Orbital (Hydro)Climate Variability in the Ice-Free early Eocene Arctic

We explore the imprint of orbital variability on Arctic temperature and hydrology using sediments recovered during the Arctic Coring Expedition in 2004. High resolution records of lipid biomarkers (GDGTs; 2-kyr) and palynological assemblages (5-kyr) in the ~4 m interval below Eocene Thermal Maximum...

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Main Authors: Fokkema, Chris Daniël, Brinkhuis, Henk, Peterse, Francien, Sluijs, Appy
Format: Other/Unknown Material
Language:unknown
Published: Authorea, Inc. 2024
Subjects:
Arctic
albedo
Arctic Basin
Online Access:http://dx.doi.org/10.22541/essoar.171259268.89696496/v1
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spelling crwinnower:10.22541/essoar.171259268.89696496/v1 2024-06-02T07:54:31+00:00 Orbital (Hydro)Climate Variability in the Ice-Free early Eocene Arctic Fokkema, Chris Daniël Brinkhuis, Henk Peterse, Francien Sluijs, Appy 2024 http://dx.doi.org/10.22541/essoar.171259268.89696496/v1 unknown Authorea, Inc. posted-content 2024 crwinnower https://doi.org/10.22541/essoar.171259268.89696496/v1 2024-05-07T14:19:28Z We explore the imprint of orbital variability on Arctic temperature and hydrology using sediments recovered during the Arctic Coring Expedition in 2004. High resolution records of lipid biomarkers (GDGTs; 2-kyr) and palynological assemblages (5-kyr) in the ~4 m interval below Eocene Thermal Maximum 2 (~54 Ma) show highly cyclic signals related to ~20-kyr precession, ~40-kyr obliquity and ~100-kyr eccentricity. The GDGTs indicate obliquity and precession variability representative of sea surface temperature (SST) variations up to ~1.4 and ~0.5 ºC, respectively. Peak SSTs coincide with an elevated supply of pollen and spores and increased marine productivity. Together, this implies an orbital control on precipitation and terrestrial nutrient supply to the Arctic Basin. Assuming that SST maxima correspond to Arctic insolation maxima (precession minima/obliquity maxima), precipitation maxima also correspond to insolation maxima, implying regional hydrological processes as a forcing rather than variations in meridional water transport, starkly contrasting Pleistocene Arctic hydrology. The relative amplitudes of precession and obliquity in the SST record match that of local insolation between spring and fall, corroborating previous suggestions of a seasonal GDGT bias. The reconstructed complete orbital imprint refutes that ACEX temperature reconstructions are biased to one end of the orbital variability. Eccentricity-related SST variability was ~0.8 ºC, ~2–3 times higher than synchronous variability in the deep ocean, and 3–4 times higher than similar variations in the tropics. This confirms eccentricity-forced global temperature variability during the Eocene, and that this had pronounced polar amplification, despite the absence of ice and snow albedo feedbacks. Other/Unknown Material albedo Arctic Basin Arctic The Winnower Arctic
institution Open Polar
collection The Winnower
op_collection_id crwinnower
language unknown
description We explore the imprint of orbital variability on Arctic temperature and hydrology using sediments recovered during the Arctic Coring Expedition in 2004. High resolution records of lipid biomarkers (GDGTs; 2-kyr) and palynological assemblages (5-kyr) in the ~4 m interval below Eocene Thermal Maximum 2 (~54 Ma) show highly cyclic signals related to ~20-kyr precession, ~40-kyr obliquity and ~100-kyr eccentricity. The GDGTs indicate obliquity and precession variability representative of sea surface temperature (SST) variations up to ~1.4 and ~0.5 ºC, respectively. Peak SSTs coincide with an elevated supply of pollen and spores and increased marine productivity. Together, this implies an orbital control on precipitation and terrestrial nutrient supply to the Arctic Basin. Assuming that SST maxima correspond to Arctic insolation maxima (precession minima/obliquity maxima), precipitation maxima also correspond to insolation maxima, implying regional hydrological processes as a forcing rather than variations in meridional water transport, starkly contrasting Pleistocene Arctic hydrology. The relative amplitudes of precession and obliquity in the SST record match that of local insolation between spring and fall, corroborating previous suggestions of a seasonal GDGT bias. The reconstructed complete orbital imprint refutes that ACEX temperature reconstructions are biased to one end of the orbital variability. Eccentricity-related SST variability was ~0.8 ºC, ~2–3 times higher than synchronous variability in the deep ocean, and 3–4 times higher than similar variations in the tropics. This confirms eccentricity-forced global temperature variability during the Eocene, and that this had pronounced polar amplification, despite the absence of ice and snow albedo feedbacks.
format Other/Unknown Material
author Fokkema, Chris Daniël
Brinkhuis, Henk
Peterse, Francien
Sluijs, Appy
spellingShingle Fokkema, Chris Daniël
Brinkhuis, Henk
Peterse, Francien
Sluijs, Appy
Orbital (Hydro)Climate Variability in the Ice-Free early Eocene Arctic
author_facet Fokkema, Chris Daniël
Brinkhuis, Henk
Peterse, Francien
Sluijs, Appy
author_sort Fokkema, Chris Daniël
title Orbital (Hydro)Climate Variability in the Ice-Free early Eocene Arctic
title_short Orbital (Hydro)Climate Variability in the Ice-Free early Eocene Arctic
title_full Orbital (Hydro)Climate Variability in the Ice-Free early Eocene Arctic
title_fullStr Orbital (Hydro)Climate Variability in the Ice-Free early Eocene Arctic
title_full_unstemmed Orbital (Hydro)Climate Variability in the Ice-Free early Eocene Arctic
title_sort orbital (hydro)climate variability in the ice-free early eocene arctic
publisher Authorea, Inc.
publishDate 2024
url http://dx.doi.org/10.22541/essoar.171259268.89696496/v1
geographic Arctic
geographic_facet Arctic
genre albedo
Arctic Basin
Arctic
genre_facet albedo
Arctic Basin
Arctic
op_doi https://doi.org/10.22541/essoar.171259268.89696496/v1
_version_ 1800740807101120512

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