Benthic δ18O records Earth’s energy imbalance

Oxygen isotope ratios (δ 18 O) of foraminifera in marine sediment records have fundamentally shaped our understanding of the ice ages and global climate change. Interpretation of these records has, however, been challenging because they reflect contributions from both ocean temperature and ice volum...

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Bibliographic Details
Published in:Nature geoscience 2023-09, Vol.16 (9), p.797-802
Main Authors: Shackleton, Sarah, Seltzer, Alan, Baggenstos, Daniel, Lisiecki, Lorraine E.
Format: Article
Language:English
Subjects:
704/106/2738
704/106/413
Benthos
Climate change
Corals
Deglaciation
Earth
Earth and Environmental Science
Earth Sciences
Earth System Sciences
Energy
Energy budget
Foraminifera
Fossils
Gases
Geochemistry
Geology
Geophysics/Geodesy
Global climate
Heinrich events
Ice ages
Ice cores
Ice volume
Insolation
Isotope ratios
Isotopes
Marine invertebrates
Marine sediments
Meltwater
Northern Hemisphere
Ocean temperature
Oceans
Oxygen
Oxygen isotope ratio
Oxygen isotopes
Rare gases
Records
Summer
Tracking
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Summary:Oxygen isotope ratios (δ 18 O) of foraminifera in marine sediment records have fundamentally shaped our understanding of the ice ages and global climate change. Interpretation of these records has, however, been challenging because they reflect contributions from both ocean temperature and ice volume. Here, instead of disentangling, we reconstruct global benthic foraminiferal δ 18 O across the last deglaciation (18–11.5 ka) with ice volume constraints from fossil corals and ocean temperature constraints from ice core noble gases. We demonstrate that, while ocean temperature and ice volume histories are distinct, their summed contributions to δ 18 O agree remarkably well with benthic δ 18 O records. Given the agreement between predicted and observed δ 18 O, we further build upon recent insight into global energy fluxes and introduce a framework to quantitively reconstruct top-of-atmosphere net radiative imbalance, or Earth’s energy imbalance, from δ 18 O. Finally, we reconstruct 150,000 years of energy imbalance, which broadly follows Northern Hemisphere summer insolation but shows millennial-scale energy gain during the cold intervals surrounding Heinrich events. This suggests that, in addition to external forcing, internal variability plays an important role in modifying the global energy budget on long (millennial-plus) timescales. While generally tracking Northern Hemisphere summer insolation, the Earth gained energy during cold millennial scale events throughout the past 150,000 years, according to an analysis of benthic oxygen isotopes.
ISSN:1752-0894
1752-0908
DOI:10.1038/s41561-023-01250-y