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A first-order global model of late Cenozoic climatic change

Published online by Cambridge University Press:  03 November 2011

Barry Saltzman  and
Kirk A. Maasch
Barry Saltzman
Affiliation:
Department of Geology and Geophysics, P.O. Box 6666, Yale University, New Haven, CT 06511, U.S.A.
Kirk A. Maasch
Affiliation:
Department of Geology and Geophysics, P.O. Box 6666, Yale University, New Haven, CT 06511, U.S.A.
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Abstract

The theory of the Quaternary climate will be incomplete unless it is embedded in a more general theory for the fuller Cenozoic that can accommodate the onset of the ice-age fluctuations. Here we construct a simple mathematical model for the late Cenozoic climatic changes based on the hypothesis that forced and free variations of the concentration of atmospheric greenhouse gases (notably CO2) coupled with changes in the global ocean state and ice mass, under the additional influence or earth-orbital forcing, are primary determinants of the climatic state over this long period. Our goal is to illustrate how a single model governing both very long-term variations and higher frequency oscillatory variations in the Pleistocene can be formulated with relatively few adjustable parameters. Although the details of this model are speculative, and other factors neglected here are undoubtedly of importance, it is hoped that the formalism described can provide a basis for developing a comprehensive theory and systematically extending and improving it. According to our model the major near-100 ka period ice-age oscillations of the Pleistocene were caused by the downdraw of atmospheric CO2 (possibly a result of weathering of rapidly uplifted topography) to low enough levels for the ‘slow climatic system’, including glacial ice and the deep ocean state, to become unstable.

Keywords

climate dynamicslate Cenozoic ice agescarbon dioxide and glaciation
Type
Research Article
Information
Earth and Environmental Science Transactions of The Royal Society of Edinburgh , Volume 81 , Issue 4: The Late Cezozoic Ice Age , 1990 , pp. 315 - 325
Copyright
Copyright © Royal Society of Edinburgh 1990

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References

Barnola, J. M., Raynaud, D., Korotkevich, Y. S. & Lorius, C. 1987 Vostok ice core provides 160,000-year record of atmospheric CO2. NATURE 329, 408–14.Google Scholar
Berger, A. 1978. A simple algorithm to compute long-term variations of daily or monthly insolation INST ASTRON GEOPHYS G LEMAITRE, CONTRIB. 18.Google Scholar
Berger, W. 1982. Climate steps in ocean history—lessons from the Pleistocene. In Climate in Earth History 4354. Washington D.C: National Academy Press.Google Scholar
Berger, W. & Spitzy, A. 1988. History of atmospheric CO2: Constraints from the deep-sea record PALEOCEANOGR 3, 401–11.Google Scholar
Barron, E. J. & Washington, W. M. 1984. The role of geographic variables in explaining paleoclimates: Results from Cretaceous climate model sensitivity studies. J GEOPHYS RES 89, 1267–79.Google Scholar
Berner, R. A., Lasaga, A. C. & Garrels, R. M. 1983. The carbonate–silicate geochemical cycle and its effect on the atmospheric carbon dioxide over the past 100 million years. AM J SCI 283, 641–83.CrossRefGoogle Scholar
Broccoli, A. J. & Manabe, S. 1987. The influence of continental ice, atmospheric CO2, and land albedo on the climate of the last glacial maximum. CLIM DYN 1, 8799.Google Scholar
Broecker, W. S. 1974. Chemical Oceanography. New York: Harcourt Brace Jovanovich.Google Scholar
Budyko, M. I. 1982. The Earth's Climate: Past and Future. New York: Academic Press.Google Scholar
Callendar, G. S. 1938. The artificial production of carbon dioxide and its influence on temperature. QUART J R METEROL SOC 64, 223–7.Google Scholar
Chalikov, D. V. & Verbitsky, M. Y. 1990. Modelling the Pleistocene ice ages. ADV GEOPHYS 32, 75130.Google Scholar
Chamberlin, T. C. 1899. An attempt to frame a working hypotheses of the cause of glacial periods on an atmospheric basis. J GEOL 7, 545–84, 667–85, 751–87.CrossRefGoogle Scholar
Chamberlin, T. C. 1906. On a possible reversal of deep sea circulation and its influence on geologic climates. J GEOL 14, 363–73.CrossRefGoogle Scholar
Croll, J. 1875. Climate and Time in their Geological Relations. London: Edw. Stanford 577 pp.Google Scholar
Crowley, T. J., Short, D. A., Mengel, J. G. & North, G. R. 1986. Role of seasonality in the evolution of climate during the last 100 million years. SCIENCE 231, 579–84.CrossRefGoogle ScholarPubMed
Drewry, D. J. 1982. Antarctica unveiled. NEW SCIENTIST 244251.Google Scholar
Flint, R. F. 1971. Glacial and Quaternary Geology. New York: John Wiley.Google Scholar
Frakes, L. A. 1979. Climates Throughout Geologic time. Amsterdam: Elsevier.Google Scholar
Gaffin, S. 1987. Ridge volume dependence on seafloor generation rate and inversion using long term sealevel change. AM J SCI 287, 596611.Google Scholar
Gammon, R. H., Sundquist, E.T. & Fraser, P. J. 1985. History of carbon dioxide in the atmosphere. In Trabalka, J. R. (ed.) Atmospheric Carbon Dioxide and the Global Carbon Cycle DOE/ER-0239, 2562.Google Scholar
Hindmarsh, R. C. A. 1990. Time-scales in the evolution of continental ice sheets. TRANS R SOC EDINBURGH 81, 371–84Google Scholar
Imbrie, J., Hays, J. D., Martinson, D. G., McIntyre, A., Mix, A. C., Morley, J. J., Pisias, N. G., Prell, W. L. & Shackleton, N. J. 1984. The orbital theory of Pleistocene climate: Support from a revised chronology of the marine δ18O record. In Berger, et al. (eds) Milankovitch and Climate (part I,) pp. 269305. Mass: Hingham.Google Scholar
Imbrie, J. and Imbrie, J. Z.Modeling the climatic response to orbital variations, SCIENCE 207, 943–53.CrossRefGoogle Scholar
Kallel, N., Labeyrie, L. D., Juillet-Leclerc, A. & Duplessy, J.-C. 1988. A deep hydrological front between intermediate and deep-water masses in the glacial Indian Ocean. NATURE 333, 651–5.Google Scholar
Kutzbach, J. E. 1976. The nature of climate and climatic variations. QUATERN RES 6 471–80.Google Scholar
Labeyrie, L. D., Duplessy, J.-C. & Blanc, P. L. 1987. Variations in mode of formation and temperature of oceanic deep waters over the past 125,000 years. NATURE 327, 477–82.Google Scholar
Leg 119 Shipboard Scientific Party. 1988. Early Glaciation of Antarctica. NATURE 333, 303–4.Google Scholar
Maasch, K. A. & Saltzman, B. 1990. A low-order dynamical model of global climatic variability during the full Pleistocene, J GEOPHYS RES 95, 1955–63.Google Scholar
Manabe, S. & Bryan, K. 1985. CO2-induced change in a coupled ocean-atmosphere model and its paleoclimatic implications. J GEOPHYS RES 90, 11689–707.CrossRefGoogle Scholar
Mercer, J. H. 1984. Simultaneous climatic change in both hemispheres and similar bipolar interglacial warming: Evidence and implications. In Hansen, J. E. and Takahashi, T. (eds), Climate Processes and Climate Sensitivity, pp. 307–13. Washington D.C.: AGU.CrossRefGoogle Scholar
Mercier, J.-L., Armijo, R., Tapponneir, P., Carey-Gailhardis, E. & Lin, H. T. 1987. Change from late Tertiary compression to Quaternary extension in southern Tibet during the India-Asia collision. TECTONICS 6, 275304.CrossRefGoogle Scholar
Milankovitch, M. 1930. Mathematische Klimalehre und Astronomische theorie der klimaschwankungen. In Köppen, W. & Geiger, R. (eds) Handbuch der Klimatologie. Berlin: Gebrüder Borntraeger.Google Scholar
Newell, R. E. 1974. Changes in the poleward energy flux by the atmosphere and ocean as a possible cause for ice ages. QUATERN RES 4, 117–27.CrossRefGoogle Scholar
Oglesby, R. J. 1990. The sensitivity of GCM simulations of glacial variations to changes in initial conditions, boundary conditions, and parameterizations. CLIM DYN (in press).Google Scholar
Oglesby, R. J. & Saltzman, B. 1990a. Extending the EBM: The effect of deep ocean temperature on climate with application to the Cretaceous. PALEOG, PALEOL, PALEOECOL (GLOBAL PLANETARY CHANGE) 82, 237–59.Google Scholar
Oglesby, R. J. & Saltzman, B. 1990b. Sensitivity of the equilibrium mean surface temperature of a GCM to systematic changes in atmospheric carbon dioxide. GEOPHYS RES LETT 17, 1089–92.Google Scholar
Plass, G. N. 1956. The carbon dioxide theory of climate change. TELLUS 8, 140–54.CrossRefGoogle Scholar
Prentice, M. L. & Matthews, R. K. 1988. Cenozoic ice-volume history: Development of a composite oxygen isotope record. GEOLOGY 16, 963–66.Google Scholar
Rau, G. H., Takahashi, T. & Des Marais, D. J. 1989. Latitudinal variations in plankton δ15C: implications for CO2 and productivity in past oceans. NATURE 341, 516–8.CrossRefGoogle Scholar
Raymo, M. E., Ruddiman, W. F. & Froelich, P. N. 1988. Influence of late Cenozoic mountain building on ocean geochemical cycles. GEOLOGY 16, 649–53.Google Scholar
Raymo, M. E., Ruddiman, W. F., Backman, J., Clement, B. M. & Martinson, D. G. 1989. Late Pliocene variation in Northern Hemisphere ice sheets and North Atlantic deep water circulation. PALEOCEANOGRAPHY 4, 413–46.CrossRefGoogle Scholar
Rooth, C. G. H., Emiliani, C. & Poor, H. W. 1978. Climate response to astronomical forcing. EARTH PLANET SCI LETT 41, 387–94.CrossRefGoogle Scholar
Ruddiman, W. F. & Kutzbach, J. E. 1984. Forcing of late Cenozoic northern hemisphere climate by plateau uplift in southeast Asia and the American south-west. J GEOPHYS RES 94, 18409–27.Google Scholar
Ruddiman, W. F., Raymo, M. E., Martinson, D. G., Clement, B. M. & Backman, J. 1989. Pleistocene evolution: Northern Hemisphere ice sheets and North Atlantic ocean. PALEOCEANOGR 4, 353412.Google Scholar
Saltzman, B. 1977. Global mass and energy requirements for glacial oscillations and their implications for mean ocean temperature oscillations. TELLUS 29, 205–12.CrossRefGoogle Scholar
Saltzman, B. 1983. Climatic systems analysis. ADV GEOPHYS 25, 173233.Google Scholar
Saltzman, B. 1988. Modelling the slow climatic attractor. In Schlesinger, M. E. (ed.) Physically-Based Modelling and Simulation of Climate and Climatic Change (vol. 2) pp. 737754. Kluwer Academic Publishers.CrossRefGoogle Scholar
Saltzman, B., Hansen, A. R. & Maasch, K. A. 1984. The late Quaternary glaciations as the response of a three-component feedback system to Earth-orbital forcing, J ATMOS SCI 41, 3380–9.Google Scholar
Saltzman, B. & Maasch, K. A. 1988. Carbon cycle instability as a cause of the late Pleistocene ice age oscillations: Modeling the asymmetric response. GLOBAL BIOGEOCHEM CYCLES 2, 177–85.Google Scholar
Saltzman, B. & Sutera, A. 1984. A model of the internal feedback system involved in late Quaternary climatic variations. J ATMOS SCI 41, 736–45.Google Scholar
Saltzman, B. & Sutera, A. 1987. The mid-Quaternary climatic transition as the free response of a three-variable dynamical model. J ATMOS SCI 44, 236–41.Google Scholar
Sergin, V. Ya., Numerical modeling of the glaciers–ocean–atmosphere global system. J GEOPHYS RES 84, 3191–204.Google Scholar
Shackleton, N. J., Backman, J., Zimmerman, H., Kent, D. V., Hall, M. A., Roberts, D. G., Schnitker, D., Baldauf, J. G., Desprairies, A., Homrighousen, R., Huddlestun, P., Keene, J. B., Kaltenback, A. J., Krumsiek, K. A. O., Morton, A. C., Murray, J. W. & Westberg-Smith, J. 1984. Oxygen isotope calibration of the onset of ice-rafting and history of glaciation in the North Atlantic region. NATURE 307, 620–3.CrossRefGoogle Scholar
Shackleton, N. J. & Imbrie, J. 1990. The δ18O spectrum of oceanic deep water over a five-decade band. CLIM CHANGE 16, 217–30.Google Scholar
Vernekar, A. D. 1972. Long-term global variations of incoming solar radiation. Meteorological Monographs 34. Boston, Mass.: American Meteorological Society.Google Scholar
Woldstedt, P. 1954. Das Eiszeitalter (vol. 1). Stuttgart: Ferdinand Enke.Google Scholar