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Late Quaternary Ice Age Climates of Tropical Australasia: Interpretations and Reconstructions

Published online by Cambridge University Press:  20 January 2017

P.J. Webster
Affiliation:
CSIRO Division of Atmospheric Physics, Aspendale, Victoria, Australia
N.A. Streten
Affiliation:
Australian Numerical Meterology Research Centre, Melbourne, Victoria, Australia

Abstract

Paleoecological and paleogeographical evidence is used to mold a framework from which the basic parameters of the late Quaternary glacial-age climate of tropical Australasia can be inferred. The theory of physical circulations, a knowledge of present tropical circulation patterns, and a study of anomalous and extreme events in the present era are used to reemphasize the view of a less pluvial tropical and subtropical zone at that time. Cooler sea-surface temperature, cooler trades, and the effect of the then exposed land areas are indicated as instrumental in producing drier conditions. Tropical areas west of Cape York Peninsula and Torres Strait were subject to fewer tropical disturbances and were similar to the present tropical savannah of the northern interior of Australia. Such effects would exist even without shifts in major climatic zones, although they are shown to be consistent with an equatorward shift of the westerlies brought about by the increased pole to equator temperature gradient. Paleoenvironmental evidence from the New Guinea Highlands and southeastern Australia suggests that their climates were anomalous. Substantial data of the glacial period in New Guinea show snow lines to be 1000 to 1500 m lower than at present which matches a 6 to 8°C lowering of temperature in highland New Guinea. The deep-sea cores of the CLIMAP Project suggest a mere 2°C cooling of the surrounding tropical oceans. It is shown that it is highly unlikely that an upper-level decrease in temperature of 6 to 8°C could be maintained while the surface cools by only 2°C. It is suggested that either the temperature of the tropical oceans of the western Pacific were overestimated by CLIMAP or that cold air incursions from higher latitudes (for which some analogs exist today) were sufficiently frequent to allow the maintenance of a snow line well below the freezing level of the ancient ambient tropical atmosphere. It is shown that in southeastern Australia considerable evidence of aridity cannot be explained by merely displacing the westerlies more equatorward. To account for the aridity, a new circulation pattern is proposed. Noting that there is CLIMAP evidence of preferred equatorward extension of sea ice, a pattern is postulated that displays only small seasonal change and is characterized by an enhanced Indian Ocean trough, marked ridging at eastern Australian longitudes, and a further trough in the western Tasman. Such a basic flow is consistent with (i) a low rainfall over southeastern Australia, (ii) frequent cold outbreak conditions favorable for the maintenance of the New Guinea glaciers, and (iii) considerable precipitation to nourish the ice caps of Tasmania and the Australian and New Zeland Alps.

Type
Original Articles
Copyright
University of Washington

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References

Bjerknes, J., 1969. Atmospheric teleconnections from the equatorial Pacific. Monthly Weather Review. 97, 163-172.2.3.CO;2>CrossRefGoogle Scholar
Bowler, J.M., 1971. Pleistocene salinates and climatic change: Evidence from lakes and lunettes in southeastern Australia. Mulvaney, D.J., Golsen, J., Aboriginal Man and Environment in Australia. Australian National University Press, Canberra, 47-65.Google Scholar
Bowler, J.M., 1973. Clay dunes: Their occurrence formation and environmental significance. Earth Science Reviews. 9, 315-338.Google Scholar
Bowler, J.M., 1975. Deglacial events in southern Australia: Their age, nature and palaeoclimatic significance. Suggate, R.P., Cresswell, M.M., Quaternary Studies—Selective Papers from IX INQUA Congress Christchurch New Zealand 2–10 December 1973. Royal Society of New Zealand, Wellington, 75-82.Google Scholar
Bowler, J.M., Hope, G.S., Jennings, J.N., Singh, G., Walker, D., 1976. Late Quaternary climates of Australia and New Guinea. Quaternary Research. 6, 359-394.Google Scholar
Charney, J.G., 1969. The intertropical convergence zone and the Hadley circulation of the atmosphere. Proceedings of the WMO-IUGG Symposium on Numerical Weather Prediction. Tokyo, Japan, Nov–Dec 1968 Japanese Meteorological Agency, Tokyo. Google Scholar
1976. CLIMAP project members. The surface of the ice age earth. Science. 191, 1131-1137.Google Scholar
Coleman, F., 1972 Frequencies, Tracks and Intensities of Tropical Cyclones in the Australian Region, November 1909 to June 1969. Bureau of Meteorology, Melbourne. Google Scholar
Costin, A.B., 1972. Carbon-14 dates from the Snowy Mountains area south-eastern Australia and their interpretation. Quaternary Research. 2, 579-590.Google Scholar
Derbyshire, E., 1971. A synoptic approach to the atmospheric circulation of the last glacial maximum in southeastern Australia. Paleogeography, Paleoclimatology, Paleoecology. 10, 103-129.Google Scholar
Dodson, J., 1977. Late Quaternary paleoecology of the Wyrie Swamp, southeastern Australia. Quaternary Research. 8, 97-114.Google Scholar
Fairbridge, R.W., 1965. African ice-age aridity. Nairn, A.E.M., Problems in Paleoclimatology. Wiley-Interscience, New York, 356-363.Google Scholar
Flohn, H., 1952. Allgemeine atmosphärische zirkulation und palaoklimatologie. Geologische Rundschau. 40, 153-178.CrossRefGoogle Scholar
Flohn, H., 1953. Studien uber die atmosphärische zirkulation in der letzten Eiszeit. Erdkunde. 7, 266-275.Google Scholar
Galloway, R.W., 1965. Late Quaternary climates of Australia. Journal of Geology. 73, 603-618.Google Scholar
Galloway, R.W., 1971. Evidence for late Quaternary climates. Mulvaney, D.J., Golson, J., Aboriginal Man and Environment in Australia. Australian National Univ. Press, Canberra, 14-25.Google Scholar
Galloway, R.W., Hope, G.S., Loeffler, E., Peterson, J.A., 1973. Late Quaternary glaciation and periglacial phenomena in Australia and New Guinea. Paleoecology of Africa and of the Surrounding Islands and Antarctica. 8, 125-138.Google Scholar
Gates, L., 1976. Modelling the Ice Age climate. Science. 191, 1138-1144.Google Scholar
Gentilli, J., 1961. Quaternary climates of the Australian region. Annals of the New York Academy of Science. 95, 465-501.Google Scholar
Hnatiuk, R.J., Smith, J.M.B., McVean, D.N.,1976 The Climate of Mt. Wilhelm: Mt. Wilhelm Studies 2. Australian National University, Canberra, Research School of Pacific Studies, Department of Biogeography and Geomorphology, Publication BG/4. Google Scholar
Heusser, C.J., 1966. Pleistocene climatic variations in the western United States. Blumenstock, D.I., Pleistocene and Post-Pleistocene Climatic Variations in the Pacific Area-A Symposium. Tenth Pacific Science Congress, Hawaii, 21st August to 6th September 1961. Bishop Museum Press, Honolulu. Google Scholar
Jennings, J.N., 1971. Sea level changes and land links. Mulvaney, D.J., Golson, J., Aboriginal Man and Environment in Australia. Australian National Univ. Press, Canberra, 1-13.Google Scholar
Kershaw, A.P., 1974. A long continuous pollen sequence from northeastern Australia. Nature (London). 251, 222-223.Google Scholar
Kraus, E.B., 1973. Comparison between ice age and present general circulations. Nature (London). 245, 129-133.CrossRefGoogle Scholar
Lamb, H.H., 1961. Fundamentals of climate. Nairn, A.E.M., Descriptive Paleoclimatology. Wiley-Interscience, New York, 8-44.Google Scholar
Löeffler, E., öeffler, 1972. Pleistocene glaciation in Papua and New Guinea. Zeitschrift für Geomorphologie Supplement Band. 13, 32-58.Google Scholar
Lourensz, R.S., 1977. Tropical Cyclones in the Australian region, July 1909 to June 1971. Bureau of Meteorology, Melbourne. Google Scholar
Manabe, S., Hahn, D.G., 1977. Simulation of the tropical climate of an ice age. Journal of Geophysical Research. 82, 3889-3911.CrossRefGoogle Scholar
Mercer, J.H., 1967 Southern Hemisphere Glacier Atlas United States Army Natick Laboratories. Technical Report 67-76-ES, Natick, Mass..CrossRefGoogle Scholar
Newell, R.E., 1975. Decreased global rainfall during the past ice age. Nature (London). 253, 33-34.CrossRefGoogle Scholar
Olascoaga, M.J., 1950. Some aspects of Argentine rainfall. Tellus. 2, 312-318.Google Scholar
Pike, A.C., 1971. The intertropical convergence zone studied with an interacting atmosphere and ocean model. Monthly Weather Review. 99, 464-477.Google Scholar
Reiner, E., 1960. The glaciation of Mount Wilhelm, Australian New Guinea. Geographical Review. 50, 490-503.CrossRefGoogle Scholar
Riehl, H., 1954 Tropical Meteorology. McGraw-Hill, New York. Google Scholar
Riehl, H., Malkus, J.S., 1958. On the heat balance in the equatorial trough zone. Geophysica. 6, 503-538.Google Scholar
Rognon, P., Williams, M.A.J., 1977. Late Quaternary climatic changes in Australia and north Africa: A preliminary interpretation. Palaeogeography, Palaeoclimatology, Palaeoecology. 21, 285-327.Google Scholar
Streten, N.A., 1973. Satellite observations of the summer decay of the Antarctic sea ice. Archivfeur Meteorologie, Geophysik und Bioklimatologie, Serie A; Meteorologie und Geophysik. 22, 119-134.Google Scholar
Streten, N.A., 1974. Some features of the summer climate of interior Alaska. Arctic. 27, 273-286.Google Scholar
Streten, N.A., 1977. Seasonal climatic variability over the southern oceans. Archivfuer Meteorologie, Geophysik und Bioklimatologie, Serie B: Klimatologie, Umweltmeteorologie, Strahlungsforschung. 25, 1-19.Google Scholar
Taylor, 162.R., Winston, J.S., 1968 Monthly and Seasonal Mean Global Charts of Brightness from ESSA 3 and 5 Digitized Pictures, February 1967-February 1968. Environmental Sciences Services Administration, Technical Report NESC 46, Washington, D. C..Google Scholar
Twidale, C.R., 1966. Late cainozoic activity of the Selwyn Upwarp northwest Queensland. Journal of the Geological Society of Australia. 13, 491-494.Google Scholar
Van Andel, T.H., Heath, G.R., Moore, T.C., McGeary, D.F.R., 1967. Late Quaternary history, climate and oceanography of the Timor Sea northwestern Australia. American Journal of Science. 265, 737-758.Google Scholar
Veeh, H.H., Chapell, J., 1970. Astronomical theory of climatic change: support from New Guinea. Science. 167, 862-865.Google Scholar
Webster, P.J., 1972. Response of the tropical atmosphere to local steady forcing. Monthly Weather Review. 100, 518-541.Google Scholar
Webster, P.J., Streten, N.A., 1972. Aspects of late Quaternary climate in tropical Australasia. Walker, D., Bridge and Barrier: The Natural and Cultural History of Torres Strait. Department of Biogeography and Geomorphology, Publication BG/3. Australian National University, Canberra, 39-60.Google Scholar
Williams, M.A.J., 1975. Late Pleistocene tropical aridity synchronous in both hemispheres?. Nature (London). 253, 617-618.Google Scholar
Wright, R.L., 1964. Geomorphology of the West Kimberley area. General Report on Lands of the West Kimberley Area. Land Research Series CSIRO No. 9. 103-118 Melbourne.Google Scholar