North Atlantic simulations in Coordinated Ocean-ice Reference Experiments phase II (CORE-II). Part II: Inter-annual to decadal variability

Gokhan Danabasoglu; Steve G. Yeager; Who M. Kim; Erik Behrens; Mats Bentsen; Daohua Bi; Arne Biastoch; Rainer Bleck; Claus Böning; Alexandra Bozec; Vittorio M. Canuto; Christophe Cassou; Eric Chassignet; Andrew C. Coward; Sergey Danilov; Nikolay Diansky; Helge Drange; Riccardo Farneti; Elodie Fernandez; Pier Giuseppe Fogli; Gael Forget; Yosuke Fujii; Stephen M. Griffies; Anatoly Gusev; Patrick Heimbach; Armando Howard; Mehmet Ilicak; Thomas Jung; Alicia R. Karspeck; Maxwell Kelley; William G. Large; Anthony Leboissetier; Jianhua Lu; Gurvan Madec; Simon J. Marsland; Simona Masina; Antonio Navarra; A. J.George Nurser; Anna Pirani; Anastasia Romanou; Salas y.Mélia David; Bonita L. Samuels; Markus Scheinert; Dmitry Sidorenko; Shan Sun; Anne Marie Treguier; Hiroyuki Tsujino; Petteri Uotila; Sophie Valcke; Aurore Voldoire; Qiang Wang; Igor Yashayaev

doi:10.1016/j.ocemod.2015.11.007

North Atlantic simulations in Coordinated Ocean-ice Reference Experiments phase II (CORE-II). Part II: Inter-annual to decadal variability

Gokhan Danabasoglu, Steve G. Yeager, Who M. Kim, Erik Behrens, Mats Bentsen, Daohua Bi, Arne Biastoch, Rainer Bleck, Claus Böning, Alexandra Bozec, Vittorio M. Canuto, Christophe Cassou, Eric Chassignet, Andrew C. Coward, Sergey Danilov, Nikolay Diansky, Helge Drange, Riccardo Farneti, Elodie Fernandez, Pier Giuseppe FogliGael Forget, Yosuke Fujii, Stephen M. Griffies, Anatoly Gusev, Patrick Heimbach, Armando Howard, Mehmet Ilicak, Thomas Jung, Alicia R. Karspeck, Maxwell Kelley, William G. Large, Anthony Leboissetier, Jianhua Lu, Gurvan Madec, Simon J. Marsland, Simona Masina, Antonio Navarra, A. J.George Nurser, Anna Pirani, Anastasia Romanou, Salas y.Mélia David, Bonita L. Samuels, Markus Scheinert, Dmitry Sidorenko, Shan Sun, Anne Marie Treguier, Hiroyuki Tsujino, Petteri Uotila, Sophie Valcke, Aurore Voldoire, Qiang Wang, Igor Yashayaev

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Abstract

Simulated inter-annual to decadal variability and trends in the North Atlantic for the 1958-2007 period from twenty global ocean - sea-ice coupled models are presented. These simulations are performed as contributions to the second phase of the Coordinated Ocean-ice Reference Experiments (CORE-II). The study is Part II of our companion paper (Danabasoglu et al., 2014) which documented the mean states in the North Atlantic from the same models. A major focus of the present study is the representation of Atlantic meridional overturning circulation (AMOC) variability in the participating models. Relationships between AMOC variability and those of some other related variables, such as subpolar mixed layer depths, the North Atlantic Oscillation (NAO), and the Labrador Sea upper-ocean hydrographic properties, are also investigated. In general, AMOC variability shows three distinct stages. During the first stage that lasts until the mid- to late-1970s, AMOC is relatively steady, remaining lower than its long-term (1958-2007) mean. Thereafter, AMOC intensifies with maximum transports achieved in the mid- to late-1990s. This enhancement is then followed by a weakening trend until the end of our integration period. This sequence of low frequency AMOC variability is consistent with previous studies. Regarding strengthening of AMOC between about the mid-1970s and the mid-1990s, our results support a previously identified variability mechanism where AMOC intensification is connected to increased deep water formation in the subpolar North Atlantic, driven by NAO-related surface fluxes. The simulations tend to show general agreement in their temporal representations of, for example, AMOC, sea surface temperature (SST), and subpolar mixed layer depth variabilities. In particular, the observed variability of the North Atlantic SSTs is captured well by all models. These findings indicate that simulated variability and trends are primarily dictated by the atmospheric datasets which include the influence of ocean dynamics from nature superimposed onto anthropogenic effects. Despite these general agreements, there are many differences among the model solutions, particularly in the spatial structures of variability patterns. For example, the location of the maximum AMOC variability differs among the models between Northern and Southern Hemispheres.

Original language	English
Pages (from-to)	65-90
Number of pages	26
Journal	Ocean Modelling
Volume	97
DOIs	https://doi.org/10.1016/j.ocemod.2015.11.007
State	Published - Jan 1 2016
Externally published	Yes

Keywords

Atlantic meridional overturning circulation variability
Atmospheric forcing
Global ocean - sea-ice modelling
Inter-annual to decadal variability and mechanisms
Ocean model comparisons
Variability in the North Atlantic

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10.1016/j.ocemod.2015.11.007

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Danabasoglu, G., Yeager, S. G., Kim, W. M., Behrens, E., Bentsen, M., Bi, D., Biastoch, A., Bleck, R., Böning, C., Bozec, A., Canuto, V. M., Cassou, C., Chassignet, E., Coward, A. C., Danilov, S., Diansky, N., Drange, H., Farneti, R., Fernandez, E., ... Yashayaev, I. (2016). North Atlantic simulations in Coordinated Ocean-ice Reference Experiments phase II (CORE-II). Part II: Inter-annual to decadal variability. Ocean Modelling, 97, 65-90. https://doi.org/10.1016/j.ocemod.2015.11.007

@article{1b76fd4e4887471bb04d83a4bae54c68,

title = "North Atlantic simulations in Coordinated Ocean-ice Reference Experiments phase II (CORE-II). Part II: Inter-annual to decadal variability",

abstract = "Simulated inter-annual to decadal variability and trends in the North Atlantic for the 1958-2007 period from twenty global ocean - sea-ice coupled models are presented. These simulations are performed as contributions to the second phase of the Coordinated Ocean-ice Reference Experiments (CORE-II). The study is Part II of our companion paper (Danabasoglu et al., 2014) which documented the mean states in the North Atlantic from the same models. A major focus of the present study is the representation of Atlantic meridional overturning circulation (AMOC) variability in the participating models. Relationships between AMOC variability and those of some other related variables, such as subpolar mixed layer depths, the North Atlantic Oscillation (NAO), and the Labrador Sea upper-ocean hydrographic properties, are also investigated. In general, AMOC variability shows three distinct stages. During the first stage that lasts until the mid- to late-1970s, AMOC is relatively steady, remaining lower than its long-term (1958-2007) mean. Thereafter, AMOC intensifies with maximum transports achieved in the mid- to late-1990s. This enhancement is then followed by a weakening trend until the end of our integration period. This sequence of low frequency AMOC variability is consistent with previous studies. Regarding strengthening of AMOC between about the mid-1970s and the mid-1990s, our results support a previously identified variability mechanism where AMOC intensification is connected to increased deep water formation in the subpolar North Atlantic, driven by NAO-related surface fluxes. The simulations tend to show general agreement in their temporal representations of, for example, AMOC, sea surface temperature (SST), and subpolar mixed layer depth variabilities. In particular, the observed variability of the North Atlantic SSTs is captured well by all models. These findings indicate that simulated variability and trends are primarily dictated by the atmospheric datasets which include the influence of ocean dynamics from nature superimposed onto anthropogenic effects. Despite these general agreements, there are many differences among the model solutions, particularly in the spatial structures of variability patterns. For example, the location of the maximum AMOC variability differs among the models between Northern and Southern Hemispheres.",

keywords = "Atlantic meridional overturning circulation variability, Atmospheric forcing, Global ocean - sea-ice modelling, Inter-annual to decadal variability and mechanisms, Ocean model comparisons, Variability in the North Atlantic",

author = "Gokhan Danabasoglu and Yeager, \{Steve G.\} and Kim, \{Who M.\} and Erik Behrens and Mats Bentsen and Daohua Bi and Arne Biastoch and Rainer Bleck and Claus B{\"o}ning and Alexandra Bozec and Canuto, \{Vittorio M.\} and Christophe Cassou and Eric Chassignet and Coward, \{Andrew C.\} and Sergey Danilov and Nikolay Diansky and Helge Drange and Riccardo Farneti and Elodie Fernandez and Fogli, \{Pier Giuseppe\} and Gael Forget and Yosuke Fujii and Griffies, \{Stephen M.\} and Anatoly Gusev and Patrick Heimbach and Armando Howard and Mehmet Ilicak and Thomas Jung and Karspeck, \{Alicia R.\} and Maxwell Kelley and Large, \{William G.\} and Anthony Leboissetier and Jianhua Lu and Gurvan Madec and Marsland, \{Simon J.\} and Simona Masina and Antonio Navarra and Nurser, \{A. J.George\} and Anna Pirani and Anastasia Romanou and David, \{Salas y.M{\'e}lia\} and Samuels, \{Bonita L.\} and Markus Scheinert and Dmitry Sidorenko and Shan Sun and Treguier, \{Anne Marie\} and Hiroyuki Tsujino and Petteri Uotila and Sophie Valcke and Aurore Voldoire and Qiang Wang and Igor Yashayaev",

note = "Publisher Copyright: {\textcopyright} 2015 Elsevier Ltd.",

year = "2016",

month = jan,

day = "1",

doi = "10.1016/j.ocemod.2015.11.007",

language = "English",

volume = "97",

pages = "65--90",

journal = "Ocean Modelling",

issn = "1463-5003",

publisher = "Elsevier B.V.",

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Danabasoglu, G , Yeager, SG , Kim, WM, Behrens, E, Bentsen, M, Bi, D, Biastoch, A, Bleck, R, Böning, C, Bozec, A, Canuto, VM, Cassou, C, Chassignet, E, Coward, AC, Danilov, S, Diansky, N, Drange, H, Farneti, R, Fernandez, E, Fogli, PG, Forget, G, Fujii, Y, Griffies, SM, Gusev, A, Heimbach, P, Howard, A, Ilicak, M, Jung, T, Karspeck, AR, Kelley, M, Large, WG, Leboissetier, A, Lu, J, Madec, G, Marsland, SJ, Masina, S, Navarra, A, Nurser, AJG, Pirani, A, Romanou, A, David, SYM, Samuels, BL, Scheinert, M, Sidorenko, D, Sun, S, Treguier, AM, Tsujino, H, Uotila, P, Valcke, S, Voldoire, A, Wang, Q & Yashayaev, I 2016, 'North Atlantic simulations in Coordinated Ocean-ice Reference Experiments phase II (CORE-II). Part II: Inter-annual to decadal variability', Ocean Modelling, vol. 97, pp. 65-90. https://doi.org/10.1016/j.ocemod.2015.11.007

TY - JOUR

T1 - North Atlantic simulations in Coordinated Ocean-ice Reference Experiments phase II (CORE-II). Part II

T2 - Inter-annual to decadal variability

AU - Danabasoglu, Gokhan

AU - Yeager, Steve G.

AU - Kim, Who M.

AU - Behrens, Erik

AU - Bentsen, Mats

AU - Bi, Daohua

AU - Biastoch, Arne

AU - Bleck, Rainer

AU - Böning, Claus

AU - Bozec, Alexandra

AU - Canuto, Vittorio M.

AU - Cassou, Christophe

AU - Chassignet, Eric

AU - Coward, Andrew C.

AU - Danilov, Sergey

AU - Diansky, Nikolay

AU - Drange, Helge

AU - Farneti, Riccardo

AU - Fernandez, Elodie

AU - Fogli, Pier Giuseppe

AU - Forget, Gael

AU - Fujii, Yosuke

AU - Griffies, Stephen M.

AU - Gusev, Anatoly

AU - Heimbach, Patrick

AU - Howard, Armando

AU - Ilicak, Mehmet

AU - Jung, Thomas

AU - Karspeck, Alicia R.

AU - Kelley, Maxwell

AU - Large, William G.

AU - Leboissetier, Anthony

AU - Lu, Jianhua

AU - Madec, Gurvan

AU - Marsland, Simon J.

AU - Masina, Simona

AU - Navarra, Antonio

AU - Nurser, A. J.George

AU - Pirani, Anna

AU - Romanou, Anastasia

AU - David, Salas y.Mélia

AU - Samuels, Bonita L.

AU - Scheinert, Markus

AU - Sidorenko, Dmitry

AU - Sun, Shan

AU - Treguier, Anne Marie

AU - Tsujino, Hiroyuki

AU - Uotila, Petteri

AU - Valcke, Sophie

AU - Voldoire, Aurore

AU - Wang, Qiang

AU - Yashayaev, Igor

PY - 2016/1/1

Y1 - 2016/1/1

N2 - Simulated inter-annual to decadal variability and trends in the North Atlantic for the 1958-2007 period from twenty global ocean - sea-ice coupled models are presented. These simulations are performed as contributions to the second phase of the Coordinated Ocean-ice Reference Experiments (CORE-II). The study is Part II of our companion paper (Danabasoglu et al., 2014) which documented the mean states in the North Atlantic from the same models. A major focus of the present study is the representation of Atlantic meridional overturning circulation (AMOC) variability in the participating models. Relationships between AMOC variability and those of some other related variables, such as subpolar mixed layer depths, the North Atlantic Oscillation (NAO), and the Labrador Sea upper-ocean hydrographic properties, are also investigated. In general, AMOC variability shows three distinct stages. During the first stage that lasts until the mid- to late-1970s, AMOC is relatively steady, remaining lower than its long-term (1958-2007) mean. Thereafter, AMOC intensifies with maximum transports achieved in the mid- to late-1990s. This enhancement is then followed by a weakening trend until the end of our integration period. This sequence of low frequency AMOC variability is consistent with previous studies. Regarding strengthening of AMOC between about the mid-1970s and the mid-1990s, our results support a previously identified variability mechanism where AMOC intensification is connected to increased deep water formation in the subpolar North Atlantic, driven by NAO-related surface fluxes. The simulations tend to show general agreement in their temporal representations of, for example, AMOC, sea surface temperature (SST), and subpolar mixed layer depth variabilities. In particular, the observed variability of the North Atlantic SSTs is captured well by all models. These findings indicate that simulated variability and trends are primarily dictated by the atmospheric datasets which include the influence of ocean dynamics from nature superimposed onto anthropogenic effects. Despite these general agreements, there are many differences among the model solutions, particularly in the spatial structures of variability patterns. For example, the location of the maximum AMOC variability differs among the models between Northern and Southern Hemispheres.

AB - Simulated inter-annual to decadal variability and trends in the North Atlantic for the 1958-2007 period from twenty global ocean - sea-ice coupled models are presented. These simulations are performed as contributions to the second phase of the Coordinated Ocean-ice Reference Experiments (CORE-II). The study is Part II of our companion paper (Danabasoglu et al., 2014) which documented the mean states in the North Atlantic from the same models. A major focus of the present study is the representation of Atlantic meridional overturning circulation (AMOC) variability in the participating models. Relationships between AMOC variability and those of some other related variables, such as subpolar mixed layer depths, the North Atlantic Oscillation (NAO), and the Labrador Sea upper-ocean hydrographic properties, are also investigated. In general, AMOC variability shows three distinct stages. During the first stage that lasts until the mid- to late-1970s, AMOC is relatively steady, remaining lower than its long-term (1958-2007) mean. Thereafter, AMOC intensifies with maximum transports achieved in the mid- to late-1990s. This enhancement is then followed by a weakening trend until the end of our integration period. This sequence of low frequency AMOC variability is consistent with previous studies. Regarding strengthening of AMOC between about the mid-1970s and the mid-1990s, our results support a previously identified variability mechanism where AMOC intensification is connected to increased deep water formation in the subpolar North Atlantic, driven by NAO-related surface fluxes. The simulations tend to show general agreement in their temporal representations of, for example, AMOC, sea surface temperature (SST), and subpolar mixed layer depth variabilities. In particular, the observed variability of the North Atlantic SSTs is captured well by all models. These findings indicate that simulated variability and trends are primarily dictated by the atmospheric datasets which include the influence of ocean dynamics from nature superimposed onto anthropogenic effects. Despite these general agreements, there are many differences among the model solutions, particularly in the spatial structures of variability patterns. For example, the location of the maximum AMOC variability differs among the models between Northern and Southern Hemispheres.

KW - Atlantic meridional overturning circulation variability

KW - Atmospheric forcing

KW - Global ocean - sea-ice modelling

KW - Inter-annual to decadal variability and mechanisms

KW - Ocean model comparisons

KW - Variability in the North Atlantic

UR - https://www.scopus.com/pages/publications/84954110225

U2 - 10.1016/j.ocemod.2015.11.007

DO - 10.1016/j.ocemod.2015.11.007

M3 - Article

AN - SCOPUS:84954110225

SN - 1463-5003

VL - 97

SP - 65

EP - 90

JO - Ocean Modelling

JF - Ocean Modelling

ER -

North Atlantic simulations in Coordinated Ocean-ice Reference Experiments phase II (CORE-II). Part II: Inter-annual to decadal variability

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