The Role of Oceanic Heat Transport and Wind Stress Forcing in Abrupt Millennial-Scale Climate Transitions
Identifieur interne : 007468 ( Main/Exploration ); précédent : 007467; suivant : 007469The Role of Oceanic Heat Transport and Wind Stress Forcing in Abrupt Millennial-Scale Climate Transitions
Auteurs : Olivier Arzel [Australie] ; Alain Colin De Verdiere [France] ; Matthew H. England [Australie]Source :
- Journal of climate [ 0894-8755 ] ; 2010.
Descripteurs français
- Pascal (Inist)
- Action vent, Paléoclimat, Période glaciaire, Evénement Dansgaard-Oeschger, Circulation thermohaline, Glace marine, Instabilité, Stabilité, Holocène, Oscillation libre, Climat froid, Variation brusque, Eau douce, Climat chaud, Stratification, Refroidissement, Modèle climat, Eau fond, Masse eau, Variation interdécennale, Océan Atlantique Nord, Transport, Transfert chaleur, Variation climatique, Paléo-océanographie, Climatologie, Forçage, Eau surface, Contrôle climatique, Température surface, Zonation, Modèle couplé.
- Wicri :
- topic : Eau douce, Climatologie.
English descriptors
- KwdEn :
- Climate models, Climatology, Cold climate, Coupled model, Dansgaard-Oeschger events, Forcing, Free oscillation, Holocene, Hot climate, Interdecadal variation, North Atlantic, Sudden variation, Water mass, Wind effect, bottom water, climate variations, climatic controls, cooling, fresh water, glacial periods, heat transfer, instability, paleo-oceanography, paleoclimate, sea ice, stability, stratification, surface temperature, surface water, thermohaline circulation, transport, zoning.
Abstract
The last glacial period was punctuated by rapid climate shifts, known as Dansgaard-Oeschger events, with strong imprint in the North Atlantic sector suggesting that they were linked with the Atlantic meridional overturning circulation. Here an idealized single-hemisphere three-dimensional ocean-atmosphere-sea ice coupled model is used to explore the possible origin of the instability driving these abrupt events and to provide a plausible explanation for the relative stability of the Holocene. Focusing on the physics of noise-free millennial oscillations under steady external (solar) forcing, it was shown that cold climates become unstable, that is, exhibit abrupt millennial-scale transitions, for significantly lower freshwater fluxes than warm climates, in agreement with previous studies making use of zonally averaged coupled models. This fundamental difference is a direct consequence of the weaker stratification of the glacial ocean, mainly caused by upper-ocean cooling. Using a two-hemisphere configuration of a coupled climate model of intermediate complexity, it is shown that this result is robust to the added presence of a bottom water mass of southern origin. The analysis reveals that under particular conditions, a pronounced interdecadal variability develops during warm interstadials. While the nature of the instability driving the millennial oscillations is identical to that found in ocean models under mixed boundary conditions, these interstadial-interdecadal oscillations share the same characteristics as those previously found in ocean models forced by fixed surface fluxes. The wind stress forcing is shown to profoundly affect both the properties and bifurcation structure of thermohaline millennial oscillations across a wide range of variation of freshwater forcing. In particular, it is shown that the wind stress forcing favors the maintenance of thermally direct meridional overturning circulations during the cold stadial phases of Dansgaard-Oeschger cycles.
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England</name><affiliation wicri:level="1"><inist:fA14 i1="01"><s1>Climate Change Research Centre, The University of New South Wales</s1><s2>Sydney, New South Wales</s2><s3>AUS</s3><sZ>1 aut.</sZ><sZ>3 aut.</sZ></inist:fA14><country>Australie</country><wicri:noRegion>Sydney, New South Wales</wicri:noRegion></affiliation></author></analytic><series><title level="j" type="main">Journal of climate</title><title level="j" type="abbreviated">J. clim.</title><idno type="ISSN">0894-8755</idno><imprint><date when="2010">2010</date></imprint></series></biblStruct></sourceDesc><seriesStmt><title level="j" type="main">Journal of climate</title><title level="j" type="abbreviated">J. clim.</title><idno type="ISSN">0894-8755</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Climate models</term><term>Climatology</term><term>Cold climate</term><term>Coupled model</term><term>Dansgaard-Oeschger events</term><term>Forcing</term><term>Free oscillation</term><term>Holocene</term><term>Hot climate</term><term>Interdecadal variation</term><term>North Atlantic</term><term>Sudden variation</term><term>Water mass</term><term>Wind effect</term><term>bottom water</term><term>climate variations</term><term>climatic controls</term><term>cooling</term><term>fresh water</term><term>glacial periods</term><term>heat transfer</term><term>instability</term><term>paleo-oceanography</term><term>paleoclimate</term><term>sea ice</term><term>stability</term><term>stratification</term><term>surface temperature</term><term>surface water</term><term>thermohaline circulation</term><term>transport</term><term>zoning</term></keywords><keywords scheme="Pascal" xml:lang="fr"><term>Action vent</term><term>Paléoclimat</term><term>Période glaciaire</term><term>Evénement Dansgaard-Oeschger</term><term>Circulation thermohaline</term><term>Glace marine</term><term>Instabilité</term><term>Stabilité</term><term>Holocène</term><term>Oscillation libre</term><term>Climat froid</term><term>Variation brusque</term><term>Eau douce</term><term>Climat chaud</term><term>Stratification</term><term>Refroidissement</term><term>Modèle climat</term><term>Eau fond</term><term>Masse eau</term><term>Variation interdécennale</term><term>Océan Atlantique Nord</term><term>Transport</term><term>Transfert chaleur</term><term>Variation climatique</term><term>Paléo-océanographie</term><term>Climatologie</term><term>Forçage</term><term>Eau surface</term><term>Contrôle climatique</term><term>Température surface</term><term>Zonation</term><term>Modèle couplé</term></keywords><keywords scheme="Wicri" type="topic" xml:lang="fr"><term>Eau douce</term><term>Climatologie</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">The last glacial period was punctuated by rapid climate shifts, known as Dansgaard-Oeschger events, with strong imprint in the North Atlantic sector suggesting that they were linked with the Atlantic meridional overturning circulation. Here an idealized single-hemisphere three-dimensional ocean-atmosphere-sea ice coupled model is used to explore the possible origin of the instability driving these abrupt events and to provide a plausible explanation for the relative stability of the Holocene. Focusing on the physics of noise-free millennial oscillations under steady external (solar) forcing, it was shown that cold climates become unstable, that is, exhibit abrupt millennial-scale transitions, for significantly lower freshwater fluxes than warm climates, in agreement with previous studies making use of zonally averaged coupled models. This fundamental difference is a direct consequence of the weaker stratification of the glacial ocean, mainly caused by upper-ocean cooling. Using a two-hemisphere configuration of a coupled climate model of intermediate complexity, it is shown that this result is robust to the added presence of a bottom water mass of southern origin. The analysis reveals that under particular conditions, a pronounced interdecadal variability develops during warm interstadials. While the nature of the instability driving the millennial oscillations is identical to that found in ocean models under mixed boundary conditions, these interstadial-interdecadal oscillations share the same characteristics as those previously found in ocean models forced by fixed surface fluxes. The wind stress forcing is shown to profoundly affect both the properties and bifurcation structure of thermohaline millennial oscillations across a wide range of variation of freshwater forcing. In particular, it is shown that the wind stress forcing favors the maintenance of thermally direct meridional overturning circulations during the cold stadial phases of Dansgaard-Oeschger cycles.</div></front></TEI><affiliations><list><country><li>Australie</li><li>France</li></country><region><li>Région Bretagne</li></region><settlement><li>Brest</li></settlement><orgName><li>Université de Bretagne Occidentale</li></orgName></list><tree><country name="Australie"><noRegion><name sortKey="Arzel, Olivier" sort="Arzel, Olivier" uniqKey="Arzel O" first="Olivier" last="Arzel">Olivier Arzel</name></noRegion><name sortKey="England, Matthew H" sort="England, Matthew H" uniqKey="England M" first="Matthew H." last="England">Matthew H. England</name></country><country name="France"><region name="Région Bretagne"><name sortKey="De Verdiere, Alain Colin" sort="De Verdiere, Alain Colin" uniqKey="De Verdiere A" first="Alain Colin" last="De Verdiere">Alain Colin De Verdiere</name></region></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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