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Shape Analysis of Cumulative Probability Density Function of Radiocarbon Dates Set in the Study of Climate Change in the Late Glacial and Holocene

Published online by Cambridge University Press:  18 July 2016

Danuta J Michczyńska  and
Anna Pazdur
Anna Pazdur
Affiliation:
Radiocarbon Laboratory, Institute of Physics, Silesian University of Technology, Krzywoustego 2, 44-100 Gliwice, Poland
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Abstract

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We report on a statistical analysis of a large set of radiocarbon dates for reconstruction of paleoclimate. Probability density functions were constructed by summing the probability distributions of individual 14C dates. Our analysis was based on 2 assumptions: 1) The amount of organic matter in sediments depends on paleogeographical conditions; 2) The number of 14C-dated samples is proportional to the amount of organic matter deposited in sediments in the examined time intervals. We quantified how many dates are required to give statistically reliable results. As an example, 785 peat dates from Poland were selected. The dates encompassed the Holocene and Late Glacial period. All dates came from the Gliwice Radiocarbon Laboratory. Results were compared with other paleoenvironmental records. Detailed analysis of the frequency distributions showed that preferential sampling plays an important part in the shape determination. The general rule to take samples from locations where visible changes of sedimentation are apparent (e.g. from the top and the bottom of the peat layer) results in narrow peaks in the probability density function near the limits of the Holocene subdivision.

Type
Part II
Information
Radiocarbon , Volume 46 , Issue 2: Proceedings of the 18th International Radiocarbon Conference (Part 2 of 2), Conference Editors: Nancy Beavan Athfield, Rodger J Sparks , 2004 , pp. 733 - 744
Copyright
Copyright © The Arizona Board of Regents on behalf of the University of Arizona 

References

Bartlein, PJ, Edwards, ME, Shafer, SL, Barker, ED. 1995. Calibration of radiocarbon ages and the interpretation of paleoenvironmental records. Quaternary Research 44:417–24.Google Scholar
Blunier, T, Chappellaz, JA, Schwander, J, Stauffer, B, Raynaud, D. 1995. Variations in atmospheric methane concentration during the Holocene epoch. Nature 374: 46–9.Google Scholar
Bluszcz, A, Michczyński, A. 1999. Statistical methods in chronostratigraphy. In: Pazdur, A, editor. Geochronology of Upper Quaternary in Poland. Wojewoda: Wind J. p 71–9. In Polish.Google Scholar
Bronk Ramsey, C. 1995. Radiocarbon calibration and analysis of stratigraphy: the OxCal program. Radiocarbon 37(2):425–30.Google Scholar
Efron, B, Tibshirani, RJ. 1993. An Introduction to the Bootstrap. New York: Chapman and Hall. 436 p.Google Scholar
Geyh, MA. 1980. Holocene sea-level history: case study of the statistical evaluation of 14C dates. Radiocarbon 22(3):695704.CrossRefGoogle Scholar
Geyh, MA, Streif, H. 1970. Studies on coastal movements and sea-level changes by means of the statistical evaluation of 14C-data. Proceedings of the “Symposium on Coastal Geodesy.” Münich, 20–24 July 1970. p 599611.Google Scholar
Goslar, T, Arnold, M, Pazdur, MF. 1998. Variations of atmospheric 14C concentrations at the Pleistocene/ Holocene transition, reconstructed from the Lake Gościąż sediment. In: Ralska-Jasiewiczowa, M, Goslar, T, Madeyska, T, Starkel, L, editors. Lake Gościąż, Central Poland. A Monographic Study. p 162–71.Google Scholar
Goździk, J, Pazdur, MF. 1987. Frequency distribution of 14C dates from Poland in the time interval 12–45 kyr BP and its palaeogeographical implications. Zeszyty Naukowe Politechniki $SAląskiej, s. Matematyka-Fizyka, z. 56, Geochronometria 4:2742.Google Scholar
Hercman, H. 2000. Reconstruction of paleoclimatic changes in Central Europe between 10 and 200 thousand years BP, based on analysis of growth frequency of speleothems. Studia Quaternaria 17:3570.Google Scholar
Ilnicki, P, Żurek, S. 1996. Peat resources in Poland. In: Lappalainen, E, editor. Global Peat Resources. Jyväskylä: International Peat Society Geological Survey of Finland. p 119–25.Google Scholar
Johnsen, SJ, Clausen, HB, Dansgaard, W, Gundestrup, NS, Hammer, CU, Andersen, U, Andersen, KK, Hvidberg, CS, Dahl-Jensen, D, Steffensen, JP, Shoji, H, Sveinbjörnsdóttir, AE, White, JWC, Jouzel, J, Fisher, D. 1997. The δ18O record along the Greenland Ice Core Project deep ice core and the problem of possible Eemian climatic instability. Journal of Geophysical Research 102:26,397410.Google Scholar
Kuc, T, Różański, K, Duliński, M. 1998. Isotopic indicators of the Late Glacial/Holocene transition recorded in the sediments of Lake Gościąż. In: Ralska-Jasiewiczowa, M, Goslar, T, Madeyska, T, Starkel, L, editors. Lake Gościąż, Central Poland. A Monographic Study. p 158–62.Google Scholar
Michczyńska, DJ, Michczyńsky, A, Pazdur, A, Żurek, S. 2003. 14C dates of peat for reconstruction of environmental changes in the past. Geochronometria 22:4754.Google Scholar
Michczyńska, DJ, Pazdur, MF, Walanus, A. 1990. Bayesian approach to probabilistic calibration of radiocarbon ages. In: Mook, WG, Waterbolk, HT, editors. Proceedings of the 2nd International Symposium 14C and Archaeology. Strasburg. PACT 29:6979.Google Scholar
Pazdur, A, Michczyński, A, Pawlyta, J, Spahiu, P. 2000. Comparison of the radiocarbon dating methods used in the Gliwice Radiocarbon Laboratory. Geochronometria 18:914.Google Scholar
Pazdur, A, Pazdur, MF. 1986a. Aparatura pomiarowa Laboratorium 14C w Gliwicach. Doświadczenia konstrukcyjne i eksploatacyjne (The measuring equipment of the Gliwice Radiocarbon Laboratory. Experience gathered in the construction and exploitation). Zeszyty Naukowe Politechniki $SAląskiej, seria Matematyka-Fizyka, z.46, Geochronometria 1:5569.Google Scholar
Pazdur, A, Pazdur, MF. 1986b. Radiocarbon chronology of the Late Glacial period in Poland. Acta Interdisciplinaria Archaeology 4:6171.Google Scholar
Pazdur, A, Pazdur, MF, Pawlyta, J, Górny, A, Olszewski, M. 1995. Paleoclimatic implications of radiocarbon dating of speleothems from Cracow-Wieluń Upland, S Poland. Radiocarbon 37(2):103–10.Google Scholar
Pazdur, MF, Michczyńska, DJ. 1989. Improvement of the procedure for probabilistic calibration of radiocarbon dates. In: Long, A, Kra, RS, Srdoć, D, editors. Proceedings of the 13th International 14C Conference. Radiocarbon 31(3):824–32.Google Scholar
Singhvi, AK, Bluszcz, A, Bateman, MD, Someshwar Rao, M. 2001. Luminescence dating of loess-paleosol sequences and coversands: methodological aspects and paleoclimatic implications. Earth Science Reviews 54: 193211.Google Scholar
Stolk, A, Törnqvist, TE, Hekhuis, KPV, Berendsen, HJA, van der Plicht, J. 1994. Calibration of 14C histograms: a comparison of methods. Radiocarbon 36(1):110.Google Scholar
Stuiver, M, Polach, HA. 1977. Discussion: reporting of 14C data. Radiocarbon 19(3):355–63.Google Scholar
van der Plicht, J. 1993. The Groningen radiocarbon calibration program. Radiocarbon 35(1):231–7.Google Scholar