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Abstract

Understanding the temperature evolution during the Holocene is crucial for future climate projections. However, a puzzling discrepancy between climate models simulating a warming trend during the second half of the Holocene parallel to the rise in atmospheric CO₂ concentrations and proxy data suggesting cooling during this period – known as the Holocene temperature conundrum – limits our understanding of how climate will evolve in the future. To solve this conundrum, the inclusion of quantitative paleotemperature records from high-latitude sites, which are extremely rare, is essential. Here, we use the hydrogen isotopic composition of fluid inclusions in speleothems from southeastern Alaska to create a quantitative temperature reconstruction of the entire Holocene. We show that the temperature in southeastern Alaska followed CO₂, in agreement with modeling results. Because our data show no proxy-model bias, they support a seasonal proxy bias to account for the Holocene temperature conundrum.

Keywords

Holocene North Pacific Paleoclimate Speleothems

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Holocene temperatures follow CO 2 in southeastern Alaska

Abstract

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