Shifts in Greenland interannual climate variability lead Dansgaard–Oeschger abrupt warming by hundreds of years

Chloe A. Brashear; Tyler R. Jones; Valerie Morris; Bruce H. Vaughn; William Roberts; William B. Skorski; Abigail G. Hughes; Richard Nunn; Sune Olander Rasmussen; Kurt M. Cuffey; Bo M. Vinther; Todd A. Sowers; Christo Buizert; Vasileios Gkinis; Christian Holme; Mari F. Jensen; Sofia E. Kjellman; Petra M. Langebroek; Florian Mekhaldi; Kevin S. Rozmiarek; Jonathan W. Rheinlænder; Margit H. Simon; Giulia Sinnl; Silje Smith-Johnsen; James W. C. White

doi:10.5194/cp-21-529-2025

Shifts in Greenland interannual climate variability lead Dansgaard–Oeschger abrupt warming by hundreds of years

Chloe A. Brashear^*, Tyler R. Jones, Valerie Morris, Bruce H. Vaughn, William Roberts, William B. Skorski, Abigail G. Hughes, Richard Nunn, Sune Olander Rasmussen, Kurt M. Cuffey, Bo M. Vinther, Todd A. Sowers, Christo Buizert, Vasileios Gkinis, Christian Holme, Mari F. Jensen, Sofia E. Kjellman, Petra M. Langebroek, Florian Mekhaldi, Kevin S. RozmiarekJonathan W. Rheinlænder, Margit H. Simon, Giulia Sinnl, Silje Smith-Johnsen, James W. C. White

^*Corresponding author for this work

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

22 Downloads (Pure)

Abstract

During the Last Glacial Period (LGP), Greenland experienced approximately 30 abrupt warming phases, known as Dansgaard–Oeschger (D–O) events, followed by cooling back to baseline glacial conditions. Studies of mean climate change across warming transitions reveal indistinguishable phase offsets between shifts in temperature, dust, sea salt, accumulation, and moisture source, thus preventing a comprehensive understanding of the “anatomy” of D–O cycles (Capron et al., 2021). One aspect of abrupt change that has not been systematically assessed is how high-frequency interannual-scale climatic variability surrounding centennial-scale mean temperature changes across D–O transitions. Here, we utilize the East Greenland Ice-core Project (EGRIP) high-resolution water isotope record, a proxy for temperature and atmospheric circulation, to quantify the amplitude of 7–15-year isotopic variability for D–O events 2–13, the Younger Dryas, and the Bølling–Allerød. On average, cold stadial periods consistently exhibit greater variability than warm interstadial periods. Most notably, we often find that reductions in the amplitude of the 7–15-year band led abrupt D–O warmings by hundreds of years. Such a large phase offset between two climate parameters in a Greenland ice core has never been documented for D–O cycles. However, similar centennial lead times have been found in proxies for Norwegian Sea ice cover relative to abrupt Greenland warming (Sadatzki et al., 2020). Using HadCM3, a fully coupled general circulation model, we assess the effects of sea ice on 7–15-year temperature variability at the EGRIP. For a range of stadial and interstadial conditions, we find a strong relationship in line with our observations between colder simulated mean temperature and enhanced temperature variability at the EGRIP location. We also find a robust correlation between year-to-year North Atlantic sea ice fluctuations and the strength of interannual-scale temperature variability at EGRIP. Together, paleoclimate proxy evidence and model simulations suggest that sea ice plays a substantial role in high-frequency climate variability prior to D–O warming. This provides a clue about the anatomy of D–O events and should be the target of future sea ice model studies.

Original language	English
Pages (from-to)	529-546
Number of pages	18
Journal	Climate of the Past
Volume	21
Issue number	2
DOIs	https://doi.org/10.5194/cp-21-529-2025
Publication status	Published - 24 Feb 2025

Access to Document

10.5194/cp-21-529-2025Licence: CC BY

cp-21-529-2025Final published version, 4.83 MBLicence: CC BY

Cite this

Brashear, C. A., Jones, T. R., Morris, V., Vaughn, B. H., Roberts, W., Skorski, W. B., Hughes, A. G., Nunn, R., Rasmussen, S. O., Cuffey, K. M., Vinther, B. M., Sowers, T. A., Buizert, C., Gkinis, V., Holme, C., Jensen, M. F., Kjellman, S. E., Langebroek, P. M., Mekhaldi, F., ... White, J. W. C. (2025). Shifts in Greenland interannual climate variability lead Dansgaard–Oeschger abrupt warming by hundreds of years. Climate of the Past, 21(2), 529-546. https://doi.org/10.5194/cp-21-529-2025

@article{cc785f20e5fe4998b11b3d0d25c752d2,

title = "Shifts in Greenland interannual climate variability lead Dansgaard–Oeschger abrupt warming by hundreds of years",

abstract = "During the Last Glacial Period (LGP), Greenland experienced approximately 30 abrupt warming phases, known as Dansgaard–Oeschger (D–O) events, followed by cooling back to baseline glacial conditions. Studies of mean climate change across warming transitions reveal indistinguishable phase offsets between shifts in temperature, dust, sea salt, accumulation, and moisture source, thus preventing a comprehensive understanding of the “anatomy” of D–O cycles (Capron et al., 2021). One aspect of abrupt change that has not been systematically assessed is how high-frequency interannual-scale climatic variability surrounding centennial-scale mean temperature changes across D–O transitions. Here, we utilize the East Greenland Ice-core Project (EGRIP) high-resolution water isotope record, a proxy for temperature and atmospheric circulation, to quantify the amplitude of 7–15-year isotopic variability for D–O events 2–13, the Younger Dryas, and the B{\o}lling–Aller{\o}d. On average, cold stadial periods consistently exhibit greater variability than warm interstadial periods. Most notably, we often find that reductions in the amplitude of the 7–15-year band led abrupt D–O warmings by hundreds of years. Such a large phase offset between two climate parameters in a Greenland ice core has never been documented for D–O cycles. However, similar centennial lead times have been found in proxies for Norwegian Sea ice cover relative to abrupt Greenland warming (Sadatzki et al., 2020). Using HadCM3, a fully coupled general circulation model, we assess the effects of sea ice on 7–15-year temperature variability at the EGRIP. For a range of stadial and interstadial conditions, we find a strong relationship in line with our observations between colder simulated mean temperature and enhanced temperature variability at the EGRIP location. We also find a robust correlation between year-to-year North Atlantic sea ice fluctuations and the strength of interannual-scale temperature variability at EGRIP. Together, paleoclimate proxy evidence and model simulations suggest that sea ice plays a substantial role in high-frequency climate variability prior to D–O warming. This provides a clue about the anatomy of D–O events and should be the target of future sea ice model studies.",

author = "Brashear, \{Chloe A.\} and Jones, \{Tyler R.\} and Valerie Morris and Vaughn, \{Bruce H.\} and William Roberts and Skorski, \{William B.\} and Hughes, \{Abigail G.\} and Richard Nunn and Rasmussen, \{Sune Olander\} and Cuffey, \{Kurt M.\} and Vinther, \{Bo M.\} and Sowers, \{Todd A.\} and Christo Buizert and Vasileios Gkinis and Christian Holme and Jensen, \{Mari F.\} and Kjellman, \{Sofia E.\} and Langebroek, \{Petra M.\} and Florian Mekhaldi and Rozmiarek, \{Kevin S.\} and Rheinl{\ae}nder, \{Jonathan W.\} and Simon, \{Margit H.\} and Giulia Sinnl and Silje Smith-Johnsen and White, \{James W. C.\}",

year = "2025",

month = feb,

day = "24",

doi = "10.5194/cp-21-529-2025",

language = "English",

volume = "21",

pages = "529--546",

journal = "Climate of the Past",

issn = "1814-9332",

publisher = "Copernicus Publications",

number = "2",

}

Brashear, CA, Jones, TR, Morris, V, Vaughn, BH, Roberts, W, Skorski, WB, Hughes, AG, Nunn, R, Rasmussen, SO, Cuffey, KM, Vinther, BM, Sowers, TA, Buizert, C, Gkinis, V, Holme, C, Jensen, MF, Kjellman, SE, Langebroek, PM, Mekhaldi, F, Rozmiarek, KS, Rheinlænder, JW, Simon, MH, Sinnl, G, Smith-Johnsen, S & White, JWC 2025, 'Shifts in Greenland interannual climate variability lead Dansgaard–Oeschger abrupt warming by hundreds of years', Climate of the Past, vol. 21, no. 2, pp. 529-546. https://doi.org/10.5194/cp-21-529-2025

TY - JOUR

T1 - Shifts in Greenland interannual climate variability lead Dansgaard–Oeschger abrupt warming by hundreds of years

AU - Brashear, Chloe A.

AU - Jones, Tyler R.

AU - Morris, Valerie

AU - Vaughn, Bruce H.

AU - Roberts, William

AU - Skorski, William B.

AU - Hughes, Abigail G.

AU - Nunn, Richard

AU - Rasmussen, Sune Olander

AU - Cuffey, Kurt M.

AU - Vinther, Bo M.

AU - Sowers, Todd A.

AU - Buizert, Christo

AU - Gkinis, Vasileios

AU - Holme, Christian

AU - Jensen, Mari F.

AU - Kjellman, Sofia E.

AU - Langebroek, Petra M.

AU - Mekhaldi, Florian

AU - Rozmiarek, Kevin S.

AU - Rheinlænder, Jonathan W.

AU - Simon, Margit H.

AU - Sinnl, Giulia

AU - Smith-Johnsen, Silje

AU - White, James W. C.

PY - 2025/2/24

Y1 - 2025/2/24

N2 - During the Last Glacial Period (LGP), Greenland experienced approximately 30 abrupt warming phases, known as Dansgaard–Oeschger (D–O) events, followed by cooling back to baseline glacial conditions. Studies of mean climate change across warming transitions reveal indistinguishable phase offsets between shifts in temperature, dust, sea salt, accumulation, and moisture source, thus preventing a comprehensive understanding of the “anatomy” of D–O cycles (Capron et al., 2021). One aspect of abrupt change that has not been systematically assessed is how high-frequency interannual-scale climatic variability surrounding centennial-scale mean temperature changes across D–O transitions. Here, we utilize the East Greenland Ice-core Project (EGRIP) high-resolution water isotope record, a proxy for temperature and atmospheric circulation, to quantify the amplitude of 7–15-year isotopic variability for D–O events 2–13, the Younger Dryas, and the Bølling–Allerød. On average, cold stadial periods consistently exhibit greater variability than warm interstadial periods. Most notably, we often find that reductions in the amplitude of the 7–15-year band led abrupt D–O warmings by hundreds of years. Such a large phase offset between two climate parameters in a Greenland ice core has never been documented for D–O cycles. However, similar centennial lead times have been found in proxies for Norwegian Sea ice cover relative to abrupt Greenland warming (Sadatzki et al., 2020). Using HadCM3, a fully coupled general circulation model, we assess the effects of sea ice on 7–15-year temperature variability at the EGRIP. For a range of stadial and interstadial conditions, we find a strong relationship in line with our observations between colder simulated mean temperature and enhanced temperature variability at the EGRIP location. We also find a robust correlation between year-to-year North Atlantic sea ice fluctuations and the strength of interannual-scale temperature variability at EGRIP. Together, paleoclimate proxy evidence and model simulations suggest that sea ice plays a substantial role in high-frequency climate variability prior to D–O warming. This provides a clue about the anatomy of D–O events and should be the target of future sea ice model studies.

AB - During the Last Glacial Period (LGP), Greenland experienced approximately 30 abrupt warming phases, known as Dansgaard–Oeschger (D–O) events, followed by cooling back to baseline glacial conditions. Studies of mean climate change across warming transitions reveal indistinguishable phase offsets between shifts in temperature, dust, sea salt, accumulation, and moisture source, thus preventing a comprehensive understanding of the “anatomy” of D–O cycles (Capron et al., 2021). One aspect of abrupt change that has not been systematically assessed is how high-frequency interannual-scale climatic variability surrounding centennial-scale mean temperature changes across D–O transitions. Here, we utilize the East Greenland Ice-core Project (EGRIP) high-resolution water isotope record, a proxy for temperature and atmospheric circulation, to quantify the amplitude of 7–15-year isotopic variability for D–O events 2–13, the Younger Dryas, and the Bølling–Allerød. On average, cold stadial periods consistently exhibit greater variability than warm interstadial periods. Most notably, we often find that reductions in the amplitude of the 7–15-year band led abrupt D–O warmings by hundreds of years. Such a large phase offset between two climate parameters in a Greenland ice core has never been documented for D–O cycles. However, similar centennial lead times have been found in proxies for Norwegian Sea ice cover relative to abrupt Greenland warming (Sadatzki et al., 2020). Using HadCM3, a fully coupled general circulation model, we assess the effects of sea ice on 7–15-year temperature variability at the EGRIP. For a range of stadial and interstadial conditions, we find a strong relationship in line with our observations between colder simulated mean temperature and enhanced temperature variability at the EGRIP location. We also find a robust correlation between year-to-year North Atlantic sea ice fluctuations and the strength of interannual-scale temperature variability at EGRIP. Together, paleoclimate proxy evidence and model simulations suggest that sea ice plays a substantial role in high-frequency climate variability prior to D–O warming. This provides a clue about the anatomy of D–O events and should be the target of future sea ice model studies.

UR - https://www.scopus.com/pages/publications/85219027145

U2 - 10.5194/cp-21-529-2025

DO - 10.5194/cp-21-529-2025

M3 - Article

SN - 1814-9332

VL - 21

SP - 529

EP - 546

JO - Climate of the Past

JF - Climate of the Past

IS - 2

ER -

Shifts in Greenland interannual climate variability lead Dansgaard–Oeschger abrupt warming by hundreds of years

Abstract

Access to Document

Other files and links

Fingerprint

Cite this