Testing the timing of radiocarbon-dated events between proxy archives
For interpreting past changes on a regional or global scale, the timings of proxy-inferred events are usually aligned with data from other locations. However, too often chronological uncertainties are ignored in proxy diagrams and multisite comparisons, making it possible for researchers to fall int...
Published in: | The Holocene |
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Main Authors: | , , , , |
Format: | Article in Journal/Newspaper |
Language: | English |
Published: |
2007
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Subjects: | |
Online Access: | https://hdl.handle.net/11370/082ae7c5-6ba0-43a4-9cdb-243be41e3152 https://research.rug.nl/en/publications/082ae7c5-6ba0-43a4-9cdb-243be41e3152 https://doi.org/10.1177/0959683607075857 https://pure.rug.nl/ws/files/6703873/2007HoloceneBlaauw.pdf |
Summary: | For interpreting past changes on a regional or global scale, the timings of proxy-inferred events are usually aligned with data from other locations. However, too often chronological uncertainties are ignored in proxy diagrams and multisite comparisons, making it possible for researchers to fall into the trap of sucking separate events into one illusionary event (or vice versa). Here we largely solve this 'suck in and smear syndrome' for radiocarbon (14 Q dated sequences. In a Bayesian framework, millions of plausible age-models are constructed to quantify the chronological uncertainties within and between proxy archives. We test the technique on replicated high-resolution 14 C-dated peat cores deposited during the 'Little lee Age' (C. AD 1400-1900), a period characterized by abrupt climate changes and severe C-14 calibration problems. Owing to internal variability in proxy data and uncertainties in age-models, these (and possibly many more) archives are not consistent in recording decadal climate change. Through explicit statistical tests of palaeoenvironmental hypotheses, we can move forward to systematic interpretations of proxy data. However, chronological uncertainties of non-annually resolved palaeoclimate records are too large for answering decadal timescale questions. |
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