Sedimentary cycles and volcanic ash beds in the Lower Pliocene lacustrine succession of Ptolemais (NW Greece): discrepancy between 40 Ar/39 Ar and astronomical ages
Publication date
1999-01-19
Authors
Steenbrink, J.
Vugt, N. van
Hilgen, F.J.
Wijbrans, J.R.
Meulenkamp, J.E.
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Article
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Abstract
A high-resolution cyclostratigraphy for the rhythmically bedded lignite-marl sequences of the Lower Pliocene Ptole-mais
Formation is combined with 40 Ar= 39 Ar dating results of intercalated volcanic ash beds. Detailed field reconnaissance
in three open-pit lignite mines reveals three end-member sediment types: lignites, composed primarily of organic material;
grey marls, a mixture of carbonate and organic material; and beige marls, almost exclusively composed of carbonate.
These lithologies are arranged in two basic types of sedimentary cycles: lignite-grey marl and lignite-beige marl cycles.
A cyclostratigraphic composite section comprising 56 lignite-marl cycles is constructed which combines the consistent
cycle patterns from three parallel sections. The concordant positions of 20 volcanic ash beds in these sections confirm the
cyclostratigraphic correlations and indicate that the lignite-marl cycles result from regional, basin-wide forcing rather than
lateral facies migrations. 40 Ar= 39 Ar ages on sanidine and biotite separates from nine volcanic ash beds were obtained by
multiple total fusion and incremental-heating experiments. The 40 Ar= 39 Ar ages range between 5:00 0:05 and 4:04 0:04
Ma and are, in general, consistent with the stratigraphic order. A least-square linear regression using the measured
40 Ar= 39 Ar ages gives an average duration of 21:8 0:8 kyr per lignite-marl cycle. Evidently, the lignite-marl cycles in
the Ptolemais Formation are linked to the precessional variation in the Earth's orbit through its influence on Mediterranean
climate. For the first time, 40 Ar= 39 Ar dating results, totally independent from any other dating and or tuning technique,
confirm the astronomical theory of climate change. The 40 Ar= 39 Ar ages of the volcanic ash beds show a constant 200 kyr
( 4.5%) age discrepancy with the astronomical ages of the same ash beds. This inconsistency remains difficult to explain.
The discrepancy is unlikely to have resulted from erroneous astronomical ages, through incorrectness in the astronomical
tuning, inaccuracies of the magnetostratigraphic data or the orbital time-series used, and=or errors in the APTS. The
40 Ar= 39 Ar dating results neither give clear indications for a possible source of error. From the excellent data set it is evident
that neither loss of radiogenic 40 Ar, nor an underestimation of the contribution of Ca- and K-derived Ar isotopes could
have caused the discrepancy. Moreover, the discrepancy is also beyond the errors in the systematic variables, like the decay
constants of 40 K or the ages for the neutron-fluence monitors. Ó 1999 Elsevier Science B.V. All rights reserved.
Keywords
cyclostratigraphy, 40 Ar= 39 Ar dating, lacustrine sediments, lignite, Pliocene, Greece