No evidence for tephra in Greenland from the historic eruption of Vesuvius in 79 CE: implications for geochronology and paleoclimatology

Gill Plunkett,Matthew Toohey,Claus Siebe,Takeshi Hasegawa,Michael Sigl,Jonathan R Pilcher,Hans F Schwaiger,Joseph R Mcconnell,Emma L Tomlinson

doi:10.5194/cp-18-45-2022

Abstract

Abstract. Volcanic fallout in polar ice sheets provides important opportunities to date and correlate ice-core records as well as to investigate the environmental impacts of eruptions. Only the geochemical characterization of volcanic ash (tephra) embedded in the ice strata can confirm the source of the eruption, however, and is a requisite if historical eruption ages are to be used as valid chronological checks on annual ice layer counting. Here we report the investigation of ash particles in a Greenland ice core that are associated with a volcanic sulfuric acid layer previously attributed to the 79 CE eruption of Vesuvius. Major and trace element composition of the particles indicates that the tephra does not derive from Vesuvius but most likely originates from an unidentified eruption in the Aleutian arc. Using ash dispersal modeling, we find that only an eruption large enough to include stratospheric injection is likely to account for the sizable (24–85 µm) ash particles observed in the Greenland ice at this time. Despite its likely explosivity, this event does not appear to have triggered significant climate perturbations, unlike some other large extratropical eruptions. In light of a recent re-evaluation of the Greenland ice-core chronologies, our findings further challenge the previous assignation of this volcanic event to 79 CE. We highlight the need for the revised Common Era ice-core chronology to be formally accepted by the wider ice-core and climate modeling communities in order to ensure robust age linkages to precisely dated historical and paleoclimate proxy records.

Highlights

Volcanism is widely accepted as the most significant natural driver of high-frequency climate variability (Crowley, 2000; Schurer et al, 2013)
The precise dating of the volcanic signals proffered by the ice cores enables the climate and societal impacts of volcanic eruptions to be evaluated with respect to historical records and has contributed to the discernment of strong chronological correlations between past volcanism, climate
Cryptotephra particles were identified in samples Queen’s University Belfast (QUB)-1832 (n = 18) and QUB-1833 (n = 5), demonstrating that ash deposition preceded the maximum of sulfuric aerosol depositions at this location in Greenland

Summary

Introduction

Volcanism is widely accepted as the most significant natural driver of high-frequency (i.e., interannual to centennial timescales) climate variability (Crowley, 2000; Schurer et al, 2013). The precise dating of the volcanic signals proffered by the ice cores enables the climate and societal impacts of volcanic eruptions to be evaluated with respect to historical records and has contributed to the discernment of strong chronological correlations between past volcanism, climate. Pinpoint the source of the eruption, a critical factor needed to determine the relationship between sulfate flux in the ice cores and atmospheric burden, determining the climatic effectiveness of an eruption. Volcanic ash (fine-grained tephra, often referred to as cryptotephra when shard concentrations are too low to be visible to the naked eye) in ice cores can enable the source volcano to be identified, improving the scope for modeling aerosol distribution and climate impact. As the magma source is subject to changes in supply, temperature and pressure, tephra chemistry may be unique to each eruption or phase of the eruption, but it frequently carries a geochemical signature in its major or trace element composition that enables it to be attributed to a specific source (Westgate and Gorton, 1981)

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