Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-27T08:25:19.079Z Has data issue: false hasContentIssue false

Insolation Regime of Interglacials1

Published online by Cambridge University Press:  20 January 2017

George J. Kukla
Affiliation:
Czechoslovak Academy of Sciences, Geological Institute Czechoslovakia

Abstract

Seasonal changes in the extent of snow cover and pack-ice were analysed in the satellite-derived maps of the Northern Hemisphere obtained during the last 5 yr. Two intervals were studied in detail: summer 1968 to summer 1969 and summer 1971 to summer 1972. These studies demonstrate that the variation in ground albedo as a result of changing snow and ice cover affects the Earth's energy budget to a far greater degree than any possible extraterrestrial mechanism could do on such a short time scale. However, the rapid expansion of snow cover between late September and November suggests possible feed-back process which could be speeded up or slowed down by minute changes in energy and moisture budget at the snow accretion area. These changes may be of any origin, natural or artificial, and on the time scales ranging from days to millenia.

In this context, the close correspondence between the radiometrically dated gross climate changes within the past 150,000 yr and between the curve showing the rate of change in winter insolation for the middle latitudes of the Northern Hemisphere is conspicuous. The periodicity of about 20,000 yr is involved.

An insolation chronology is introduced here, which is based entirely on astronomic factors (on the so called Milankovitch mechanism of Earth orbital elements). It is independent of any geologic or geochronologic dating systems. Two alternating units comprise the insolation chronology. The positive insolation regime (PIR) is an episode defined by progressively increasing winter irradiation in the Northern Hemisphere, whereas the negative insolation regime (NIR) is an episode of progressively decreasing winter irradiation. The PIR closely correlates with the generally warm intervals such as interglacials and temperate interstadials, the NIR with generally cold intervals. This basic pattern interferes with short-term oscillations which may retard or advance the climate response on the scale of centuries.

It is observed that the positive insolation regime designated as PIR 110, which started at 11,000 YBP, has ended recently. The new negative insolation regime, NIR 0/ + 8, will last for the next 8000 yr. Inasmuch within the last radiometrically dated 150,000 yr no NIR is known to correlate with generally warm interval, the prognosis is for a long-lasting global cooling more severe than any experienced hitherto by civilized mankind.

Type
Original Articles
Copyright
Academic Press, Inc.

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

2 present: Lamont Doherty Geological Observatory, Palisades, New York 10964.
1

Lamont Doherty Geological Observatory Contribution No. 1888.

References

Adhemar, J.F. 1842 Les Revolutions de la Mer, Deluges periodiques ParisGoogle Scholar
Broecker, W.S. 1966 Absolute dating and the astronomical theory of glaciation Science 151 299 304 CrossRefGoogle ScholarPubMed
Broecker, W.S. Van Donk, J. 1970 Insolation changes, ice volume and the O18 record in deep-sea cores Reviews of Geophysics and Space Physics 2 169 198 Google Scholar
Budyko, M.I. 1969 The effect of the solar radiation variations on the climate of the Earth Tellus 21 612 619 Google Scholar
Croll, J. Fourth edition 1875 Climate and Time in their Geological Relations: A Theory of Secular Changes of the Earth's Climate 577 1890. LondonGoogle Scholar
Dickson, R.R. Posey, J. 1967 Maps of snow cover probability for the Northern Hemisphere Monthly Weather Rev. 95 U.S. Department of Commerce 347 353 Google Scholar
Dreimanis, A. Karrow, P.F. 1965 Southern Ontario Guidebook for Field Conference G, Great Lakes-Ohio River Valley INQUA VII Congress, 1965 Nebraska Academy of Science 90 110 Google Scholar
Emiliani, C. Geiss, J. 1959 On glaciations and their causes Geologische Rundschau 46 576 601 Google Scholar
Ericson, D.B. Ewing, M. Wollin, G. Heezen, B.C. 1961 Atlantic deep-sea sediment cores Bulletin of the Geological Society of America 72 173 286 Google Scholar
Fairbridge, R.W. 1961 Convergence of evidence on climatic change and ice ages New York Academy of Science Annals 95 542 579 Google Scholar
James, N.P. Mountjoy, E.W. Omura, A. 1971 An Early Wisconsin reef terrace at Barbados, West Indies, and its climatic implications Bulletin of the Geological Society of America 82 2011 2018 CrossRefGoogle Scholar
Kondratyev, K.Y.A. 1969 Radiation in the atmosphere Academic Press New York and London 912 Google Scholar
Kort, V.G. 1964 Antarctic oceanography Odishaw, H. Research in Geophysics Vol. 2 MIT 309 333 Google Scholar
Köppen, W. Wegener, A. 1924 Die Klimate der Geologischen Vorzeit BerlinGoogle Scholar
Kossina, E. 1933 Die Erdoberfläche Gutenberg, B. Handbuch der Geophysik Vol. 2 Borntraeger Berlin 869 954 Google Scholar
Kukla, J. 1969 The cause of the Holocene climate change Geologie en Mijnbouw 48 307 334 Google Scholar
Kukla, J. 1972 Insolation and glacials Boreas 2 63 96 CrossRefGoogle Scholar
McDonald, B.C. 1971 Late Quaternary stratigraphy and deglaciation in Eastern Canada Turekian, K.K. Late Cenozoic Glacial Ages Yale Univ. Press 331 353 Google Scholar
Mesolella, K.J. Matthews, R.K. Broecker, W.S. Thurber, D.L. 1969 The astronomical theory of climatic change. Barbados data Journal of Geology 77 250 274 Google Scholar
Mitchell, J.M. Jr. 1965 Theoretical paleoclimatology Wright, H.E. Jr. Frey, D.G. The Quaternary of the United States. A Review Volume for the VII Congress of the Intern. Association for Quaternary Research 881 901 Google Scholar
Mörner, N.-A. 1971 The Plum Point Interstadial: age, climate and subdivision Canadian Journal of Earth Sciences 2 1423 1431 CrossRefGoogle Scholar
Namias, J. 1970 Macroscale variations in sea surface temperatures in the North Pacific Journal of Geophysical Research 75 565 582 Google Scholar
Rasool, S.I. 1967 Satellite meteorology Fairbridge, R.W. The Encyclopedia of Atmospheric Sciences and Astrogeology Reinhold Publishing Corporation New York, Amsterdam, London 847 851 Google Scholar
Rona, E. Emiliani, C. 1969 Absolute dating of Caribbean cores P 6304-9 and P6304-9 Science 163 66 68 Google Scholar
Sellers, W.D. 1969 A global climatic model based on the energy balance of the Earth's atmosphere system Journal of Applied Meteorology 2 392 400 Google Scholar
Shaw, D.M. Donn, W.I. 1968 Milankovitch Radiation Variation: A quantitative evaluation Science 162 1270 1272 Google Scholar
Shumskiy, P.A. Krenke, A.N. Zotikov, I.A. 1964 Ice and its changes Odishaw, H. Research in Geophysics Vol. 2 MIT 425 460 Google Scholar
Vernekar, A.D. 1968 Long-period global variations of incoming solar radiation Research on the Theory of Climate, II Report on the Travelers Research Center. Inc. 298 Hartford, ConnGoogle Scholar
Willman, H.B. Frye, J.C. 1970 Pleistocene stratigraphy of Illinois Illinois Geological Survey Bulletin 94 204 Google Scholar
Zagwijn, W. Paepe, R. 1968 Die Stratigraphie der Weichselzeitlichen Ablagerungen der Niederlande und Belgiens Eiszeitalter und Gegenwart 19 129 146 Google Scholar