Milankovitch cycles explained

Milankovitch cycles describe the collective effects of changes in the Earth's movements on its climate over thousands of years. The term was coined and named after the Serbian geophysicist and astronomer Milutin Milanković. In the 1920s, he hypothesized that variations in eccentricity, axial tilt, and precession combined to result in cyclical variations in the intra-annual and latitudinal distribution of solar radiation at the Earth's surface, and that this orbital forcing strongly influenced the Earth's climatic patterns.[1] [2]

Earth movements

The Earth's rotation around its axis, and revolution around the Sun, evolve over time due to gravitational interactions with other bodies in the Solar System. The variations are complex, but a few cycles are dominant.[3]

The Earth's orbit varies between nearly circular and mildly elliptical (its eccentricity varies). When the orbit is more elongated, there is more variation in the distance between the Earth and the Sun, and in the amount of solar radiation, at different times in the year. In addition, the rotational tilt of the Earth (its obliquity) changes slightly. A greater tilt makes the seasons more extreme. Finally, the direction in the fixed stars pointed to by the Earth's axis changes (axial precession), while the Earth's elliptical orbit around the Sun rotates (apsidal precession). The combined effect of precession with eccentricity is that proximity to the Sun occurs during different astronomical seasons.[4]

Milankovitch studied changes in these movements of the Earth, which alter the amount and location of solar radiation reaching the Earth. This is known as solar forcing (an example of radiative forcing). Milankovitch emphasized the changes experienced at 65° north due to the great amount of land at that latitude. Land masses change temperature more quickly than oceans, because of the mixing of surface and deep water and the fact that soil has a lower volumetric heat capacity than water.[5]

Orbital eccentricity

See main article: Orbital eccentricity. The Earth's orbit approximates an ellipse. Eccentricity measures the departure of this ellipse from circularity. The shape of the Earth's orbit varies between nearly circular (theoretically the eccentricity can hit zero) and mildly elliptical (highest eccentricity was 0.0679 in the last 250 million years).[6] Its geometric or logarithmic mean is 0.0019. The major component of these variations occurs with a period of 405,000 years[7] (eccentricity variation of ±0.012). Other components have 95,000-year and 124,000-year cycles[7] (with a beat period of 400,000 years). They loosely combine into a 100,000-year cycle (variation of −0.03 to +0.02). The present eccentricity is 0.0167[7] and decreasing.

Eccentricity varies primarily due to the gravitational pull of Jupiter and Saturn. The semi-major axis of the orbital ellipse, however, remains unchanged; according to perturbation theory, which computes the evolution of the orbit, the semi-major axis is invariant. The orbital period (the length of a sidereal year) is also invariant, because according to Kepler's third law, it is determined by the semi-major axis. Longer-term variations are caused by interactions involving the perihelia and nodes of the planets Mercury, Venus, Earth, Mars, and Jupiter.[6]

Effect on temperature

The semi-major axis is a constant. Therefore, when Earth's orbit becomes more eccentric, the semi-minor axis shortens. This increases the magnitude of seasonal changes.[8]

The relative increase in solar irradiation at closest approach to the Sun (perihelion) compared to the irradiation at the furthest distance (aphelion) is slightly larger than four times the eccentricity. For Earth's current orbital eccentricity, incoming solar radiation varies by about 6.8%, while the distance from the Sun currently varies by only 3.4% (5.1abbr=unitNaNabbr=unit).[9]

Perihelion presently occurs around 3 January, while aphelion is around 4 July. When the orbit is at its most eccentric, the amount of solar radiation at perihelion will be about 23% more than at aphelion. However, the Earth's eccentricity is so small (at least at present) that the variation in solar irradiation is a minor factor in seasonal climate variation, compared to axial tilt and even compared to the relative ease of heating the larger land masses of the northern hemisphere.[10]

Effect on lengths of seasons

Season durations[11]
YearNorthern
hemisphere
Southern
hemisphere
Date (UTC)Season
duration
2005Winter solsticeSummer solstice21 December 2005 18:3588.99 days
2006Spring equinoxAutumn equinox20 March 2006 18:2692.75 days
2006Summer solsticeWinter solstice21 June 2006 12:2693.65 days
2006Autumn equinoxSpring equinox23 September 2006 4:0389.85 days
2006Winter solsticeSummer solstice22 December 2006 0:2288.99 days
2007Spring equinoxAutumn equinox21 March 2007 0:0792.75 days
2007Summer solsticeWinter solstice21 June 2007 18:0693.66 days
2007Autumn equinoxSpring equinox23 September 2007 9:5189.85 days
2007Winter solsticeSummer solstice22 December 2007 06:08 

The seasons are quadrants of the Earth's orbit, marked by the two solstices and the two equinoxes. Kepler's second law states that a body in orbit traces equal areas over equal times; its orbital velocity is highest around perihelion and lowest around aphelion. The Earth spends less time near perihelion and more time near aphelion. This means that the lengths of the seasons vary. Perihelion currently occurs around 3 January, so the Earth's greater velocity shortens winter and autumn in the northern hemisphere. Summer in the northern hemisphere is 4.66 days longer than winter, and spring is 2.9 days longer than autumn. Greater eccentricity increases the variation in the Earth's orbital velocity. Currently, however, the Earth's orbit is becoming less eccentric (more nearly circular). This will make the seasons in the immediate future more similar in length.

Axial tilt (obliquity)

See main article: Axial tilt. The angle of the Earth's axial tilt with respect to the orbital plane (the obliquity of the ecliptic) varies between 22.1° and 24.5°, over a cycle of about 41,000 years. The current tilt is 23.44°, roughly halfway between its extreme values. The tilt last reached its maximum in 8,700 BC, which correlates with the beginning of the Holocene, the current geological epoch. It is now in the decreasing phase of its cycle, and will reach its minimum around the year 11,800 AD. Increased tilt increases the amplitude of the seasonal cycle in insolation, providing more solar radiation in each hemisphere's summer and less in winter. However, these effects are not uniform everywhere on the Earth's surface. Increased tilt increases the total annual solar radiation at higher latitudes, and decreases the total closer to the equator.[12]

The current trend of decreasing tilt, by itself, will promote milder seasons (warmer winters and colder summers), as well as an overall cooling trend.[12] Because most of the planet's snow and ice lies at high latitude, decreasing tilt may encourage the termination of an interglacial period and the onset of a glacial period for two reasons: 1) there is less overall summer insolation, and 2) there is less insolation at higher latitudes (which melts less of the previous winter's snow and ice).[12]

Axial precession

See main article: Axial precession. Axial precession is the trend in the direction of the Earth's axis of rotation relative to the fixed stars, with a period of about 25,700 years. Also known as the precession of the equinoxes, this motion means that eventually Polaris will no longer be the north pole star. This precession is caused by the tidal forces exerted by the Sun and the Moon on the rotating Earth; both contribute roughly equally to this effect.

Currently, perihelion occurs during the southern hemisphere's summer. This means that solar radiation due to both the axial tilt inclining the southern hemisphere toward the Sun, and the Earth's proximity to the Sun, will reach maximum during the southern summer and reach minimum during the southern winter. These effects on heating are thus additive, which means that seasonal variation in irradiation of the southern hemisphere is more extreme. In the northern hemisphere, these two factors reach maximum at opposite times of the year: the north is tilted toward the Sun when the Earth is furthest from the Sun. The two effects work in opposite directions, resulting in less extreme variations in insolation.

In about 10,000 years, the north pole will be tilted toward the Sun when the Earth is at perihelion. Axial tilt and orbital eccentricity will both contribute their maximum increase in solar radiation during the northern hemisphere's summer. Axial precession will promote more extreme variation in irradiation of the northern hemisphere and less extreme variation in the south. When the Earth's axis is aligned such that aphelion and perihelion occur near the equinoxes, axial tilt will not be aligned with or against eccentricity.

Apsidal precession

See main article: Apsidal precession.

The orbital ellipse itself precesses in space, in an irregular fashion, completing a full cycle in about 112,000 years relative to the fixed stars.[13] Apsidal precession occurs in the plane of the ecliptic and alters the orientation of the Earth's orbit relative to the ecliptic. This happens primarily as a result of interactions with Jupiter and Saturn. Smaller contributions are also made by the sun's oblateness and by the effects of general relativity that are well known for Mercury.[14]

Apsidal precession combines with the 25,700-year cycle of axial precession (see above) to vary the position in the year that the Earth reaches perihelion. Apsidal precession shortens this period to about 21,000 years, at present. According to a relatively old source (1965), the average value over the last 300,000 years was 23,000 years, varying between 20,800 and 29,000 years.[13]

As the orientation of Earth's orbit changes, each season will gradually start earlier in the year. Precession means the Earth's nonuniform motion (see above) will affect different seasons. Winter, for instance, will be in a different section of the orbit. When the Earth's apsides (extremes of distance from the sun) are aligned with the equinoxes, the length of spring and summer combined will equal that of autumn and winter. When they are aligned with the solstices, the difference in the length of these seasons will be greatest.

Orbital inclination

See main article: Orbital inclination.

The inclination of Earth's orbit drifts up and down relative to its present orbit. This three-dimensional movement is known as "precession of the ecliptic" or "planetary precession". Earth's current inclination relative to the invariable plane (the plane that represents the angular momentum of the Solar System—approximately the orbital plane of Jupiter) is 1.57°. Milankovitch did not study planetary precession. It was discovered more recently and measured, relative to Earth's orbit, to have a period of about 70,000 years. When measured independently of Earth's orbit, but relative to the invariable plane, however, precession has a period of about 100,000 years. This period is very similar to the 100,000-year eccentricity period. Both periods closely match the 100,000-year pattern of glacial events.[15]

Theory constraints

Materials taken from the Earth have been studied to infer the cycles of past climate. Antarctic ice cores contain trapped air bubbles whose ratios of different oxygen isotopes are a reliable proxy for global temperatures around the time the ice was formed. Study of this data concluded that the climatic response documented in the ice cores was driven by northern hemisphere insolation as proposed by the Milankovitch hypothesis.[16] Similar astronomical hypotheses had been advanced in the 19th century by Joseph Adhemar, James Croll, and others.[17]

Analysis of deep-ocean cores and of lake depths,[18] [19] and a seminal paper by Hays, Imbrie, and Shackleton[20] provide additional validation through physical evidence. Climate records contained in a core of rock drilled in Arizona show a pattern synchronized with Earth's eccentricity, and cores drilled in New England match it, going back 215 million years.[21]

100,000-year issue

See main article: 100,000-year problem.

Of all the orbital cycles, Milankovitch believed that obliquity had the greatest effect on climate, and that it did so by varying the summer insolation in northern high latitudes. Therefore, he deduced a 41,000-year period for ice ages.[22] [23] However, subsequent research[20] [24] [25] has shown that ice age cycles of the Quaternary glaciation over the last million years have been at a period of 100,000 years, which matches the eccentricity cycle. Various explanations for this discrepancy have been proposed, including frequency modulation or various feedbacks (from carbon dioxide, or ice sheet dynamics). Some models can reproduce the 100,000-year cycles as a result of non-linear interactions between small changes in the Earth's orbit and internal oscillations of the climate system.[26] [27] In particular, the mechanism of the stochastic resonance was originally proposed in order to describe this interaction.[28] [29]

Jung-Eun Lee of Brown University proposes that precession changes the amount of energy that Earth absorbs, because the southern hemisphere's greater ability to grow sea ice reflects more energy away from Earth. Moreover, Lee says, "Precession only matters when eccentricity is large. That's why we see a stronger 100,000-year pace than a 21,000-year pace."[30] [31] Some others have argued that the length of the climate record is insufficient to establish a statistically significant relationship between climate and eccentricity variations.[32]

Transition changes

See main article: Mid-Pleistocene Transition.

From 1–3 million years ago, climate cycles matched the 41,000-year cycle in obliquity. After one million years ago, the Mid-Pleistocene Transition (MPT) occurred with a switch to the 100,000-year cycle matching eccentricity. The transition problem refers to the need to explain what changed one million years ago.[33] The MPT can now be reproduced in numerical simulations that include a decreasing trend in carbon dioxide and glacially induced removal of regolith.[34]

Interpretation of unsplit peak variances

Even the well-dated climate records of the last million years do not exactly match the shape of the eccentricity curve. Eccentricity has component cycles of 95,000 and 125,000 years. Some researchers, however, say the records do not show these peaks, but only indicate a single cycle of 100,000 years.[35] The split between the two eccentricity components, however, is observed at least once in a drill core from the 500-million year-old Scandinavian Alum Shale.[36]

Unsynced stage five observation

Deep-sea core samples show that the interglacial interval known as marine isotope stage 5 began 130,000 years ago. This is 10,000 years before the solar forcing that the Milankovitch hypothesis predicts. (This is also known as the causality problem because the effect precedes the putative cause.)[37]

Present and future conditions

Since orbital variations are predictable,[38] any model that relates orbital variations to climate can be run forward to predict future climate, with two caveats: the mechanism by which orbital forcing influences climate is not definitive; and non-orbital effects can be important (for example, the human impact on the environment principally increases greenhouse gases resulting in a warmer climate[39] [40] [41]).

An often-cited 1980 orbital model by Imbrie predicted "the long-term cooling trend that began some 6,000 years ago will continue for the next 23,000 years."[42] Another work[43] suggests that solar insolation at 65° N will reach a peak of 460 W·m−2 in around 6,500 years, before decreasing back to current levels (450 W·m−2)[44] in around 16,000 years. Earth's orbit will become less eccentric for about the next 100,000 years, so changes in this insolation will be dominated by changes in obliquity, and should not decline enough to permit a new glacial period in the next 50,000 years.[45] [46]

Other celestial bodies

Mars

Since 1972, speculation sought a relationship between the formation of Mars' alternating bright and dark layers in the polar layered deposits, and the planet's orbital climate forcing. In 2002, Laska, Levard, and Mustard showed ice-layer radiance, as a function of depth, correlate with the insolation variations in summer at the Martian north pole, similar to palaeoclimate variations on Earth. They also showed Mars' precession had a period of about 51 kyr, obliquity had a period of about 120 kyr, and eccentricity had a period ranging between 95 and 99 kyr. In 2003, Head, Mustard, Kreslavsky, Milliken, and Marchant proposed Mars was in an interglacial period for the past 400 kyr, and in a glacial period between 400 and 2100 kyr, due to Mars' obliquity exceeding 30°. At this extreme obliquity, insolation is dominated by the regular periodicity of Mars' obliquity variation.[47] [48] Fourier analysis of Mars' orbital elements, show an obliquity period of 128 kyr, and a precession index period of 73 kyr.[49] [50]

Mars has no moon large enough to stabilize its obliquity, which has varied from 10 to 70 degrees. This would explain recent observations of its surface compared to evidence of different conditions in its past, such as the extent of its polar caps.[51] [52]

Outer Solar system

Saturn's moon Titan has a cycle of approximately 60,000 years that could change the location of the methane lakes.[53] Neptune's moon Triton has a variation similar to Titan's, which could cause its solid nitrogen deposits to migrate over long time scales.[54]

Exoplanets

Scientists using computer models to study extreme axial tilts have concluded that high obliquity could cause extreme climate variations, and while that would probably not render a planet uninhabitable, it could pose difficulty for land-based life in affected areas. Most such planets would nevertheless allow development of both simple and more complex lifeforms.[55] Although the obliquity they studied is more extreme than Earth ever experiences, there are scenarios 1.5 to 4.5 billion years from now, as the Moon's stabilizing effect lessens, where obliquity could leave its current range and the poles could eventually point almost directly at the Sun.[56]

Bibliography

External links

Notes and References

  1. Kerr . Richard A. . 14 July 1978 . Climate Control: How Large a Role for Orbital Variations? . Science . 201 . 4351 . 144–146 . 10.1126/science.201.4351.144 . 1746691 . 17801827 . 1978Sci...201..144K . 29 July 2022.
  2. Web site: Why Milankovitch (Orbital) Cycles Can't Explain Earth's Current Warming . Buis . Alan . 27 February 2020 . NASA . 29 July 2022.
  3. Master of Science . A Computational Study on the Evolution of the Dynamics of the Obliquity of the Earth . https://archive.today/20140930142332/https://etd.ohiolink.edu/ap/10?6433295551748::NO:10:P10_ETD_SUBID:56397 . dead . 30 September 2014 . PDF . Girkin AM . 2005 . Miami University .
  4. . . February–March 1895 . Sedimentary Measurement of Cretaceous Time . . 3 . 2 . 121–127 . 10.1086/607150 . 30054556 . 1895JG......3..121G . 129629329 . As the earth's axis slowly describes its circle on the celestial sphere the relation of the seasons to perihelion is steadily shifted. . Note: It is intuitive that if equinoxes and solstices occur in shifting positions on an eccentric orbit, then these astronomical seasons must occur at shifting proximities; and as either eccentricity and tilt vary, the intensities of the effects of these shifts also vary.'l
  5. 86 . 1 . 97–102 . 2020 . Thermal Properties of Soils as affected by Density and Water Content . Abu-Hamdeh . Biosystems Engineering. 10.1016/S1537-5110(03)00112-0 . Volumetric heat capacity ranged from 1.48 to 3.54 MJ/m3/°C for clay and from 1.09 to 3.04 MJ/m3/°C for sand at moisture contents from 0 to 0·25 (kg/kg) [etc.] . 16 May 2021 . Note: See Table of specific heat capacities; water is about 4.2 MJ/m3/°C.
  6. Laskar J, Fienga A, Gastineau M, Manche H . La2010: A New Orbital Solution for the Long-term Motion of the Earth . Astronomy & Astrophysics. 2011. 532. A889. 10.1051/0004-6361/201116836 . 2011A&A...532A..89L . A89. 1103.1084. 10990456. See specifically the downloadable data file.
  7. Laskar2020
  8. Berger A, Loutre MF, Mélice JL . Equatorial insolation: from precession harmonics to eccentricity frequencies. Climate of the Past Discussions. 2 . 519–533. 2006. 10.5194/cpd-2-519-2006. 4. free.
  9. Web site: Buis . Alan . Milankovitch (Orbital) Cycles and Their Role in Earth's Climate . NASA's Jet Propulsion Laboratory . February 27, 2020 . 8 January 2024.
  10. Web site: Buis . Alan . Milankovitch (Orbital) Cycles and Their Role in Earth's Climate . NASA's Jet Propulsion Laboratory . February 27, 2020 . 8 January 2024.
  11. Data from United States Naval Observatory
  12. Web site: climate.nasa.gov . 27 February 2020 . . 10 May 2021. Milankovitch (Orbital) Cycles and Their Role in Earth's Climate. Alan . Buis . . Over the last million years, it has varied between 22.1 and 24.5 degrees. ... The greater Earth's axial tilt angle, the more extreme our seasons are .... Larger tilt angles favor periods of deglaciation (the melting and retreat of glaciers and ice sheets). These effects aren't uniform globally – higher latitudes receive a larger change in total solar radiation than areas closer to the equator. ... Earth's axis is currently tilted 23.4 degrees, ... As ice cover increases, it reflects more of the Sun's energy back into space, promoting even further cooling. . Note: See Axial tilt. Zero obliquity results in minimum (zero) continuous insolation at the poles and maximum continuous insolation at the equator. Any increase of obliquity (to 90 degrees) causes seasonal increase of insolation at the poles and causes decrease of insolation at the equator on any day of the year except an equinox.
  13. van den Heuvel EP . On the Precession as a Cause of Pleistocene Variations of the Atlantic Ocean Water Temperatures. Geophysical Journal International. 1966. 11. 3. 323–336. 1966GeoJ...11..323V . 10.1111/j.1365-246X.1966.tb03086.x . free. Note: The reader may question the number and precision of the periods which the author reports in this early paper.
  14. Barbieri . L. . Talamucci . F. . 1802.07115 . Calculation of Apsidal Precession via Perturbation Theory . Advances in Astrophysics . 20 February 2018. 4 . 3 . 10.22606/adap.2019.43003 . 67784452 .
  15. Muller RA, MacDonald GJ . 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 . 8329–34 . August 1997 . 11607741 . 33747 . 10.1073/pnas.94.16.8329 . 1997PNAS...94.8329M . free .
  16. Kawamura K, Parrenin F, Lisiecki L, Uemura R, Vimeux F, Severinghaus JP, Hutterli MA, Nakazawa T, Aoki S, Jouzel J, Raymo ME, Matsumoto K, Nakata H, Motoyama H, Fujita S, Goto-Azuma K, Fujii Y, Watanabe O . 6 . Northern Hemisphere forcing of climatic cycles in Antarctica over the past 360,000 years . Nature . 448 . 7156 . 912–6 . August 2007 . 17713531 . 10.1038/nature06015 . 1784780 . 2007Natur.448..912K .
  17. Book: Imbrie . John . Imbrie . Katherine Palmer . Ice Ages . Macmillan Education UK . London . 1979 . 978-1-349-04701-7 . 10.1007/978-1-349-04699-7 . 29 July 2024 .
  18. Kerr RA . Milankovitch Climate Cycles Through the Ages: Earth's orbital variations that bring on ice ages have been modulating climate for hundreds of millions of years . Science . 235 . 4792 . 973–4 . February 1987 . 17782244 . 10.1126/science.235.4792.973 . 1987Sci...235..973K . 1698758 . /O
  19. Olsen PE . A 40-million-year lake record of early mesozoic orbital climatic forcing . Science . 234 . 4778 . 842–8 . November 1986 . 17758107 . 10.1126/science.234.4778.842 . 37659044 . 1986Sci...234..842O . 1698087 .
  20. Hays JD, Imbrie J, Shackleton NJ . Variations in the Earth's Orbit: Pacemaker of the Ice Ages . Science . 194 . 4270 . 1121–32 . December 1976 . 17790893 . 10.1126/science.194.4270.1121 . 667291 . 1976Sci...194.1121H . John Imbrie . Nicholas Shackleton . James D. Hays .
  21. News: Every 202,500 Years, Earth Wanders in a New Direction. Bakalar N . The New York Times. 21 May 2018. 25 May 2018.
  22. Book: Milankovitch M . Canon of Insolation and the Ice Age Problem. 1941. 1998. Zavod za Udz̆benike i Nastavna Sredstva . Belgrade . 978-86-17-06619-0.
    see also Web site: Astronomical Theory of Climate Change.
  23. Book: Imbrie J, Imbrie KP . Ice Ages: Solving the Mystery . 1986 . Harvard University Press . 978-0-674-44075-3 . 158.
  24. Shackleton NJ, Berger A, Peltier WR . William Richard Peltier. An alternative astronomical calibration of the lower Pleistocene timescale based on ODP Site 677. Transactions of the Royal Society of Edinburgh: Earth Sciences. 3 November 2011. 81. 4. 251–261. 10.1017/S0263593300020782. 129842704.
  25. Abe-Ouchi A, Saito F, Kawamura K, Raymo ME, Okuno J, Takahashi K, Blatter H . Insolation-driven 100,000-year glacial cycles and hysteresis of ice-sheet volume . Nature . 500 . 7461 . 190–3 . August 2013 . 23925242 . 10.1038/nature12374 . 4408240 . 2013Natur.500..190A .
  26. Ghil M . Michael Ghil. Cryothermodynamics: the chaotic dynamics of paleoclimate. Physica D. 77. 1–3. 1994. 130–159. 10.1016/0167-2789(94)90131-7. 1994PhyD...77..130G .
  27. Gildor H, Tziperman E . Sea ice as the glacial cycles' climate switch: Role of seasonal and orbital forcing. Paleoceanography. 15. 6. 2000. 605–615. 10.1029/1999PA000461. 2000PalOc..15..605G. free.
  28. Benzi . R . Sutera . A . Vulpiani . A . 1 November 1981 . The mechanism of stochastic resonance . Journal of Physics A: Mathematical and General . 14 . 11 . L453–L457 . 10.1088/0305-4470/14/11/006 . 1981JPhA...14L.453B . 123005407 . 0305-4470. free .
  29. Benzi . Roberto . Parisi . Giorgio . Giorgio Parisi . Sutera . Alfonso . Vulpiani . Angelo . February 1982 . Stochastic resonance in climatic change . Tellus . en . 34 . 1 . 10–16 . 10.1111/j.2153-3490.1982.tb01787.x. 1982Tell...34...10B .
  30. Web site: Earth's orbital variations and sea ice synch glacial periods . Stacey K . m.phys.org . 26 January 2017.
  31. Hemispheric sea ice distribution sets the glacial tempo. Lee JE, Shen A, Fox-Kemper B, Ming Y . 1 January 2017. Geophys. Res. Lett.. 1008–1014 . 10.1002/2016GL071307. 44. 2. 2017GeoRL..44.1008L. free.
  32. Wunsch C . Quantitative estimate of the Milankovitch-forced contribution to observed Quaternary climate change. Quaternary Science Reviews. 23. 2004. 1001–12. 10.1016/j.quascirev.2004.02.014. 9–10. 2004QSRv...23.1001W .
  33. Zachos JC, Shackleton NJ, Revenaugh JS, Pälike H, Flower BP . Climate response to orbital forcing across the Oligocene-Miocene boundary . Science . 292 . 5515 . 274–8 . April 2001 . 11303100 . 10.1126/science.1058288 . 24 October 2010 . dead . 38231747 . 2001Sci...292..274Z . https://web.archive.org/web/20171203224507/http://scencemag.org/cgi/pmidlookup?view=long&pmid=11303100 . 3 December 2017 .
  34. Willeit M, Ganopolski A, Calov R, Brovkin V . Mid-Pleistocene transition in glacial cycles explained by declining CO2 and regolith removal . Science Advances . 5 . 4 . eaav7337 . April 2019 . 30949580 . 6447376 . 10.1126/sciadv.aav7337 . 2019SciA....5.7337W .
  35. Web site: Nonlinear coupling between 100 ka periodicity of the paleoclimate records in loess and periodicities of precession and semi-precession. ProQuest.
  36. Sørensen, A.L., Nielsen, A.T., Thibault, N., Zhao, Z., Schovsbo, N.H., Dahl, T.W., 2020. Astronomically forced climate change in the late Cambrian. Earth Planet. Sci. Lett. 548, 116475. https://doi.org/10.1016/j.epsl.2020.116475
  37. Karner DB, Muller RA . PALEOCLIMATE: A Causality Problem for Milankovitch . Science . 288 . 5474 . 2143–4 . June 2000 . 17758906 . 10.1126/science.288.5474.2143 . 9873679 .
  38. Varadi F, Runnegar B, Ghil M . Michael Ghil . Successive Refinements in Long-Term Integrations of Planetary Orbits . The Astrophysical Journal . 592 . 1 . 2003 . 620–630 . 10.1086/375560 . 2003ApJ...592..620V . free .
  39. Kaufman DS, Schneider DP, McKay NP, Ammann CM, Bradley RS, Briffa KR, Miller GH, Otto-Bliesner BL, Overpeck JT, Vinther BM . 6 . Recent warming reverses long-term arctic cooling . Science . 325 . 5945 . 1236–9 . September 2009 . 19729653 . 10.1126/science.1173983 . 23844037 . 10.1.1.397.8778 . 2009Sci...325.1236K .
  40. Web site: Arctic Warming Overtakes 2,000 Years of Natural Cooling . UCAR . 3 September 2009 . 19 May 2011 . dead . https://web.archive.org/web/20110427235538/http://www2.ucar.edu/news/846/arctic-warming-overtakes-2000-years-natural-cooling . 27 April 2011 .
  41. News: Bello D . Global Warming Reverses Long-Term Arctic Cooling . Scientific American . 4 September 2009 . 19 May 2011 .
  42. Imbrie J, Imbrie JZ . Modeling the climatic response to orbital variations . Science . 207 . 4434 . 943–53 . February 1980 . 17830447 . 10.1126/science.207.4434.943 . 7317540 . 1980Sci...207..943I .
  43. Mukherjee . Pami . Sinha . Nitesh . Chakraborty . Supriyo . 2017-07-10 . Investigating the dynamical behavior of the Intertropical Convergence Zone since the last glacial maximum based on terrestrial and marine sedimentary records . Quaternary International . Third Pole: The Last 20,000 Years - Part 1 . en . 443 . 49–57 . 10.1016/j.quaint.2016.08.030 . 2017QuInt.443...49M . 1040-6182.
  44. Web site: Energy resources: solar energy . 2023-06-17 . Energy resources: solar energy . en .
  45. Berger A, Loutre MF . Climate. An exceptionally long interglacial ahead? . Science . 297 . 5585 . 1287–8 . August 2002 . 12193773 . 10.1126/science.1076120 . 128923481 .
  46. Ganopolski A, Winkelmann R, Schellnhuber HJ . Critical insolation-CO2 relation for diagnosing past and future glacial inception . Nature . 529 . 7585 . 200–3 . January 2016 . 26762457 . 10.1038/nature16494 . 4466220 . 2016Natur.529..200G .
  47. John F. Mustard . Laskar J, Levrard B, Mustard JF . Orbital forcing of the martian polar layered deposits . Nature . 419 . 6905 . 375–7 . September 2002 . 12353029 . 10.1038/nature01066 . 2002Natur.419..375L . 4380705 . 11 December 2020 . 19 July 2011 . https://web.archive.org/web/20110719160258/http://www.planetary.brown.edu/pdfs/2839.pdf . dead .
  48. Head JW, Mustard JF, Kreslavsky MA, Milliken RE, Marchant DR . Recent ice ages on Mars . Nature . 426 . 6968 . 797–802 . December 2003 . 14685228 . 10.1038/nature02114 . 2003Natur.426..797H . 2355534 .
  49. Brzostowski M . Martian Milankovic Cycles, a Constraint for Understanding Martian Geology? . Western Pacific Geophysics Meeting, Supplement to Eos, Transactions, American Geophysical Union . 2004 . 85 . 28 . WP11.
  50. Web site: Brzostowski M . Milankovic Cycles on Mars and the Impact on Economic Exploration . ACE 2020 . American Association of Petroleum Geologists . 11 December 2020 . 2020.
  51. 2008GeoRL..3518201S. Temperature response of Mars to Milankovitch cycles. Geophysical Research Letters. 35. 18. L18201. Schorghofer N . 16598911. 2008. 10.1029/2008GL034954.
  52. Web site: 3.5 Modeling Milankovitch cycles on Mars (2010 – 90; Annual Symp Planet Atmos). Confex.
  53. Web site: Lake Asymmetry on Titan Explained. Wethington . Nicholos . 30 November 2009.
  54. Web site: Sun Blamed for Warming of Earth and Other Worlds. LiveScience.com. 12 March 2007.
  55. Williams DM, Pollard P. Earth-like worlds on eccentric orbits: excursions beyond the habitable zone. Inter. J. Astrobio.. 1. 1. 21–9. 2002. 10.1017/s1473550402001064. 2002IJAsB...1...61W. 37593615. 17 September 2009. 22 August 2013. https://web.archive.org/web/20130822060604/http://physics.bd.psu.edu/faculty/williams/3DEarthClimate/ija2003.pdf. dead.
  56. Neron de Surgy O, Laskar J . On the long term evolution of the spin of the Earth . Astronomy and Astrophysics . 318 . 975–989 . February 1997 . 1997A&A...318..975N .