Seasonal Temperatures in West Antarctica During the Holocene

Overview

Journal Nature

Specialty Science

Date 2023 Jan 11

PMID 36631651

Authors

Tyler R Jones

Kurt M Cuffey

William H G Roberts

Bradley R Markle

Eric J Steig

C Max Stevens

Paul J Valdes

T J Fudge

Michael Sigl

Abigail G Hughes

Valerie Morris

Bruce H Vaughn

Joshua Garland

Bo M Vinther

Kevin S Rozmiarek

Chloe A Brashear

James W C White

Affiliations

Soon will be listed here.

Abstract

The recovery of long-term climate proxy records with seasonal resolution is rare because of natural smoothing processes, discontinuities and limitations in measurement resolution. Yet insolation forcing, a primary driver of multimillennial-scale climate change, acts through seasonal variations with direct impacts on seasonal climate. Whether the sensitivity of seasonal climate to insolation matches theoretical predictions has not been assessed over long timescales. Here, we analyse a continuous record of water-isotope ratios from the West Antarctic Ice Sheet Divide ice core to reveal summer and winter temperature changes through the last 11,000 years. Summer temperatures in West Antarctica increased through the early-to-mid-Holocene, reached a peak 4,100 years ago and then decreased to the present. Climate model simulations show that these variations primarily reflect changes in maximum summer insolation, confirming the general connection between seasonal insolation and warming and demonstrating the importance of insolation intensity rather than seasonally integrated insolation or season duration. Winter temperatures varied less overall, consistent with predictions from insolation forcing, but also fluctuated in the early Holocene, probably owing to changes in meridional heat transport. The magnitudes of summer and winter temperature changes constrain the lowering of the West Antarctic Ice Sheet surface since the early Holocene to less than 162 m and probably less than 58 m, consistent with geological constraints elsewhere in West Antarctica.

Citing Articles

Reply to: Limitations of ice cores in reconstructing temperature seasonality.

Jones T, Cuffey K, Steig E, Markle B Nature. 2025; 637(8044):E7-E8.

PMID: 39743606 DOI: 10.1038/s41586-024-08182-6.

Limitations of ice cores in reconstructing temperature seasonality.

Laepple T, Munch T, Hirsch N, Shaw F, Horhold M Nature. 2025; 637(8044):E1-E6.

PMID: 39743605 DOI: 10.1038/s41586-024-08181-7.

Global mean sea level likely higher than present during the holocene.

Creel R, Austermann J, Kopp R, Khan N, Albrecht T, Kingslake J Nat Commun. 2024; 15(1):10731.

PMID: 39737914 PMC: 11685612. DOI: 10.1038/s41467-024-54535-0.

WorldSeasons: a seasonal classification system interpolating biome classifications within the year for better temporal aggregation in climate science.

Littleboy C, Subke J, Bunnefeld N, Jones I Sci Data. 2024; 11(1):927.

PMID: 39191780 PMC: 11350142. DOI: 10.1038/s41597-024-03732-z.

Ocean cavity regime shift reversed West Antarctic grounding line retreat in the late Holocene.

Lowry D, Han H, Golledge N, Gomez N, Johnson K, McKay R Nat Commun. 2024; 15(1):3176.

PMID: 38653971 PMC: 11039676. DOI: 10.1038/s41467-024-47369-3.

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