The 100,000-year problem (also 100 ky problem or 100 ka problem) of the Milankovitch theory of orbital forcing refers to a discrepancy between the reconstructed geologic temperature record and the reconstructed amount of incoming solar radiation, or insolation over the past 800,000 years.[1] Due to variations in the Earth's orbit, the amount of insolation varies with periods of around 21,000, 40,000, 100,000, and 400,000 years. Variations in the amount of incident solar energy drive changes in the climate of the Earth, and are recognised as a key factor in the timing of initiation and termination of glaciations.

δ18O, a proxy for temperature, for the last 600,000 years (an average from several deep sea sediment carbonate samples)[a]

While there is a Milankovitch cycle in the range of 100,000 years, related to Earth's orbital eccentricity, its contribution to variation in insolation is much smaller than those of precession and obliquity. The 100,000-year problem refers to the lack of an obvious explanation for the periodicity of ice ages at roughly 100,000 years for the past million years, but not before, when the dominant periodicity corresponded to 41,000 years. The unexplained transition between the two periodicity regimes is known as the Mid-Pleistocene Transition, dated to some 800,000 years ago.

The related 400,000-year problem refers to the absence of a 400,000-year periodicity due to orbital eccentricity in the geological temperature record over the past 1.2 million years.[2]

The transition in periodicity from 41,000 years to 100,000 years can now be reproduced in numerical simulations that include a decreasing trend in carbon dioxide and glacially induced removal of regolith, as explained in more detail in the article Mid-Pleistocene Transition.[3]

Recognition of the 100,000-year cycle

edit
 
A δ18O record for the past 140,000 years from Greenland (NGRIP) and Antarctica (EPICA, Vostok) ice cores

The geologic temperature record can be reconstructed from sedimentary evidence. Perhaps the most useful paleotemperature indicator of past climate is the fractionation of oxygen isotopes, denoted δ18O. This fractionation is controlled mainly by the amount of water locked up in ice and the absolute temperature of the planet and has allowed a timescale of marine isotope stages to be constructed.

By the late 1990s, δ18O records of air (in the Vostok ice core) and marine sediments were available and were compared with estimates of insolation, which should affect both temperature and ice volume. As described by Shackleton (2000), the deep-sea sediment record of δ18O "is dominated by a 100,000-year cyclicity that is universally interpreted as the main ice-age rhythm". Shackleton (2000) adjusted the time scale of the Vostok ice core δ18O record to fit the assumed orbital forcing and used spectral analysis to identify and subtract the component of the record that in this interpretation could be attributed to a linear (directly proportional) response to the orbital forcing. The residual signal (the remainder), when compared with the residual from a similarly retuned marine core isotope record, was used to estimate the proportion of the signal that was attributable to ice volume, with the rest (having attempted to allow for the Dole effect) being attributed to temperature changes in the deep water.

The 100,000-year component of ice volume variation was found to match sea level records based on coral age determinations, and to lag orbital eccentricity by several thousand years, as would be expected if orbital eccentricity were the pacing mechanism. Strong non-linear "jumps" in the record appear at deglaciations, although the 100,000-year periodicity was not the strongest periodicity in this "pure" ice volume record.

The separate deep sea temperature record was found to vary directly in phase with orbital eccentricity, as did the Antarctic temperature and CO2; so eccentricity appears to exert a geologically immediate effect on air temperatures, deep-sea temperatures, and atmospheric carbon dioxide concentrations. Shackleton (2000) concluded: "The effect of orbital eccentricity probably enters the paleoclimatic record through an influence on the concentration of atmospheric CO2".[4]

Elkibbi and Rial (2001) identified the 100 ka cycle as one of five main challenges met by the Milankovitch model of orbital forcing of the ice ages.[5]

Hypotheses to explain the problem

edit
 
The effect of obliquity variations may, in concert with precession, be amplified by orbital inclination.

As the 100,000-year periodicity only dominates the climate of the past million years, there is insufficient information to separate the component frequencies of eccentricity using spectral analysis, making the reliable detection of significant longer-term trends more difficult, although the spectral analysis of much longer palaeoclimate records, such as the Lisiecki and Raymo stack of marine cores[6] and James Zachos' composite isotopic record, helps to put the last million years in a longer-term context. Hence there is still no clear proof of the mechanism responsible for the 100 ka periodicity—but there are several credible hypotheses.

Climatic resonance

edit

The mechanism may be internal to the Earth system. The Earth's climate system may have a natural resonance frequency of 100 ka; that is to say, feedback processes within the climate automatically produce a 100 ka effect, much as a bell naturally rings at a certain pitch.[7][8] Opponents to this claim point out that the resonance would have to have developed 1 million years ago, as a 100 ka periodicity was weak to non-existent for the preceding 2 million years. This is feasible—continental drift and sea floor spreading rate change have been postulated as possible causes of such a change.[9] Free oscillations of components of the Earth system have been considered as a cause,[10] but too few Earth systems have thermal inertia on a thousand-year timescale for any long-term changes to accumulate. The most common hypothesis looks to the Northern Hemisphere ice sheets, which might expand through a few shorter cycles until large enough to undergo a sudden collapse.[11] The 100,000-year problem has been scrutinized by José A. Rial, Jeseung Oh and Elizabeth Reischmann[12] who find that master-slave synchronization between the climate system's natural frequencies and the eccentricity forcing started the 100 ky ice ages of the late Pleistocene and explain their large amplitude.

Orbital inclination

edit
 
Precessional cycles may produce a 100,000-year effect.

Orbital inclination has a 100 ka periodicity, while eccentricity's 95 and 125ka periods could inter-react to give a 108ka effect. While it is possible that the less significant, and originally overlooked, inclination variability has a deep effect on climate,[13] the eccentricity only modifies insolation by a small amount: 1–2% of the shift caused by the 21,000-year precession and 41,000-year obliquity cycles. Such a big impact from inclination would therefore be disproportionate in comparison to other cycles.[9] One possible mechanism suggested to account for this was the passage of Earth through regions of cosmic dust. Our eccentric orbit would take us through dusty clouds in space, which would act to occlude some of the incoming radiation, shadowing the Earth.[13]

In such a scenario, the abundance of the isotope 3He, produced by solar rays splitting gases in the upper atmosphere, would be expected to decrease—and initial investigations did indeed find such a drop in 3He abundance.[14][15] Others have argued possible effects from the dust entering the atmosphere itself, for example by increasing cloud cover (on 9 July and 9 January, when the Earth passes through the invariable plane, mesospheric cloud increases).[16] Therefore, the 100 ka eccentricity cycle can act as a "pacemaker" to the system, amplifying the effect of precession and obliquity cycles at key moments, with its perturbation.[17]

Precession cycles

edit

A similar suggestion holds the 21,636-year[failed verification] precession cycles solely responsible. Ice ages are characterized by the slow buildup of ice volume, followed by relatively swift melting phases. It is possible that ice built up over several precession cycles, only melting after four or five such cycles.[18]

Dust and albedo

edit

It has been suggested that ice-sheet albedo and dust are responsible. The high albedo of northern ice sheets will resist climatic warming from Milankovitch maxima unless they are covered in dust. Dust episodes occur just before each interglacial warming period, and it is claimed that the resulting reduced albedo of northern ice sheets assists in interglacial warming. Dust episodes are said to be caused by low atmospheric CO2 creating CO2-deserts in northern China upland areas, with the resulting dust creating the Loess Plateau and coating the northern ice sheets.[19]

Solar luminosity fluctuation

edit

A mechanism that may account for periodic fluctuations in solar luminosity has also been proposed as an explanation. Diffusion waves occurring within the Sun can be modeled in such a way that they explain the observed climatic shifts on Earth.[20]

Land vs. oceanic photosynthesis

edit
 
An algal bloom. The relative importance of land- and sea-based photosynthesis may fluctuate on a 100,000-year timescale.

The Dole effect describes trends in δ18O arising from trends in the relative importance of land-dwelling and oceanic photosynthesizers. Such a variation is a plausible cause of the phenomenon.[21][22]

Ongoing research

edit

The recovery of higher-resolution ice cores spanning more of the past 1,000,000 years by the ongoing EPICA project may help shed more light on the matter. A new, high-precision dating method developed by the team[23] allows better correlation of the various factors involved and puts the ice core chronologies on a stronger temporal footing, endorsing the traditional Milankovitch hypothesis, that climate variations are controlled by insolation in the northern hemisphere. The new chronology is inconsistent with the "inclination" theory of the 100,000-year cycle. The establishment of leads and lags against different orbital forcing components with this method—which uses the direct insolation control over nitrogen-oxygen ratios in ice core bubbles—is in principle a great improvement in the temporal resolution of these records and another significant validation of the Milankovitch hypothesis. An international climate modelling exercise (Abe-ouchi et al., Nature, 2013[24]) demonstrated that climate models can replicate the 100,000-year cyclicity given the orbital forcing and carbon dioxide levels of the late Pleistocene. The isostatic history of ice sheets was implicated in mediating the 100,000-year response to the orbital forcing. Larger ice sheets are lower in elevation because they depress the continental crust upon which they sit, and are therefore more vulnerable to melting.

See also

edit

Notes

edit
  1. ^ The source for these data is unknown.

References

edit
  1. ^ Raymo, Maureen E.; Nisancioglu, Kerim H. (2003). "The 41 kyr world: Milankovitch's other unsolved mystery". Paleoceanography. 18 (1): 1011. Bibcode:2003PalOc..18.1011R. doi:10.1029/2002PA000791. S2CID 17640098. All serious students of Earth's climate history have heard of the '100 kyr problem' of Milankovitch orbital theory, namely the lack of an obvious explanation of the dominant ~100 kyr periodicity in climate records of the last 800,000 years.
  2. ^ Huggett, Richard J. (2006). The natural history of the Earth : debating long-term change in the geosphere and biosphere. London: Routledge. ISBN 0-203-00407-8. OCLC 77059125.
  3. ^ Brovkin, V.; Calov, R.; Ganopolski, A.; Willeit, M. (April 2019). "Mid-Pleistocene transition in glacial cycles explained by declining CO2 and regolith removal". Science Advances. 5 (4): eaav7337. doi:10.1126/sciadv.aav7337. PMC 6447376. PMID 30949580.
  4. ^ Shackleton, N.J. (2000). "The 100,000-Year Ice-Age Cycle Identified and Found to Lag Temperature, Carbon Dioxide, and Orbital Eccentricity". Science. 289 (5486): 1897–1902. Bibcode:2000Sci...289.1897S. doi:10.1126/science.289.5486.1897. PMID 10988063. S2CID 5787438.
  5. ^ Elkibbi, Maya; Rial, Jose A (2001). "An outsider's review of the astronomical theory of the climate: is the eccentricity-driven insolation the main driver of the ice ages?". Earth-Science Reviews. 56 (1–4): 161–177. Bibcode:2001ESRv...56..161E. doi:10.1016/s0012-8252(01)00061-7.
  6. ^ Lisiecki, Lorraine (2005). "LR04 Benthic Stack". lorraine-lisiecki.com. Retrieved 16 October 2014.
  7. ^ Ghil, Michael (1994). "Cryothermodynamics: the chaotic dynamics of paleoclimate". Physica D: Nonlinear Phenomena. 77 (1–3): 130–159. Bibcode:1994PhyD...77..130G. doi:10.1016/0167-2789(94)90131-7.
  8. ^ Gildor, Hezi; Tziperman, Eli (2000). "Sea ice as the glacial cycles' climate switch: Role of seasonal and orbital forcing". Paleoceanography. 15 (6): 605–615. Bibcode:2000PalOc..15..605G. doi:10.1029/1999PA000461.
  9. ^ a b Ruddiman, William F. (December 2006). "Orbital changes and climate". Quaternary Science Reviews. 25 (23–24): 3092–3112. Bibcode:2006QSRv...25.3092R. doi:10.1016/j.quascirev.2006.09.001.
  10. ^ Saltzman, Barry; Hansen, Anthony R.; Maasch, Kirk A. (December 1984). "The late Quaternary glaciations as the response of a three-component feedback system to Earth-orbital forcing". Journal of the Atmospheric Sciences. 41 (23): 3380–3389. Bibcode:1984JAtS...41.3380S. doi:10.1175/1520-0469(1984)041<3380:TLQGAT>2.0.CO;2.
  11. ^ Denton, G. H.; Anderson, R. F.; et al. (2010). "The Last Glacial Termination". Science. 328 (5986): 1652–1656. Bibcode:2010Sci...328.1652D. doi:10.1126/science.1184119. PMID 20576882. S2CID 27485445.
  12. ^ Rial, José A.; Oh, Jeseung; Reischmann, Elizabeth (10 March 2013). "Synchronization of the climate system to eccentricity forcing and the 100,000-year problem". Nature Geoscience. 6 (4): 289–293. Bibcode:2013NatGe...6..289R. doi:10.1038/NGEO1756. S2CID 140578902.
  13. ^ a b Muller, Richard A.; MacDonald, Gordon J. (1995). "Glacial cycles and orbital inclination". Nature. 377 (6545) (published 14 September 1995): 107–108. Bibcode:1995Natur.377..107M. doi:10.1038/377107b0. S2CID 4288107.
  14. ^ Farley, K.A. (13 July 1995). "Cenozoic variations in the flux of interplanetary dust recorded by 3He in a deep-sea sediment". Nature. 376 (6536): 153–156. Bibcode:1995Natur.376..153F. doi:10.1038/376153a0. S2CID 4316071.
  15. ^ Kortenkamp, Stephen J.; Dermott, Stanley F. (8 May 1998). "A 100,000-Year Periodicity in the Accretion Rate of Interplanetary Dust". Science. 280 (5365): 874–6. Bibcode:1998Sci...280..874K. doi:10.1126/science.280.5365.874. PMID 9572725.
  16. ^ Muller, Richard A.; MacDonald, Gordon J. (5 August 1997). "Spectrum of 100-kyr glacial cycle: orbital inclination, not the eccentricity". Proc Natl Acad Sci U S A. 94 (16): 8329–34. Bibcode:1997PNAS...94.8329M. doi:10.1073/pnas.94.16.8329. PMC 33747. PMID 11607741.
  17. ^ Hays, J.D.; Imbrie, John; Shackleton, N.J. (10 December 1976). "Variations in the Earth's Orbit: Pacemaker of the Ice Ages". Science. 194 (4270): 1121–32. Bibcode:1976Sci...194.1121H. doi:10.1126/science.194.4270.1121. PMID 17790893. S2CID 667291.
  18. ^ Imbrie, John; Imbrie, John Z. (29 February 1980). "Modeling the Climatic Response to Orbital Variations". Science. 207 (4434): 943–53. Bibcode:1980Sci...207..943I. doi:10.1126/science.207.4434.943. PMID 17830447. S2CID 7317540.
  19. ^ Ellis, Ralph (1 November 2016). "Modulation of Ice Ages via Dust and Albedo". Geoscience Frontiers. 7–2016: 891–909. doi:10.1016/j.gsf.2016.04.004.
  20. ^ Ehrlich, Robert (May 2007). "Solar resonant diffusion waves as a driver of terrestrial climate change". Journal of Atmospheric and Solar-Terrestrial Physics. 69 (7): 759–766. arXiv:astro-ph/0701117. Bibcode:2007JASTP..69..759E. doi:10.1016/j.jastp.2007.01.005. S2CID 7015360.
  21. ^ Bender, Michael; Sowers, Todd; Labeyrie, Laurent (September 1994). "The Dole effect and its variations during the last 130,000 years as measured in the Vostok ice core" (PDF). Global Biogeochemical Cycles. 8 (3): 363–376. Bibcode:1994GBioC...8..363B. doi:10.1029/94GB00724.
  22. ^ Sowers, Todd; Bender, Michael; Labeyrie, Laurent; Martinson, Doug; Jouzel, Jean; Raynaud, Dominique; Pichon, Jean Jacques; Korotkevich, Yevgeniy Sergeevich (1993). "A 135000-year Vostok-SPECMAP common temporal framework" (PDF). Paleoceanography. 8 (6): 737–766. Bibcode:1993PalOc...8..737S. doi:10.1029/93PA02328.
  23. ^ Kawamura, K.; Parrenin, F. D. R.; Lisiecki, L.; Uemura, R.; Vimeux, F. O.; Severinghaus, J. P.; Hutterli, M. A.; Nakazawa, T.; Aoki, S.; Jouzel, J.; Raymo, M. E.; Matsumoto, K.; Nakata, H.; Motoyama, H.; Fujita, S.; Goto-Azuma, K.; Fujii, Y.; Watanabe, O. (23 August 2007). "Northern Hemisphere forcing of climatic cycles in Antarctica over the past 360,000 years". Nature. 448 (7156): 912–916. Bibcode:2007Natur.448..912K. doi:10.1038/nature06015. PMID 17713531. S2CID 1784780.
  24. ^ Abe-Ouchi, Ayako; et al. (2013). "Insolation-driven 100,000-year glacial cycles and hysteresis of ice-sheet volume". Nature. 500 (7461): 190–193. Bibcode:2013Natur.500..190A. doi:10.1038/nature12374. PMID 23925242. S2CID 4408240.