Abstract

Ice-core timescales are vital for the understanding of past climate; hence they should be updated whenever significant amounts of new data can contribute to improvements. Here, the Greenland ice-core chronology was revised for the last 3835 years by synchronizing six deep ice-cores and three shallow ice-cores from the central Greenland ice sheet. A layer-counting bias was found in all ice cores because of site-specific signal disturbances, and a manual comparison of all ice cores was deemed necessary to increase timescale accuracy. A new method was applied by combining automated counting of annual layers on multiple parallel proxies and manual fine-tuning. After examining sources of error and their correlation lengths, the uncertainty rate was quantified to be one year per century. The new timescale is younger than the previous Greenland chronology by about 13 years at 3800 years ago. The most recent 800 years are largely unaffected by the revision, while the slope of the offset between timescales is steepest between 800 and 1000 years ago. Moreover, offset-oscillations of about 5 years around the average are observed between 2500 and 3800 years ago. The non-linear offset behavior is attributed to previous mismatches of volcanic eruptions, to the much more extensive data set available to this study, and to the finer resolution of the new ice-core matching. In response to volcanic eruptions, averaged water isotopes and layer thicknesses from Greenland ice cores provide evidence of notable cooling lasting for up to a decade, longer than reported in previous studies of volcanic forcing. By analysis of the common variations of cosmogenic radionuclides, the new ice-core timescale is found to be in alignment with the IntCal20 curve. Radiocarbon dated evidence found in the proximity of eruption sites such as Vesuvius or Thera was compared to the ice-core dataset; no conclusive evidence was found regarding if these two eruptions can be matched to acidity spikes in the ice cores. A hitherto unidentified cooling event in the ice cores is observed at about 3600 years ago (1600 BCE), which could have been caused by a large eruption which is, however, not clearly recorded in the acidity signal. The hunt for clear signs of the Thera eruption in Greenland ice-cores thus remains elusive.

Highlights

  • The Late Holocene saw the development of the entire human civilization, while being characterized by a stable climate 25 punctuated by short-term events, such as volcanic eruptions

  • Given the known inconsistencies between existing Greenland Holocene timescales and thanks to the advent of a new highresolution dataset from the recent EastGRIP ice core (Mojtabavi et al, 2020; Erhardt et al, In Prep.), we find it timely to revise the Greenland Ice Core Chronology 2005 (GICC05) timescale, providing a new unified ice-core chronology that includes all available data from Greenland deep ice cores

  • This conclusion is supported by our new time scale at least until 3400 years b2k, by observing that the transfer 615 function of GICC05 to GICC21 behaves to the one produced by Adolphi & Muscheler (Figure 9a), which indicates that the revised timescale is in a better alignment with the IntCal time scale, i.e. ages from radiocarbon dated samples

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Summary

Introduction

The Late Holocene saw the development of the entire human civilization, while being characterized by a stable climate 25 punctuated by short-term events, such as volcanic eruptions. Many detailed regional proxy records cover this period and can help reconstruct the history of recent climate. Paleoclimatic chronologies allow the synchronization of such proxy records from different geographic locations, thereby 30 providing a fundamental tool for the understanding of the Earth’s climate. In the Holocene, recent studies investigated the comprehensive impact of volcanic eruptions, suggesting for example a 10-year cooling in European summer temperatures (Sigl et al, 2015) or a 5-year positive North Atlantic Oscillation (NAO) (Sjolte et al, 2018), both after tropical eruptions.

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