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AMS 14C Dating on the Fossvogur Sediments, Iceland

Published online by Cambridge University Press:  18 July 2016

G J Andersen ,
J A N Heinemeier ,
H L Nielsen ,
Niels Rud ,
M S Thomsen ,
Sigfús Johnsen ,
Árný Sveinbjörnsdóttir  and
Árni Hjartarson
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Abstract

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Several new AMS 14C dates on shells from the Fossvogur sea sediments in southern Iceland are reported. Up till now, researchers have assumed that the Fossvogur sediments formed during the last interglacial period (Eem), some 100,000 years ago. However, a recent 14C determination from this location yielded an age of ca 11,000 yr. Because of the importance of these sediments for the Quaternary chronology of Iceland, further sampling for 14C dating was subsequently initiated. The present results on several shell samples collected from the Fossvogur layers strongly indicate that these sediments were formed during the warm Allerød period toward the end of the last glaciation.

Type
II. Carbon Cycle in the Environment
Information
Radiocarbon , Volume 31 , Issue 3: June 20-25, 1988 Dubrovnik, Yugoslavia , 1989 , pp. 592 - 600
Copyright
Copyright © The American Journal of Science 

References

Broecker, WS and Olson, EA, 1961, Lamont radiocarbon measurements VIII: Radiocarbon, v 3, p 176204.Google Scholar
Dansgaard, W, Clausen, HB, Gundestrup, N and Johnsen, S, 1985, Dating and climatic interpretation of two deep Greenland ice cores, in Langway, CC, Oeschger, H and Dansgaard, W, eds, Greenland ice core: Geophysics, geochemistry and the environment: Am Geophys Union, Geophys Mono 33, Climate processes and climate sensitivity (Maurice Ewing ser), p 7176.CrossRefGoogle Scholar
Eicher, U, 1980, Pollen- und Sauerstoffisotopenanalysen an spätglazialen Profilen vom Gerzensee, Faulenseemoss und vom Regenmoos ob Boltigen: Mitt Naturforsch Ges in Bern, v 37, p 6580.Google Scholar
Eicher, U and Siegenthaler, U, 1976, Palynological and oxygen isotope investigations on Late-Glacial sediment cores from Swiss lakes: Boreas, v 5, p 109117.CrossRefGoogle Scholar
Einarsson, Th, 1968, Jardfraedi. Saga bergs of lands: Reykjavik, Heimskringla, 335 p (in Icelandic).Google Scholar
Geirsdóttir, Á, 1979, Fossvogslögin: BSc thesis, Univ Iceland, 72 p (in Icelandic).Google Scholar
Heinemeier, J, Hornshøj, P, Larsen, G, Nielsen, HL, Olesen, S, Rud, N, Stensgaard, R and Thomsen, MS, 1986, Accelerator mass spectrometry at Aarhus, in Hedges, REM and Hall, ET, eds, Proc AMS Workshop: Oxford Research Lab Archaeol, p 5359.Google Scholar
Heinemeier, J, Hornshøj, P, Nielsen, HL, Rud, N and Thomsen, MS, 1987, Accelerator mass spectrometry applied to 22,24Na, 31,32Si, and 14C: Nuclear Instruments & Methods, v B29, p 110113.Google Scholar
Hjartarson, Á, 1987, Chronology of the glacial history of the Reykjavik area, in Conference on the Late Glacial history of Iceland, Proc, Reykjavík April 28, 1987: Geol Soc Iceland, p 45 (in Icelandic).Google Scholar
Hjartarson, Á and Gudjónsson, S, 1984, Reykjavíkurhöfn. Jardfraedi vid Sundin bla: Natl Energy Authority, internal rept OS-84034/VOD-04, 35 p (in Icelandic).Google Scholar
Håkansson, S, 1983, A reservoir age for the coastal waters of Iceland: Geol Fören Stockh Förh, v 105, p 6467.CrossRefGoogle Scholar
Håkansson, S, 1987, University of Lund radiocarbon dates XX: Radiocarbon, v 29, no.3, p 353379.CrossRefGoogle Scholar
Jónsson, J, 1973, Grágrýtid: Náttúrufr, v 42, p 2130 (in Icelandic).Google Scholar
Krog, H and Tauber, H, 1973, C-14 chronology of Late- and Postglacial marine deposits in North Jutland: Denm Geol Survey Yearbook, p 93105.Google Scholar
Mangerud, J, 1972, Radiocarbon dating of marine shells, including a discussion of apparent age of Recent shells from Norway: Boreas, v 2, p 143172.CrossRefGoogle Scholar
Mook, WG and Streurman, HJ, 1983, Physical and chemical aspects of radiocarbon dating: PACT, no. 8, Strassbourg, p 3155.Google Scholar
Oeschger, H, Beer, J, Siegenthaler, U, Stauffer, B, Dansgaard, W and Langway, CC, 1984, Late glacial climate history from ice cores: Am Geophys Union Mono 29, p 299.Google Scholar
Paterson, WSB and Hammer, CU, 1987, Ice core and other glaciological data, in North America and adjacent oceans during the last deglaciation, The geology of North America: Geol Soc America, v K-3, p 91109.Google Scholar
Pjeturss, H, 1904, Athugasemd urn jardlög í Fossvogi og vàdar à nágrenni Reykjavàkur: Tàmarit àsl Bókmenntafélagsins, v 25, p 4957.Google Scholar
Stuiver, M and Polach, HA, 1977, Discussion: Reporting of 14C data: Radiocarbon, v 19, no. 3, p 355363.Google Scholar
Thomsen, MS, Heinemeier, J, Hornshøj, P and Rud, N, 1987, Isotopic ratio of 22,24Na measured by accelerator mass spectrometry: Nuclear Instruments & Methods, v B28, p 433437.CrossRefGoogle Scholar
Thomsen, MS, Heinemeier, J, Hornshøj, P, Nielsen, HL and Rud, N, 1988, Accelerator mass spectrometry applied to 32Si: Nuclear Instruments & Methods, v B31, p 425432.CrossRefGoogle Scholar
Wegmüller, S and Welten, M, 1973, Spätglaziale Bimstufflagen des Laacher Vulkanismus im Gebiet der westlichen Schweiz und der Dauphiné (F): Eclogae geol Helv, v 66, p 533541.Google Scholar
Vogel, JS, Southon, JR, Nelson, DE and Brown, TA, 1984, Performance of catalytically condensed graphite for use in accelerator mass spectrometry: Nuclear Instruments & Methods, v B5, p 289293.CrossRefGoogle Scholar