Improving the reliability of bulk sediment radiocarbon dating

Radiocarbon dated chronologies are the most extensively applied dating technique when investigating the last ∼45,000 years. In lake and marine sediments, a single macrofossil or several microfossils are the preferred sample material because they have a 14 C age that accurately reflects the time of d...

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Bibliographic Details
Published in:Quaternary Science Reviews
Main Authors: Strunk, Astrid, Olsen, Jesper, Sanei, Hamed, Rudra, Arka, Larsen, Nicolaj K.
Format: Article in Journal/Newspaper
Language:English
Published: 2020
Subjects:
Age offset
Bulk sediment
Greenland
Organic geochemistry
Paleolimnology
Pyrolysis
Quaternary
Radiocarbon dating
Radiogenic isotopes
Stable isotopes
Online Access:https://pure.au.dk/portal/en/publications/6926aba9-547a-4264-8b72-3e1c0b6750c3
https://doi.org/10.1016/j.quascirev.2020.106442
http://www.scopus.com/inward/record.url?scp=85087775994&partnerID=8YFLogxK
Description
Summary:Radiocarbon dated chronologies are the most extensively applied dating technique when investigating the last ∼45,000 years. In lake and marine sediments, a single macrofossil or several microfossils are the preferred sample material because they have a 14 C age that accurately reflects the time of deposition. However, absence of macro- or microfossils are a recurring challenge. Often, it is necessary to use bulk sediment samples for radiocarbon dating, but they frequently yield ages clearly exceeding the depositional timeframe due to occurrence of organic material of older origin. Until now, it has not been possible to assess if the dating result of a bulk sediment sample is reliable, or to adequately explain the mechanisms behind age disagreement between bulk and macro- and microfossils. In this study, we investigate the age offset between paired bulk and macrofossil ages in sediment cores from three lakes in SE and E Greenland. Furthermore, we distinguish three quantifiable main carbon sources in the samples: a) recent terrestrial organic fragments, b) recent aquatic organic matter, and c) reworked land-derived old carbon, through pyrolysis organic geochemistry, organic petrographic microscopy, and isotopic fractionization. Our results show that the offset between bulk (humic fraction) and macrofossil radiocarbon ages in three similar lakes range from 9 14 C yr to 20.1 14 C kyr. We observe a reduced age offset between bulk- and macrofossil ages, and thereby a higher reliability of bulk (humic fraction) ages, correlated with increased values of TOC, C/N ratio, and high CO 2 release in pyrolysis (S3 value). We recommend that future studies presenting bulk sediment chronologies apply pyrolysis organic geochemistry, organic petrographic microscopy, and isotopic fractionization as demonstrated here, to select reliable sediment intervals for bulk dating and retrieve more robust results.

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