Ice core evidence for the Los Chocoyos supereruption disputes millennial-scale climate impact

Helen Innes; William Hutchison; Michael Sigl; Laura Crick; Peter M. Abbott; Matthias Bigler; Nathan J. Chellman; Siwan M. Davies; Steffen Kutterolf; Joseph R. McConnell; Mirko Severi; R. Stephen J. Sparks; Anders Svensson; Eric W. Wolff; James William Buchanan Rae; Andrea Burke

doi:10.1038/S43247-025-02095-6

Ice core evidence for the Los Chocoyos supereruption disputes millennial-scale climate impact

Helen Innes^*, William Hutchison, Michael Sigl, Laura Crick, Peter M. Abbott, Matthias Bigler, Nathan J. Chellman, Siwan M. Davies, Steffen Kutterolf, Joseph R. McConnell, Mirko Severi, R. Stephen J. Sparks, Anders Svensson, Eric W. Wolff, James William Buchanan Rae, Andrea Burke

^*Corresponding author for this work

School of Earth & Environmental Sciences

Research output: Contribution to journal › Article › peer-review

Abstract

Volcanic supereruptions are considered among the few drivers of global and existential catastrophes, with recent hypotheses suggesting massive volcanic stratospheric sulfate injection could instigate major shifts in global climate. The absence of supereruptions during recent history as well as large uncertainties on eruption ages limits understanding of the climatic risk they impose. Polar ice cores have well-resolved continuous age models, record past temperature, and contain volcanic sulfate and cryptotephra deposits which can be geochemically fingerprinted to determine eruption timing and improve stratospheric sulfur loading estimates. Here, we provide an age of 79,500 years for the Atitlán Los Chocoyos supereruption, one of the largest Quaternary eruptions, by identifying tephra shards in ice cores from both Greenland and Antarctica. This ice core age is supported by a revised marine sediment core stratigraphy age for the Los Chocoyos ash layer. Through comparison with well-dated ice-core temperature proxy records, our study suggests that despite being one of the largest sulfur emissions recorded in ice cores, the Los Chocoyos supereruption did not trigger a millennial-scale cold period.

Original language	English
Article number	137
Number of pages	11
Journal	Communications Earth & Environment
Volume	6
DOIs	https://doi.org/10.1038/S43247-025-02095-6
Publication status	Published - 22 Feb 2025

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Light Element Analysis Facility (LEAF): Light Element Analysis Facility (LEAF)
Irvine, J. T. S. (PI), Baker, R. (CoI) & Miller, D. N. (CoI)
EPSRC
5/04/20 → 4/04/23
Project: Standard
Electon Microscopy: Electon Microscopy for the characterisation and manipulation of advanced function materials and their interfaces at the nanoscale
Irvine, J. T. S. (PI), Baker, R. (CoI) & Zhou, W. (CoI)
EPSRC
1/04/18 → 2/09/20
Project: Standard

Ice core sulfur and tephra geochemical data for 79.5 ka (AICC2012) eruption, identified as the Los Chocoyos supereruption (dataset)
Innes, H. (Creator), Hutchison, W. (Creator), Sigl, M. (Creator), Crick, L. (Creator), Abbott, P. M. (Creator), Bigler, M. (Creator), Chellman, N. J. (Creator), Davies, S. M. (Creator), Kutterolf, S. (Creator), McConnell, J. R. (Creator), Severi, M. (Creator), Sparks, R. S. J. (Creator), Svensson, A. (Creator), Wolff, E. W. (Creator), Rae, J. W. B. (Creator) & Burke, A. (Creator), University of St Andrews, 24 Feb 2025
DOI: 10.17630/62b68476-ca09-4011-9ad5-c9d44b09d6a8
Dataset

File

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Innes, H., Hutchison, W., Sigl, M., Crick, L., Abbott, P. M., Bigler, M., Chellman, N. J., Davies, S. M., Kutterolf, S., McConnell, J. R., Severi, M., Sparks, R. S. J., Svensson, A., Wolff, E. W., Rae, J. W. B., & Burke, A. (2025). Ice core evidence for the Los Chocoyos supereruption disputes millennial-scale climate impact. Communications Earth & Environment, 6, Article 137. https://doi.org/10.1038/S43247-025-02095-6

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title = "Ice core evidence for the Los Chocoyos supereruption disputes millennial-scale climate impact",

abstract = "Volcanic supereruptions are considered among the few drivers of global and existential catastrophes, with recent hypotheses suggesting massive volcanic stratospheric sulfate injection could instigate major shifts in global climate. The absence of supereruptions during recent history as well as large uncertainties on eruption ages limits understanding of the climatic risk they impose. Polar ice cores have well-resolved continuous age models, record past temperature, and contain volcanic sulfate and cryptotephra deposits which can be geochemically fingerprinted to determine eruption timing and improve stratospheric sulfur loading estimates. Here, we provide an age of 79,500 years for the Atitl{\'a}n Los Chocoyos supereruption, one of the largest Quaternary eruptions, by identifying tephra shards in ice cores from both Greenland and Antarctica. This ice core age is supported by a revised marine sediment core stratigraphy age for the Los Chocoyos ash layer. Through comparison with well-dated ice-core temperature proxy records, our study suggests that despite being one of the largest sulfur emissions recorded in ice cores, the Los Chocoyos supereruption did not trigger a millennial-scale cold period.",

author = "Helen Innes and William Hutchison and Michael Sigl and Laura Crick and Abbott, {Peter M.} and Matthias Bigler and Chellman, {Nathan J.} and Davies, {Siwan M.} and Steffen Kutterolf and McConnell, {Joseph R.} and Mirko Severi and Sparks, {R. Stephen J.} and Anders Svensson and Wolff, {Eric W.} and Rae, {James William Buchanan} and Andrea Burke",

note = "Funding: This work was funded by IAPETUS2 NERC Doctoral Training Program Studentship (HI), UKRI Future Leaders Fellowship MR/S-33505/1 (WH), ERC Horizon 2020 grant 820047 (MSi and PMA), Leverhulme Trust grant RPG-2015-246 and Fellowship EM-2018-050/4 (RSJS), Leverhulme Trust Prize PLP-2021-167 (AB). The EPMA facilities at the University of St Andrews are supported by the EPSRC Light Element Analysis Facility Grant EP/T019298/1 and the EPSRC Strategic Equipment Resource Grant EP/R023751/1. We thank the National Science Foundation-Ice Core Facility (NSF-2041950). ",

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doi = "10.1038/S43247-025-02095-6",

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Innes, H , Hutchison, W, Sigl, M, Crick, L, Abbott, PM, Bigler, M, Chellman, NJ, Davies, SM, Kutterolf, S, McConnell, JR, Severi, M, Sparks, RSJ, Svensson, A, Wolff, EW, Rae, JWB & Burke, A 2025, 'Ice core evidence for the Los Chocoyos supereruption disputes millennial-scale climate impact', Communications Earth & Environment, vol. 6, 137. https://doi.org/10.1038/S43247-025-02095-6

TY - JOUR

T1 - Ice core evidence for the Los Chocoyos supereruption disputes millennial-scale climate impact

AU - Innes, Helen

AU - Hutchison, William

AU - Sigl, Michael

AU - Crick, Laura

AU - Abbott, Peter M.

AU - Bigler, Matthias

AU - Chellman, Nathan J.

AU - Davies, Siwan M.

AU - Kutterolf, Steffen

AU - McConnell, Joseph R.

AU - Severi, Mirko

AU - Sparks, R. Stephen J.

AU - Svensson, Anders

AU - Wolff, Eric W.

AU - Rae, James William Buchanan

AU - Burke, Andrea

N1 - Funding: This work was funded by IAPETUS2 NERC Doctoral Training Program Studentship (HI), UKRI Future Leaders Fellowship MR/S-33505/1 (WH), ERC Horizon 2020 grant 820047 (MSi and PMA), Leverhulme Trust grant RPG-2015-246 and Fellowship EM-2018-050/4 (RSJS), Leverhulme Trust Prize PLP-2021-167 (AB). The EPMA facilities at the University of St Andrews are supported by the EPSRC Light Element Analysis Facility Grant EP/T019298/1 and the EPSRC Strategic Equipment Resource Grant EP/R023751/1. We thank the National Science Foundation-Ice Core Facility (NSF-2041950).

PY - 2025/2/22

Y1 - 2025/2/22

N2 - Volcanic supereruptions are considered among the few drivers of global and existential catastrophes, with recent hypotheses suggesting massive volcanic stratospheric sulfate injection could instigate major shifts in global climate. The absence of supereruptions during recent history as well as large uncertainties on eruption ages limits understanding of the climatic risk they impose. Polar ice cores have well-resolved continuous age models, record past temperature, and contain volcanic sulfate and cryptotephra deposits which can be geochemically fingerprinted to determine eruption timing and improve stratospheric sulfur loading estimates. Here, we provide an age of 79,500 years for the Atitlán Los Chocoyos supereruption, one of the largest Quaternary eruptions, by identifying tephra shards in ice cores from both Greenland and Antarctica. This ice core age is supported by a revised marine sediment core stratigraphy age for the Los Chocoyos ash layer. Through comparison with well-dated ice-core temperature proxy records, our study suggests that despite being one of the largest sulfur emissions recorded in ice cores, the Los Chocoyos supereruption did not trigger a millennial-scale cold period.

AB - Volcanic supereruptions are considered among the few drivers of global and existential catastrophes, with recent hypotheses suggesting massive volcanic stratospheric sulfate injection could instigate major shifts in global climate. The absence of supereruptions during recent history as well as large uncertainties on eruption ages limits understanding of the climatic risk they impose. Polar ice cores have well-resolved continuous age models, record past temperature, and contain volcanic sulfate and cryptotephra deposits which can be geochemically fingerprinted to determine eruption timing and improve stratospheric sulfur loading estimates. Here, we provide an age of 79,500 years for the Atitlán Los Chocoyos supereruption, one of the largest Quaternary eruptions, by identifying tephra shards in ice cores from both Greenland and Antarctica. This ice core age is supported by a revised marine sediment core stratigraphy age for the Los Chocoyos ash layer. Through comparison with well-dated ice-core temperature proxy records, our study suggests that despite being one of the largest sulfur emissions recorded in ice cores, the Los Chocoyos supereruption did not trigger a millennial-scale cold period.

U2 - 10.1038/S43247-025-02095-6

DO - 10.1038/S43247-025-02095-6

M3 - Article

SN - 2662-4435

VL - 6

JO - Communications Earth & Environment

JF - Communications Earth & Environment

M1 - 137

ER -

Ice core evidence for the Los Chocoyos supereruption disputes millennial-scale climate impact

Abstract

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Light Element Analysis Facility (LEAF): Light Element Analysis Facility (LEAF)

Electon Microscopy: Electon Microscopy for the characterisation and manipulation of advanced function materials and their interfaces at the nanoscale

Datasets

Ice core sulfur and tephra geochemical data for 79.5 ka (AICC2012) eruption, identified as the Los Chocoyos supereruption (dataset)

Cite this