggests that Earth's axis of rotation shifted one or more times during the general time-frame attributed to snowball Earth. This could feasibly produce the same distribution of glacial deposits without requiring any of them to have been deposited at equatorial latitude.[74] While the physics behind the proposition is sound, the removal of one flawed data point from the original study rendered the application of the concept in these circumstances unwarranted.[75]

Several alternative explanations for the evidence have been proposed.

Survival of life through frozen periods

A black smoker, a type of hydrothermal vent

A tremendous glaciation would curtail photosynthetic life on Earth, thus depleting atmospheric oxygen, and thereby allowing non-oxidized iron-rich rocks to form.

Detractors argue that this kind of glaciation would have made life extinct entirely. However, microfossils such as stromatolites and oncolites prove that, in shallow marine environments at least, life did not suffer any perturbation. Instead life developed a trophic complexity and survived the cold period unscathed.[76] Proponents counter that it may have been possible for life to survive in these ways:

However, organisms and ecosystems, as far as it can be determined by the fossil record, do not appear to have undergone the significant change that would be expected by a mass extinction. With the advent of more precise dating, a phytoplankton extinction event which had been associated with snowball Earth was shown to precede glaciations by 16 million years.[80] Even if life were to cling on in all the ecological refuges listed above, a whole-Earth glaciation would result in a biota with a noticeably different diversity and composition. This change in diversity and composition has not yet been observed[81]– in fact, the organisms which should be most susceptible to climatic variation emerge unscathed from the snowball Earth.[43]

Implications

A snowball Earth has profound implications in the history of life on Earth. While many refugia have been postulated, global ice cover would certainly have ravaged ecosystems dependent on sunlight. Geochemical evidence from rocks associated with low-latitude glacial deposits have been interpreted to show a crash in oceanic life during the glacials.

The melting of the ice may have presented many new opportunities for diversification, and may indeed have driven the rapid evolution which took place at the end of the Cryogenian period.

Effect on early evolution

Dickinsonia costata, an Ediacaran organism of unknown affinity, with a quilted appearance

The Neoproterozoic was a time of remarkable diversification of multicellular organisms, including animals. Organism size and complexity increased considerably after the end of the snowball glaciations. This development of multicellular organisms may have been the result of increased evolutionary pressures resulting from multiple icehouse-hothouse cycles; in this sense, snowball Earth episodes may have "pumped" evolution. Alternatively, fluctuating nutrient levels and rising oxygen may have played a part. Interestingly, another major glacial episode may have ended just a few million years before the Cambrian explosion.

Mechanistically, the effect of snowball Earth (in particular the later glaciations) on complex life is likely to have occurred through the process of kin selection. Organ-scale differentiation, in particular the terminal (irreversible) differentiation present in animals, requires the individual cell (and the genes contained within it) to "sacrifice" their ability to reproduce, so that the colony is not disrupted. From the short-term perspective of the gene, more offspring will be gained by causing the cell in which it is contained to ignore any signals received from the colony, and to reproduce at the maximum rate, regardless of the implications for the wider group. Today, this incentive explains the formation of tumours in animals and plants.

It has been argued[82] that because snowball Earth would undoubtedly have decimated the population size of any given species, the extremely small populations that resulted would all have been descended from a small number of individuals (see founder effect), and consequently the average relatedness between any two individuals (in this case individual cells) would have been exceptionally high as a result of glaciations. Altruism is known to increase from rarity when relatedness (R) exceeds the ratio of the cost (C) to the altruist (in this case, the cell giving up its own reproduction by differentiating), to the benefit (B) to the recipient of altruism (the germ line of the colony, that reproduces as a result of the differentiation), i.e. R > C/B (see Hamilton's rule). The evolutionary pressure of the high relatedness in the context of a post-glaciation population boom may have been sufficient to overcome the reproductive cost of forming a complex animal, for the first time in Earth's history.

There is also a rival hypothesis which has been gaining currency in recent years: that early snowball Earths did not so much affect the evolution of life on Earth as result from it. In fact the two hypotheses are not mutually exclusive. The idea is that Earth's life forms affect the global carbon cycle and so major evolutionary events alter the carbon cycle, redistributing carbon within various reservoirs within the biosphere system and in the process temporarily lowering the atmospheric (greenhouse) carbon reservoir until the revised biosphere system settled into a new state. The Snowball I episode (of the Huronian glaciation 2.4 to 2.1 billion years) and Snowball II (of the Precambrian's Cryogenian between 580 – 850 million years and which itself had a number of distinct episodes) are respectively thought to be caused by the evolution of oxygenic photosynthesis and then the rise of more advanced multicellular animal life and life's colonization of the land.[83][84]

Effects on ocean circulation

Global ice cover, if it existed, may – in concert with geothermal heating – have led to a lively, well mixed ocean with great vertical convective circulation.[85]

Occurrence and timing of snowball Earths

Neoproterozoic

There are three or four significant ice ages during the late Neoproterozoic. Of these, the Marinoan was the most significant, and the Sturtian glaciations were also truly widespread.[86] Even the leading snowball proponent Hoffman agrees that the 350 thousand-year-long[1] Gaskiers glaciation did not lead to global glaciation,[47] although it was probably as intense as the late Ordovician glaciation. The status of the Kaigas "glaciation" or "cooling event" is currently unclear; some workers do not recognise it as a glacial, others suspect that it may reflect poorly dated strata of Sturtian association, and others believe it may indeed be a third ice age.[87] It was certainly less significant than the Sturtian or Marinoan glaciations, and probably not global in extent. Emerging evidence suggests that the Earth underwent a number of glaciations during the Neoproterozoic, which would stand strongly at odds with the snowball hypothesis.[4]

Palaeoproterozoic

The snowball Earth hypothesis has been invoked to explain glacial deposits in the Huronian Supergroup of Canada, though the palaeomagnetic evidence that suggests ice sheets at low latitudes is contested.[88][89] The glacial sediments of the Makganyene formation of South Africa are slightly younger than the Huronian glacial deposits (~2.25 billion years old) and were deposited at tropical latitudes.[90] It has been proposed that rise of free oxygen that occurred during the Great Oxygenation Event removed methane in the atmosphere through oxidation. As the Sun was notably weaker at the time, Earth's climate may have relied on methane, a powerful greenhouse gas, to maintain surface temperatures above freezing.

In the absence of this methane greenhouse, temperatures plunged and a snowball event could have occurred.[89]

Karoo Ice Age

Before the theory of continental drift, glacial deposits in Carboniferous strata in tropical continents areas such as India and South America led to speculation that the Karoo Ice Age glaciation reached into the tropics. However, a continental reconstruction shows that ice was in fact constrained to the polar parts of the supercontinent Gondwana.

See also

References

  1. 1 2 3 4 Pu, J.P. (2016). "Dodging snowballs: Geochronology of the Gaskiers glaciation and the first appearance of the Ediacaran biota". Geology. Geological Society of America. 44 (11): 955. doi:10.1130/G38284.1.
  2. Smith, A. G. (2009). "Neoproterozoic timescales and stratigraphy". Geological Society, London, Special Publications. 326: 27–54. Bibcode:2009GSLSP.326...27S. doi:10.1144/SP326.2.
  3. 1 2 Kirschvink, J. L. (1992). "Late Proterozoic low-latitude global glaciation: The snowball Earth". In Schopf, J. W.; Klein, C. The Proterozoic Biosphere: A Multidisciplinary Study (PDF). Cambridge University Press. pp. 51–2.
  4. 1 2 Allen, Philip A.; Etienne, James L. (2008). "Sedimentary challenge to Snowball Earth". Nature Geoscience. 1 (12): 817–825. Bibcode:2008NatGe...1..817A. doi:10.1038/ngeo355.
  5. Hoffman, Paul F. (2011). "A history of Neoproterozoic glacial geology, 1871– 1997". In Arnaud, E.; Halverson, G.P.; Shields-Zhou, G. The Geological Record of Neoproterozoic Glaciations. Geological Society, London, Memoirs. Geological Society of London. pp. 17–37.
  6. Alderman, A. R.; Tilley, C. E. (1960). "Douglas Mawson 1882-1958". Biographical Memoirs of Fellows of the Royal Society. 5: 119–127. doi:10.1098/rsbm.1960.0011.
  7. W. B. Harland (1964). "Critical evidence for a great infra-Cambrian glaciation". International Journal of Earth Sciences. 54 (1): 45–61. Bibcode:1964GeoRu..54...45H. doi:10.1007/BF01821169.
  8. M.I. Budyko (1969). "Effect of solar radiation variation on climate of Earth". Tellus A. 21 (5): 611–1969. doi:10.1111/j.2153-3490.1969.tb00466.x.
  9. A. Faegre (1972). "An Intransitive Model of the Earth-Atmosphere-Ocean System". Journal of Applied Meteorology. 11 (1): 4–6. doi:10.1175/1520-0450(1972)011<0004:aimote>2.0.co;2.
  10. 1 2 3 Kirschvink, Joseph (1992). "Late Proterozoic low-latitude global glaciation: the Snowball Earth". In J. W. Schopf; C. Klein. The Proterozoic Biosphere: A Multidisciplinary Study. Cambridge University Press.
  11. Princeton University - Franklyn Van Houten, expert on sedimentary rocks, dies at 96
  12. Hoffman, P. F.; Kaufman, A. J.; Halverson, G. P.; Schrag, D. P. (1998). "A Neoproterozoic Snowball Earth" (PDF). Science. 281 (5381): 1342–1346. Bibcode:1998Sci...281.1342H. PMID 9721097. doi:10.1126/science.281.5381.1342.
  13. MacDonald, Francis, Calibrating the Cryogenian, Science, 5 March 2010: Vol. 327 no. 5970 pp. 1241-1243 5 March 2010 Abstract
  14. Snowball Earth: New Evidence Hints at Global Glaciation 716.5 Million Years Ago
  15. Harland, W.B. (1964). "Critical evidence for a great infra-Cambrian glaciation" (PDF). International Journal of Earth Sciences. 54 (1): 45–61. Bibcode:1964GeoRu..54...45H. doi:10.1007/BF01821169. Retrieved 11 March 2008.
  16. 1 2 Meert, J.G.; Van Der Voo, R.; Payne, T.W. (1994). "Paleomagnetism of the Catoctin volcanic province: A new Vendian-Cambrian apparent polar wander path for North America". Journal of Geophysical Research. 99 (B3): 4625–41. Bibcode:1994JGR....99.4625M. doi:10.1029/93JB01723. Retrieved 11 March 2008.
  17. Budyko, M.I. (1969). "The effect of solar radiation variations on the climate of the earth". Tellus. 21 (5): 611–9. doi:10.1111/j.2153-3490.1969.tb00466.x.
  18. 1 2 3 4 5 6 7 8 9 Eyles, N.; Januszczak, N. (2004). "'Zipper-rift': A tectonic model for Neoproterozoic glaciations during the breakup of Rodinia after 750 Ma" (PDF). Earth-Science Reviews. 65 (1–2): 1–73. Bibcode:2004ESRv...65....1E. doi:10.1016/S0012-8252(03)00080-1. Retrieved 4 May 2007.
  19. Briden, J.C.; Smith, A.G.; Sallomy, J.T. (1971). "The geomagnetic field in Permo-Triassic time". Geophys. J. R. Astron. Soc. 23: 101–117. doi:10.1111/j.1365-246X.1971.tb01805.x.
  20. 1 2 D.A.D. Evans (2000). "Stratigraphic, geochronological, and palaeomagnetic constraints upon the Neoproterozoic climatic paradox". American Journal of Science. 300 (5): 347–433. doi:10.2475/ajs.300.5.347.
  21. 1 2 Young, G.M. (1 February 1995). "Are Neoproterozoic glacial deposits preserved on the margins of Laurentia related to the fragmentation of two supercontinents?". Geology. 23 (2): 153–6. Bibcode:1995Geo....23..153Y. doi:10.1130/0091-7613(1995)023<0153:ANGDPO>2.3.CO;2. Retrieved 27 April 2007.
  22. Meert, J. G.; Van Der Voo, R. (1994). "The Neoproterozoic (1000–540 Ma) glacial intervals: No more snowball earth?". Earth and Planetary Science Letters. 123: 1–13. Bibcode:1994E&PSL.123....1M. doi:10.1016/0012-821X(94)90253-4.
  23. Abrajevitch, A.; Van Der Voo, R. (2010). "Incompatible Ediacaran paleomagnetic directions suggest an equatorial geomagnetic dipole hypothesis". Earth and Planetary Science Letters. 293 (1–2): 164–170. Bibcode:2010E&PSL.293..164A. doi:10.1016/j.epsl.2010.02.038.
  24. Font, E; C.F. Ponte Neto; M. Ernesto (2011). "Paleomagnetism and rock magnetism of the Neoproterozoic Itajaí Basin of the Rio de la Plata craton (Brazil): Cambrian to Cretaceous widespread remagnetizations of South America". Gondwana Research. 20 (4): 782–797. doi:10.1016/j.gr.2011.04.005. Retrieved 6 May 2011.
  25. Rowan, C. J.; Tait, J. (2010). "Oman's low latitude "Snowball Earth" pole revisited: Late Cretaceous remagnetisation of Late Neoproterozoic carbonates in Northern Oman". American Geophysical Union, Fall Meeting 2010: #GP33C–09590959. Bibcode:2010AGUFMGP33C0959R.
  26. Sohl, L.E.; Christie-blick, N.; Kent, D.V. (1999). "Paleomagnetic polarity reversals in Marinoan (ca. 600 Ma) glacial deposits of Australia; implications for the duration of low-latitude glaciation in Neoproterozoic time". Bulletin of the Geological Society of America. 111 (8): 1120–39. Bibcode:1999GSAB..111.1120S. doi:10.1130/0016-7606(1999)111<1120:PPRIMC>2.3.CO;2. Retrieved 11 March 2008.
  27. Arnaud, E.; Eyles, C. H. (2002). "Glacial influence on Neoproterozoic sedimentation: the Smalfjord Formation, northern Norway". Sedimentology. 49 (4): 765–88. doi:10.1046/j.1365-3091.2002.00466.x.
  28. MacDonald, F. A.; Schmitz, M. D.; Crowley, J. L.; Roots, C. F.; Jones, D. S.; Maloof, A. C.; Strauss, J. V.; Cohen, P. A.; Johnston, D. T.; Schrag, D. P. (2010). "Calibrating the Cryogenian". Science. 327 (5970): 1241–1243. Bibcode:2010Sci...327.1241M. PMID 20203045. doi:10.1126/science.1183325. Lay summary.
  29. Donovan, S. K.; Pickerill, R. K. (1997). "Dropstones: their origin and significance: a comment". Palaeogeography, Palaeoclimatology, Palaeoecology. 131 (1): 175–8. doi:10.1016/S0031-0182(96)00150-2.
  30. Thunell, R. C.; Tappa, E.; Anderson, D. M. (1 December 1995). "Sediment fluxes and varve formation in Santa Barbara Basin, offshore California". Geology. 23 (12): 1083–6. Bibcode:1995Geo....23.1083T. doi:10.1130/0091-7613(1995)023<1083:SFAVFI>2.3.CO;2. Retrieved 27 April 2007.
  31. Jensen, P. A.; Wulff-pedersen, E. (1 March 1996). "Glacial or non-glacial origin for the Bigganjargga tillite, Finnmark, Northern Norway". Geological Magazine. 133 (2): 137–45. doi:10.1017/S0016756800008657. Retrieved 27 April 2007.
  32. 1 2 Condon, D.J.; Prave, A.R.; Benn, D.I. (1 January 2002). "Neoproterozoic glacial-rainout intervals: Observations and implications". Geology. 30 (1): 35–38. Bibcode:2002Geo....30...35C. doi:10.1130/0091-7613(2002)030<0035:NGRIOA>2.0.CO;2. Retrieved 4 May 2007.
  33. Halverson, G.P.; Maloof, A.C.; Hoffman, P.F. (2004). "The Marinoan glaciation (Neoproterozoic) in northeast Svalbard" (PDF). Basin Research. 16 (3): 297–324. doi:10.1111/j.1365-2117.2004.00234.x. Retrieved 5 May 2007.
  34. Peltier, W.R. (2004). "Climate dynamics in deep time: modeling the "snowball bifurcation" and assessing the plausibility of its occurrence". In Jenkins, G.S.; McMenamin, M.A.S.; McKey, C.P.; Sohl, L. The Extreme Proterozoic: Geology, Geochemistry, and Climate. American Geophysical union. pp. 107–124.
  35. D.H. Rothman; J.M. Hayes; R.E. Summons (2003). "Dynamics of the Neoproterozoic carbon cycle". Proc. Natl. Acad. Sci. U.S.A. 100 (14): 124–9. Bibcode:2003PNAS..100.8124R. PMC 166193Freely accessible. PMID 12824461. doi:10.1073/pnas.0832439100.
  36. Kaufman, Alan J.; Knoll, Andrew H.; Narbonne, Guy M. (24 June 1997). "Isotopes, ice ages, and terminal Proterozoic earth history". Proc. Natl. Acad. Sci. U.S.A. 94 (13): 6600–5. Bibcode:1997PNAS...94.6600K. PMC 21204Freely accessible. PMID 11038552. doi:10.1073/pnas.94.13.6600. Retrieved 6 May 2007.
  37. M.J. Kennedy (1996). "Stratigraphy, sedimentology, and isotopic geochemistry of Australian Neoproterozoic postglacial camp dolostones: deglaciation, d13C excursions and carbonate precipitation". Journal of Sedimentary Research. 66 (6): 1050–64. Bibcode:1996JSedR..66.1050K. doi:10.2110/jsr.66.1050.
  38. Spencer, A.M. (1971). "Late Pre-Cambrian glaciation in Scotland". Mem. Geol. Soc. Lond. 6.
  39. P. F. Hoffman; D. P. Schrag (2002). "The snowball Earth hypothesis: testing the limits of global change" (PDF 1.3 Mb). Terra Nova. 14 (3): 129–55. doi:10.1046/j.1365-3121.2002.00408.x.
  40. Wang, Jiasheng; Jiang, Ganqing; Xiao, Shuhai; Li, Qing; Wei, Qing (2008). "Carbon isotope evidence for widespread methane seeps in the ca. 635 Ma Doushantuo cap carbonate in south China" (PDF). Geology. 36 (5): 347. doi:10.1130/G24513A.1.
  41. δ11B, in Kasemann, S.A.; Hawkesworth, C.J.; Prave, A.R.; Fallick, A.E.; Pearson, P.N. (2005). "Boron and calcium isotope composition in Neoproterozoic carbonate rocks from Namibia: evidence for extreme environmental change". Earth and Planetary Science Letters. 231 (1–2): 73–86. Bibcode:2005E&PSL.231...73K. doi:10.1016/j.epsl.2004.12.006. Retrieved 4 May 2007.
  42. Bodiselitsch, Bernd.; Koeberl, C.; Master, S.; Reimold, W.U. (8 April 2005). "Estimating Duration and Intensity of Neoproterozoic Snowball Glaciations from Ir Anomalies". Science. 308 (5719): 239–42. Bibcode:2005Sci...308..239B. PMID 15821088. doi:10.1126/science.1104657. Retrieved 4 May 2007.
  43. 1 2 Grey, K.; Walter, M.R.; Calver, C.R. (1 May 2003). "Neoproterozoic biotic diversification: Snowball Earth or aftermath of the Acraman impact?". Geology. 31 (5): 459–62. Bibcode:2003Geo....31..459G. doi:10.1130/0091-7613(2003)031<0459:NBDSEO>2.0.CO;2. Retrieved 29 May 2007.
  44. 1 2 R. Rieu; P.A. Allen; M. Plotze; T. Pettke (2007). "Climatic cycles during a Neoproterozoic "snowball" glacial epoch" (PDF). Geology. 35 (4): 299–302. Bibcode:2007Geo....35..299R. doi:10.1130/G23400A.1.
  45. 1 2 Young, G.M. (1999). "Some aspects of the geochemistry, provenance and palaeoclimatology of the Torridonian of NW Scotland". Journal of the Geological Society. 156 (6): 1097–1111. doi:10.1144/gsjgs.156.6.1097.
  46. Reprinted by permission from Macmillan Publishers Ltd.: Nature 405:425-429, copyright 2000. See Hyde et al. (2000).
  47. 1 2 Hoffman, P.F. (2005). "On Cryogenian (Neoproterozoic) ice-sheet dynamics and the limitations of the glacial sedimentary record". South African Journal of Geology. 108 (4): 557–77. doi:10.2113/108.4.557.
  48. Jacobsen, S.B. (2001). "Earth science. Gas hydrates and deglaciations" (PDF). Nature. 412 (6848): 691–3. PMID 11507621. doi:10.1038/35089168. Retrieved 21 May 2007.
  49. Meert, J.G.; Torsvik, T.H. (2004). GS Jenkins; MAS McMenamin; CP McKey; CP Sohl; L Sohl, eds. "Paleomagnetic Constraints on Neoproterozoic 'Snowball Earth' Continental Reconstructions" (PDF). Geophysical Monograph Series. 146. American Geophysical Union: 5–11. Bibcode:2004GMS...146....5M. ISBN 0-87590-411-4. doi:10.1029/146GM02. Retrieved 6 May 2007.
  50. Smith, A.G.; Pickering, K.T. (2003). "Oceanic gateways as a critical factor to initiate icehouse Earth". Journal of the Geological Society. 160 (3): 337–40. doi:10.1144/0016-764902-115. Retrieved 26 April 2007.
  51. Kerr, R.A. (1999). "Early life thrived despite earthly travails". Science. 284 (5423): 2111–3. PMID 10409069. doi:10.1126/science.284.5423.2111.
  52. Kirschvink, J.L. (2002). "When All of the Oceans Were Frozen" (PDF). Recherche. 355: 26–30. Retrieved 17 January 2008.
  53. Schrag, D.P.; Berner, R.A.; Hoffman, P.F.; Halverson, G.P. (2002). "On the initiation of a snowball Earth". Geochem. Geophys. Geosyst. 3 (10.1029): 1036. Bibcode:2002GGG....3fQ...1S. doi:10.1029/2001GC000219. Retrieved 28 February 2007.
  54. Hoffman, P.F.; Kaufman, A.J.; Halverson, G.P.; Schrag, D.P. (28 August 1998). "A Neoproterozoic Snowball Earth". Science. 281 (5381): 1342–6. Bibcode:1998Sci...281.1342H. PMID 9721097. doi:10.1126/science.281.5381.1342. Retrieved 4 May 2007. Full online article (pdf 260 Kb)
  55. Snowball Earth ocean chemistry driven by extensive ridge volcanism during Rodinia breakup, T.M. Gernon, T.K. Hincks, T. Tyrrell, E.J. Rohling, and M. R. Palmer , T.M. Gernon et al., Nature Geoscience, 18 January 2016
  56. Hyde, W.T.; Crowley, T.J.; Baum, S.K.; Peltier, W.R. (2000). "Neoproterozoic 'snowball Earth' simulations with a coupled climate/ice-sheet model" (PDF). Nature. 405 (6785): 425–9. PMID 10839531. doi:10.1038/35013005. Archived from the original (PDF) on 28 November 2007. Retrieved 5 May 2007.
  57. 1 2 Crowley, T.J.; Hyde, W.T.; Peltier, W.R. (2001). "CO 2 levels required for deglaciation of a 'near-snowball' Earth". Geophys. Res. Lett. 28 (2): 283–6. Bibcode:2001GeoRL..28..283C. doi:10.1029/2000GL011836.
  58. Glacier ecosystems
  59. Pierrehumbert, R.T. (2004). "High levels of atmospheric carbon dioxide necessary for the termination of global glaciation". Nature. 429 (6992): 646–9. Bibcode:2004Natur.429..646P. PMID 15190348. doi:10.1038/nature02640. Retrieved 29 May 2007.
  60. Kennedy, Martin; David Mrofka; Chris von der Borch (2008). "Snowball Earth termination by destabilization of equatorial permafrost methane clathrate" (PDF). Nature. 453 (29 May): 642–5. Bibcode:2008Natur.453..642K. PMID 18509441. doi:10.1038/nature06961.
  61. Hoffman, P.F. (1999). "The break-up of Rodinia, birth of Gondwana, true polar wander and the snowball Earth". Journal of African Earth Sciences. 28 (1): 17–33. Bibcode:1999JAfES..28...17H. doi:10.1016/S0899-5362(99)00018-4. Retrieved 29 April 2007.
  62. Peltier, W. Richard, Yonggang Liu & John W. Crowley, (2007), "Snowball Earth prevention by dissolved organic carbon remineralization" (Nature 450, 813-818 (6 December 2007) | doi:10.1038/nature06354)
  63. Cryoconite pans on Snowball Earth: supraglacial oases for Cryogenian eukaryotes?
  64. Did snowball Earth’s melting let oxygen fuel life?
  65. 1 2 Harland, W. B. (2007). "Origin and assessment of Snowball Earth hypotheses". Geology Magazine. 144 (4): 633–42. doi:10.1017/S0016756807003391.
  66. Fairchild, I. J.; Kennedy, M. J. (2007). "Neoproterozoic glaciations in the Earth System". Journal of the Geological Society. 164 (5): 895–921. doi:10.1144/0016-76492006-191.
  67. Chumakov, N. M. (2008). "A problem of Total Glaciations on the Earth in the Late Precambrian". Stratigraphy and Geological Correlation. 16 (2): 107–119. Bibcode:2008SGC....16..107C. doi:10.1134/S0869593808020019.
  68. Kilner, B.; Niocaill, C.M.; Brasier, M. (2005). "Low-latitude glaciation in the Neoproterozoic of Oman". Geology. 33 (5): 413–6. Bibcode:2005Geo....33..413K. doi:10.1130/G21227.1.
  69. Poulsen, C.J.; Pierrehumbert, R.T.; Jacob, R.L. (2001). "Impact of ocean dynamics on the simulation of the Neoproterozoic snowball Earth". Geophysical Research Letters. 28 (8): 1575–8. Bibcode:2001GeoRL..28.1575P. doi:10.1029/2000GL012058.
  70. Kennedy, M.J.; Christie-blick, N.; Sohl, L.E. (2001). "Are Proterozoic cap carbonates and isotopic excursions a record of gas hydrate destabilization following Earth's coldest intervals?" (PDF). Geology. 29 (5): 443–6. Bibcode:2001Geo....29..443K. doi:10.1130/0091-7613(2001)029<0443:APCCAI>2.0.CO;2.
  71. "LiveScience.com: The Day The Earth Fell Over".
  72. Kirschvink, J.L.; Ripperdan, R.L.; Evans, D.A. (25 July 1997). "Evidence for a Large-Scale Reorganization of Early Cambrian Continental Masses by Inertial Interchange True Polar Wander". Science. 277 (5325): 541–545. doi:10.1126/science.277.5325.541. Retrieved 5 May 2007.
  73. Meert, J.G. (1999). "A palaeomagnetic analysis of Cambrian true polar wander" (PDF). Earth Planet. Sci. Lett. 168: 131–144. Bibcode:1999E&PSL.168..131M. doi:10.1016/S0012-821X(99)00042-4. Retrieved 6 May 2007.
  74. http://www.pppl.gov/colloquia_pres/WC01OCT08_Maloof.pdf
  75. Torsvik, T.H. (2 January 1998). "Polar Wander and the Cambrian". Science. 279 (5347): 9. Bibcode:1998Sci...279....9T. doi:10.1126/science.279.5347.9a. Retrieved 5 May 2007.
  76. Corsetti, F.A.; Awramik, S.M.; Pierce, D. (15 April 2003). "A complex microbiota from snowball Earth times: Microfossils from the Neoproterozoic Kingston Peak Formation, Death Valley, USA". Proc. Natl. Acad. Sci. U.S.A. 100 (8): 4399–4404. Bibcode:2003PNAS..100.4399C. PMC 153566Freely accessible. PMID 12682298. doi:10.1073/pnas.0730560100. Retrieved 28 June 2007.
  77. Vincent, W.F. (2000). "Life on Snowball Earth". Science. 287 (5462): 2421–2. PMID 10766616. doi:10.1126/science.287.5462.2421b. Retrieved 5 May 2007.
  78. McKay, C.P. (2000). "Thickness of tropical ice and photosynthesis on a snowball Earth". Geophys. Res. Lett. 27 (14): 2153–6. Bibcode:2000GeoRL..27.2153M. PMID 11543492. doi:10.1029/2000GL008525.
  79. Hoffman, P.F.; Schrag, D.P. (2000). "Snowball Earth" (PDF). Scientific American. 282 (1): 68–75. doi:10.1038/scientificamerican0100-68.
  80. Corsetti, F. A. (2009). "Palaeontology: Extinction before the snowball". Nature Geoscience. 2 (6): 386–387. Bibcode:2009NatGe...2..386C. doi:10.1038/ngeo533.
  81. Corsetti, F.A.; Olcott, A.N.; Bakermans, C. (2006). "The biotic response to Neoproterozoic Snowball Earth". Palaeogeography, Palaeoclimatology, Palaeoecology. 232 (2–4): 114–130. doi:10.1016/j.palaeo.2005.10.030.
  82. Boyle RA, Lenton TM, Williams HTP (2007). "Neoproterozoic 'snowball Earth' glaciations and the evolution of altruism" (PDF). Geobiology. 5 (4): 337–349. doi:10.1111/j.1472-4669.2007.00115.x. Retrieved 17 June 2011.
  83. Cowie, J., (2007) Climate Change: Biological and Human Aspects. Cambridge University Press. (Pages 73 - 77.) ISBN 978-0-521-69619-7.
  84. Lenton, T., & Watson, A., (2011) Revolutions That Made The Earth. Oxford University Press. (Pages 30 -36, 274 - 282.) ISBN 978-0-19-958704-9.
  85. Ashkenazy, Y.; Gildor, H.; Losch, M.; MacDonald, F. A.; Schrag, D. P.; Tziperman, E. (2013). "Dynamics of a Snowball Earth ocean". Nature. 495 (7439): 90–93. doi:10.1038/nature11894.
  86. Stern, R.J.; Avigad, D.; Miller, N.R.; Beyth, M. (2006). "Geological Society of Africa Presidential Review: Evidence for the Snowball Earth Hypothesis in the Arabian-Nubian Shield and the East African Orogen". Journal of African Earth Sciences. 44: 1–20. Bibcode:2006JAfES..44....1S. doi:10.1016/j.jafrearsci.2005.10.003.
  87. Smith, A. G. (2009). "Neoproterozoic timescales and stratigraphy". Geological Society, London, Special Publications. 326: 27–54. Bibcode:2009GSLSP.326...27S. doi:10.1144/SP326.2.
  88. Williams G.E.; Schmidt P.W. (1997). "Paleomagnetism of the Paleoproterozoic Gowganda and Lorrain formations, Ontario: low palaeolatitude for Huronian glaciation" (PDF). EPSL. 153 (3): 157–169. Bibcode:1997E&PSL.153..157W. doi:10.1016/S0012-821X(97)00181-7.
  89. 1 2 Robert E. Kopp; Joseph L. Kirschvink; Isaac A. Hilburn & Cody Z. Nash (2005). "The Paleoproterozoic snowball Earth: A climate disaster triggered by the evolution of oxygenic photosynthesis". Proc. Natl. Acad. Sci. U.S.A. 102 (32): 11131–6. Bibcode:2005PNAS..10211131K. PMC 1183582Freely accessible. PMID 16061801. doi:10.1073/pnas.0504878102.
  90. Evans, D. A., Beukes, N. J. & Kirschvink, J. L. (1997) Nature 386, 262–266.

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