Dating Quaternary lacustrine sediments in the McMurdo Dry Valleys, Antarctica

Reports of erroneously old 14C dates for modem Antarctic materials have thrown doubt into 14C chronologies. The carbon reservoir effect purported to exist in Quaternary lacustrine sediments of the McMurdo Dry Valleys was investigated by studying 14C distribution, and testing alternate dating techniq...

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Bibliographic Details
Published in:Palaeogeography, Palaeoclimatology, Palaeoecology
Main Authors: Doran, Peter T., Berger, G. W., Lyons, W. B., Wharton, R. A., Davisson, M. L., Southon, J., Dibb, J. E.
Format: Text
Language:unknown
Published: LSU Digital Commons 1999
Subjects:
Antarctica
Dating
Geochronology
Lacustrine
Lakes
Sediments
Antarctic
McMurdo Dry Valleys
Bonney
Fryxell
Hoare
Lake Bonney
Lake Fryxell
Lake Hoare
Hand Lake
Hand, Lake
Antarc*
Online Access:https://digitalcommons.lsu.edu/geo_pubs/684
https://doi.org/10.1016/S0031-0182(98)00159-X
Description
Summary:Reports of erroneously old 14C dates for modem Antarctic materials have thrown doubt into 14C chronologies. The carbon reservoir effect purported to exist in Quaternary lacustrine sediments of the McMurdo Dry Valleys was investigated by studying 14C distribution, and testing alternate dating techniques. Our results show that the carbon reservoir effect is not pervasive. Stream and near-shore microbial mats and dissolved inorganic carbon (DIC) in the surface waters of Lake Fryxell are in equilibrium with modem 14CO2. The surface waters of Lake Hoare and Lake Bonney, however, have DIC 14C ages of 1650 and 2080 yr B.P., respectively. These older age estimates are suggested to be due to the direct input of large amounts of glacial melt with relict DIC. On the other hand, Lake Fryxell receives only a minor component of its inflow directly from a glacier, while a large component must travel long distances in numerous shallow ephemeral streams after leaving local valley glaciers. This mode of melt-water input allows the water to equilibrate with modem CO2 before entering the lake. Bottom-water 14C ages for Lake Hoare closely match surface sediment ages, supporting the widely published period ~1200 yr B.P. (after a 1650 yr reservoir correction) when most dry valley lakes apparently evaporated to small brine ponds and/or disappeared completely. Lake Bonney bottom-water is ~8000 yr B.P. Carbon dating is shown to be a viable technique for lake edge deposits, and possibly lake bottom deposits where a correction to the sediment surface age can be obtained. However, we conclude that deep-water paleolake deposits can not be reliably dated using 14C alone because of an inability to determine the age of the reservoir correction (i.e. accounting for the initial carbon reservoir, plus the age of the bottom water). A suite of alternative and complimentary dating techniques were tested on modern and late Holocene lacustrine deposits. These include thermoluminescence (TL), 210Pb, 137Cs, and paleomagnetism. Of these techniques, TL (or ...

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