CO2-driven ocean circulation changes as an amplifier of Paleocene-Eocene thermal maximum hydrate destabilization

Changes in ocean circulation have been proposed as a trigger mechanism for the large coupled climate and carbon cycle perturbations at the Paleocene-Eocene Thermal Maximum (PETM, ca. 55 Ma). An abrupt warming of oceanic intermediate waters could have initiated the thermal destabilization of sediment...

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Main Authors: Lunt, DJ, Valdes, PJ, Dunkley Jones, T, Ridgwell, A, Haywood, AM, Schmidt, DN, Marsh, R, Maslin, M
Format: Article in Journal/Newspaper
Language:unknown
Published: GEOLOGICAL SOC AMER, INC 2010
Subjects:
CARBON-ISOTOPE EXCURSION
CLIMATE SENSITIVITY
METHANE HYDRATE
PERSPECTIVE
GRADIENTS
RELEASE
CYCLE
Southern Ocean
Methane hydrate
Online Access:http://discovery.ucl.ac.uk/264205/
id ftucl:oai:eprints.ucl.ac.uk.OAI2:264205
record_format openpolar
spelling ftucl:oai:eprints.ucl.ac.uk.OAI2:264205 2023-05-15T17:12:03+02:00 CO2-driven ocean circulation changes as an amplifier of Paleocene-Eocene thermal maximum hydrate destabilization Lunt, DJ Valdes, PJ Dunkley Jones, T Ridgwell, A Haywood, AM Schmidt, DN Marsh, R Maslin, M 2010-10 http://discovery.ucl.ac.uk/264205/ unknown GEOLOGICAL SOC AMER, INC GEOLOGY , 38 (10) 875 - 878. (2010) CARBON-ISOTOPE EXCURSION CLIMATE SENSITIVITY METHANE HYDRATE PERSPECTIVE GRADIENTS RELEASE CYCLE Article 2010 ftucl 2013-11-09T21:10:55Z Changes in ocean circulation have been proposed as a trigger mechanism for the large coupled climate and carbon cycle perturbations at the Paleocene-Eocene Thermal Maximum (PETM, ca. 55 Ma). An abrupt warming of oceanic intermediate waters could have initiated the thermal destabilization of sediment-hosted methane gas hydrates and potentially triggered sediment slumps and slides. In an ensemble of fully coupled atmosphere-ocean general circulation model (AOGCM) simulations of the late Paleocene and early Eocene, we identify such a circulation-driven enhanced intermediate-water warming. Critically, we find an approximate twofold amplification of Atlantic intermediate-water warming when CO2 levels are doubled from 2x to 4x preindustrial CO2 compared to when they are doubled from 1x to 2x. This warming is largely focused on the equatorial and South Atlantic and is driven by a significant reduction in deep-water formation from the Southern Ocean. This scenario is consistent with altered PETM circulation patterns inferred from benthic carbon isotope data and the intensity of deep-sea carbonate dissolution in the South Atlantic. The linkage between intermediate-water warming and gas hydrate destabilization could provide an important feedback in the establishment of peak PETM warmth. Article in Journal/Newspaper Methane hydrate Southern Ocean University College London: UCL Discovery Southern Ocean
institution Open Polar
collection University College London: UCL Discovery
op_collection_id ftucl
language unknown
topic CARBON-ISOTOPE EXCURSION
CLIMATE SENSITIVITY
METHANE HYDRATE
PERSPECTIVE
GRADIENTS
RELEASE
CYCLE
spellingShingle CARBON-ISOTOPE EXCURSION
CLIMATE SENSITIVITY
METHANE HYDRATE
PERSPECTIVE
GRADIENTS
RELEASE
CYCLE
Lunt, DJ
Valdes, PJ
Dunkley Jones, T
Ridgwell, A
Haywood, AM
Schmidt, DN
Marsh, R
Maslin, M
CO2-driven ocean circulation changes as an amplifier of Paleocene-Eocene thermal maximum hydrate destabilization
topic_facet CARBON-ISOTOPE EXCURSION
CLIMATE SENSITIVITY
METHANE HYDRATE
PERSPECTIVE
GRADIENTS
RELEASE
CYCLE
description Changes in ocean circulation have been proposed as a trigger mechanism for the large coupled climate and carbon cycle perturbations at the Paleocene-Eocene Thermal Maximum (PETM, ca. 55 Ma). An abrupt warming of oceanic intermediate waters could have initiated the thermal destabilization of sediment-hosted methane gas hydrates and potentially triggered sediment slumps and slides. In an ensemble of fully coupled atmosphere-ocean general circulation model (AOGCM) simulations of the late Paleocene and early Eocene, we identify such a circulation-driven enhanced intermediate-water warming. Critically, we find an approximate twofold amplification of Atlantic intermediate-water warming when CO2 levels are doubled from 2x to 4x preindustrial CO2 compared to when they are doubled from 1x to 2x. This warming is largely focused on the equatorial and South Atlantic and is driven by a significant reduction in deep-water formation from the Southern Ocean. This scenario is consistent with altered PETM circulation patterns inferred from benthic carbon isotope data and the intensity of deep-sea carbonate dissolution in the South Atlantic. The linkage between intermediate-water warming and gas hydrate destabilization could provide an important feedback in the establishment of peak PETM warmth.
format Article in Journal/Newspaper
author Lunt, DJ
Valdes, PJ
Dunkley Jones, T
Ridgwell, A
Haywood, AM
Schmidt, DN
Marsh, R
Maslin, M
author_facet Lunt, DJ
Valdes, PJ
Dunkley Jones, T
Ridgwell, A
Haywood, AM
Schmidt, DN
Marsh, R
Maslin, M
author_sort Lunt, DJ
title CO2-driven ocean circulation changes as an amplifier of Paleocene-Eocene thermal maximum hydrate destabilization
title_short CO2-driven ocean circulation changes as an amplifier of Paleocene-Eocene thermal maximum hydrate destabilization
title_full CO2-driven ocean circulation changes as an amplifier of Paleocene-Eocene thermal maximum hydrate destabilization
title_fullStr CO2-driven ocean circulation changes as an amplifier of Paleocene-Eocene thermal maximum hydrate destabilization
title_full_unstemmed CO2-driven ocean circulation changes as an amplifier of Paleocene-Eocene thermal maximum hydrate destabilization
title_sort co2-driven ocean circulation changes as an amplifier of paleocene-eocene thermal maximum hydrate destabilization
publisher GEOLOGICAL SOC AMER, INC
publishDate 2010
url http://discovery.ucl.ac.uk/264205/
geographic Southern Ocean
geographic_facet Southern Ocean
genre Methane hydrate
Southern Ocean
genre_facet Methane hydrate
Southern Ocean
op_source GEOLOGY , 38 (10) 875 - 878. (2010)
_version_ 1766068808748892160

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