Hostname: page-component-586b7cd67f-t8hqh Total loading time: 0 Render date: 2024-11-29T01:02:15.025Z Has data issue: false hasContentIssue false
  • English
  • Français

Absolute Production of Radiocarbon and the Long-Term Trend of Atmospheric Radiocarbon

Published online by Cambridge University Press:  18 July 2016

Tomasz Goslar
Tomasz Goslar*
Affiliation:
Institute of Physics, Silesian University of Technology, ul. Krzywoustego 2,44-100 Gliwice, Poland. 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.

This paper presents simulations of the long-term trend of atmospheric radiocarbon, performed with the modified PANDORA model. The author shows that taking into account the outflow-supply carbon fluxes makes the decrease of D14C between 40 and 0 ka BP larger by 40–80‰, not much depending on which data (sedimentary magnetism, archaeomagnetism or 10Be) is used for the scenario of relative variations of 14C production. This, together with the effect of CO2 increase reasonably reconciles model-simulated and observed decline of atmospheric Δ14C.

Type
I. Our ‘Dry’ Environment: Above Sea Level
Information
Radiocarbon , Volume 43 , Issue 2B: Proceedings of the 17th International Radiocarbon Conference (Part 2 of 3), Conference Editors: Israel Carmi, Elisabetta Boaretto , 2001 , pp. 743 - 749
Copyright
Copyright © 2001 by the Arizona Board of Regents on behalf of the University of Arizona 

References

Baes, CF Jr, Börkström, A, Mulholland, PJ. 1985. Uptake of carbon dioxide by the oceans. In: Trabalka, JR, editor. Atmospheric carbon dioxide and the global carbon cycle. US Department of Energy Report DOE/ER-0239.p83111.Google Scholar
Bard, E, Hamelin, B, Fairbanks, RG, Zindler, A. 1990. Calibration of 14C timescale over the past 30,000 years using mass spectrometric U-Th ages from Barbados corals. Nature 345:405–10.CrossRefGoogle Scholar
Bard, E. 1997a. Nuclide production by cosmic rays during the last ice age. Science 277:532–3.Google Scholar
Bard, E, Raisbeck, GM, Yiou, F, Jouzel, J. 1997b. Solar modulation of cosmogenic nuclide production over the last millennium: comparison between 14C and 10Be records. Earth and Planetary Science Letters 150:453–62.Google Scholar
Bard, E. 1998a. Geochemical and geophysical implications of the radiocarbon calibration. Geochimica et Cosmochimica Acta 62:2025–38.Google Scholar
Bard, E, Arnold, M, Hamelin, B, Tisnerat-Laborde, N, Cabioch, G. 1998b. Radiocarbon calibration by means of mass spectrometric 230Th/234U and 14C ages of corals: an updated database including samples from Barbados, Mururoa and Tahiti. Radiocarbon 40(3):1085–92.Google Scholar
Broecker, WS, Peng, TH, Trumbore, S, Bonani, G, Wölfli, W. 1990. The distribution of radiocarbon in the Glacial Ocean. Global Biogeochemical Cycles 4:103–17.Google Scholar
Broecker, WS, Takahashi, T. 1978. The relationship between lysocline depth and in situ carbonate ion concentration. Deep Sea Research 25:6595.CrossRefGoogle Scholar
Castagnoli, G, Lal, D. 1980. Solar modulation effects in terrestrial production of carbon-14. Radiocarbon 22(3):133–58.CrossRefGoogle Scholar
Damon, PE. 1988. Production and decay of radiocarbon and its modulation by geomagnetic field-solar activity changes with possible implications for global environment. In: Stephenson, FR, Wolfendale, W, editors. Secular solar and geomagnetic variations in the last 10,000 years. Kluwer Academic Publishers. p 315–28.Google Scholar
Damon, PE, Sternberg, RE. 1989. Global production and decay of radiocarbon. Radiocarbon 31:697703.Google Scholar
Etcheto, J, Boutin, J, Merlivat, L. 1991. Seasonal variations of the CO2 exchange coefficient over the global ocean using satellite wind speed measurements. Tellus 43B:247–55.Google Scholar
Frank, M, Schwarz, B, Baumann, S, Kubik, PW, Suter, M, Mangini, A. 1997. A 200 kyr record of cosmogenic radionuclide production rate and geomagnetic field intensity from 10Be in globally stacked deep-sea sediment. Earth and Planetary Science Letters 149:121–9.Google Scholar
Goslar, T, Arnold, M, Bard, E, Kuc, T, Pazdur, MF, Ralska-Jasiewiczowa, M, Tisnerat, N, Różański, K, Walanus, A, Wicik, B, Więckowski, K. 1995. High concentration of atmospheric 14C during the Younger Dryas cold episode. Nature 377:414–7.Google Scholar
Goslar, T, Wohlfarth, B, Björck, S, Possnert, G, Björck, J. 1999. Variations of atmospheric 14C concentrations over the Alleröd-Younger Dryas transition. Climate Dynamics 15:2942.CrossRefGoogle Scholar
Goslar, T, Arnold, M, Tisnerat-Laborde, N, Czernik, J, Więckowski, K. 2000. Variations of Younger Dryas atmospheric radiocarbon explicable without ocean circulation changes. Nature 403:877–80.Google Scholar
Guyodo, Y, Valet, JP. 1996. Relative variations in geomagnetic intensity from sedimentary records in the past 200,000 years. Earth and Planetary Science Letters 143:2336.Google Scholar
Keir, RS. 1983. Reduction of thermohaline circulation during deglaciation: the effect on atmospheric radiocarbon and CO2 . Earth and Planetary Science Letters 64: 445–56.Google Scholar
Kitagawa, H, van der Plicht, J. 1998. Atmospheric radiocarbon calibration to 45,000 yr B.P.: late glacial fluctuations and cosmogenic isotope production. Science 279:1187–90.Google Scholar
Korff, SA, Mendell, RB. 1980. Variations in radiocarbon production in the Earth's atmosphere. Radiocarbon 22:159–65.Google Scholar
Lal, D. 1988. Theoreticaly expected variations in the terrestrial cosmic-ray production of isotopes. In Solar-Terrestrial relationships and the Earth environment in the last millenia. Societa Italiana di Fisica, Bologna, Italy, 95:216–33.Google Scholar
Lal, D. 1992. Expected secular variations in the global terrestrial production rate of radiocarbon. In: Bard, E, Broecker, WS, editors. The Last Deglaciation: absolute and radiocarbon chronologies. Springer-Verlag. p 113–26.Google Scholar
Lal, D, Revelle, R. 1984. Atmospheric pCO2 changes recorded in lake sediments. Nature 308:344–6.Google Scholar
Light, ES, Merker, M, Verschell, HJ, Mendell, RB, Korff, SA. 1973. Time-dependent world wide distribution of atmospheric neutrons and of their products, II, Calculation. Journal of Geophysical Research 78:2741–62.CrossRefGoogle Scholar
Mackenzie, FT, Ver, LM, Sabine, C, Lane, M, Lerman, A. 1993. C, N, P, S global biogeochemical cycles and modeling of global change. In: Wollast, R, Mackenzie, FT, Chou, L, editors. Interactions of C, N, P and S biogeochemical cycles and global change. Springer-Verlag. p 162.Google Scholar
Mazaud, A, Laj, C, Bard, E, Arnold, M, Tric, E. 1991. Geomagnetic field control of 14C production over the last 80 ky: implications for the radiocarbon time-scale. Geophysical Research Letters 18:1885–8.Google Scholar
McElhinny, MW, Senanayake, WE. 1982. Variations in the Geomagnetic Dipole 1: the past 50,000 years. Journal of Geomagnetism and Geoelectricity 34:3951.Google Scholar
Oeschger, H, Siegenthaler, U, Schotterer, U, Gugelmann, A. 1975. A box-diffusion model to study the carbon dioxide exchange in nature. Tellus 27:169–92.Google Scholar
Olson, JS, Garrels, RM, Berner, RA, Armentano, TV, Dyer, MI, Yaalon, DH. 1985. The natural carbon cycle. In: Trabalka, JR, editor. Atmospheric carbon dioxide and the global carbon cycle. US Department of Energy Report DOE/ER-0239. p 177213.Google Scholar
Schramm, A, Stein, M, Goldstein, SL. 2000. Calibration of the 14C time scale to 40 ka by 234U-230Th dating of Lake Lisan sediments (last glacial Dead Sea). Earth and Planetary Science Letters 175:2740.Google Scholar
Siegenthaler, U, Sarmiento, JL. 1993. Atmospheric carbon dioxide and the ocean. Nature 365:119–25.Google Scholar
Stuiver, M, Braziunas, T, Becker, B, Kromer, B. 1991. Climatic, solar, oceanic, and geomagnetic influences on Late-Glacial and Holocene atmospheric 14C/12C change. Quaternary Research 35:124.CrossRefGoogle Scholar
Stuiver, M, Long, A, Kra, RS, editors. 1993. Calibration 1993. Radiocarbon 35(1):244 p.Google Scholar
Stuiver, M, van der Plicht, J, editors. 1998. INTCAL98. Radiocarbon 40(3):123 p.Google Scholar
Stuiver, M, Reimer, PJ, Bard, E, Warren Beck, J, Burr, GS, Hughen, KA, Kromer, B, McCormac, G, van der Plicht, J, Spurk, M. 1998. INTCAL98 radiocarbon age calibration, 24,000–0 cal BP. Radiocarbon 40(3):1041–83.Google Scholar
Tric, E, Valet, JP, Tucholka, P, Paterne, M, Labeyrie, L, Guichard, F, Tauxe, L, Fontugne, M. 1992. Paleointensity of the Geomagnetic field during the last 80,000 years. Journal of Geophysical Research B97:9337–51.Google Scholar
Wollast, R. 1993. Interactions of carbon and nitrogen cycles in the coastal zone. In: Wollast, R, Mackenzie, FT, Chou, L, editors. Interactions of C, N, P and S Biogeochemical Cycles and Global Change. Springer-Verlag, p 195210.CrossRefGoogle Scholar