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Quaternary Sea Level Fluctuations on a Tectonic coast: New 230Th/234U Dates from the Huon Peninsula, New Guinea

Published online by Cambridge University Press:  20 January 2017

A.L. Bloom
Affiliation:
Cornell University, Ithaca, New York, USA.
W.S. Broecker
Affiliation:
Columbia University, New York, New York, USA.
J.M.A. Chappell
Affiliation:
Australian National University, Canberra, Australia.
R.K. Matthews
Affiliation:
Brown University, Providence, Rhode Island, USA.
K.J. Mesolella
Affiliation:
Weaver Oil and Gas Co., Houston, Texas, USA.

Abstract

Emerged coral reef terraces on the Huon Peninsula in New Guinea were reported in a reconnaissance dating study by Veeh and Chappell 1970. Age definition achieved was not good for several important terraces, and we report here a series of new 230Th/234U dates, which further clarify the history of late Quaternary eustatic sea level fluctuations. More than 20 reef complexes are present, ranging well beyond 250,000 yr old: we are concerned with the seven lowest complexes. Major reef-building episodes dated by 30Th/234U are reef complex I at 5–9 ka (kilo anno = 1000 yr), r.c. IIIb at 41 ka (four dates), r.c. IV at 61 ka (four dates), r.c. V at 85 ka (two dates), r.c. VI at 107 ka (two dates), and r.c. VII at 118–142 ka. Complex II was previously dated by 14C at 29 ka: this age has not yet been confirmed, and may be only a lower limit. The reef crests were built during or immediately before intervals of sea level maxima, when rates of rising sea level and tectonic uplift briefly coincided. The culmination of each reef-building episode was only a few thousand years in duration, and multiple dates from the same reef complex generally group within the statistical errors of the individual dates.

Several methods can be used to estimate the altitude of each sea level maximum relative to present sea level. The least complicated is to calculate mean tectonic uplift rate for each profile of the terraces, and use the mean rate to calculate the tectonic displacement of each dated reef complex on that profile. The difference between the present altitude of a reef complex and its calculated tectonic uplift gives the paleosea level at the time the reef grew. We estimate uplift rates for six surveyed sections by calibrating against published paleosea level estimates from Barbados and elsewhere, viz 125 ka, paleosea at +6 m; 103 ka, −15 m; 82 ka, −13 m. For each section the individual uplift rates for reefs V, VI, and VIIb are within 5% of their section means. Using the mean rates. paleosea level estimates for reef crests II, IIIB, and IV are made for each section. Consistency of estimates between sections is good, giving −28 m for the 60 ka paleosea level, around −38 m for the 42 ka level and −41 m for the 28 ka level (if the age is older the paleosea level would be lower. Using the mean uplift rates, the 82 ka and 103 ka paleosea levels are also estimated for each section: all individual estimates are plotted graphically, and a sea level curve drawn. The reef stratigraphy indicates sea level lowerings between each dated reef crest: the crests probably represent the interstadials of the Wisconsin (Würm, Weichsel) Glaciation, and intervening lower levels correspond to stadials. Since the last time of eustatic sea level higher than the present (about 125 ka), five sea level maxima occurred at roughly 20-ka intervals, none being as high as the present.

Type
Original Articles
Copyright
University of Washington

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References

Allied Intelligence Documents, 2nd World War(1943). New Guinea geographical data. Objective folder. 73, and associated reports.Google Scholar
Bloom, A.L., (1971). Glacial eustatic and isostatic controls of sea level since the last glaciation. Turekian, K.K., Late Cenozoic glacial ages Yale Univ. Press, New Haven 355379.Google Scholar
Broecker, W.S., Donk, J.van, (1970). Isolation changes, ice volumes, and O18 record in deep sea cores. Reviews, Geophysics and Space Physics 8, 169198.CrossRefGoogle Scholar
Broecker, W.S., Thurber, D.L., (1965). Uranium-series dating of corals and oolites from Bahamian and Florida Key limestones. Science 149, 5860.CrossRefGoogle Scholar
Broecker, W.S., Thurber, D.L., Goddard, John, Ku, Teh-Lung, Matthews, R.K., Mesolella, K.J., (1968). Milankovitch hypothesis supported by precise dating of coral reefs and deep-sea sediments. Science 159, 297300.CrossRefGoogle ScholarPubMed
Chappell, J.M.A., (1974). Upper mantle rheology in a tectonic region: evidence from New Guinea. Journal of Geophysical Research 79, 390398.CrossRefGoogle Scholar
Chappell, J.M.A., (1974). Geology of coral terraces, Huon Peninsula, New Guinea: a study of Quaternary tectonic movements and sea level changes. Geological Society of America Bulletin 85, 553570.2.0.CO;2>CrossRefGoogle Scholar
Chappell, J.M.A., Polach, H.A., (1972). Some effects of partial recrystallization on 14C dating late Pleistocene corals and molluscs. Quaternary Research 2, 244252.CrossRefGoogle Scholar
Chappell, J. M. A., Broecker, W. S., Polach, H. Z., Thom, B. G., (1973). (in press). Problem of dating upper Pleistocene sea levels from coral reef areas. Great Barrier Reef Expedition 1973, Proc. , Univ. of Queensland.Google Scholar
Curray, J.R., Shepard, F.P., (1972). Some major problems of Holocene sea levels. Abstracts, Second National Conference. AMQUA1618.Google Scholar
Darwin, Charles, (1842). Structure and Distribution of Coral Reefs. 214plus plates, 1962.Google Scholar
Dreimanis, A., Karrow, P.F., (1972). Glacial history of the Great Lakes-St. Lawrence region, the classification of the Wisconsin (an) Stage, and its correlatives. International Geological Congress, 24th Session. 515Section 12.Google Scholar
Fairbridge, R.W., (1960). The changing level of the sea. Scientific American 202, 7079.CrossRefGoogle Scholar
Guirtman, G., Miller, D.S., Friedman, G.M., (1972). Control and distribution of uranium in coral reefs during diagenesis. (Abstr.). Geological Society of America 4, n. 7 522523.Google Scholar
Husseini, S.I., Matthews, R.K., (1972). Distribution of high-magnesium calcite in lime muds of the Great Bahama Bank—diagenetic implications. Journal Sedimentary Petrology 42, 179182.Google Scholar
James, N.P., Mountjoy, E.W., Omura, Akio, (1971). an Early Wisconsin reef terrace at Barbados, West Indies and its climatic implications. Geological Society of America Bulletin v. 82, 20112018.CrossRefGoogle Scholar
Kaufman, A., (1964). Th230-U234 dating of carbonates from Lakes Lahontin and Bonneville. Ph.D. thesis Columbia Univ, NY.Google Scholar
Konishi, Kenji, Schlanger, S.O., Omura, Akio, (1970). Neotectonic rates in the central Ryukyu Islands derived from 230Th coral ages. Marine Geology 9, 225240.CrossRefGoogle Scholar
Ku, T.L., (1974). Eustatic sea level 120,000 years ago on Oahu, Hawaii. Science (in press).CrossRefGoogle Scholar
Labeyrie, J., Lalou, C., Delibrias, G., (1969). Etude des transgressions marines sur l'atoll de Mururoa par la datation des différents niveaux de corail. Mururoa: Direction de Centres D'Expérimentations Nucléaires. Service Mixte de Controle Biologique 203212.Google Scholar
Land, L.S., MacKenzie, T.F., Gould, S.J., (1967). Pleistocene history of Bermude. Geological Society of America Bulletin 78, 993.CrossRefGoogle 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, 250274.CrossRefGoogle Scholar
Moore, W.S., Somayajulu, B.L.K., (1974). Age determinations of fossil corals using Th230/Th234 and Th230/Th227. .Google Scholar
Plafker, G., (1972). Alaskan earthquake of 1964 and Chilean earthquake of 1960: implications for are tectonics. Journal of Geophysical Research 77, 901925.CrossRefGoogle Scholar
Polach, H.D., Chappell, J.M.A., Lovering, J.F., (1969). ANU radiocarbon Date List III. Radiocarbon 11, 245262.CrossRefGoogle Scholar
Prest, V.K., (1970). Quaternary geology of Canada. Geology and Economic Minerals of Canada. fifth edition Econ. Geol. Rept. No. 1 Dept. Energy, Mines and Resources, Ottawa, Canada 676764.Google Scholar
Putnam, W.C., Axelrod, D.I., Bailey, H.P., McGill, J.T., (1960). Natural coastal environments of the world. University of California, Los Angeles 140.Google Scholar
Steinen, R.P., Harrison, R.S., Matthews, R.K., (1973). Eustatic low stand of sea level between 125,000 and 105,000 B.P.: Evidence from the sub-surface of Barbados, West Indies. Geological Society America Bulletin v 84, 6370.2.0.CO;2>CrossRefGoogle Scholar
Stuiver, M., (1970). Tree ring, varve and Carbon 14 chronologies. Nature (London) 228, 454455.CrossRefGoogle ScholarPubMed
Thurber, D.L., Broecker, W.S., Blanchard, R.L., Potratz, H.A., (1965). Uranium-series ages of Pacific atoll coral. Science 149, 5558.CrossRefGoogle ScholarPubMed
Veeh, H.H., (1966). Th230/U238 and U234/U238 ages of Pleistocene high sea level stand. Journal of Geophysical Research 71, 33793386.CrossRefGoogle Scholar
Veeh, H.H., Chappell, J.M.A., (1970). Astronomic theory of climatic change: support from New Guinea. Science 167, 862865.CrossRefGoogle ScholarPubMed
Willman, H.B., Frye, J.C., (1970). Pleistocene stratigraphy of Illinois. Illinois Geological Survey Bulletin 94, 204.Google Scholar
Yoshikawa, Torao, (1970). On the relations between Quaternary tectonic movement and seismic crustal deformation in Japan. Bulletin of the Department of Geography, University of Tokyo 2, 124.Google Scholar