Your search keyword '"Biastoch, A."' showing total 23 results

1. Lagrangian ocean analysis: Fundamentals and practices

Author

van Sebille, Erik, Griffies, Stephen M., Abernathey, Ryan, Adams, Thomas P., Berloff, Pavel, Biastoch, Arne, Blanke, Bruno, Chassignet, Eric P., Cheng, Yu, Cotter, Colin J., Deleersnijder, Eric, Döös, Kristofer, Drake, Henri F., Drijfhout, Sybren, Gary, Stefan F., Heemink, Arnold W., Kjellsson, Joakim, Koszalka, Inga Monika, Lange, Michael, Lique, Camille, MacGilchrist, Graeme A., Marsh, Robert, Mayorga Adame, C. Gabriela, McAdam, Ronan, Nencioli, Francesco, Paris, Claire B., Piggott, Matthew D., Polton, Jeff A., Rühs, Siren, Shah, Syed H.A.M., Thomas, Matthew D., Wang, Jinbo, Wolfram, Phillip J., Zanna, Laure, and Zika, Jan D.

Published

2018

2. Simulating the Agulhas system in global ocean models – nesting vs. multi-resolution unstructured meshes

Author

Biastoch, Arne, Sein, Dmitry, Durgadoo, Jonathan V., Wang, Qiang, and Danilov, Sergey

Published

2018

3. An assessment of the Arctic Ocean in a suite of interannual CORE-II simulations. Part III: Hydrography and fluxes

Author

Ilıcak, Mehmet, Drange, Helge, Wang, Qiang, Gerdes, Rüdiger, Aksenov, Yevgeny, Bailey, David, Bentsen, Mats, Biastoch, Arne, Bozec, Alexandra, Böning, Claus, Cassou, Christophe, Chassignet, Eric, Coward, Andrew C., Curry, Beth, Danabasoglu, Gokhan, Danilov, Sergey, Fernandez, Elodie, Fogli, Pier Giuseppe, Fujii, Yosuke, Griffies, Stephen M., Iovino, Doroteaciro, Jahn, Alexandra, Jung, Thomas, Large, William G., Lee, Craig, Lique, Camille, Lu, Jianhua, Masina, Simona, George Nurser, A.J., Roth, Christina, Salas y Mélia, David, Samuels, Bonita L., Spence, Paul, Tsujino, Hiroyuki, Valcke, Sophie, Voldoire, Aurore, Wang, Xuezhu, and Yeager, Steve G.

Published

2016

4. An assessment of the Arctic Ocean in a suite of interannual CORE-II simulations. Part II: Liquid freshwater

Author

Wang, Qiang, Ilicak, Mehmet, Gerdes, Rüdiger, Drange, Helge, Aksenov, Yevgeny, Bailey, David A, Bentsen, Mats, Biastoch, Arne, Bozec, Alexandra, Böning, Claus, Cassou, Christophe, Chassignet, Eric, Coward, Andrew C., Curry, Beth, Danabasoglu, Gokhan, Danilov, Sergey, Fernandez, Elodie, Fogli, Pier Giuseppe, Fujii, Yosuke, Griffies, Stephen M., Iovino, Doroteaciro, Jahn, Alexandra, Jung, Thomas, Large, William G., Lee, Craig, Lique, Camille, Lu, Jianhua, Masina, Simona, Nurser, A.J. George, Rabe, Benjamin, Roth, Christina, Salas y Mélia, David, Samuels, Bonita L., Spence, Paul, Tsujino, Hiroyuki, Valcke, Sophie, Voldoire, Aurore, Wang, Xuezhu, and Yeager, Steve G.

Published

2016

5. An assessment of the Arctic Ocean in a suite of interannual CORE-II simulations. Part I: Sea ice and solid freshwater

Author

Wang, Qiang, Ilicak, Mehmet, Gerdes, Rüdiger, Drange, Helge, Aksenov, Yevgeny, Bailey, David A., Bentsen, Mats, Biastoch, Arne, Bozec, Alexandra, Böning, Claus, Cassou, Christophe, Chassignet, Eric, Coward, Andrew C., Curry, Beth, Danabasoglu, Gokhan, Danilov, Sergey, Fernandez, Elodie, Fogli, Pier Giuseppe, Fujii, Yosuke, Griffies, Stephen M., Iovino, Doroteaciro, Jahn, Alexandra, Jung, Thomas, Large, William G., Lee, Craig, Lique, Camille, Lu, Jianhua, Masina, Simona, Nurser, A.J. George, Rabe, Benjamin, Roth, Christina, Salas y Mélia, David, Samuels, Bonita L., Spence, Paul, Tsujino, Hiroyuki, Valcke, Sophie, Voldoire, Aurore, Wang, Xuezhu, and Yeager, Steve G.

Published

2016

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

Author

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

Published

2016

7. An assessment of Southern Ocean water masses and sea ice during 1988–2007 in a suite of interannual CORE-II simulations

Author

Downes, Stephanie M., Farneti, Riccardo, Uotila, Petteri, Griffies, Stephen M., Marsland, Simon J., Bailey, David, Behrens, Erik, Bentsen, Mats, Bi, Daohua, Biastoch, Arne, Böning, Claus, Bozec, Alexandra, Canuto, Vittorio M., Chassignet, Eric, Danabasoglu, Gokhan, Danilov, Sergey, Diansky, Nikolay, Drange, Helge, Fogli, Pier Giuseppe, Gusev, Anatoly, Howard, Armando, Ilicak, Mehmet, Jung, Thomas, Kelley, Maxwell, Large, William G., Leboissetier, Anthony, Long, Matthew, Lu, Jianhua, Masina, Simona, Mishra, Akhilesh, Navarra, Antonio, George Nurser, A.J., Patara, Lavinia, Samuels, Bonita L., Sidorenko, Dmitry, Spence, Paul, Tsujino, Hiroyuki, Wang, Qiang, and Yeager, Stephen G.

Published

2015

8. An assessment of Antarctic Circumpolar Current and Southern Ocean meridional overturning circulation during 1958–2007 in a suite of interannual CORE-II simulations

Author

Farneti, Riccardo, Downes, Stephanie M., Griffies, Stephen M., Marsland, Simon J., Behrens, Erik, Bentsen, Mats, Bi, Daohua, Biastoch, Arne, Böning, Claus, Bozec, Alexandra, Canuto, Vittorio M., Chassignet, Eric, Danabasoglu, Gokhan, Danilov, Sergey, Diansky, Nikolay, Drange, Helge, Fogli, Pier Giuseppe, Gusev, Anatoly, Hallberg, Robert W., Howard, Armando, Ilicak, Mehmet, Jung, Thomas, Kelley, Maxwell, Large, William G., Leboissetier, Anthony, Long, Matthew, Lu, Jianhua, Masina, Simona, Mishra, Akhilesh, Navarra, Antonio, George Nurser, A.J., Patara, Lavinia, Samuels, Bonita L., Sidorenko, Dmitry, Tsujino, Hiroyuki, Uotila, Petteri, Wang, Qiang, and Yeager, Steve G.

Published

2015

9. An assessment of global and regional sea level for years 1993–2007 in a suite of interannual CORE-II simulations

Author

Griffies, Stephen M., Yin, Jianjun, Durack, Paul J., Goddard, Paul, Bates, Susan C., Behrens, Erik, Bentsen, Mats, Bi, Daohua, Biastoch, Arne, Böning, Claus W., Bozec, Alexandra, Chassignet, Eric, Danabasoglu, Gokhan, Danilov, Sergey, Domingues, Catia M., Drange, Helge, Farneti, Riccardo, Fernandez, Elodie, Greatbatch, Richard J., Holland, David M., Ilicak, Mehmet, Large, William G., Lorbacher, Katja, Lu, Jianhua, Marsland, Simon J., Mishra, Akhilesh, George Nurser, A.J., Salas y Mélia, David, Palter, Jaime B., Samuels, Bonita L., Schröter, Jens, Schwarzkopf, Franziska U., Sidorenko, Dmitry, Treguier, Anne Marie, Tseng, Yu-heng, Tsujino, Hiroyuki, Uotila, Petteri, Valcke, Sophie, Voldoire, Aurore, Wang, Qiang, Winton, Michael, and Zhang, Xuebin

Published

2014

10. North Atlantic simulations in Coordinated Ocean-ice Reference Experiments phase II (CORE-II). Part I: Mean states

Author

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

Published

2014

11. Spurious AMOC trends in global ocean sea-ice models related to subarctic freshwater forcing

Author

Behrens, Erik, Biastoch, Arne, and Böning, Claus W.

Published

2013

12. Towards an understanding of Labrador Sea salinity drift in eddy-permitting simulations

Author

Rattan, Sanjay, Myers, Paul G., Treguier, Anne-Marie, Theetten, Sebastien, Biastoch, Arne, and Böning, Claus

Published

2010

13. Lagrangian validation of numerical drifter trajectories using drifting buoys: Application to the Agulhas system

Author

van Sebille, E., van Leeuwen, P.J., Biastoch, A., Barron, C.N., and de Ruijter, W.P.M.

Published

2009

14. Coordinated Ocean-ice Reference Experiments (COREs)

Author

Griffies, Stephen M., Biastoch, Arne, Böning, Claus, Bryan, Frank, Danabasoglu, Gokhan, Chassignet, Eric P., England, Matthew H., Gerdes, Rüdiger, Haak, Helmuth, Hallberg, Robert W., Hazeleger, Wilco, Jungclaus, Johann, Large, William G., Madec, Gurvan, Pirani, Anna, Samuels, Bonita L., Scheinert, Markus, Gupta, Alex Sen, Severijns, Camiel A., Simmons, Harper L., Treguier, Anne Marie, Winton, Mike, Yeager, Stephen, and Yin, Jianjun

Published

2009

15. North Atlantic Simulations in Coordinated Ocean-Ice Reference Experiments Phase II (CORE-II) Part II: Inter-Annual to Decadal Variability

Author

Gokhan Danabasoglu, Steve G Yeager, Who M Kim, Erik Behrens, Mats Bentsen, Daohua Bi, Arne Biastoch, Rainer Bleck, Claus Boening, 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 M 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, David Salas y Melia, Bonita L Samuels, Markus Scheinert, Dmitry Sidorenko, Shan Sun, Anne-Marie Treguier, Hiroyuki Tsujino, Petteri Uotila, Sophie Valcke, Aurore Voldoire, Qiang Wang, and Igor Yashayaev

Subjects

Oceanography

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 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.

Published

2015

16. Simulating the Agulhas system in global ocean models – nesting vs. multi-resolution unstructured meshes

Author

Sergey Danilov, Jonathan V. Durgadoo, Qiang Wang, Arne Biastoch, and Dimitry Sein

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, 010505 oceanography, Mesoscale meteorology, Geotechnical Engineering and Engineering Geology, Oceanography, Grid, 01 natural sciences, Unstructured grid, Boundary current, Nonlinear system, 13. Climate action, Climatology, Scalability, Computer Science (miscellaneous), Polygon mesh, 14. Life underwater, Throughput (business), Geology, 0105 earth and related environmental sciences

Abstract

Many questions in ocean and climate modelling require the combined use of high resolution, global coverage and multi-decadal integration length. For this combination, even modern resources limit the use of traditional structured-mesh grids. Here we compare two approaches: A high-resolution grid nested into a global model at coarser resolution (NEMO with AGRIF) and an unstructured-mesh grid (FESOM) which allows to variably enhance resolution where desired. The Agulhas system around South Africa is used as a testcase, providing an energetic interplay of a strong western boundary current and mesoscale dynamics. Its open setting into the horizontal and global overturning circulations also requires global coverage. Both model configurations simulate a reasonable large-scale circulation. Distribution and temporal variability of the wind-driven circulation are quite comparable due to the same atmospheric forcing. However, the overturning circulation differs, owing each model's ability to represent formation and spreading of deep water masses. In terms of regional, high-resolution dynamics, all elements of the Agulhas system are well represented. Owing to the strong nonlinearity in the system, Agulhas Current transports of both configurations and in comparison with observations differ in strength and temporal variability. Similar decadal trends in Agulhas Current transport and Agulhas leakage are linked to the trends in wind forcing. Although the number of 3D wet grid points used in FESOM is similar to that in the nested NEMO, FESOM uses about two times the number of CPUs to obtain the same model throughput (in terms of simulated model years per day). This is feasible due to the high scalability of the FESOM code.

Published

2018

17. North Atlantic Simulations in Coordinated Ocean-Ice Reference Experiments Phase II (CORE-II). Part I: Mean States

Author

Gokhan Danabasoglu, Steve G Yeager, David Bailey, Erik Behrens, Mats Bentsen, Daohua Bi, Arne Biastoch, Claus Boning, 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 M Howard, Thomas Jung, Maxwell Kelley, William G Large, Anthony Leboissetier, Jianhua Lu, Gurvan Madec, Simon J Marsland, Simona Masina, Antonio Navarra, A J George Nurser, Anna Pirani, David Salas y Melia, Bonita L Samuels, Markus Scheinert, Dmitry Sidorenko, Anne-Marie Treguier, Hiroyuki Tsujino, Petteri Uotila, Sophie Valcke, Aurore Voldoire, and Qiang Wang

Subjects

Earth Resources And Remote Sensing, Meteorology And Climatology

Abstract

Simulation characteristics from eighteen global ocean-sea-ice coupled models are presented with a focus on the mean Atlantic meridional overturning circulation (AMOC) and other related fields in the North Atlantic. These experiments use inter-annually varying atmospheric forcing data sets for the 60-year period from 1948 to 2007 and are performed as contributions to the second phase of the Coordinated Oceanice Reference Experiments (CORE-II). The protocol for conducting such CORE-II experiments is summarized. Despite using the same atmospheric forcing, the solutions show significant differences. As most models also differ from available observations, biases in the Labrador Sea region in upper-ocean potential temperature and salinity distributions, mixed layer depths, and sea-ice cover are identified as contributors to differences in AMOC. These differences in the solutions do not suggest an obvious grouping of the models based on their ocean model lineage, their vertical coordinate representations, or surface salinity restoring strengths. Thus, the solution differences among the models are attributed primarily to use of different subgrid scale parameterizations and parameter choices as well as to differences in vertical and horizontal grid resolutions in the ocean models. Use of a wide variety of sea-ice models with diverse snow and sea-ice albedo treatments also contributes to these differences. Based on the diagnostics considered, the majority of the models appear suitable for use in studies involving the North Atlantic, but some models require dedicated development effort. atmospheric forcing atmospheric temperatures

Published

2013

18. An assessment of Southern Ocean water masses and sea ice during 1988–2007 in a suite of interannual CORE-II simulations

Author

Claus W. Böning, Simon J. Marsland, Lavinia Patara, Riccardo Farneti, Maxwell Kelley, A. M. Howard, David A. Bailey, Hiroyuki Tsujino, Jianhua Lu, Helge Drange, Matthew C. Long, Vittorio Canuto, Mats Bentsen, Nikolay Diansky, Stephen M. Griffies, Bonita L. Samuels, Anatoly Gusev, Erik Behrens, A. J. George Nurser, Qiang Wang, Dmitry Sidorenko, Alexandra Bozec, Eric P. Chassignet, Arne Biastoch, Gokhan Danabasoglu, Sergey Danilov, Paul Spence, Antonio Navarra, Simona Masina, Pier Giuseppe Fogli, Petteri Uotila, Mehmet Ilicak, Thomas Jung, Akhilesh Mishra, Daohua Bi, Stephanie M. Downes, Anthony Leboissetier, William G. Large, Stephen Yeager, Downes SM, Farneti R, Uotila P, Griffies SM, Marsland SJ, Bailey D, Behrens E, Bentsen M, Bi DH, Biastoch A, Boning C, Bozec A, Canuto VM, Chassignet E, Danabasoglu G, Danilov S, Diansky N, Drange H, Fogli PG, Gusev A, Howard A, Ilicak M, Jung T, Kelley M, Large WG, Leboissetier A, Long M, Lu JH, Masina S, Mishra A, Navarra A, Nurser AJG, Patara L, Samuels BL, Sidorenko D, Spence P, Tsujino H, Wang Q, and Yeager SG

Subjects

Atmospheric Science, geography, Ocean observations, geography.geographical_feature_category, Mixed layer, Antarctic sea ice, Geotechnical Engineering and Engineering Geology, Oceanography, Southern Ocean, CORE-II experiments, Water masses, Sea ice, Ocean dynamics, Sea ice thickness, Computer Science (miscellaneous), Sea ice, Environmental science, Thermohaline circulation, Ocean heat content

Abstract

We characterise the representation of the Southern Ocean water mass structure and sea ice within a suite of 15 global ocean-ice models run with the Coordinated Ocean-ice Reference Experiment Phase II (CORE-II) protocol. The main focus is the representation of the present (1988-2007) mode and intermediate waters, thus framing an analysis of winter and summer mixed layer depths; temperature, salinity, and potential vorticity structure; and temporal variability of sea ice distributions. We also consider the interannual variability over the same 20 year period. Comparisons are made between models as well as to observation-based analyses where available. The CORE-II models exhibit several biases relative to Southern Ocean observations, including an underestimation of the model mean mixed layer depths of mode and intermediate water masses in March (associated with greater ocean surface heat gain), and an overestimation in September (associated with greater high latitude ocean heat loss and a more northward winter sea-ice extent). In addition, the models have cold and fresh/warm and salty water column biases centred near 50 degrees S. Over the 1933-2007 period, the CORE-II models consistently simulate spatially variable trends in sea-ice concentration, surface freshwater fluxes, mixed layer depths, and 200-700 in ocean heat content. In particular, sea-ice coverage around most of the Antarctic continental shelf is reduced, leading to a cooling and freshening of the near surface waters. The shoaling of the mixed layer is associated with increased surface buoyancy gain, except in the Pacific where sea ice is also influential. The models are in disagreement, despite the common CORE-II atmospheric state, in their spatial pattern of the 20-year trends in the mixed layer depth and sea-ice. (C) 2015 Elsevier Ltd. All rights reserved

Published

2015

19. An assessment of Antarctic Circumpolar Current and Southern Ocean meridional overturning circulation during 1958–2007 in a suite of interannual CORE-II simulations

Author

Simon J. Marsland, Anthony Leboissetier, Steve G. Yeager, Antonio Navarra, Lavinia Patara, Vittorio Canuto, Simona Masina, Daohua Bi, Pier Giuseppe Fogli, Matthew C. Long, Mehmet Ilicak, Stephanie M. Downes, Eric P. Chassignet, Mats Bentsen, A. J. George Nurser, William G. Large, Riccardo Farneti, Petteri Uotila, Sergey Danilov, Anatoly Gusev, Maxwell Kelley, Akhilesh Mishra, Claus W. Böning, Robert Hallberg, Hiroyuki Tsujino, Jianhua Lu, Dmitry Sidorenko, Alexandra Bozec, Gokhan Danabasoglu, Thomas Jung, A. M. Howard, Nikolay Diansky, Stephen M. Griffies, Helge Drange, Bonita L. Samuels, Erik Behrens, Qiang Wang, Arne Biastoch, Farneti R, Downes SM, Griffies SM, Marsland SJ, Behrens E, Bentsen M, Bi DH, Biastoch A, Boning C, Bozec A, Canuto VM, Chassignet E, Danabasoglu G, Danilov S, Diansky N, Drange H, Fogli PG, Gusev A, Hallberg RW, Howard A, Ilicak M, Jung T, Kelley M, Large WG, Leboissetier A, Long M, Lu JH, Masina S, Mishra A, Navarra A, Nurser AJG, Patara L, Samuels BL, Sidorenko D, Tsujino H, Uotila P, Wang Q, and Yeager SG

Subjects

Atmospheric Science, Momentum (technical analysis), Isopycnal, Buoyancy, 010504 meteorology & atmospheric sciences, 010505 oceanography, Advection, Mode (statistics), Mesoscale meteorology, Forcing (mathematics), engineering.material, Geotechnical Engineering and Engineering Geology, Oceanography, 01 natural sciences, 13. Climate action, Climatology, Computer Science (miscellaneous), engineering, Thermohaline circulation, 14. Life underwater, Global ocean–sea ice modeling, Model comparisons, Southern Ocean meridional overturning circulation, Antarctic Circumpolar Current, Southern Ocean dynamics, Geology, 0105 earth and related environmental sciences

Abstract

In the framework of the second phase of the Coordinated Ocean-ice Reference Experiments (CORE-II), we present an analysis of the representation of the Antarctic Circumpolar Current (ACC) and Southern Ocean meridional overturning circulation (MOC) in a suite of seventeen global ocean-sea ice models. We focus on the mean, variability and trends of both the ACC and MOC over the 1958-2007 period, and discuss their relationship with the surface forcing. We aim to quantify the degree of eddy saturation and eddy compensation in the models participating in CORE-II, and compare our results with available observations, previous fineresolution numerical studies and theoretical constraints. Most models show weak ACC transport sensitivity to changes in forcing during the past five decades, and they can be considered to be in an eddy saturated regime. Larger contrasts arise when considering MOC trends, with a majority of models exhibiting significant strengthening of the MOC during the late 20th and early 21st century. Only a few models show a relatively small sensitivity to forcing changes, responding with an intensified eddy-induced circulation that provides some degree of eddy compensation, while still showing considerable decadal trends. Both ACC and MOC interannual variabilities are largely controlled by the Southern Annular Mode (SAM). Based on these results, models are clustered into two groups. Models with constant or two-dimensional (horizontal) specification of the eddy-induced advection coefficient K show larger ocean interior decadal trends, larger ACC transport decadal trends and no eddy compensation in the MOC. Eddy-permitting models or models with a threedimensional time varying K show smaller changes in isopycnal slopes and associated ACC trends, and partial eddy compensation. As previously argued, a constant in time or space lc is responsible for a poor representation of mesoscale eddy effects and cannot properly simulate the sensitivity of the ACC and MOC to changing surface forcing. Evidence is given for a larger sensitivity of the MOC as compared to the ACC transport, even when approaching eddy saturation. Future process studies designed for disentangling the role of momentum and buoyancy forcing in driving the ACC and MOC are proposed. (C) 2015 Elsevier Ltd. All rights reserved.

Published

2015

20. An assessment of the Arctic Ocean in a suite of interannual CORE-II simulations. Part II: Liquid freshwater

Author

Sergey Danilov, Christophe Cassou, Rüdiger Gerdes, Claus W. Böning, Mats Bentsen, Yosuke Fujii, Eric P. Chassignet, Hiroyuki Tsujino, Jianhua Lu, Christina Roth, Gokhan Danabasoglu, David A. Bailey, Doroteaciro Iovino, Steve G. Yeager, Yevgeny Aksenov, Helge Drange, A. J. George Nurser, Craig M. Lee, Thomas Jung, Elodie Fernandez, Bonita L. Samuels, Andrew C. Coward, Stephen M. Griffies, William G. Large, Qiang Wang, Benjamin Rabe, Arne Biastoch, Alexandra Bozec, Beth Curry, Xuezhu Wang, Mehmet Ilicak, Simona Masina, David Salas y Mélia, Aurore Voldoire, Pier Giuseppe Fogli, Sophie Valcke, Camille Lique, Paul Spence, and Alexandra Jahn

Subjects

geography, Atmospheric Science, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 010505 oceanography, Sea ice, Flux, Spatial distribution, Geotechnical Engineering and Engineering Geology, Oceanography, 01 natural sciences, The arctic, Marine Sciences, Freshwater, CORE II atmospheric forcing, 13. Climate action, Climatology, Phase (matter), Arctic Ocean, Computer Science (miscellaneous), Environmental science, Model development, 14. Life underwater, 0105 earth and related environmental sciences

Abstract

The Arctic Ocean simulated in 14 global ocean-sea ice models in the framework of the Coordinated Ocean-ice Reference Experiments, phase II (CORE-II) is analyzed in this study. The focus is on the Arctic liquid freshwater (FW) sources and freshwater content (FWC). The models agree on the interannual variability of liquid FW transport at the gateways where the ocean volume transport determines the FW transport variability. The variation of liquid FWC is induced by both the surface FW flux (associated with sea ice production) and lateral liquid FW transport, which are in phase when averaged on decadal time scales. The liquid FWC shows an increase starting from the mid-1990s, caused by the reduction of both sea ice formation and liquid FW export, with the former being more significant in most of the models. The mean state of the FW budget is less consistently simulated than the temporal variability. The model ensemble means of liquid FW transport through the Arctic gateways compare well with observations. On average, the models have too high mean FWC, weaker upward trends of FWC in the recent decade than the observation, and low consistency in the temporal variation of FWC spatial distribution, which needs to be further explored for the purpose of model development.

Published

2016

21. Lagrangian ocean analysis: Fundamentals and practices

Author

Erik van Sebille, Stephen M. Griffies, Ryan Abernathey, Thomas P. Adams, Pavel Berloff, Arne Biastoch, Bruno Blanke, Eric P. Chassignet, Yu Cheng, Colin J. Cotter, Eric Deleersnijder, Kristofer Döös, Henri F. Drake, Sybren Drijfhout, Stefan F. Gary, Arnold W. Heemink, Joakim Kjellsson, Inga Monika Koszalka, Michael Lange, Camille Lique, Graeme A. MacGilchrist, Robert Marsh, and C. Gabriela Mayorga A

Published

2018

22. Spurious AMOC trends in global ocean sea-ice models related to subarctic freshwater forcing

Author

Erik Behrens, Arne Biastoch, and Claus W. Böning

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, 010505 oceanography, Forcing (mathematics), Geotechnical Engineering and Engineering Geology, Oceanography, 01 natural sciences, Subarctic climate, 6. Clean water, Ocean sea, Salinity, Flux (metallurgy), 13. Climate action, Climatology, Computer Science (miscellaneous), Environmental science, 14. Life underwater, Sea surface salinity, Precipitation, Spurious relationship, 0105 earth and related environmental sciences

Abstract

Highlights: • OGCM simulations of the AMOC are highly sensitive to the subarctic freshwater forcing. • Trends in the simulated AMOC are linked to the salinity of the DSOW. • DSOW salinity trends can be traced back to the freshwater transport by the NAC. • The NAC freshwater budget is highly affected by the salinity restoring used in OGCMs. • Modifications in the subarctic precipitation can help to minimize the restoring flux. Global ocean sea-ice models with an atmospheric forcing based on bulk formulations of the air-sea fluxes exhibit spurious trends in key flow indices like the Atlantic Meridional Overturning Circulation (AMOC), constraining their use in investigations of multi-decadal ocean variability. To identify the critical model factors affecting the temporal evolution of the AMOC on time scales of up to 60 years, a series of experiments with both eddy-permitting (0.25°) and non-eddying (0.5°) ocean-ice models has been performed, focusing on the influence of artificial choices for the freshwater forcing, in particular the restoring of sea surface salinity towards climatological values. The atmospheric forcing builds on the proposal for Coordinated Ocean-ice Reference Experiments (CORE), utilizing the refined atmospheric reanalysis products for 1948–2006 compiled by Large and Yeager. Sensitivity experiments with small variations in precipitation (within the observational uncertainty) and sea surface salinity restoring in the subarctic Atlantic produce a wide range of AMOC transports, between upward drifts to more than 22 Sv and nearly-collapsed states with less than 7 Sv, reflecting the excessive role of the salinity feedback in such simulations. In all cases the AMOC is tightly related to the density of the Denmark Strait overflow; changes in that density are governed by the salinity in the Nordic Seas; and in turn, that salinity is strongly affected by the properties of the inflowing North Atlantic water.

Published

2013

23. Lagrangian ocean analysis: Fundamentals and practices

Author

van Sebille, E, Griffies, SM, Abernathey, R, Adams, TP, Berloff, P, Biastoch, A, Blanke, B, Chassignet, EP, Cheng, Y, Cotter, CJ, Deleersnijder, E, Doos, K, Drake, HF, Drijfhout, S, Gary, SF, Heemink, AW, Kjellsson, J, Koszalka, IM, Lange, M, Lique, C, MacGilchrist, GA, Marsh, R, Adame, CGM, McAdam, R, Nencioli, F, Paris, CB, Piggott, MD, Polton, JA, Ruehs, S, Shah, SHAM, Thomas, MD, Wang, J, Wolfram, PJ, Zanna, L, Zika, JD, Grantham Institute for Climate Change and the Environment, Imperial College London, Department of Earth, Atmospheric and Planetary Sciences [MIT, Cambridge] (EAPS), Massachusetts Institute of Technology (MIT), Helmholtz Centre for Ocean Research [Kiel] (GEOMAR), Laboratoire d'Océanographie Physique et Spatiale (LOPS), Institut de Recherche pour le Développement (IRD)-Institut Français de Recherche pour l'Exploitation de la Mer (IFREMER)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS), Center for Ocean-Atmospheric Prediction Studies (COAPS), Florida State University [Tallahassee] (FSU), Department of Mathematics [Imperial College London], Institute of Mechanics, Department of Meteorology [Stockholm] (MISU), Stockholm University, Royal Netherlands Meteorological Institute (KNMI), Joint Institute for the Study of the Atmosphere and Ocean (JISAO), University of Washington [Seattle], Ocean and Earth Science [Southampton], University of Southampton-National Oceanography Centre (NOC), Plymouth Marine Laboratory (PML), Plymouth Marine Laboratory, Marine and Atmospheric Research, Sub Physical Oceanography, Dep Natuurkunde, Natural Environment Research Council (NERC), Engineering & Physical Science Research Council (E, European Research Council, Institut de Recherche pour le Développement (IRD)-Institut Français de Recherche pour l'Exploitation de la Mer (IFREMER)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS), and UCL - SST/IMMC/MEMA - Applied mechanics and mathematics

Subjects

[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, Atmospheric Science, Connectivity, Particle tracking, Oceanography, Geotechnical Engineering and Engineering Geology, Ocean circulation, Future modelling, Lagrangian analysis, Computer Science (miscellaneous), 0405 Oceanography, Physics::Atmospheric and Oceanic Physics, ComputingMethodologies_COMPUTERGRAPHICS

Abstract

Highlights: • Lagrangian ocean analysis is a powerful way to analyse the output of ocean circulation models • We present a review of the Kinematic framework, available tools, and applications of Lagrangian ocean analysis • While there are unresolved questions, the framework is robust enough to be used widely in ocean modelling Abstract: Lagrangian analysis is a powerful way to analyse the output of ocean circulation models and other ocean velocity data such as from altimetry. In the Lagrangian approach, large sets of virtual particles are integrated within the three-dimensional, time-evolving velocity fields. Over several decades, a variety of tools and methods for this purpose have emerged. Here, we review the state of the art in the field of Lagrangian analysis of ocean velocity data, starting from a fundamental kinematic framework and with a focus on large-scale open ocean applications. Beyond the use of explicit velocity fields, we consider the influence of unresolved physics and dynamics on particle trajectories. We comprehensively list and discuss the tools currently available for tracking virtual particles. We then showcase some of the innovative applications of trajectory data, and conclude with some open questions and an outlook. The overall goal of this review paper is to reconcile some of the different techniques and methods in Lagrangian ocean analysis, while recognising the rich diversity of codes that have and continue to emerge, and the challenges of the coming age of petascale computing.