Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-25T08:35:52.379Z Has data issue: false hasContentIssue false
  • English
  • Français

Why Early-Historical Radiocarbon Dates Downwind from the Mediterranean are Too Early

Published online by Cambridge University Press:  18 July 2016

Douglas J Keenan
Douglas J Keenan*
Affiliation:
The Limehouse Cut, London E14 6N, United Kingdom. Email: [email protected].
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Several authors have claimed that radiocarbon dates in the Ancient Near East are too early. Herein, a hypothesis that might explain this is presented. Marine degassing of “old” carbon (i.e. 14C-deficient C), induced by upwelling of old subsurface water, has been observed, in modern times, to cause century-scale 14C ages in the surface atmosphere. A review of the Mediterranean Sea post-ice-age circulation concludes that the subsurface waters became very old, primarily due to millennia-long stagnation. It is hypothesized that as the stagnation ended, subsurface waters were brought towards the surface, where they degassed old carbon. Additionally, Anatolian dendrochronology is shown to not contradict the hypothesis.

Type
Discussion
Information
Radiocarbon , Volume 44 , Issue 1 , 2002 , pp. 225 - 237
Copyright
Copyright © 2002 by the Arizona Board of Regents on behalf of the University of Arizona 

References

Aksu, AE, Yasar, D, Mudie, PJ. 1995. Paleoclimatic and paleoceanographic conditions leading to development of sapropel layer S1 in the Aegean Sea. Palaeogeography, Palaeoclimatology, Palaeoecology 116:71101.Google Scholar
Aksu, AE, Hiscott, RN, Yasar, D. 1999. Oscillating Quaternary water levels of the Marmara Sea. Marine Geology 153:275302.Google Scholar
Arthur, MA, Dean, WA. 1998. Organic-matter production and preservation and evolution of anoxia in the Holocene Black Sea. Paleoceanography 13:395411.Google Scholar
Arya, SP. 1999. Air pollution meteorology and dispersion. Oxford University Press.Google Scholar
Asioli, A. 1996. High resolution foraminifera biostratigraphy in the central Adriatic basin during the last deglaciation. Memorie dell'Istituto Italiano di Idrobiologia 55:197217. (See especially Figure 5) Google Scholar
Baillie, MGL. 1995. A slice through time: dendrochronology and precision dating. Chapter 3. London: Batsford.Google Scholar
Barry, RG, Chorley, RJ. 1998. Atmosphere, weather & climate. Routledge. (See especially Figures 8.27, 8.29) Google Scholar
Bhushan, R, Krishnaswami, S, Somayajulu, BLK. 1997. 14C in air over the Arabian Sea. Current Science 73:273–6.Google Scholar
Bonani, G, Haas, H, Hawass, Z, Lehner, M, Nakhla, S, Nolan, J, Wenke, R, Wölfli, W. 2001. Radiocarbon dates of Old and Middle Kingdom monuments in Egypt. Radiocarbon 43(3):1297–320. (See also Haas and Doubrava [1998], referenced by Bonani et al.) Google Scholar
Braziunas, TF, Fung, I Y, Stuiver, M. 1995. The preindustrial atmospheric 14CO2 latitudinal gradient as related to exchanges among atmospheric, oceanic, and terrestrial reservoirs. Global Biogeochemical Cycles 9:565–84.Google Scholar
Bruins, HJ. 2001. Near East chronology: towards an integrated 14C time foundation. Radiocarbon 43(3):1147–54.Google Scholar
Bruins, HJ, van der Plicht, J. 2001. Radiocarbon challenges archaeo-historical time frameworks in the Near East: the Early Bronze Age of Jericho in relation to Egypt. Radiocarbon 43(3):1321–32.CrossRefGoogle Scholar
Bryden, HL, Candela, J, Kinder, TH. 1994. Exchange through the Strait of Gibraltar. Progress in Oceanography 33:201–48.CrossRefGoogle Scholar
Calvert, SE, Nielsen, B, Fontugne, MR. 1992. Evidence from nitrogen isotope ratios for enhanced productivity during formation of eastern Mediterranean sapropels. Nature 359:223–5.Google Scholar
Capotondi, L, Borsetti, AM, Morigi, C. 1999. Foraminiferal ecozones, a high resolution proxy for the late Quaternary biochronology in the central Mediterranean Sea. Marine Geology 153:253–74. (See especially Figure 9) Google Scholar
Chouhan, SL, Davis, PA. 2001. Testing the atmospheric dispersion model of CSA N288.1 with site-specific data. AECL 12099. (Atomic Energy of Canada Limited report series: ISSN 0067-0367) Google Scholar
Copin-Montégut, C. 1993. Alkalinity and carbon budgets in the Mediterranean Sea. Global Biogeochemical Cycles 7:915–25.Google Scholar
Crawford, H. 1991. Sumer and the Sumerians. Cambridge University Press. p 1820.Google Scholar
Cryer, FH. 1995. Chronology: issues and problems. In: Sasson, JM, editor. Civilizations of the Ancient Near East. Macmillan. p 651–64.Google Scholar
Damon, PE, Burr, G, Peristykh, AN, Jacoby, GC, D'Arrigo, RD. 1996. Regional radiocarbon effect due to thawing of frozen earth. Radiocarbon 38(3):597602.Google Scholar
Dickinson, O. 1994. The Aegean Bronze Age. Cambridge University Press. p 1720.Google Scholar
Dutta, K, Bushan, R, Somayajula, BLK. 2000. Anthropogenic radiocarbon in Bay of Bengal. Paper presented at the 17th International Radiocarbon Conference. Judean Hills, Israel, June 2000.Google Scholar
Facorellis, Y, Maniatis, Y, Kromer, B. 1998. Apparent 14C ages of marine mollusk shells from a Greek island: calculation of the marine reservoir effect in the Aegean Sea. Radiocarbon 40(2):963–73.Google Scholar
Fontugne, MR, Paterne, M, Calvert, SE, Murat, A, Guichard, F, Arnold, M. 1989. Adriatic deep water formation during the Holocene. Paleoceanography 4:199206.Google Scholar
Fontugne, M, Arnold, M, Labeyrie, L, Paterne, M, Calvert, SE, Duplessy, J-C. 1994. Paleoenvironment, sapropel chronology and Nile river discharge during the last 20,000 years as indicated by deep-sea sediment records in the eastern Mediterranean. In: Bar-Yosef, O, Kra, RS, editors. Late Quaternary chronology and paleoclimates of the eastern Mediterranean. Tucson: Radiocarbon. p 7588.Google Scholar
Gasse, F, Van Campo, E. 1994. Abrupt post-glacial events in West Asia and North Africa monsoon domains. Earth and Planetary Science Letters 126:435–46. (See section 3.2) CrossRefGoogle Scholar
Görsdorf, J, Dreyer, G, Hartung, U. 1998. New 14C dating of the archaic royal necropolis Umm El-Qaab At Abydos (Egypt). Radiocarbon 40(2):641–7.Google Scholar
Goyet, C, Bradshaw, AL, Brewer, PG. 1991. The carbonate system in the Black Sea. Deep-Sea Research 38: S1049S1068.CrossRefGoogle Scholar
Guidi, A, Whitehouse, R. 1996. A radiocarbon chronology for the Bronze Age: the Italian situation. Acta Archaeologica 67:271–82.Google Scholar
Hagens, G. 1996. A critical review of dead-reckoning from the 21st dynasty. Journal of the American Research Center in Egypt 33:153–63.CrossRefGoogle Scholar
Hiscock, WT, Murray, JW. 2002. Knorr 2001 cruise data. [Available at http://www.ocean.washington.edu/cruises/Knorr2001/CruiseData.htm.]Google Scholar
Hua, Q, Barbetti, M, Jacobsen, GE, Zoppi, U, Lawson, EM. 2000a. Bomb radiocarbon in annual tree rings from Thailand and Australia. Nuclear Instruments and Methods in Physics Research B 172:359–65.CrossRefGoogle Scholar
Hua, Q, Barbetti, M, Zoppi, U, Lawson, EM. 2000b. Regional reduction of atmospheric 14C by upwelling in the tropical Indian Ocean. Paper presented at the 17th International Radiocarbon Conference. Judean Hills, Israel. June 2000.Google Scholar
Hubberten, H-W, Bruns, M, Calamiotou, M, Apostolakis, C, Filippakis, S, Grimanis, A. 1990. Radiocarbon dates from the Akrotiri excavations. In: Hardy, DA, editor. Thera and the Aegean world III. Volume 3. London: Thera Foundation. p 179–87.Google Scholar
James, P. 1991. Centuries of darkness London: Jonathan Cape. (For references to reviews and follow-up work, see http://www.centuries.co.uk)Google Scholar
Jirikowic, JL, Kalin, RM. 1993. A possible paleoclimatic ENSO indicator in the spatial variation of annual tree-ring 14C. Geophysical Research Letters 20:439–42.Google Scholar
Jones, GA, Gagnon, AR. 1994. Radiocarbon chronology of Black Sea sediments. Deep-Sea Research I 41:531–57.Google Scholar
Jorissen, FJ. 1999. Benthic foraminiferal successions across Late Quaternary Mediterranean sapropels. Marine Geology 153:91101.CrossRefGoogle Scholar
Jorissen FJ and nine others. 1993. Late Quaternary central Mediterranean biochronology. Marine Micropaleontology 21:169189.Google Scholar
Kallel N, Paterne M and seven others. 1997. Enhanced rainfall in the Mediterranean region during the last sapropel event. Oceanologica Acta 20:697712.Google Scholar
Keller, J, Rehren, T, Stadlbauer, E. 1990. Explosive volcanism in the Hellenic Arc. In: Hardy, DA, editor. Thera and the Aegean world III. Volume 2. London: Thera Foundation. p 1326.Google Scholar
King, KJ, Carter, B. 1999. Estimates of atmospheric 14C Discharges from CANDU facilities. CANDU Owners Group Reports 176. (Additional data supplied by K J King, private communication, January 2002) Google Scholar
Knapp, AB. 1992. Mesopotamia, history of (chronology). In: Freeman, DN, editor. The Anchor Bible dictionary. Volume 4. Doubleday. p 714–20.Google Scholar
Kromer, B, Fasani, L, Kuniholm, PI, Manning, S. 1997. Precise absolute dates of archaeological sites by 14C wiggle-matching of floating tree-ring sections. Paper presented at the 16th International Radiocarbon Conference. Groningen, The Netherlands. June 1997.Google Scholar
Kuniholm, PI. 2001. Aegean Dendrochronology Project December 2001 progress report. [Available at http://www.arts.cornell.edu/dendro/2001news/adp2001.html]Google Scholar
Kuniholm, PI, Tarter, SL, Griggs, CB. 1993. Dendrochronological report. In: Summers, GD, editor. Tille Höyük 4. Appendix 2. British Institute of Archaeology at Ankara.Google Scholar
Kuniholm, PI, Kromer, B, Manning, SW, Newton, M, Latini, CE, Bruce, MJ. 1996. Anatolian tree rings and the absolute chronology of the eastern Mediterranean, 2200-718 BC. Nature 381:780783. (Annotations by C Renfrew on pages 733–4) Google Scholar
Lane-Serff, GF, Rohling, EJ, Bryden, HL, Charnock, H. 1997. Postglacial connection of the Black Sea to the Mediterranean and its relation to the timing of sapropel formation. Paleoceanography 12:169–74.Google Scholar
Lange, M. 1998. Wadi Shaw 82/52: 14C dates from a peri-dynastic site in northwest Sudan, supporting the Egyptian historical chronology. Radiocarbon 40(2):687692.CrossRefGoogle Scholar
Lassey, KR, Manning, MR, O'Brien, BJ. 1990. An overview of oceanic radiocarbon. Reviews in Aquatic Sciences 3:117–46.Google Scholar
Levin, I, Kromer, B, Wagenbach, D, Münnich, KO. 1987. Carbon isotope measurements of atmospheric CO2 at a coastal station in Antarctica. Tellus 39B:8995.Google Scholar
Levin, I, Kromer, B, Barabas, M, Münnich, KO. 1988. Environmental distribution and long-term dispersion of reactor 14CO2 around two German nuclear power plants. Health Physics 54:149–56.Google Scholar
Lewis, E, Wallace, DWR. 1998. Program developed for CO2 system calculations. ORNL/CDIAC 105. Oak Ridge: Oak Ridge National Laboratory. (The CO2SYS program and documentation are available via http://cdiac.esd.ornl.gov/oceans/co2rprt.html)Google Scholar
Lueck, RG, Mudge, TD. 1997. Topographically induced mixing around a shallow seamount. Science 276:1831–3.Google Scholar
Martinez-Ruiz, F, Kastner, M, Paytan, A, Ortega-Huertas, M, Bernasconi, SM. 2000. Geochemical evidence for enhanced productivity during S1 sapropel deposition in the eastern Mediterranean. Paleoceanography 15:200–9.Google Scholar
Mazar, A. 1992. Archaeology of the land of the Bible. Doubleday. p 28–9.Google Scholar
Merrillees, RS. 1992. The absolute chronology of the Bronze Age in Cyprus. Bulletin of the American Schools of Oriental Research 288:4752.Google Scholar
Monserud, RA. 1986. Time-series analyses of tree-ring chronologies. Forest Science 32:349–72.Google Scholar
Murat, A, Got, H. 2000. Organic carbon variations of the eastern Mediterranean Holocene sapropel: a key for understanding formation processes. Palaeogeography, Palaeoclimatology, Palaeoecology 158:241–57.CrossRefGoogle Scholar
Myers, PG, Haines, K, Rohling, EJ. 1998. Modeling the paleocirculation of the Mediterranean: the last glacial maximum and the Holocene with emphasis on the formation of sapropel S1 . Paleoceanography 13:586606.Google Scholar
Nelson, DE, Vogel, JS, Southon, JR. 1990. Another suite of confusing radiocarbon dates for the destruction of Akrotiri. In: Hardy, DA, editor. Thera and the Aegean world III. Volume 3. London: Thera Foundation. p 197206. (See especially p 206) Google Scholar
New, M, Hulme, M, Jones, P. 1999. Representing twentieth-century space–time variability. Part I: development of a 1961–90 mean monthly terrestrial climatology. Journal of Climate 12:829–56. [See also http:// ipcc-ddc.cru.uea.ac.uk/cru_data/cru_index.html]Google Scholar
Nicholson, SE. 1996. A review of climate dynamics and climate variability in eastern Africa. In: Johnson, TC, Odada, EO, editors. Limnology, Climatology and Paleoclimatology of the East African Lakes. Gordon and Breach. p 2556. (See especially Figure 2) Google Scholar
Otlet, RL, Walker, AJ, Fulker, MJ. 1990. Survey of the dispersion of 14C in the vicinity of the UK reprocessing site at Sellafield. Radiocarbon 32(1):2330.Google Scholar
Pasquill, F, Smith, FB. 1983. Atmospheric diffusion. John Wiley.Google Scholar
Reddaway, JM, Bigg, GR. 1996. Climatic change over the Mediterranean and links to the more general atmospheric circulation. International Journal of Climatology 16:651–61. (Additional data supplied by J M Reddaway, private communication 1998) Google Scholar
Roberts N, Reed JM. and nine others. 2001. The tempo of Holocene climatic change in the eastern Mediterranean region. The Holocene 11:721–36.Google Scholar
Rohl, DM. 1995. A test of time: pharaohs and kings. London: Century. (See especially Chapters 1–6) Google Scholar
Rossignol-Strick, M. 1983. African monsoons, an immediate climate response to orbital insolation. Nature 304:46–9.Google Scholar
Rozanski, K, Levin, I, Stock, J, Guevara Falcon, RE, Rubio, F. 1995. Atmospheric 14CO2 variations in the equatorial region. Radiocarbon 37(2):509–15.CrossRefGoogle Scholar
van Santvoort PJM., de Lange GJ, Thomson J and four others. 1996. Active post-depositional oxidation of the most recent sapropel (S1) in sediments of the Eastern Mediterranean Sea. Geochimica et Cosmochimica Acta 60:4007–24.Google Scholar
Siegenthaler, U. 1989. Carbon-14 in the oceans. In: Fritz, P, Fontes, J-C, editors. Handbook of environmental isotope geochemistry 3. Elsevier. p 75137.Google Scholar
Stanley, DJ, Galili, E. 1996. Sediment dispersal along northern Israel coast during the early Holocene. Marine Geology 130:11–7.Google Scholar
Stuiver, M, Reimer, PJ, Bard, E, Beck, JW, Burr, GS, Hughen, KA, Kromer, B, McCormac, G, van der Plicht, J, Spurk, M. 1998. INTCAL98 radiocarbon age calibration. Radiocarbon 40(3):1041–83.Google Scholar
Taha, MF, Harb, SA, Nagib, MK, Tantawy, AH. 1981. The climate of the Near East. In: Takahashi, K, Arakawa, H, editors. World survey of climatology 9: climates of southern and western Asia. Chapter 3. Elsevier. (See especially Table V) Google Scholar
Thomson, J, Higgs, NC, Wilson, TRS, Croudace, IW, de Lange, GJ, van Santvoort, PJM. 1995. Redistribution and geochemical behaviour of redox-sensitive elements around S1, the most recent eastern Mediterranean sapropel. Geochimica et Cosmochimica Acta 59:3487–501.Google Scholar
Tinè, S. 1998. Unacceptable anomalies or incorrect use of radiocarbon dating in Sardinia? In: Balmuth, MS, Tykot, RH, editors. Sardinian and Aegean chronology. Chapter 6. Oxford: Oxbow Books.Google Scholar
Tong, H. 1990. Non-linear time series Oxford University Press.Google Scholar
Troelstra, SR, Ganssen, GM, van der Borg, K, de Jong, AFM. 1991. A Late Quaternary stratigraphic framework for eastern Mediterranean sapropel S1. Radiocarbon 33(1):1521.Google Scholar
Vergnaud-Grazzini C. and six others. 1989. Mediterranean outflow through the Strait of Gibraltar since 18 000 years BP. Oceanologica Acta 12:305–24.Google Scholar
Weinstein, J. 1989. Review: chronologies in the Near East. Radiocarbon 31(1):101–3.Google Scholar
Wiener, M and 12 others. 1995. Discussion. Ägypten und Levante 5:121–32.Google Scholar
Wu, P, Haines, K. 1996. Modeling the dispersal of Levantine intermediate water and its role in Mediterranean deep water formation. Journal of Geophysical Research 101:6591–607.Google Scholar
Yamaguchi, DK. 1986. Interpretation of cross correlation between tree-ring series. Tree-Ring Bulletin 46:4754.Google Scholar