Curated/Reviewed by Matthew A. McIntosh
An ice age is a long period of reduction in the temperature of the Earth’s surface and atmosphere, resulting in the presence or expansion of continental and polar ice sheets and alpine glaciers. Earth’s climate alternates between ice ages and greenhouse periods, during which there are no glaciers on the planet. Earth is currently in the Quaternary glaciation. Individual pulses of cold climate within an ice age are termed glacial periods (or, alternatively, glacials, glaciations, glacial stages, stadials, stades, or colloquially, ice ages), and intermittent warm periods within an ice age are called interglacials or interstadials.
In the terminology of glaciology, ice age implies the presence of extensive ice sheets in both northern and southern hemispheres. By this definition, we are in an interglacial period—the Holocene. The amount of heat-trapping gases emitted into Earth’s oceans and atmosphere is predicted to prevent the next glacial period, which otherwise would begin in around 50,000 years, and likely more glacial cycles.
History of Research
In 1742, Pierre Martel (1706–1767), an engineer and geographer living in Geneva, visited the valley of Chamonix in the Alps of Savoy. Two years later he published an account of his journey. He reported that the inhabitants of that valley attributed the dispersal of erratic boulders to the glaciers, saying that they had once extended much farther. Later similar explanations were reported from other regions of the Alps. In 1815 the carpenter and chamois hunter Jean-Pierre Perraudin (1767–1858) explained erratic boulders in the Val de Bagnes in the Swiss canton of Valais as being due to glaciers previously extending further.
An unknown woodcutter from Meiringen in the Bernese Oberland advocated a similar idea in a discussion with the Swiss-German geologist Jean de Charpentier (1786–1855) in 1834. Comparable explanations are also known from the Val de Ferret in the Valais and the Seeland in western Switzerland and in Goethe’s scientific work. Such explanations could also be found in other parts of the world. When the Bavarian naturalist Ernst von Bibra (1806–1878) visited the Chilean Andes in 1849–1850, the natives attributed fossil moraines to the former action of glaciers.
Meanwhile, European scholars had begun to wonder what had caused the dispersal of erratic material. From the middle of the 18th century, some discussed ice as a means of transport. The Swedish mining expert Daniel Tilas (1712–1772) was, in 1742, the first person to suggest drifting sea ice in order to explain the presence of erratic boulders in the Scandinavian and Baltic regions. In 1795, the Scottish philosopher and gentleman naturalist, James Hutton (1726–1797), explained erratic boulders in the Alps by the action of glaciers. Two decades later, in 1818, the Swedish botanist Göran Wahlenberg (1780–1851) published his theory of a glaciation of the Scandinavian peninsula. He regarded glaciation as a regional phenomenon.
Only a few years later, the Danish-Norwegian geologist Jens Esmark (1762–1839) argued for a sequence of worldwide ice ages. In a paper published in 1824, Esmark proposed changes in climate as the cause of those glaciations. He attempted to show that they originated from changes in Earth’s orbit. Esmark discovered the similarity between moraines near Haukalivatnet lake near sea level in Rogaland and moraines at branches of Jostedalsbreen. Esmark’s discovery were later attributed to or appropriated by Theodor Kjerulf and Louis Agassiz.
During the following years, Esmark’s ideas were discussed and taken over in parts by Swedish, Scottish and German scientists. At the University of Edinburgh Robert Jameson (1774–1854) seemed to be relatively open to Esmark’s ideas, as reviewed by Norwegian professor of glaciology Bjørn G. Andersen (1992). Jameson’s remarks about ancient glaciers in Scotland were most probably prompted by Esmark. In Germany, Albrecht Reinhard Bernhardi (1797–1849), a geologist and professor of forestry at an academy in Dreissigacker (since incorporated in the southern Thuringian city of Meiningen), adopted Esmark’s theory. In a paper published in 1832, Bernhardi speculated about the polar ice caps once reaching as far as the temperate zones of the globe.
In 1829, independently of these debates, the Swiss civil engineer Ignaz Venetz (1788–1859) explained the dispersal of erratic boulders in the Alps, the nearby Jura Mountains, and the North German Plain as being due to huge glaciers. When he read his paper before the Schweizerische Naturforschende Gesellschaft, most scientists remained sceptical. Finally, Venetz convinced his friend Jean de Charpentier. De Charpentier transformed Venetz’s idea into a theory with a glaciation limited to the Alps. His thoughts resembled Wahlenberg’s theory. In fact, both men shared the same volcanistic, or in de Charpentier’s case rather plutonistic assumptions, about the Earth’s history. In 1834, de Charpentier presented his paper before the Schweizerische Naturforschende Gesellschaft. In the meantime, the German botanist Karl Friedrich Schimper (1803–1867) was studying mosses which were growing on erratic boulders in the alpine upland of Bavaria. He began to wonder where such masses of stone had come from. During the summer of 1835 he made some excursions to the Bavarian Alps. Schimper came to the conclusion that ice must have been the means of transport for the boulders in the alpine upland. In the winter of 1835 to 1836 he held some lectures in Munich. Schimper then assumed that there must have been global times of obliteration (“Verödungszeiten”) with a cold climate and frozen water.
Schimper spent the summer months of 1836 at Devens, near Bex, in the Swiss Alps with his former university friend Louis Agassiz (1801–1873) and Jean de Charpentier. Schimper, de Charpentier and possibly Venetz convinced Agassiz that there had been a time of glaciation. During the winter of 1836/37, Agassiz and Schimper developed the theory of a sequence of glaciations. They mainly drew upon the preceding works of Venetz, de Charpentier and on their own fieldwork. Agassiz appears to have been already familiar with Bernhardi’s paper at that time. At the beginning of 1837, Schimper coined the term “ice age” (“Eiszeit”) for the period of the glaciers. In July 1837 Agassiz presented their synthesis before the annual meeting of the Schweizerische Naturforschende Gesellschaft at Neuchâtel. The audience was very critical and some opposed to the new theory because it contradicted the established opinions on climatic history. Most contemporary scientists thought that the Earth had been gradually cooling down since its birth as a molten globe.
In order to persuade the skeptics, Agassiz embarked on geological fieldwork. He published his book Study on Glaciers (“Études sur les glaciers”) in 1840. De Charpentier was put out by this, as he had also been preparing a book about the glaciation of the Alps. De Charpentier felt that Agassiz should have given him precedence as it was he who had introduced Agassiz to in-depth glacial research. As a result of personal quarrels, Agassiz had also omitted any mention of Schimper in his book.
It took several decades before the ice age theory was fully accepted by scientists. This happened on an international scale in the second half of the 1870s, following the work of James Croll, including the publication of Climate and Time, in Their Geological Relations in 1875, which provided a credible explanation for the causes of ice ages.
There are three main types of evidence for ice ages: geological, chemical, and paleontological.
Geological evidence for ice ages comes in various forms, including rock scouring and scratching, glacial moraines, drumlins, valley cutting, and the deposition of till or tillites and glacial erratics. Successive glaciations tend to distort and erase the geological evidence for earlier glaciations, making it difficult to interpret. Furthermore, this evidence was difficult to date exactly; early theories assumed that the glacials were short compared to the long interglacials. The advent of sediment and ice cores revealed the true situation: glacials are long, interglacials short. It took some time for the current theory to be worked out.
The chemical evidence mainly consists of variations in the ratios of isotopes in fossils present in sediments and sedimentary rocks and ocean sediment cores. For the most recent glacial periods, ice cores provide climate proxies, both from the ice itself and from atmospheric samples provided by included bubbles of air. Because water containing lighter isotopes has a lower heat of evaporation, its proportion decreases with warmer conditions. This allows a temperature record to be constructed. This evidence can be confounded, however, by other factors recorded by isotope ratios.
The paleontological evidence consists of changes in the geographical distribution of fossils. During a glacial period, cold-adapted organisms spread into lower latitudes, and organisms that prefer warmer conditions become extinct or retreat into lower latitudes. This evidence is also difficult to interpret because it requires (1) sequences of sediments covering a long period of time, over a wide range of latitudes and which are easily correlated; (2) ancient organisms which survive for several million years without change and whose temperature preferences are easily diagnosed; and (3) the finding of the relevant fossils.
Despite the difficulties, analysis of ice core and ocean sediment cores has provided a credible record of glacials and interglacials over the past few million years. These also confirm the linkage between ice ages and continental crust phenomena such as glacial moraines, drumlins, and glacial erratics. Hence the continental crust phenomena are accepted as good evidence of earlier ice ages when they are found in layers created much earlier than the time range for which ice cores and ocean sediment cores are available.
Major Ice Ages
There have been at least five major ice ages in the Earth’s history (the Huronian, Cryogenian, Andean-Saharan, late Paleozoic, and the latest Quaternary Ice Age). Outside these ages, the Earth seems to have been ice free even in high latitudes; such periods are known as greenhouse periods.
Rocks from the earliest well-established ice age, called the Huronian, have been dated to around 2.4 to 2.1 Ga (billion years) ago during the early Proterozoic Eon. Several hundreds of kilometers of the Huronian Supergroup are exposed 10 to 100 kilometers (6.2 to 62.1 mi) north of the north shore of Lake Huron, extending from near Sault Ste. Marie to Sudbury, northeast of Lake Huron, with giant layers of now-lithified till beds, dropstones, varves, outwash, and scoured basement rocks. Correlative Huronian deposits have been found near Marquette, Michigan, and correlation has been made with Paleoproterozoic glacial deposits from Western Australia. The Huronian ice age was caused by the elimination of atmospheric methane, a greenhouse gas, during the Great Oxygenation Event.
The next well-documented ice age, and probably the most severe of the last billion years, occurred from 720 to 630 million years ago (the Cryogenian period) and may have produced a Snowball Earth in which glacial ice sheets reached the equator, possibly being ended by the accumulation of greenhouse gases such as CO2 produced by volcanoes. “The presence of ice on the continents and pack ice on the oceans would inhibit both silicate weathering and photosynthesis, which are the two major sinks for CO2 at present.” It has been suggested that the end of this ice age was responsible for the subsequent Ediacaran and Cambrian explosion, though this model is recent and controversial.
The Andean-Saharan occurred from 460 to 420 million years ago, during the Late Ordovician and the Silurian period.
The evolution of land plants at the onset of the Devonian period caused a long term increase in planetary oxygen levels and reduction of CO2 levels, which resulted in the late Paleozoic icehouse. Its former name, the Karoo glaciation, was named after the glacial tills found in the Karoo region of South Africa. There were extensive polar ice caps at intervals from 360 to 260 million years ago in South Africa during the Carboniferous and early Permian Periods. Correlatives are known from Argentina, also in the center of the ancient supercontinent Gondwanaland.
The Quaternary Glaciation / Quaternary Ice Age started about 2.58 million years ago at the beginning of the Quaternary Period when the spread of ice sheets in the Northern Hemisphere began. Since then, the world has seen cycles of glaciation with ice sheets advancing and retreating on 40,000- and 100,000-year time scales called glacial periods, glacials or glacial advances, and interglacial periods, interglacials or glacial retreats. The earth is currently in an interglacial, and the last glacial period ended about 10,000 years ago. All that remains of the continental ice sheets are the Greenland and Antarctic ice sheets and smaller glaciers such as on Baffin Island.
The definition of the Quaternary as beginning 2.58 Ma is based on the formation of the Arctic ice cap. The Antarctic ice sheet began to form earlier, at about 34 Ma, in the mid-Cenozoic (Eocene-Oligocene Boundary). The term Late Cenozoic Ice Age is used to include this early phase.
Ice ages can be further divided by location and time; for example, the names Riss (180,000–130,000 years bp) and Würm (70,000–10,000 years bp) refer specifically to glaciation in the Alpine region. The maximum extent of the ice is not maintained for the full interval. The scouring action of each glaciation tends to remove most of the evidence of prior ice sheets almost completely, except in regions where the later sheet does not achieve full coverage.
Glacials and Interglacials
Within the current glaciation, more temperate and more severe periods have occurred. The colder periods are called glacial periods, the warmer periods interglacials, such as the Eemian Stage. There is evidence that similar glacial cycles occurred in previous glaciations, including the Andean-Saharan and the late Paleozoic ice house. The glacial cycles of the late Paleozoic ice house are likely responsible for the deposition of cyclothems.
Glacials are characterized by cooler and drier climates over most of the earth and large land and sea ice masses extending outward from the poles. Mountain glaciers in otherwise unglaciated areas extend to lower elevations due to a lower snow line. Sea levels drop due to the removal of large volumes of water above sea level in the icecaps. There is evidence that ocean circulation patterns are disrupted by glaciations. The glacials and interglacials coincide with changes in orbital forcing of climate due to Milankovitch cycles, which are periodic changes in the Earth’s orbit and the tilt of the Earth’s rotational axis.
The earth has been in an interglacial period known as the Holocene for around 11,700 years, and an article in Nature in 2004 argues that it might be most analogous to a previous interglacial that lasted 28,000 years. Predicted changes in orbital forcing suggest that the next glacial period would begin at least 50,000 years from now. Moreover, anthropogenic forcing from increased greenhouse gases is estimated to potentially outweigh the orbital forcing of the Milankovitch cycles for hundreds of thousand of years.
An important form of feedback is provided by the Earth’s albedo, which is how much of the sun’s energy is reflected rather than absorbed by the Earth. Ice and snow increase Earth’s albedo, while forests reduce its albedo. When the air temperature decreases, ice and snow fields grow, and they reduce forest cover. This continues until competition with a negative feedback mechanism forces the system to an equilibrium.
In 1956, Ewing and Donn hypothesized that an ice-free Arctic Ocean leads to increased snowfall at high latitudes. When low-temperature ice covers the Arctic Ocean there is little evaporation or sublimation and the polar regions are quite dry in terms of precipitation, comparable to the amount found in mid-latitude deserts. This low precipitation allows high-latitude snowfalls to melt during the summer. An ice-free Arctic Ocean absorbs solar radiation during the long summer days, and evaporates more water into the Arctic atmosphere. With higher precipitation, portions of this snow may not melt during the summer and so glacial ice can form at lower altitudes and more southerly latitudes, reducing the temperatures over land by increased albedo as noted above. Furthermore, under this hypothesis the lack of oceanic pack ice allows increased exchange of waters between the Arctic and the North Atlantic Oceans, warming the Arctic and cooling the North Atlantic.
Additional fresh water flowing into the North Atlantic during a warming cycle may also reduce the global ocean water circulation. Such a reduction (by reducing the effects of the Gulf Stream) would have a cooling effect on northern Europe, which in turn would lead to increased low-latitude snow retention during the summer. It has also been suggested[by whom?] that during an extensive glacial, glaciers may move through the Gulf of Saint Lawrence, extending into the North Atlantic Ocean far enough to block the Gulf Stream.
Ice sheets that form during glaciations erode the land beneath them. This can reduce the land area above sea level and thus diminish the amount of space on which ice sheets can form. This mitigates the albedo feedback, as does the rise in sea level that accompanies the reduced area of ice sheets, since open ocean has a lower albedo than land.
Another negative feedback mechanism is the increased aridity occurring with glacial maxima, which reduces the precipitation available to maintain glaciation. The glacial retreat induced by this or any other process can be amplified by similar inverse positive feedbacks as for glacial advances.
According to research published in Nature Geoscience, human emissions of carbon dioxide (CO2) will defer the next ice age. Researchers used data on Earth’s orbit to find the historical warm interglacial period that looks most like the current one and from this have predicted that the next ice age would usually begin within 1,500 years. They go on to predict that emissions have been so high that it will not.
The causes of ice ages are not fully understood for either the large-scale ice age periods or the smaller ebb and flow of glacial–interglacial periods within an ice age. The consensus is that several factors are important: atmospheric composition, such as the concentrations of carbon dioxide and methane (the specific levels of the previously mentioned gases are now able to be seen with the new ice core samples from EPICA Dome C in Antarctica over the past 800,000 years); changes in the earth’s orbit around the Sun known as Milankovitch cycles; the motion of tectonic plates resulting in changes in the relative location and amount of continental and oceanic crust on the earth’s surface, which affect wind and ocean currents; variations in solar output; the orbital dynamics of the Earth–Moon system; the impact of relatively large meteorites and volcanism including eruptions of supervolcanoes.
Some of these factors influence each other. For example, changes in Earth’s atmospheric composition (especially the concentrations of greenhouse gases) may alter the climate, while climate change itself can change the atmospheric composition (for example by changing the rate at which weathering removes CO2).
Maureen Raymo, William Ruddiman and others propose that the Tibetan and Colorado Plateaus are immense CO
2 “scrubbers” with a capacity to remove enough CO2 from the global atmosphere to be a significant causal factor of the 40 million year Cenozoic Cooling trend. They further claim that approximately half of their uplift (and CO2 “scrubbing” capacity) occurred in the past 10 million years.
Changes in Earth’s Atmosphere
There is evidence that greenhouse gas levels fell at the start of ice ages and rose during the retreat of the ice sheets, but it is difficult to establish cause and effect (see the notes above on the role of weathering). Greenhouse gas levels may also have been affected by other factors which have been proposed as causes of ice ages, such as the movement of continents and volcanism.
The Snowball Earth hypothesis maintains that the severe freezing in the late Proterozoic was ended by an increase in CO2 levels in the atmosphere, mainly from volcanoes, and some supporters of Snowball Earth argue that it was caused in the first place by a reduction in atmospheric CO2. The hypothesis also warns of future Snowball Earths.
In 2009, further evidence was provided that changes in solar insolation provide the initial trigger for the earth to warm after an Ice Age, with secondary factors like increases in greenhouse gases accounting for the magnitude of the change.
Position of the Continents
The geological record appears to show that ice ages start when the continents are in positions which block or reduce the flow of warm water from the equator to the poles and thus allow ice sheets to form. The ice sheets increase Earth’s reflectivity and thus reduce the absorption of solar radiation. With less radiation absorbed the atmosphere cools; the cooling allows the ice sheets to grow, which further increases reflectivity in a positive feedback loop. The ice age continues until the reduction in weathering causes an increase in the greenhouse effect.
There are three main contributors from the layout of the continents that obstruct the movement of warm water to the poles:
- A continent sits on top of a pole, as Antarctica does today.
- A polar sea is almost land-locked, as the Arctic Ocean is today.
- A supercontinent covers most of the equator, as Rodinia did during the Cryogenian period.
Since today’s Earth has a continent over the South Pole and an almost land-locked ocean over the North Pole, geologists believe that Earth will continue to experience glacial periods in the geologically near future.
Some scientists believe that the Himalayas are a major factor in the current ice age, because these mountains have increased Earth’s total rainfall and therefore the rate at which carbon dioxide is washed out of the atmosphere, decreasing the greenhouse effect. The Himalayas’ formation started about 70 million years ago when the Indo-Australian Plate collided with the Eurasian Plate, and the Himalayas are still rising by about 5 mm per year because the Indo-Australian plate is still moving at 67 mm/year. The history of the Himalayas broadly fits the long-term decrease in Earth’s average temperature since the mid-Eocene, 40 million years ago.
Fluctuations in Ocean Currents
Another important contribution to ancient climate regimes is the variation of ocean currents, which are modified by continent position, sea levels and salinity, as well as other factors. They have the ability to cool (e.g. aiding the creation of Antarctic ice) and the ability to warm (e.g. giving the British Isles a temperate as opposed to a boreal climate). The closing of the Isthmus of Panama about 3 million years ago may have ushered in the present period of strong glaciation over North America by ending the exchange of water between the tropical Atlantic and Pacific Oceans.
Analyses suggest that ocean current fluctuations can adequately account for recent glacial oscillations. During the last glacial period the sea-level has fluctuated 20–30 m as water was sequestered, primarily in the Northern Hemisphere ice sheets. When ice collected and the sea level dropped sufficiently, flow through the Bering Strait (the narrow strait between Siberia and Alaska is about 50 m deep today) was reduced, resulting in increased flow from the North Atlantic. This realigned the thermohaline circulation in the Atlantic, increasing heat transport into the Arctic, which melted the polar ice accumulation and reduced other continental ice sheets. The release of water raised sea levels again, restoring the ingress of colder water from the Pacific with an accompanying shift to northern hemisphere ice accumulation.
According to a study published in Nature in 2021, all glacial periods of ice ages over the last 1.5 million years were associated with northward shifts of melting Antarctic icebergs which changed ocean circulation patterns, leading to more CO2 being pulled out of the atmosphere. The authors suggest that this process may be disrupted in the future as the Southern Ocean will become too warm for the icebergs to travel far enough to trigger these changes.
Uplift of the Tibetan Plateau
Matthias Kuhle’s geological theory of Ice Age development was suggested by the existence of an ice sheet covering the Tibetan Plateau during the Ice Ages (Last Glacial Maximum?). According to Kuhle, the plate-tectonic uplift of Tibet past the snow-line has led to a surface of c. 2,400,000 square kilometres (930,000 sq mi) changing from bare land to ice with a 70% greater albedo. The reflection of energy into space resulted in a global cooling, triggering the Pleistocene Ice Age. Because this highland is at a subtropical latitude, with 4 to 5 times the insolation of high-latitude areas, what would be Earth’s strongest heating surface has turned into a cooling surface.
Kuhle explains the interglacial periods by the 100,000-year cycle of radiation changes due to variations in Earth’s orbit. This comparatively insignificant warming, when combined with the lowering of the Nordic inland ice areas and Tibet due to the weight of the superimposed ice-load, has led to the repeated complete thawing of the inland ice areas.
Variations in Earth’s Orbit
The Milankovitch cycles are a set of cyclic variations in characteristics of the Earth’s orbit around the Sun. Each cycle has a different length, so at some times their effects reinforce each other and at other times they (partially) cancel each other.
There is strong evidence that the Milankovitch cycles affect the occurrence of glacial and interglacial periods within an ice age. The present ice age is the most studied and best understood, particularly the last 400,000 years, since this is the period covered by ice cores that record atmospheric composition and proxies for temperature and ice volume. Within this period, the match of glacial/interglacial frequencies to the Milanković orbital forcing periods is so close that orbital forcing is generally accepted. The combined effects of the changing distance to the Sun, the precession of the Earth’s axis, and the changing tilt of the Earth’s axis redistribute the sunlight received by the Earth. Of particular importance are changes in the tilt of the Earth’s axis, which affect the intensity of seasons. For example, the amount of solar influx in July at 65 degrees north latitude varies by as much as 22% (from 450 W/m2 to 550 W/m2). It is widely believed that ice sheets advance when summers become too cool to melt all of the accumulated snowfall from the previous winter. Some believe that the strength of the orbital forcing is too small to trigger glaciations, but feedback mechanisms like CO2 may explain this mismatch.
While Milankovitch forcing predicts that cyclic changes in the Earth’s orbital elements can be expressed in the glaciation record, additional explanations are necessary to explain which cycles are observed to be most important in the timing of glacial–interglacial periods. In particular, during the last 800,000 years, the dominant period of glacial–interglacial oscillation has been 100,000 years, which corresponds to changes in Earth’s orbital eccentricity and orbital inclination. Yet this is by far the weakest of the three frequencies predicted by Milankovitch. During the period 3.0–0.8 million years ago, the dominant pattern of glaciation corresponded to the 41,000-year period of changes in Earth’s obliquity (tilt of the axis). The reasons for dominance of one frequency versus another are poorly understood and an active area of current research, but the answer probably relates to some form of resonance in the Earth’s climate system. Recent work suggests that the 100K year cycle dominates due to increased southern-pole sea-ice increasing total solar reflectivity.
The “traditional” Milankovitch explanation struggles to explain the dominance of the 100,000-year cycle over the last 8 cycles. Richard A. Muller, Gordon J. F. MacDonald, and others have pointed out that those calculations are for a two-dimensional orbit of Earth but the three-dimensional orbit also has a 100,000-year cycle of orbital inclination. They proposed that these variations in orbital inclination lead to variations in insolation, as the Earth moves in and out of known dust bands in the solar system. Although this is a different mechanism to the traditional view, the “predicted” periods over the last 400,000 years are nearly the same. The Muller and MacDonald theory, in turn, has been challenged by Jose Antonio Rial.
Another worker, William Ruddiman, has suggested a model that explains the 100,000-year cycle by the modulating effect of eccentricity (weak 100,000-year cycle) on precession (26,000-year cycle) combined with greenhouse gas feedbacks in the 41,000- and 26,000-year cycles. Yet another theory has been advanced by Peter Huybers who argued that the 41,000-year cycle has always been dominant, but that the Earth has entered a mode of climate behavior where only the second or third cycle triggers an ice age. This would imply that the 100,000-year periodicity is really an illusion created by averaging together cycles lasting 80,000 and 120,000 years. This theory is consistent with a simple empirical multi-state model proposed by Didier Paillard. Paillard suggests that the late Pleistocene glacial cycles can be seen as jumps between three quasi-stable climate states. The jumps are induced by the orbital forcing, while in the early Pleistocene the 41,000-year glacial cycles resulted from jumps between only two climate states. A dynamical model explaining this behavior was proposed by Peter Ditlevsen. This is in support of the suggestion that the late Pleistocene glacial cycles are not due to the weak 100,000-year eccentricity cycle, but a non-linear response to mainly the 41,000-year obliquity cycle.
Variations in the Sun’s Energy Output
There are at least two types of variation in the Sun’s energy output:
- In the very long term, astrophysicists believe that the Sun’s output increases by about 7% every one billion (109) years.
- Shorter-term variations such as sunspot cycles, and longer episodes such as the Maunder Minimum, which occurred during the coldest part of the Little Ice Age.
The long-term increase in the Sun’s output cannot be a cause of ice ages.
Volcanic eruptions may have contributed to the inception and/or the end of ice age periods. At times during the paleoclimate, carbon dioxide levels were two or three times greater than today. Volcanoes and movements in continental plates contributed to high amounts of CO2 in the atmosphere. Carbon dioxide from volcanoes probably contributed to periods with highest overall temperatures. One suggested explanation of the Paleocene-Eocene Thermal Maximum is that undersea volcanoes released methane from clathrates and thus caused a large and rapid increase in the greenhouse effect. There appears to be no geological evidence for such eruptions at the right time, but this does not prove they did not happen.
Recent Glacial and Interglacial Phases
The current geological period, the Quaternary, which began about 2.6 million years ago and extends into the present, is marked by warm and cold episodes, cold phases called glacials (Quaternary ice age) lasting about 100,000 years, and which are then interrupted by the warmer interglacials which lasted about 10,000–15,000 years. The last cold episode of the last glacial period ended about 10,000 years ago. Earth is currently in an interglacial period of the Quaternary, called the Holocene.
Glacial Stages in North America
The major glacial stages of the current ice age in North America are the Illinoian, Eemian and Wisconsin glaciation. The use of the Nebraskan, Afton, Kansan, and Yarmouthian stages to subdivide the ice age in North America has been discontinued by Quaternary geologists and geomorphologists. These stages have all been merged into the Pre-Illinoian in the 1980s.
During the most recent North American glaciation, during the latter part of the Last Glacial Maximum (26,000 to 13,300 years ago), ice sheets extended to about 45th parallel north. These sheets were 3 to 4 kilometres (1.9 to 2.5 mi) thick.
This Wisconsin glaciation left widespread impacts on the North American landscape. The Great Lakes and the Finger Lakes were carved by ice deepening old valleys. Most of the lakes in Minnesota and Wisconsin were gouged out by glaciers and later filled with glacial meltwaters. The old Teays River drainage system was radically altered and largely reshaped into the Ohio River drainage system. Other rivers were dammed and diverted to new channels, such as Niagara Falls, which formed a dramatic waterfall and gorge, when the waterflow encountered a limestone escarpment. Another similar waterfall, at the present Clark Reservation State Park near Syracuse, New York, is now dry.
The area from Long Island to Nantucket, Massachusetts was formed from glacial till, and the plethora of lakes on the Canadian Shield in northern Canada can be almost entirely attributed to the action of the ice. As the ice retreated and the rock dust dried, winds carried the material hundreds of miles, forming beds of loess many dozens of feet thick in the Missouri Valley. Post-glacial rebound continues to reshape the Great Lakes and other areas formerly under the weight of the ice sheets.
The Driftless Area, a portion of western and southwestern Wisconsin along with parts of adjacent Minnesota, Iowa, and Illinois, was not covered by glaciers.
Last Glacial Period in the Semiarid Andes around Aconcagua and Tupungato
A specially interesting climatic change during glacial times has taken place in the semi-arid Andes. Beside the expected cooling down in comparison with the current climate, a significant precipitation change happened here. So, researches in the presently semiarid subtropic Aconcagua-massif (6,962 m) have shown an unexpectedly extensive glacial glaciation of the type “ice stream network”. The connected valley glaciers exceeding 100 km in length, flowed down on the East-side of this section of the Andes at 32–34°S and 69–71°W as far as a height of 2,060 m and on the western luff-side still clearly deeper.
Where current glaciers scarcely reach 10 km in length, the snowline (ELA) runs at a height of 4,600 m and at that time was lowered to 3,200 m asl, i.e. about 1,400 m. From this follows that—beside of an annual depression of temperature about c. 8.4 °C— here was an increase in precipitation. Accordingly, at glacial times the humid climatic belt that today is situated several latitude degrees further to the S, was shifted much further to the N.
Effects of Glaciation
Although the last glacial period ended more than 8,000 years ago, its effects can still be felt today. For example, the moving ice carved out the landscape in Canada. The erratic boulders, till, drumlins, eskers, fjords, kettle lakes, moraines, cirques, horns, etc., are typical features left behind by the glaciers.
The weight of the ice sheets was so great that they deformed the Earth’s crust and mantle. After the ice sheets melted, the ice-covered land rebounded. Due to the high viscosity of the Earth’s mantle, the flow of mantle rocks which controls the rebound process is very slow—at a rate of about 1 cm/year near the center of rebound area today.
During glaciation, water was taken from the oceans to form the ice at high latitudes, thus global sea level dropped by about 110 meters, exposing the continental shelves and forming land-bridges between land-masses for animals to migrate. During deglaciation, the melted ice-water returned to the oceans, causing sea level to rise. This process can cause sudden shifts in coastlines and hydration systems resulting in newly submerged lands, emerging lands, collapsed ice dams resulting in salination of lakes, new ice dams creating vast areas of freshwater, and a general alteration in regional weather patterns on a large but temporary scale. It can even cause temporary reglaciation. This type of chaotic pattern of rapidly changing land, ice, saltwater and freshwater has been proposed as the likely model for the Baltic and Scandinavian regions, as well as much of central North America at the end of the last glacial maximum, with the present-day coastlines only being achieved in the last few millennia of prehistory. Also, the effect of elevation on Scandinavia submerged a vast continental plain that had existed under much of what is now the North Sea, connecting the British Isles to Continental Europe.
The redistribution of ice-water on the surface of the Earth and the flow of mantle rocks causes changes in the gravitational field as well as changes to the distribution of the moment of inertia of the Earth. These changes to the moment of inertia result in a change in the angular velocity, axis, and wobble of the Earth’s rotation.
The weight of the redistributed surface mass loaded the lithosphere, caused it to flex and also induced stress within the Earth. The presence of the glaciers generally suppressed the movement of faults below. During deglaciation, the faults experience accelerated slip triggering earthquakes. Earthquakes triggered near the ice margin may in turn accelerate ice calving and may account for the Heinrich events. As more ice is removed near the ice margin, more intraplate earthquakes are induced and this positive feedback may explain the fast collapse of ice sheets.
In Europe, glacial erosion and isostatic sinking from weight of ice made the Baltic Sea, which before the Ice Age was all land drained by the Eridanos River.
- Ehlers, Jürgen; Gibbard, Philip (2011). “Quaternary glaciation”. Encyclopedia of Snow, Ice and Glaciers. Encyclopedia of Earth Sciences Series. pp. 873–882. doi:10.1007/978-90-481-2642-2_423. ISBN 978-90-481-2641-5.
- Cohen, K .M.; Finney, S. C.; Gibbard, P. L.; Fan, J.-X. “International Chronostratigraphic Chart 2013” (PDF). stratigraphy.org. ICS. Retrieved 7 January 2019.
- Imbrie, J.; Imbrie, K. P. (1979). Ice ages: solving the mystery. Short Hills NJ: Enslow Publishers.
- “Global Warming Good News: No More Ice Ages”. LiveScience. 2007.
- “Human-made climate change suppresses the next ice age”. Potsdam Institute for Climate Impact Research in Germany. 2016.
- Rémy F, Testut L (2006). “Mais comment s’écoule donc un glacier ? Aperçu historique” (PDF). Comptes Rendus Geoscience (in French). 338 (5): 368–385. Bibcode:2006CRGeo.338..368R. doi:10.1016/j.crte.2006.02.004.Note: p. 374
- Montgomery 2010
- Martel, Pierre (1898). “Appendix: Martel, P. (1744) An account of the glacieres or ice alps in Savoy, in two letters, one from an English gentleman to his friend at Geneva; the other from Pierre Martel, engineer, to the said English gentleman”. In Mathews, C.E. (ed.). The annals of Mont Blanc. London: Unwin. p. 327. See (Montgomery 2010) for a full bibliography
- Krüger, Tobias (2013). Discovering the Ice Ages. International Reception and Consequences for a Historical Understanding of Climate (German edition: Basel 2008). Leiden. p. 47.
- Krüger 2013, pp. 78–83
- Krüger 2013, p. 150
- Krüger 2013, pp. 83, 151
- Goethe, Johann Wolfgang von: Geologische Probleme und Versuch ihrer Auflösung, Mineralogie und Geologie in Goethes Werke, Weimar 1892,
- Krüger 2013, p. 83
- Krüger 2013, p. 38
- Krüger 2013, pp. 61–2
- Krüger 2013, pp. 88–90
- Krüger 2013, pp. 91–6
- Hestmark, Geir (2018). “Jens Esmark’s mountain glacier traverse 1823 − the key to his discovery of Ice Ages”. Boreas. 47 (1): 1–10. doi:10.1111/bor.12260. ISSN 1502-3885.
The discovery of Ice Ages is one of the most revolutionary advances made in the Earth sciences. In 1824 Danish‐Norwegian geoscientist Jens Esmark published a paper stating that there was indisputable evidence that Norway and other parts of Europe had previously been covered by enormous glaciers carving out valleys and fjords, in a cold climate caused by changes in the eccentricity of Earth’s orbit. Esmark and his travel companion Otto Tank arrived at this insight by analogous reasoning: enigmatic landscape features they observed close to sea level along the Norwegian coast strongly resembled features they observed in the front of a retreating glacier during a mountain traverse in the summer of 1823.
- Berg, Bjørn Ivar (2020-02-25), “Jens Esmark”, Norsk biografisk leksikon(in Norwegian Bokmål), retrieved 2021-02-28
- Hverven, Tom Egil. “Isens spor”. Klassekampen. Retrieved 2021-02-28.
- Andersen, Bjørn G. (1992). “Jens Esmark—a pioneer in glacial geology”. Boreas. 21: 97–102. doi:10.1111/j.1502-3885.1992.tb00016.x.
- Davies, Gordon L. (1969). The Earth in Decay. A History of British Geomorphology 1578–1878. London: New York, American Elsevier Pub. Co. pp. 267f.
Cunningham, Frank F. (1990). James David Forbes. Pioneer Scottish Glaciologist. Edinburgh: Scottish Academic Press. p. 15.
- Krüger 2013, pp. 142–47
- Krüger 2013, pp. 104–05
- Krüger 2013, pp. 150–53
- Krüger 2013, pp. 155–59
- Krüger 2013, pp. 167–70
- Krüger 2013, p. 173
- Krüger 2008, pp. 177–78
- Agassiz, Louis; Bettannier, Joseph (1840). Études sur les glaciers. Ouvrage accompagné d’un atlas de 32 planches, Neuchâtel. H. Nicolet.
- Krüger 2008, pp. 223–4. De Charpentier, Jean: Essais sur les glaciers et sur le terrain erratique du bassin du Rhône, Lausanne 1841.
- Krüger 2013, pp. 181–84
- Krüger 2013, pp. 458–60
- “How are past temperatures determined from an ice core?”. Scientific American. 2004-09-20.
- Putnam, Aaron E.; Denton, George H.; Schaefer, Joerg M.; Barrell, David J. A.; Andersen, Bjørn G.; Finkel, Robert C.; Schwartz, Roseanne; Doughty, Alice M.; Kaplan, Michael R.; Schlüchter, Christian (2010). “Glacier advance in southern middle-latitudes during the Antarctic Cold Reversal”. Nature Geoscience. 3 (10): 700–704. Bibcode:2010NatGe…3..700P. doi:10.1038/ngeo962.
- Lockwood, J.G.; van Zinderen-Bakker, E. M. (November 1979). “The Antarctic Ice-Sheet: Regulator of Global Climates?: Review”. The Geographical Journal. 145 (3): 469–471. doi:10.2307/633219. JSTOR 633219.
- Warren, John K. (2006). Evaporites: sediments, resources and hydrocarbons. Birkhäuser. p. 289.
- Allaby, Michael (January 2013). A Dictionary of Geology and Earth Sciences (Fourth ed.). Oxford University Press.
- Kopp, Robert (14 June 2005). “The Paleoproterozoic snowball Earth: A climate disaster triggered by the evolution of oxygenic photosynthesis”. PNAS. 102 (32): 11131–6. Bibcode:2005PNAS..10211131K. doi:10.1073/pnas.0504878102. PMC 1183582. PMID 16061801.
- Hyde WT, Crowley TJ, Baum SK, Peltier WR (May 2000). “Neoproterozoic ‘snowball Earth’ simulations with a coupled climate/ice-sheet model” (PDF). Nature. 405 (6785): 425–9. Bibcode:2000Natur.405..425H. doi:10.1038/35013005. PMID 10839531. S2CID 1672712.
- Chris Clowes (2003). “”Snowball” Scenarios of the Cryogenian”. Paleos: Life through deep time. Archived from the original on 15 June 2009.
- University of Houston-Clear Lake – Disasters Class Notes – Chapter 12: Climate Change sce.uhcl.edu/Pitts/disastersclassnotes/chapter_12_Climate_Change.doc
- Ghienne, Jean-François (January 2003). “Late Ordovician sedimentary environments, glacial cycles, and post-glacial transgression in the Taoudeni Basin, West Africa”. Palaeogeography, Palaeoclimatology, Palaeoecology. 189(3–4): 117–145. doi:10.1016/S0031-0182(02)00635-1.
- Heckel, P.H. (2008). “Pennsylvanian cyclothems in Midcontinent North America as far-ﬁeld effects of waxing and waning of Gondwana ice sheets”. In Fielding, C.R.; Frank, T.D.; Isbell, J.L. (eds.). Resolving the Late Paleozoic Ice Age in Time and Space. pp. 275–290.
- Walker, M.; Johnsen, S.; Rasmussen, S. O.; Popp, T.; Steffensen, J.-P.; Gibbard, P.; Hoek, W.; Lowe, J.; Andrews, J.; Bjo; Cwynar, L. C.; Hughen, K.; Kershaw, P.; Kromer, B.; Litt, T.; Lowe, D. J.; Nakagawa, T.; Newnham, R.; Schwander, J. (2009). “Formal definition and dating of the GSSP (Global Stratotype Section and Point) for the base of the Holocene using the Greenland NGRIP ice core, and selected auxiliary records” (PDF). J. Quaternary Sci. 24 (1): 3–17. Bibcode:2009JQS….24….3W. doi:10.1002/jqs.1227.
- Augustin, L; Barbante, C; Barnes, PRF; Barnola, JM; Bigler, M; Castellano, E; Cattani, O; Chappellaz, J; et al. (2004-06-10). “Eight glacial cycles from an Antarctic ice core” (PDF). Nature. 429 (6992): 623–8. Bibcode:2004Natur.429..623A. doi:10.1038/nature02599. PMID 15190344. S2CID 4342139. Archived from the original (PDF) on June 24, 2009.
- “Next Ice Age Delayed By Rising Carbon Dioxide Levels”. ScienceDaily. 2007. Retrieved 2008-02-28.
- Ewing, M.; Donn, W. L. (1956-06-15). “A Theory of Ice Ages”. Science. 123(3207): 1061–1066. Bibcode:1956Sci…123.1061E. doi:10.1126/science.123.3207.1061. ISSN 0036-8075. PMID 17748617.
- Garrison, Tom (2009). Oceanography: An Invitation to Marine Science(7th ed.). Cengage Learning. p. 582.
- Bryden, H.L.; H.R. Longworth; S.A. Cunningham (2005). “Slowing of the Atlantic meridional overturning circulation at 25° N”. Nature. 438 (7068): 655–657. Bibcode:2005Natur.438..655B. doi:10.1038/nature04385. PMID 16319889. S2CID 4429828.
- Curry, R.; C. Mauritzen (2005). “Dilution of the northern North Atlantic in recent decades”. Science. 308 (5729): 1772–1774. Bibcode:2005Sci…308.1772C. doi:10.1126/science.1109477. PMID 15961666. S2CID 36017668.
- Huddart, David; Stott, Tim A. (2013-04-16). Earth Environments: Past, Present and Future. John Wiley & Sons.
- Bennett, Matthew M.; Glasser, Neil F. (2010-03-29). Glacial Geology: Ice Sheets and Landforms. Wiley.
Another factor is the increased aridity occurring with glacial maxima, which reduces the precipitation available to maintain glaciation. The glacial retreat induced by this or any other process can be amplified by similar inverse positive feedbacks as for glacial advances.
- Black, Richard (9 January 2012). “Carbon emissions ‘will defer Ice Age'”. BBC News. Retrieved 10 August 2012.
- Luthi, Dieter; et al. (2008-03-17). “High-resolution carbon dioxide concentration record 650,000–800,000 years before present” (PDF). Nature. 453 (7193): 379–382. Bibcode:2008Natur.453..379L. doi:10.1038/nature06949. PMID 18480821. S2CID 1382081.
- Ruddiman, W.F.; Kutzbach, J.E. (1991). “Plateau Uplift and Climate Change”. Scientific American. 264 (3): 66–74. Bibcode:1991SciAm.264c..66R. doi:10.1038/scientificamerican0391-66.
- Raymo, Maureen E.; Ruddiman, William F.; Froelich, Philip N. (1988-07-01). “Influence of late Cenozoic mountain building on ocean geochemical cycles”. Geology. 16 (7): 649–653. Bibcode:1988Geo….16..649R. doi:10.1130/0091-7613(1988)016<0649:IOLCMB>2.3.CO;2. ISSN 0091-7613.
- Clark, Peter U.; Dyke, Arthur S.; Shakun, Jeremy D.; Carlson, Anders E.; Clark, Jorie; Wohlfarth, Barbara; Mitrovica, Jerry X.; Hostetler, Steven W. & McCabe, A. Marshall (2009). “The Last Glacial Maximum”. Science. 325(5941): 710–714. Bibcode:2009Sci…325..710C. doi:10.1126/science.1172873. PMID 19661421. S2CID 1324559.
- Lee Hannah, Climate Change Biology, 2nd ed. (Amsterdam: Academic Press, 2014), 23-28.
- Svitil, K.A. (April 1996). “We are all Panamanians”. Discover.—formation of Isthmus of Panama may have started a series of climatic changes that led to evolution of hominids
- Hu, Aixue; Meehl, Gerald A.; Otto-Bliesner, Bette L.; Waelbroeck, Claire; Weiqing Han; Loutre, Marie-France; Lambeck, Kurt; Mitrovica, Jerry X.; Rosenbloom, Nan (2010). “Influence of Bering Strait flow and North Atlantic circulation on glacial sea-level changes” (PDF). Nature Geoscience. 3 (2): 118–121. Bibcode:2010NatGe…3..118H. CiteSeerX 10.1.1.391.8727. doi:10.1038/ngeo729.
- “Melting icebergs key to sequence of an ice age, scientists find”. phys.org. Retrieved 12 February 2021.
- Starr, Aidan; Hall, Ian R.; Barker, Stephen; Rackow, Thomas; Zhang, Xu; Hemming, Sidney R.; van der Lubbe, H. J. L.; Knorr, Gregor; Berke, Melissa A.; Bigg, Grant R.; Cartagena-Sierra, Alejandra; Jiménez-Espejo, Francisco J.; Gong, Xun; Gruetzner, Jens; Lathika, Nambiyathodi; LeVay, Leah J.; Robinson, Rebecca S.; Ziegler, Martin (January 2021). “Antarctic icebergs reorganize ocean circulation during Pleistocene glacials”. Nature. 589(7841): 236–241. doi:10.1038/s41586-020-03094-7. ISSN 1476-4687. PMID 33442043. S2CID 231598435. Retrieved 12 February 2021.
- Kuhle, Matthias (December 1988). “The Pleistocene Glaciation of Tibet and the Onset of Ice Ages — An Autocycle Hypothesis”. GeoJournal. 17 (4): 581–595. doi:10.1007/BF00209444. JSTOR 41144345. S2CID 189891305.
- 2c (Quaternary Glaciation — Extent and Chronology, Part III: South America, Asia, Africa, Australia, AntarcticaKuhle, M. (2004). “The High Glacial (Last Ice Age and LGM) ice cover in High and Central Asia”. In Ehlers, J.; Gibbard, P.L. (eds.). Quaternary Glaciations: South America, Asia, Africa, Australasia, Antarctica. Development in Quaternary Science: Quaternary Glaciations: Extent and Chronology Vol. 3. Amsterdam: Elsevier. pp. 175–199.
- Kuhle, M. (1999). “Reconstruction of an approximately complete Quaternary Tibetan inland glaciation between the Mt. Everest- and Cho Oyu Massifs and the Aksai Chin. A new glaciogeomorphological SE–NW diagonal profile through Tibet and its consequences for the glacial isostasy and Ice Age cycle”. GeoJournal. 47 (1–2): 3–276. doi:10.1023/A:1007039510460. S2CID 128089823.
- Kuhle, M. (2011). “Ice Age Development Theory”. In Singh, V.P.; Singh, P.; Haritashya, U.K. (eds.). Encyclopedia of Snow, Ice and Glaciers. Springer. pp. 576–581.
- “Earth’s orbital variations and sea ice synch glacial periods”.
- “Ice-Age Explanation – Sciforums”. www.sciforums.com.
- Muller, R. A.; MacDonald, G. J. (1997-08-05). “Spectrum of 100-kyr glacial cycle: orbital inclination, not eccentricity”. Proceedings of the National Academy of Sciences of the United States of America. 94 (16): 8329–8334. Bibcode:1997PNAS…94.8329M. doi:10.1073/pnas.94.16.8329. ISSN 0027-8424. PMC 33747. PMID 11607741.
- Richard A. Muller. “A New Theory of Glacial Cycles”. Muller.lbl.gov. Retrieved 2012-08-07.
- Muller, R. A. (1997-07-11). “Glacial Cycles and Astronomical Forcing”. Science. 277 (5323): 215–218. Bibcode:1997Sci…277..215M. doi:10.1126/science.277.5323.215.
- Rial, J.A. (July 1999). “Pacemaking the ice ages by frequency modulation of Earth’s orbital eccentricity” (PDF). Science. 285 (5427): 564–8. doi:10.1126/science.285.5427.564. PMID 10417382. Archived from the original (PDF) on 2008-10-15.
- Huybers, Peter; Wunsch, Carl (2005-03-24). “Obliquity pacing of the late Pleistocene glacial terminations”. Nature. 434 (7032): 491–494. Bibcode:2005Natur.434..491H. doi:10.1038/nature03401. ISSN 1476-4687. PMID 15791252. S2CID 2729178.
- Paillard, D. (22 January 1998). “The timing of Pleistocene glaciations from a simple multiple-state climate model”. Nature. 391 (6665): 378–381. Bibcode:1998Natur.391..378P. doi:10.1038/34891. S2CID 4409193.
- Ditlevsen, P.D. (2009). “Bifurcation structure and noise-assisted transitions in the Pleistocene glacial cycles”. Paleoceanography. 24 (3): PA3204. arXiv:0902.1641. Bibcode:2009PalOc..24.3204D. doi:10.1029/2008PA001673. as PDF
- Guinan, E.F.; Ribas, I. (2002). “Our Changing Sun: The Role of Solar Nuclear Evolution and Magnetic Activity on Earth’s Atmosphere and Climate”. The Evolving Sun and its Influence on Planetary Environments. p. 85.
- Rieke, George. “Long Term Climate”. Retrieved 25 April 2013.
- “PETM: Global Warming, Naturally | Weather Underground”. www.wunderground.com. Archived from the original on 2016-12-02. Retrieved 2016-12-02.
- “Quaternary Period”. National Geographic. 2017-01-06.
- Hallberg, G.R. (1986). “Pre-Wisconsin glacial stratigraphy of the Central Plains region in Iowa, Nebraska, Kansas, and Missouri”. Quaternary Science Reviews. 5: 11–15. Bibcode:1986QSRv….5…11H. doi:10.1016/0277-3791(86)90169-1.
- Richmond, G.M.; Fullerton, D.S. (1986). “Summation of Quaternary glaciations in the United States of America”. Quaternary Science Reviews. 5: 183–196. Bibcode:1986QSRv….5..183R. doi:10.1016/0277-3791(86)90184-8.
- Gibbard, P.L., S. Boreham, K.M. Cohen and A. Moscariello, 2007, Global chronostratigraphical correlation table for the last 2.7 million years v. 2007b., jpg version 844 KB. Subcommission on Quaternary Stratigraphy, Department of Geography, University of Cambridge, Cambridge, England
- Kuhle, M. (1984). “Spuren hocheiszeitlicher Gletscherbedeckung in der Aconcagua-Gruppe (32–33° S)”. Zentralblatt für Geologie und Paläontologie, Teil I. 11/12: 1635–46.
- Kuhle, M. (1986). “Die Vergletscherung Tibets und die Entstehung von Eiszeiten”. Spektrum der Wissenschaft (9/86): 42–54.
- Kuhle, Matthias (June 1987). “Subtropical Mountain- and Highland-Glaciation as Ice Age Triggers and the Waning of the Glacial Periods in the Pleistocene”. GeoJournal. 14 (4): 393–421. doi:10.1007/BF02602717. JSTOR 41144132. S2CID 129366521.
- Kuhle, M. (2004). “The Last Glacial Maximum (LGM) glacier cover of the Aconcagua group and adjacent massifs in the Mendoza Andes (South America)”. In Ehlers, J.; Gibbard, P.L. (eds.). Quaternary Glaciations: South America, Asia, Africa, Australasia, Antarctica. Development in Quaternary Science. Amsterdam: Elsevier. pp. 75–81.
- Kuhle, M. (2011). “Ch 53: The High-Glacial (Last Glacial Maximum) Glacier Cover of the Aconcagua Group and Adjacent Massifs in the Mendoza Andes (South America) with a Closer Look at Further Empirical Evidence”. In Ehlers, J.; Gibbard, P.L.; Hughes, P.D. (eds.). Quaternary Glaciations – Extent and Chronology: A Closer Look. Development in Quaternary Science. Amsterdam: Elsevier. pp. 735–8.
- Brüggen, J. (1929). “Zur Glazialgeologie der chilenischen Anden”. Geol. Rundsch. 20 (1): 1–35. Bibcode:1929GeoRu..20….1B. doi:10.1007/BF01805072. S2CID 128436981.
- Andersen, Bjørn G.; Borns, Harold W. Jr. (1997). The Ice Age World: an introduction to quaternary history and research with emphasis on North America and Northern Europe during the last 2.5 million years. Oslo: Universitetsforlaget. ISBN 978-82-00-37683-5. Archived from the original on 2013-01-12. Retrieved 2013-10-14.
- Johnston, A. (1989). “The effect of large ice sheets on earthquake genesis”. In Gregersen, S.; Basham, P. (eds.). Earthquakes at North-Atlantic passive margins: Neotectonics and postglacial rebound. Dordrecht: Kluwer. pp. 581–599.
- Wu, Patrick; Hasegawa, Henry S. (October 1996). “Induced stresses and fault potential in eastern Canada due to a realistic load: a preliminary analysis”. Geophysical Journal International. 127 (1): 215–229. Bibcode:1996GeoJI.127..215W. doi:10.1111/j.1365-246X.1996.tb01546.x.
- Turpeinen, H.; Hampel, A.; Karow, T.; Maniatis, G. (2008). “Effect of ice sheet growth and melting on the slip evolution of thrust faults”. Earth and Planetary Science Letters. 269 (1–2): 230–241. Bibcode:2008E&PSL.269..230T. doi:10.1016/j.epsl.2008.02.017.
- Hunt, A. G.; Malin, P. E. (May 1998). “Possible triggering of Heinrich events by ice-load-induced earthquakes”. Nature. 393 (6681): 155–158. Bibcode:1998Natur.393..155H. doi:10.1038/30218. ISSN 0028-0836. S2CID 4393858.
Originally published by Wikipedia, 08.20.2001, under a Creative Commons Attribution-ShareAlike 3.0 Unported license.