Testing Pollen Sorted by Flow Cytometry as the Basis for High-Resolution Lacustrine Chronologies

Documenting leads and lags in terrestrial records of past climate change is critical to understanding the behavior of Earth’s natural climate system and making reliable predictions of future climate conditions. However, uncertainties of several hundred years in age models make it difficult to distin...

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Veröffentlicht in:	Radiocarbon 2019-02, Vol.61 (1), p.359-374
Hauptverfasser:	Zimmerman, Susan R H, Brown, Thomas A, Hassel, Christiane, Heck, Jessica
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Sprache:	eng
Schlagworte:	Age Archives & records Carbon Carbon 14 Charcoal Climate models Flow cytometry High resolution Lakes Organic carbon Pollen Radiometric dating Sediments Time series Vegetation
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creator	Zimmerman, Susan R H Brown, Thomas A Hassel, Christiane Heck, Jessica
description	Documenting leads and lags in terrestrial records of past climate change is critical to understanding the behavior of Earth’s natural climate system and making reliable predictions of future climate conditions. However, uncertainties of several hundred years in age models make it difficult to distinguish synchronicity and feedbacks in paleo archives. In lakes this is often due to the lack of terrestrial macrofossils in climate-sensitive locations, such as high alpine or dryland settings. The potential of radiocarbon (14C) dating of pollen has long been recognized, but the difficulty of cleanly separating pollen from other kinds of organic carbon has limited its usefulness. Here we report 14C ages on pollen separated by flow cytometry, from a set of closely spaced samples from Mono Lake, California. The accuracy of the pollen ages is tested using well-dated bracketing tephras, the South Mono and North Mono-Inyo tephras. In spite of the purity of the sorted samples, the pollen dates are older than the bounding tephras by ~400 yr, similar to some other pollen-dating studies. While improvements in sample preparation protocols are planned, understanding the geological processes involved in the production, preservation, and deposition of pollen at each site will be critical to developing robust high-resolution age models.
doi_str_mv	10.1017/RDC.2018.89
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source	Cambridge Journals; Free Full-Text Journals in Chemistry
subjects	Age Archives & records Carbon Carbon 14 Charcoal Climate models Flow cytometry High resolution Lakes Organic carbon Pollen Radiometric dating Sediments Time series Vegetation
title	Testing Pollen Sorted by Flow Cytometry as the Basis for High-Resolution Lacustrine Chronologies
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