Volcanic climate forcing preceding the inception of the Younger Dryas: Implications for tracing the Laacher See eruption

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Volcanic climate forcing preceding the inception of the Younger Dryas : Implications for tracing the Laacher See eruption. / Abbott, P. M.; Niemeier, U.; Timmreck, C.; Riede, F.; McConnell, J. R.; Severi, M.; Fischer, H.; Svensson, A.; Toohey, M.; Reinig, F.; Sigl, M.

In: Quaternary Science Reviews, Vol. 274, 107260, 15.12.2021.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Abbott, PM, Niemeier, U, Timmreck, C, Riede, F, McConnell, JR, Severi, M, Fischer, H, Svensson, A, Toohey, M, Reinig, F & Sigl, M 2021, 'Volcanic climate forcing preceding the inception of the Younger Dryas: Implications for tracing the Laacher See eruption', Quaternary Science Reviews, vol. 274, 107260. https://doi.org/10.1016/j.quascirev.2021.107260

APA

Abbott, P. M., Niemeier, U., Timmreck, C., Riede, F., McConnell, J. R., Severi, M., Fischer, H., Svensson, A., Toohey, M., Reinig, F., & Sigl, M. (2021). Volcanic climate forcing preceding the inception of the Younger Dryas: Implications for tracing the Laacher See eruption. Quaternary Science Reviews, 274, [107260]. https://doi.org/10.1016/j.quascirev.2021.107260

Vancouver

Abbott PM, Niemeier U, Timmreck C, Riede F, McConnell JR, Severi M et al. Volcanic climate forcing preceding the inception of the Younger Dryas: Implications for tracing the Laacher See eruption. Quaternary Science Reviews. 2021 Dec 15;274. 107260. https://doi.org/10.1016/j.quascirev.2021.107260

Author

Abbott, P. M. ; Niemeier, U. ; Timmreck, C. ; Riede, F. ; McConnell, J. R. ; Severi, M. ; Fischer, H. ; Svensson, A. ; Toohey, M. ; Reinig, F. ; Sigl, M. / Volcanic climate forcing preceding the inception of the Younger Dryas : Implications for tracing the Laacher See eruption. In: Quaternary Science Reviews. 2021 ; Vol. 274.

Bibtex

@article{4a229a5dcbcd4606b97ef1c7f8d97e81,
title = "Volcanic climate forcing preceding the inception of the Younger Dryas: Implications for tracing the Laacher See eruption",
abstract = "Climatic warming from the last glacial maximum to the current interglacial period was punctuated by a similar to 1300 years long cold period, commonly referred to as the Younger Dryas (YD). Several hypotheses have been proposed for the mechanism triggering the abrupt inception of the YD, including freshwater forcing, an extra-terrestrial impact, and aerosols from volcanic eruptions. Here, we use synchronised sulphate and sulphur records from both Greenland and Antarctic ice cores to reconstruct volcanic forcing between 13,200-12,800 a BPGICC05 (years before 1950 CE on the Greenland Ice Core Chronology 2005; GICC05). This continuous reconstruction of stratospheric sulphur injections highlights a -110-year cluster of four major bipolar volcanic signals alongside several smaller events just prior to the YD inception. The cumulative Northern Hemisphere aerosol burden and radiative forcing from this cluster exceeds the most volcanically active periods during the Common Era, which experienced notable multidecadal scale cooling commonly attributed to volcanic effects. The Laacher See eruption (LSE), recently redated to 13,006 +/- 9 cal a BP, falls within our time window of study and has been proposed as a trigger for the YD but a direct volcanic imprint for the LSE in the Greenland ice cores has thus far proved elusive. Comparison of simulated sulphate deposition for mid- and high-sulphur LSE-type emission scenarios to the ice-core estimated sulphate deposition and interhemispheric asymmetry ratios allows several signals between 13,025 and 12,975 a BPGICC05 to be proposed as plausible candidates for the LSE. The magnitude and persistence of volcanic forcing directly preceding the YD inception highlights the need to consider stratospheric sulphur injections and their radiative forcing in future analyses and climate model experiments used to explore the mechanisms that triggered this or similar abrupt cooling events. (C) 2021 The Authors. Published by Elsevier Ltd.",
keywords = "Ice cores, Sulphate, Volcanic radiative forcing, Younger Dryas, Laacher See eruption, ANTARCTIC ICE-CORES, WAIS DIVIDE, GREENLAND, RECORD, CIRCULATION, SULFUR, OCEAN, SYNCHRONIZATION, CHRONOLOGY, SULFATE",
author = "Abbott, {P. M.} and U. Niemeier and C. Timmreck and F. Riede and McConnell, {J. R.} and M. Severi and H. Fischer and A. Svensson and M. Toohey and F. Reinig and M. Sigl",
year = "2021",
month = dec,
day = "15",
doi = "10.1016/j.quascirev.2021.107260",
language = "English",
volume = "274",
journal = "Quaternary Science Reviews",
issn = "0277-3791",
publisher = "Pergamon Press",

}

RIS

TY - JOUR

T1 - Volcanic climate forcing preceding the inception of the Younger Dryas

T2 - Implications for tracing the Laacher See eruption

AU - Abbott, P. M.

AU - Niemeier, U.

AU - Timmreck, C.

AU - Riede, F.

AU - McConnell, J. R.

AU - Severi, M.

AU - Fischer, H.

AU - Svensson, A.

AU - Toohey, M.

AU - Reinig, F.

AU - Sigl, M.

PY - 2021/12/15

Y1 - 2021/12/15

N2 - Climatic warming from the last glacial maximum to the current interglacial period was punctuated by a similar to 1300 years long cold period, commonly referred to as the Younger Dryas (YD). Several hypotheses have been proposed for the mechanism triggering the abrupt inception of the YD, including freshwater forcing, an extra-terrestrial impact, and aerosols from volcanic eruptions. Here, we use synchronised sulphate and sulphur records from both Greenland and Antarctic ice cores to reconstruct volcanic forcing between 13,200-12,800 a BPGICC05 (years before 1950 CE on the Greenland Ice Core Chronology 2005; GICC05). This continuous reconstruction of stratospheric sulphur injections highlights a -110-year cluster of four major bipolar volcanic signals alongside several smaller events just prior to the YD inception. The cumulative Northern Hemisphere aerosol burden and radiative forcing from this cluster exceeds the most volcanically active periods during the Common Era, which experienced notable multidecadal scale cooling commonly attributed to volcanic effects. The Laacher See eruption (LSE), recently redated to 13,006 +/- 9 cal a BP, falls within our time window of study and has been proposed as a trigger for the YD but a direct volcanic imprint for the LSE in the Greenland ice cores has thus far proved elusive. Comparison of simulated sulphate deposition for mid- and high-sulphur LSE-type emission scenarios to the ice-core estimated sulphate deposition and interhemispheric asymmetry ratios allows several signals between 13,025 and 12,975 a BPGICC05 to be proposed as plausible candidates for the LSE. The magnitude and persistence of volcanic forcing directly preceding the YD inception highlights the need to consider stratospheric sulphur injections and their radiative forcing in future analyses and climate model experiments used to explore the mechanisms that triggered this or similar abrupt cooling events. (C) 2021 The Authors. Published by Elsevier Ltd.

AB - Climatic warming from the last glacial maximum to the current interglacial period was punctuated by a similar to 1300 years long cold period, commonly referred to as the Younger Dryas (YD). Several hypotheses have been proposed for the mechanism triggering the abrupt inception of the YD, including freshwater forcing, an extra-terrestrial impact, and aerosols from volcanic eruptions. Here, we use synchronised sulphate and sulphur records from both Greenland and Antarctic ice cores to reconstruct volcanic forcing between 13,200-12,800 a BPGICC05 (years before 1950 CE on the Greenland Ice Core Chronology 2005; GICC05). This continuous reconstruction of stratospheric sulphur injections highlights a -110-year cluster of four major bipolar volcanic signals alongside several smaller events just prior to the YD inception. The cumulative Northern Hemisphere aerosol burden and radiative forcing from this cluster exceeds the most volcanically active periods during the Common Era, which experienced notable multidecadal scale cooling commonly attributed to volcanic effects. The Laacher See eruption (LSE), recently redated to 13,006 +/- 9 cal a BP, falls within our time window of study and has been proposed as a trigger for the YD but a direct volcanic imprint for the LSE in the Greenland ice cores has thus far proved elusive. Comparison of simulated sulphate deposition for mid- and high-sulphur LSE-type emission scenarios to the ice-core estimated sulphate deposition and interhemispheric asymmetry ratios allows several signals between 13,025 and 12,975 a BPGICC05 to be proposed as plausible candidates for the LSE. The magnitude and persistence of volcanic forcing directly preceding the YD inception highlights the need to consider stratospheric sulphur injections and their radiative forcing in future analyses and climate model experiments used to explore the mechanisms that triggered this or similar abrupt cooling events. (C) 2021 The Authors. Published by Elsevier Ltd.

KW - Ice cores

KW - Sulphate

KW - Volcanic radiative forcing

KW - Younger Dryas

KW - Laacher See eruption

KW - ANTARCTIC ICE-CORES

KW - WAIS DIVIDE

KW - GREENLAND

KW - RECORD

KW - CIRCULATION

KW - SULFUR

KW - OCEAN

KW - SYNCHRONIZATION

KW - CHRONOLOGY

KW - SULFATE

U2 - 10.1016/j.quascirev.2021.107260

DO - 10.1016/j.quascirev.2021.107260

M3 - Journal article

VL - 274

JO - Quaternary Science Reviews

JF - Quaternary Science Reviews

SN - 0277-3791

M1 - 107260

ER -

ID: 286311215