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 the European Project for Ice Coring in Antarctica (EPICA) Dome C in Antarctica over the past 800,000 years); changes in 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 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 ).
Maureen Raymo,
William Ruddiman and others propose that the
Tibetan and
Colorado Plateaus are immense "scrubbers" with a capacity to remove enough 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 "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 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 . The hypothesis also warns of future Snowball Earths. In 2009, further evidence was provided that changes in solar
insolation provide the initial trigger for 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. Analyses suggest that ocean current fluctuations can adequately account for recent glacial oscillations. During the last glacial period the sea-level fluctuated 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 metres – 165 feet – 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 four to five 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 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 Earth's
axis, and the changing tilt of Earth's axis redistribute the sunlight received by Earth. Of particular importance are changes in the tilt of 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 may explain this mismatch. While Milankovitch forcing predicts that cyclic changes in 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 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 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.
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 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 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.
Volcanism 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==