The 852/3CE Mount Churchill eruption: examining the potential climatic and societal impacts and the timing of the Medieval Climate Anomaly in the North Atlantic region
The 852/3CE Mount Churchill eruption: examining the potential climatic and societal impacts and the timing of the Medieval Climate Anomaly in the North Atlantic region
The 852/3 CE eruption of Mount Churchill, Alaska, was one of the largest first-millennium volcanic events, with a magnitude of 6.7 (VEI 6) and a tephra volume of 39.4-61.9 km3 (95 % confidence). The spatial extent of the ash fallout from this event is considerable and the cryptotephra (White River Ash east; WRAe) extends as far as Finland and Poland. Proximal ecosystem and societal disturbances have been linked with this eruption; however, wider eruption impacts on climate and society are unknown. Greenland ice core records show that the eruption occurred in winter 852/3 ± 1 CE and that the eruption is associated with a relatively moderate sulfate aerosol loading but large abundances of volcanic ash and chlorine. Here we assess the potential broader impact of this eruption using palaeoenvironmental reconstructions, historical records and climate model simulations. We also use the fortuitous timing of the 852/3 CE Churchill eruption and its extensively widespread tephra deposition of the White River Ash (east) (WRAe) to examine the climatic expression of the warm Medieval Climate Anomaly period (MCA; ca. 950-1250 CE) from precisely linked peatlands in the North Atlantic region. The reconstructed climate forcing potential of the 852/3 CE Churchill eruption is moderate compared with the eruption magnitude, but tree-ring-inferred temperatures report a significant atmospheric cooling of 0.8 C in summer 853 CE. Modelled climate scenarios also show a cooling in 853 CE, although the average magnitude of cooling is smaller (0.3 C). The simulated spatial patterns of cooling are generally similar to those generated using the tree-ring-inferred temperature reconstructions. Tree-ring-inferred cooling begins prior to the date of the eruption suggesting that natural internal climate variability may have increased the climate system's susceptibility to further cooling. The magnitude of the reconstructed cooling could also suggest that the climate forcing potential of this eruption may be underestimated, thereby highlighting the need for greater insight into, and consideration of, the role of halogens and volcanic ash when estimating eruption climate forcing potential. Precise comparisons of palaeoenvironmental records from peatlands across North America and Europe, facilitated by the presence of the WRAe isochron, reveal no consistent MCA signal. These findings contribute to the growing body of evidence that characterises the MCA hydroclimate as time-transgressive and heterogeneous rather than a well-defined climatic period. The presence of the WRAe isochron also demonstrates that no long-term (multidecadal) climatic or societal impacts from the 852/3 CE Churchill eruption were identified beyond areas proximal to the eruption. Historical evidence in Europe for subsistence crises demonstrate a degree of temporal correspondence on interannual timescales, but similar events were reported outside of the eruption period and were common in the 9th century. The 852/3 CE Churchill eruption exemplifies the difficulties of identifying and confirming volcanic impacts for a single eruption, even when the eruption has a small age uncertainty.
1475-1508
Mackay, Helen
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Plunkett, Gill
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Jensen, Britta J.L.
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Aubry, Thomas J.
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Corona, Christophe
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Kim, Woon Mi
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Toohey, Matthew
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Sigl, Michael
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Anchukaitis, Kevin J.
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Raible, Christoph
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Bolton, Matthew S.M.
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Manning, Joseph G.
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Newfield, Timothy P.
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Di Cosmo, Nicola
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Kostick, Conor
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Yang, Zhen
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McClung, Lisa Coyle
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Amesbury, Matthew
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Monteath, Alistair
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Hughes, Paul D.M.
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Charman, Dan
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Booth, Robert
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Davies, Kimberley L.
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Blundell, Antony
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Swindles, Graeme T.
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29 June 2022
Mackay, Helen
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Plunkett, Gill
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Corona, Christophe
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Kim, Woon Mi
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Toohey, Matthew
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Sigl, Michael
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Stoffel, Markus
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Anchukaitis, Kevin J.
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Raible, Christoph
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Bolton, Matthew S.M.
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Manning, Joseph G.
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Newfield, Timothy P.
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Di Cosmo, Nicola
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Ludlow, Francis
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Kostick, Conor
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Yang, Zhen
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McClung, Lisa Coyle
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Amesbury, Matthew
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Monteath, Alistair
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Hughes, Paul D.M.
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Langdon, Pete G.
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Charman, Dan
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Booth, Robert
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Davies, Kimberley L.
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Blundell, Antony
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Mackay, Helen, Plunkett, Gill, Jensen, Britta J.L., Aubry, Thomas J., Corona, Christophe, Kim, Woon Mi, Toohey, Matthew, Sigl, Michael, Stoffel, Markus, Anchukaitis, Kevin J., Raible, Christoph, Bolton, Matthew S.M., Manning, Joseph G., Newfield, Timothy P., Di Cosmo, Nicola, Ludlow, Francis, Kostick, Conor, Yang, Zhen, McClung, Lisa Coyle, Amesbury, Matthew, Monteath, Alistair, Hughes, Paul D.M., Langdon, Pete G., Charman, Dan, Booth, Robert, Davies, Kimberley L., Blundell, Antony and Swindles, Graeme T.
(2022)
The 852/3CE Mount Churchill eruption: examining the potential climatic and societal impacts and the timing of the Medieval Climate Anomaly in the North Atlantic region.
Climate of the Past, 18 (6), .
(doi:10.5194/cp-18-1475-2022).
Abstract
The 852/3 CE eruption of Mount Churchill, Alaska, was one of the largest first-millennium volcanic events, with a magnitude of 6.7 (VEI 6) and a tephra volume of 39.4-61.9 km3 (95 % confidence). The spatial extent of the ash fallout from this event is considerable and the cryptotephra (White River Ash east; WRAe) extends as far as Finland and Poland. Proximal ecosystem and societal disturbances have been linked with this eruption; however, wider eruption impacts on climate and society are unknown. Greenland ice core records show that the eruption occurred in winter 852/3 ± 1 CE and that the eruption is associated with a relatively moderate sulfate aerosol loading but large abundances of volcanic ash and chlorine. Here we assess the potential broader impact of this eruption using palaeoenvironmental reconstructions, historical records and climate model simulations. We also use the fortuitous timing of the 852/3 CE Churchill eruption and its extensively widespread tephra deposition of the White River Ash (east) (WRAe) to examine the climatic expression of the warm Medieval Climate Anomaly period (MCA; ca. 950-1250 CE) from precisely linked peatlands in the North Atlantic region. The reconstructed climate forcing potential of the 852/3 CE Churchill eruption is moderate compared with the eruption magnitude, but tree-ring-inferred temperatures report a significant atmospheric cooling of 0.8 C in summer 853 CE. Modelled climate scenarios also show a cooling in 853 CE, although the average magnitude of cooling is smaller (0.3 C). The simulated spatial patterns of cooling are generally similar to those generated using the tree-ring-inferred temperature reconstructions. Tree-ring-inferred cooling begins prior to the date of the eruption suggesting that natural internal climate variability may have increased the climate system's susceptibility to further cooling. The magnitude of the reconstructed cooling could also suggest that the climate forcing potential of this eruption may be underestimated, thereby highlighting the need for greater insight into, and consideration of, the role of halogens and volcanic ash when estimating eruption climate forcing potential. Precise comparisons of palaeoenvironmental records from peatlands across North America and Europe, facilitated by the presence of the WRAe isochron, reveal no consistent MCA signal. These findings contribute to the growing body of evidence that characterises the MCA hydroclimate as time-transgressive and heterogeneous rather than a well-defined climatic period. The presence of the WRAe isochron also demonstrates that no long-term (multidecadal) climatic or societal impacts from the 852/3 CE Churchill eruption were identified beyond areas proximal to the eruption. Historical evidence in Europe for subsistence crises demonstrate a degree of temporal correspondence on interannual timescales, but similar events were reported outside of the eruption period and were common in the 9th century. The 852/3 CE Churchill eruption exemplifies the difficulties of identifying and confirming volcanic impacts for a single eruption, even when the eruption has a small age uncertainty.
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cp-18-1475-2022
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Accepted/In Press date: 1 April 2022
Published date: 29 June 2022
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Acknowledgements. This paper benefitted from discussion at events of the Past Global Changes (PAGES) working group “Volcanic Impacts on Climate and Society” (VICS) as well as with Angus M. Duncan and Richard J. Payne. PAGES is supported by the Chinese Academy of Sciences (CAS) and the Swiss Academy of Sciences (SCNAT). Helen Mackay and Matthew Amesbury were supported by the UK Natural Environment Research Council (PRECIP project grants NE/G019851/1, NE/G020272/1, NE/G019673/1 and NE/G02006X/1 and MILLI-PEAT project grant NE/1012915/1). A Quaternary Research Association New Research Workers award was granted to Helen Mackay and the NERC Radiocarbon Facility NRCF010001 (allocation numbers 1744.1013 and 1789.0414). Christophe Corona and Markus Stoffel were supported by the Swiss National Science Foundation Sinergia project CALDERA (grant agreement no. CRSII5_183571). Woon Mi Kim and Christoph Raible are supported by the Swiss National Science Foundation (SNSF, grant nos. 200020_172745 and 200020_200492). The climate mode simulations were performed at the Swiss National Super Computing Centre (CSCS). Michael Sigl acknowledges funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement 820047). Francis Ludlow and Conor Kostick were supported by an Irish Research Council Laureate Award (CLICAB, IRCLA/2017/303). Joseph G. Manning and Francis Ludlow acknowledge support from US National Science Foundation Award no. 1824770. Francis Lud-low and Zhen Yang acknowledge additional support from an ERC Synergy Grant (4-OCEANS; grant agreement 951649). Thomas J. Aubry acknowledges support from the European Union’s Horizon 2020 research and innovation programme under the Marie Skłodowska-Curie grant agreement no. 835939 and from Sidney Sussex College through a Junior Research Fellowship. We are grateful to all reviewers for their constructive comments and valuable suggestions.
Funding Information:
Financial support. This research has been supported by the Natural Environment Research Council (grant nos. NE/G019851/1, NE/G020272/1, NE/G019673/1, NE/G02006X/1 and NE/1012915/1), the Schweizerischer Nationalfonds zur Förderung der Wissenschaftlichen Forschung (grant nos. CR-SII5_183571, 200020_172745 and 200020_200492), the National Science Foundation (grant no. 1824770), the Irish Research Council (grant no. IRCLA/2017/303) and the H2020 European Research Council (grant nos. 820047, 835939 and 951649).
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Local EPrints ID: 485245
URI: http://eprints.soton.ac.uk/id/eprint/485245
ISSN: 1814-9324
PURE UUID: e5e5d408-7402-4fc8-9ab1-5470f65e820e
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Date deposited: 01 Dec 2023 17:46
Last modified: 17 Mar 2024 02:47
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Author:
Helen Mackay
Author:
Gill Plunkett
Author:
Britta J.L. Jensen
Author:
Thomas J. Aubry
Author:
Christophe Corona
Author:
Woon Mi Kim
Author:
Matthew Toohey
Author:
Michael Sigl
Author:
Markus Stoffel
Author:
Kevin J. Anchukaitis
Author:
Christoph Raible
Author:
Matthew S.M. Bolton
Author:
Joseph G. Manning
Author:
Timothy P. Newfield
Author:
Nicola Di Cosmo
Author:
Francis Ludlow
Author:
Conor Kostick
Author:
Zhen Yang
Author:
Lisa Coyle McClung
Author:
Matthew Amesbury
Author:
Alistair Monteath
Author:
Pete G. Langdon
Author:
Dan Charman
Author:
Robert Booth
Author:
Kimberley L. Davies
Author:
Antony Blundell
Author:
Graeme T. Swindles
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