Hostname: page-component-77c89778f8-rkxrd Total loading time: 0 Render date: 2024-07-21T02:36:29.237Z Has data issue: false hasContentIssue false
  • English
  • Français

Implications of the Radiocarbon Timescale for Ice-Sheet Chronology and Sea-Level Change

Published online by Cambridge University Press:  20 January 2017

A. Mark Tushingham  and
W. Richard Peltier
Get access Rights & Permissions [Opens in a new window]

Abstract

A new extended radiocarbon calibration curve has allowed a reexamination of relative sea-level data based on pre-Holocene dates. At sites located far from any Late Pleistocene ice sheet, the effect of employing this new calibration curve is that the calibrated data (with ages up to 17,100 14C yr B.P.) now agree with the corresponding relative sea-level curve predicted by the ICE-3G deglaciation model. An important implication of this new calibration curve is that the last glacial maximum (ca. 18,000 14C yr B.P.) is inferred to have occurred 22,000-21,000 cal yr B.P. This allows for additional ice to be incorporated in a revised deglaciation model than suggested by ICE-3G. The predicted relative sealevel curves of this new model match the relative sea-level data as well as those of ICE-3G. Further, the total sea-level rise of 124 m at Barbados since the last glacial maximum predicted by this new model agrees with the estimated value of 121 ± 5 m obtained from the depths of drowned reef-crest corals.

Type
Short Paper
Information
Quaternary Research , Volume 39 , Issue 1 , January 1993 , pp. 125 - 129
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

Al-Asfour, T. A. (1982). “Changing Sea Level along the North Coast of Kuwait Bay.” Kegan Paul International, Boston.Google Scholar
Bard, E. Hamelin, B. Fairbanks, R. G., and Zindler, A. (1990a). Calibration of the 14C timescale over the past 30,000 years using mass spectrometric U-Th ages from Barbados corals. Nature 345, 405410.Google Scholar
Bard, E. Hamelin, B. Fairbanks, R. G. Zindler, A. Mathieu, G., and Arnold, M. (1990b). U-Th and 14C ages of corals from Barbados and their use for calibrating the 14C time scale beyond 9000 years B.P. Nuclear Instruments and Methods in Physics Research B52, 461468.Google Scholar
Becker, B. Kromer, B., and Trimborn, P. (1991). A stable-isotope tree-ring timescale of the Late Glacial/Holocene boundary. Nature 353, 647649.CrossRefGoogle Scholar
Chappell, J., and Polach, H. (1991). Post-glacial sea-level rise from a coral record at Huan Peninsula, Papua New Guinea. Nature 349, 147149.Google Scholar
Craddock, C. Anderson, J. J., and Webers, G. F. (1964). Geologic outline of the Ellsworth Mountains. In “Antarctic Geology” (Aide, J. R., Ed.), pp. 155170. North-Holland, Amsterdam.Google Scholar
Dehant, V. Loutre, M.-F., and Berger, A. (1990). Potential impact of the Northern Hemisphere Quaternary ice sheets on the frequencies of the astroclimatic orbital parameters. Journal of Geophysical Research 95, 75737578.CrossRefGoogle Scholar
Delibrias, G. (1974). Variations du niveau de la mer, sur la côte ouest africaine, depuis 26,000 ans. Colloques International du C.N.R.S. 219, 127134.Google Scholar
Denton, G. H., and Hughes, T. (1981). “The Last Great Ice Sheet.” Wiley, New York.Google Scholar
Donner, J. (1968). The late-glacial and post-glacial shoreline displacement in southwest Finland. In “Means of Correlation of Quaternary Successions” (Morrison, R. B. and Wright, H. E. Jr., Eds.), pp. 367373. Univ. Utah Press, Salt Lake City.Google Scholar
Dyke, A. S., and Prest, V. K. (1987). Late Wisconsinan and Holocene history of the Laurentide Ice Sheet. Géographie physique et Quater-naire 41, 237263.Google Scholar
Fairbanks, R. G. (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.Google Scholar
Grosswald, M. G. (1980). Late Weichselian ice sheet of northern Eurasia. Quaternary Research 13, 132.Google Scholar
Grosswald, M. G. (1990). An ice sheet on the East Siberian Shelf in the Late Pleistocene. Polar Geography and Geology 14, 294304.CrossRefGoogle Scholar
Hamelin, B. Bard, E. Zindler, A., and Fairbanks, R. G. (1991). 234U/238U mass spectrometry of corals: how accurate is the U-Th age of the last interglacial period? Earth and Planetary Science Letters 106, 169180.Google Scholar
Hardy, L. (1976). “Contribution à l’étude géomorphologique de la portion québécoise des Basses Terres de la Baie de James.” Unpublished Ph.D. dissertation, McGill University, Montreal, Canada.Google Scholar
Hays, J. D. Imbrie, J., and Shackleton, N. J. (1977). Variations in the Earth’s orbit: Pacemaker of the ice age. Science 194, 11211132.Google Scholar
Hillaire-Marcel, C. (1980). Multiple component post-glacial emergence. In “Earth Rheology, Isostasy, and Eustasy” (Mörner, N.-A., Ed.), pp. 215230. Wiley, New York.Google Scholar
Hyde, W. T., and Peltier, W. R. (1987). Sensitivity experiments with a model of the ice age cyc)e: The response to Milankovitch forcing. Journal of Atmospheric Sciences 44, 13511374.Google Scholar
Mazaud, A. Laj, C Bard, E. Arnold, M., and Tric, E. (1991). Geomagnetic field control of 14C production over the last 80 ky: Implications for the radiocarbon time-scale. Geophysical Research Letters 18, 18851888.Google Scholar
Pearson, G. W. Pilcher, J. R. Baillie, M. G. I. Corbett, D. M., and Qua, F. (1986). High precision 14C measurements of Irish oaks to show the natural 14C variations from AD 1840-5210 BC. Radiocar-bon 28, 911934.Google Scholar
Peltier, W. R. (1988). Lithospheric thickness, Antarctic deglaciation history, and ocean basin discretization effects in a global model of post-glacial sea level change: A summary of some sources of non-uniqueness. Quaternary Research 29, 93112.Google Scholar
Peltier, W. R. (1989). Mantle viscosity. In “Mantle Convection; Plate Tectonics and Global Dynamics” (Peltier, W. R., Ed.), pp. 389478. Gordon and Breach Science, New York.Google Scholar
Pettier, W. R. (1991). The ICE-3G model of late Pleistocene deglacia-tion: Construction, verification, and applications. In “Glacial Isos-tasy, Sea-Level and Mantle Rheology” (Sabadini, R. et al., Eds.), pp. 95119. Kluwer Academic, Amsterdam.Google Scholar
Stuiver, M. Braziunas, T. F. Becker, B., and Kromer, B. (1991). Climate, solar, oceanic, and geomagnetic influences on Late-Glacial and Holocene atmospheric 14C/12C change. Quaternary Research 35, 124.CrossRefGoogle Scholar
Tjia, H. D. Fujii, S. Kigoshi, K., and Sugimura, A. (1975). Additional dates on raised shorelines in Malaysia and Indonesia. Sains Malay-siana 4, 6984.Google Scholar
Tushingham, A. M. (1989). “A Global Model of Late Pleistocene De-glaciation: Implications for Earth Structure and Sea Level Change.” Unpublished Ph.D. dissertation, University of Toronto, Canada.Google Scholar
Tushingham, A. M., and Peltier, W. R. (1991). ICE-3G: A new model of late Pleistocene deglaciation on geophysical predictions of postglacial relative sea level change. Journal of Geophysical Research 96, 44974523.Google Scholar
Vogel, J. C, and Marais, M. (1971). Pretoria radiocarbon dates I. Radiocarbon 13, 378394.Google Scholar
Vogel, J. C., and Visser, E. (1981). Pretoria radiocarbon dates II. Radiocarbon 23, 4380.Google Scholar