Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-22T06:13:07.317Z Has data issue: false hasContentIssue false

Sea-Surface Temperature Estimates for the Tropical Western Pacific during the Last Glaciation and Their Implications for the Pacific Warm Pool

Published online by Cambridge University Press:  20 January 2017

Robert Thunell
Affiliation:
Department of Geological Sciences, University of South Carolina, Columbia, South Carolina, 29208
David Anderson
Affiliation:
Department of Geological Sciences, University of South Carolina, Columbia, South Carolina, 29208
Debrorah Gellar
Affiliation:
Department of Geological Sciences, University of South Carolina, Columbia, South Carolina, 29208
Qingmin Miao
Affiliation:
Department of Geological Sciences, University of South Carolina, Columbia, South Carolina, 29208

Abstract

Twenty deep-sea sediment cores from the western Pacific between 30°N and 30°S provide evidence of sea-surface temperature (SST) changes throughout the tropics and subtropics. Glacial SSTs were estimated using the modern analog technique (MAT) applied to planktonic foraminifers and planktonic foraminiferal δ18O changes. We used δ18O to identify the last glacial maximum. The MAT method differs from the traditional transfer function approach in that it utilizes a global coretop database, and estimates paleotemperature by finding analogs from the modern coretop samples. In addition, the MAT approach appears to be less susceptible than the transfer function technique to biases introduced by carbonate dissolution. Our results indicate that tropical SSTs differed by less than 2°C from present; away from the tropics (30°N and 30°S) SSTs were at least 3°C cooler. Our results differ from those of previous studies in the western Pacific by using a set of well-preserved, high-sedimentation rate cores from shallow regions. The results of this study clearly indicate that a western Pacific warm pool existed during the last glacial maximum (LGM), providing a heat and moisture source for a Walker Circulation cell similar to that of today. We propose that a steeper lapse rate existed during the last glacial maximum and that this can explain at least part of the discrepancy between marine and terrestrial temperature estimates adjacent to New Guinea for the LGM.

Type
Articles
Copyright
University of Washington

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.)

References

Anderson, D. W. Prell, W., and Barratt, N. (1989). Estimates of sea surface temperature in the Coral Sea at the last glacial maximum. Paleoceanography 4, 615627.CrossRefGoogle Scholar
Berger, W. (1968). Planktonic foraminifera; Selective solution and paleoclimatic interpretation. Deep-Sea Research 15, 3143.Google Scholar
Bjerknes, J. (1969). Atmospheric teleconnections from the equatorial Pacific. Monthly Weather Review 91, 163172.2.3.CO;2>CrossRefGoogle Scholar
Bottomley, M. Folland, C., Hsiung J,, Newell, R., and Parker, D. (1990). “Global Ocean Surface Temperature Atlas,” pp. 1313. Meteorological Office, Bracknell, UK.Google Scholar
Bradshaw, J. (1959). Ecology of living planktonic foraminifera in the north and equatorial Pacific Ocean. Contributions from the Cushman Foundation for Foraminiferal Research 10, 2564.Google Scholar
Broecker, W. (1986). Oxygen isotope constraints on surface ocean temperatures. Quaternary Research 26, 121134.CrossRefGoogle Scholar
Caratini, C., and Tissot, C. (1988). Paleogeographical evolution of the Mahakam Delta in Kalimantan, Indonesia during the Quaternary and late Pliocene. Review of Palaeobotany and Palynology 55, 217228.CrossRefGoogle Scholar
CLIMAP Project Members (1976). The surface of the ice age Earth. Science 191, 11311137.Google Scholar
CLIMAP Project Members (1981). Seasonal reconstruction of the earth’s surface at the last glacial maximum. Geological Society of America Map and Chart Series, 36.Google Scholar
Emiliani, C. (1955). Pleistocene temperatures. Journal of Geology 63, 538578.CrossRefGoogle Scholar
Emiliani, C. (1966). Paleotemperature analysis of Carribean cores P6304-8 and P6304-9 and a generalized temperature curve for the past 425,000 years. Journal of Geology 74, 109134.CrossRefGoogle Scholar
Fairbanks, R. (1989). A 17,000 year glacio-eustatic sea level record: Influence of glacial melting rates on the Younger Dryas event and deep ocean circulation. Nature 342, 637642.CrossRefGoogle Scholar
Fairbanks, R. (1990). The age and origin of the “Younger Dryas climate event” in Greenland ice cores. Paleoceanography 5, 937948.CrossRefGoogle Scholar
Flohn, H, (1971). Tropical circulation patterns. Bonner Meteorologische Ahhandlungen 15, 115.Google Scholar
Gellar, D. (1992). “Glacial-interglacial History of the Western Pacific: Sea Surface Temperature and Paleoproductivity Fluctuations.” Unpublished MS thesis, University of South Carolina.Google Scholar
Hasoldonckx, P. (1977). The palynology of a Holocene marginal peat swamp environment in Johore, Malaysia. Review of Paleobotany and Palynology 24, 227238.CrossRefGoogle Scholar
Hastenrath, S. (1991). “Climate Dynamics of the Tropics.” Kluwer, Dordecht, Netherlands.CrossRefGoogle Scholar
Hutson, W. H. (1979). The Aghulas Current during the Late Pleistocene: Analysis of modern analogs. Science 207, 6466.CrossRefGoogle Scholar
Imbrie, J., and Kipp, N. (1971). A new micropaleontological method for paleoclimatology: Application to a Late Pleistocene Caribbean core. In “The Late Cenozoic Glacial Ages” (Turekian, K. K., Ed.), pp. 181. Yale Univ. Press, New Haven, CT.Google Scholar
Imbrie, J. Hays, J. Martinson, D. McIntyre, A. Mix, A. Morley, J. Pisias, N. Prell, W., and Shackleton, N. (1984). The orbital theory of Pleistocene climate: Support from a revised chronology of the marine S180 record. In “Milankovitch and Climate” (Berger, A., Ed.), pp. 269305. Reidel, Dordecht.Google Scholar
Kutzbach, J., and Guetter, P. (1986). The influence of changing orbital parameters and surface boundary conditions on climate simulations for the past 18,000 years. Journal of Atmospheric Science 43, 17261759.2.0.CO;2>CrossRefGoogle Scholar
Lafontaine, C. (1988). Comparison of the simulated and geologic observations from equatorial land regions for the past 18,000 years. Unpublished MS Thesis, University of Wisconsin.Google Scholar
Lyle, M. Murray, D. Finney, B. Dymond, J. Robbins, J., and Brooksforce, K. (1988). The record of late Pleistocene biogenic sedimentation in the eastern tropical Pacific Ocean. Paleoceanography 3, 3960.CrossRefGoogle Scholar
Lyle, M. Prahl, F., and Sparrow, M. (1992). Up welling and productivity changes inferred from a temperature record in the central equatorial Pacific. Nature 355, 812815.CrossRefGoogle Scholar
Miao, Q. Thunell, R., and Anderson, D. (1994). Glacial-Holocene carbonate dissolution and sea surface temperatures in the South China and Sulu Seas. Paleoceanography (in press).CrossRefGoogle Scholar
Moore, T. C. Pisias, N. G., and Heath, G. R. (1977). Climate changes and lags in Pacific carbonate preservation, sea surface temperature, and global ice volume. In “The Fate of Fossil Fuel C02 in the Oceans” (Anderson, N. R. and Malahoff, A., Eds.), pp. 145165. Plenum, New York.CrossRefGoogle Scholar
Moore, T. C. Burckle, L. Geitzenauer, K. Luz, B. Molina-Cruz, A. Robertson, J. Sachs, H. Sancetta, C. Thiede, J. Thompson, P., and Wenkam, C. (1980). The reconstruction of sea surface temperatures in the Pacific Ocean of 18,000 B.P. Marine Micropaleontology 5, 215247.CrossRefGoogle Scholar
Morley, J., and Heuser, L. (1989). Late Quaternary atmospheric and oceanographic variations in the western Pacific inferred from pollen and radiolarian analysis. Quaternary Science Reviews 8, 263276.CrossRefGoogle Scholar
Ohkouchi, N., and Taira, A. (1993). Late Quaternary biomarker records in the western equatorial Pacific. Eos 74, 366.Google Scholar
Overpeck, J. T. Webb, T. III, and Prentice, I. (1985). Quantitative interpretation of fossil pollen spectra: Dissimilarity coefficients and the method of modem analogs. Quaternary Research 23, 87108.CrossRefGoogle Scholar
Parker, F., and Berger, W. (1971). Faunal and solution patterns of planktonic foraminifera in surface sediments of the South Pacific. Deep-Sea Research 18, 73107.Google Scholar
Pedersen, T. (1983). Increased productivity in the eastern equatorial Pacific during the last glacial maximum (19,000 to 14,000 yr BP). Geology 11, 1619.2.0.CO;2>CrossRefGoogle Scholar
Pedersen, T. Nielsen, T., and Pickering, M. (1991). Timing of late Quaternary productivity pulses in the Panama Basin and implications for atmospheric CO. Paleoceanography 6, 657677.CrossRefGoogle Scholar
Peterson, G. M. Webb, T. III Kutzbach, J. Van der Hammen, T. Wijmstra, T., and Street, F. (1979). The continental record of environmental conditions at 18,000 yr B.P. and initial evaluation. Quaternary Research 12, 4782.CrossRefGoogle Scholar
Prell, W. (1985). “The Stability of Low-Latitude Sea Surface Temperatures: An Evaluation of the CLIMAP Reconstruction with Emphasis on the Positive SST Anomalies,” pp. 60. Technical Report. TR025, United States Department of Energy, Washington, DC.Google Scholar
Quinn, W. H. (1971). Late Quaternary meteorological and oceanographic developments in the equatorial Pacific. Nature 229, 330331.CrossRefGoogle ScholarPubMed
Rind, D., and Peteet, D. (1985). Terrestrial conditions at the last glacial maximum and CLIMAP sea-surface temperature estimates: Are they consistent? Quaternary Research 24, 122.Google Scholar
Sautter, L., and Thunell, R. (1991). Seasonal variability in the 8180 and 813C of planktonic foraminifera from an upwelling environment: Sed-iment trap results from the San Pedro Basin, Southern California Bight. Paleoceanography 6, 307334.CrossRefGoogle Scholar
Shackleton, N. (1967). Oxygen isotope analyses and Pleistocene paleotemperatures reassessed. Nature 218, 1517.CrossRefGoogle Scholar
Street, F., and Grove, A. (1979). Global maps of lake-level fluctuations since 30,000 yr B.P. Quaternary Research 12, 83118.CrossRefGoogle Scholar
Stuijts, I. Newsome, J., and Flenley, J. (1988). Evidence for late Quaternary vegetational change in the Sumatran and Javan highlands. Review of Paleobotany and Palynology 55, 207216.CrossRefGoogle Scholar
Stute, M. SchJosser, P. Clark, J., and Broecker, W. S. (1992). Paieotemperatures in the Southwestern United States derived from noble gases in ground water. Science 256, 10001002.CrossRefGoogle ScholarPubMed
Tchernia, P. (1980). “Descriptive Regional Oceanography.” Pergamon, New York.Google Scholar
Thompson, P. (1976). Planktonic foraminiferal dissolution and progress towards a Pleistocene equatorial Pacific transfer function. Journal of Foraminiferal Research 6, 208227.CrossRefGoogle Scholar
Thompson, P. (1981). Planktonic foraminifera in the western north Pacific during the past 150,000 years: Comparison of modem and fossil assemblages. Palaeogeography, Palaeoclimatology, Palaeoecology 35, 241279.CrossRefGoogle Scholar
Thunell, R., and Honjo, S. (1981). Calcite dissolution and the modification of planktonic foraminiferal assemblages. Marine Micropaleontology 6, 169182.CrossRefGoogle Scholar
Thunell, R. C., and Honjo, S. (1987). Seasonal and interannual changes in planktonic foraminiferal production in the north Pacific. Nature 328, 335337.CrossRefGoogle Scholar
Walker, D., and Flenley, J. (1979). Late Quaternary vegetational history of the Enga Providence of Upland Papua New Guinea. Philosophical Transactions of the Royal Society of London 286, 265344.Google Scholar
Webster, P., and Streten, N. (1978). Late Quaternary ice age climates of tropical Australasia, interpretation and reconstruction. Quaternary Research 10, 279309.CrossRefGoogle Scholar
Yan, J. (1990). “Paleoceanography and Paleoclimate Studies of West Pacific Marginal Sea Since Late Pleistocene.” Unpublished Ph.D. dissertation, Institute of Oceanography, Qingdao, China.Google Scholar
Yan, X. Klemas, V., and Chen, D. (1992). The Western Pacific warm pool observed from space. Eos 73, 4144.CrossRefGoogle Scholar