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2. Air-Sea Fluxes With a Focus on Heat and Momentum

Author

Cronin, Meghan F, Gentemann, Chelle L, Edson, James, Ueki, Iwao, Bourassa, Mark, Brown, Shannon, Clayson, Carol Anne, Fairall, Chris W, Farrar, J Thomas, Gille, Sarah T, Gulev, Sergey, Josey, Simon A, Kato, Seiji, Katsumata, Masaki, Kent, Elizabeth, Krug, Marjolaine, Minnett, Peter J, Parfitt, Rhys, Pinker, Rachel T, Jr, Stackhouse Paul W, Swart, Sebastiaan, Tomita, Hiroyuki, Vandemark, Douglas, AWeller, Robert, Yoneyama, Kunio, Yu, Lisan, and Zhang, Dongxiao

Subjects
air-sea heat flux, latent heat flux, surface radiation, ocean wind stress, autonomous surface vehicle, OceanSITES, ICOADS, satellite-based ocean monitoring system, Oceanography, Ecology
Published
2019

4. The Natal Bight Coastal Counter-Current: A modeling study

Author

Heye, Sonia, Krug, Marjolaine, Penven, Pierrick, Hart-davis, Michael, Heye, Sonia, Krug, Marjolaine, Penven, Pierrick, and Hart-davis, Michael

Abstract

Output from a high-resolution ocean model, a wind reanalysis and a particle tracking tool are used to improve our understanding of the shelf circulation in an embayment off South Africa's east coast, known as the KwaZulu-Natal Bight. This region spans across roughly 140 km of coastline and is located between 29 degrees S and 30 degrees S. It is influenced by the strong, south-westward flowing Agulhas Current on its offshore edge, while its shelf is dominated by weak and variable currents. On the KwaZulu-Natal Bight's shelf, realistic high-resolution model simulations indicate the presence of a mean north-eastward flow: the Natal Bight Coastal Counter-Current. The mean surface circulation depicts a Natal Bight Coastal Counter Current stretching along the 50 m isobath from the southern to the northern section of the KwaZulu-Natal Bight while progressively becoming narrower and weaker northwards. The mean vertical structure of this counter current extends throughout the water column and at its origin, it almost connects with the Agulhas Undercurrent. In this region, the Natal Bight Coastal Counter-Current is about 20 km wide and has an average speed of 20 cm/s at its core, which may exceed 100 cm/ s during individual events. The passage of southward propagating anticyclonic eddies offshore of the Agulhas Current are associated with a southward flow along the southern KwaZulu-Natal Bight region and the inter-ruption of the otherwise north-eastward shelf currents. While the circulation in the KwaZulu-Natal Bight is primarily driven by perturbations at the Agulhas Current front, there is also some indication of a direct wind -driven influence in coastal waters, inshore of the 50 m isobath and north of 29.5 degrees S. Virtual particle tracking experiments show that the Natal Bight Coastal Counter Current may increase connectivity between Marine Protected Areas within the KwaZulu-Natal Bight, where the current greatly increases the water retention. This may trap nutrients f

Published
2022
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5. Corrigendum: OceanGliders: A Component of the Integrated GOOS

Author

Testor, Pierre, primary, Young, Brad de, additional, Rudnick, Daniel L., additional, Glenn, Scott, additional, Hayes, Daniel, additional, Lee, Craig M., additional, Pattiaratchi, Charitha, additional, Hill, Katherine, additional, Heslop, Emma, additional, Turpin, Victor, additional, Alenius, Pekka, additional, Barrera, Carlos, additional, Barth, John A., additional, Beaird, Nicholas, additional, Bécu, Guislain, additional, Bosse, Anthony, additional, Bourrin, François, additional, Brearley, J. Alexander, additional, Chao, Yi, additional, Chen, Sue, additional, Chiggiato, Jacopo, additional, Coppola, Laurent, additional, Crout, Richard, additional, Cummings, James, additional, Curry, Beth, additional, Curry, Ruth, additional, Davis, Richard, additional, Desai, Kruti, additional, DiMarco, Steve, additional, Edwards, Catherine, additional, Fielding, Sophie, additional, Fer, Ilker, additional, Frajka-Williams, Eleanor, additional, Gildor, Hezi, additional, Goni, Gustavo, additional, Gutierrez, Dimitri, additional, Haugan, Peter, additional, Hebert, David, additional, Heiderich, Joleen, additional, Henson, Stephanie, additional, Heywood, Karen, additional, Hogan, Patrick, additional, Houpert, Loïc, additional, Huh, Sik, additional, Inall, Mark E., additional, Ishii, Masso, additional, Ito, Shin-ichi, additional, Itoh, Sachihiko, additional, Jan, Sen, additional, Kaiser, Jan, additional, Karstensen, Johannes, additional, Kirkpatrick, Barbara, additional, Klymak, Jody, additional, Kohut, Josh, additional, Krahmann, Gerd, additional, Krug, Marjolaine, additional, McClatchie, Sam, additional, Marin, Frédéric, additional, Mauri, Elena, additional, Mehra, Avichal, additional, Meredith, Michael P., additional, Meunier, Thomas, additional, Miles, Travis, additional, Morell, Julio M., additional, Mortier, Laurent, additional, Nicholson, Sarah, additional, O'Callaghan, Joanne, additional, O'Conchubhair, Diarmuid, additional, Oke, Peter, additional, Pallàs-Sanz, Enric, additional, Palmer, Matthew, additional, Park, JongJin, additional, Perivoliotis, Leonidas, additional, Poulain, Pierre-Marie, additional, Perry, Ruth, additional, Queste, Bastien, additional, Rainville, Luc, additional, Rehm, Eric, additional, Roughan, Moninya, additional, Rome, Nicholas, additional, Ross, Tetjana, additional, Ruiz, Simon, additional, Saba, Grace, additional, Schaeffer, Amandine, additional, Schönau, Martha, additional, Schroeder, Katrin, additional, Shimizu, Yugo, additional, Sloyan, Bernadette M., additional, Smeed, David, additional, Snowden, Derrick, additional, Song, Yumi, additional, Swart, Sebastian, additional, Tenreiro, Miguel, additional, Thompson, Andrew, additional, Tintore, Joaquin, additional, Todd, Robert E., additional, Toro, Cesar, additional, Venables, Hugh, additional, Wagawa, Taku, additional, Waterman, Stephanie, additional, Watlington, Roy A., additional, and Wilson, Doug, additional

Published
2021
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7. Evolving the Physical Global Ocean Observing System for Research and Application Services Through International Coordination

Author

Sloyan, Bernadette M., Wilkin, John, Hill, Katherine Louise, Chidichimo, Maria Paz, Cronin, Meghan F., Johannessen, Johnny A., Karstensen, Johannes, Krug, Marjolaine, Lee, Tong, Oka, Eitarou, Palmer, Matthew D., Rabe, Benjamin, Speich, Sabrina, von Schuckmann, Karina, Weller, Robert A., Yu, Weidong, Sloyan, Bernadette M., Wilkin, John, Hill, Katherine Louise, Chidichimo, Maria Paz, Cronin, Meghan F., Johannessen, Johnny A., Karstensen, Johannes, Krug, Marjolaine, Lee, Tong, Oka, Eitarou, Palmer, Matthew D., Rabe, Benjamin, Speich, Sabrina, von Schuckmann, Karina, Weller, Robert A., and Yu, Weidong

Abstract

Climate change and variability are major societal challenges, and the ocean is an integral part of this complex and variable system. Key to the understanding of the ocean�s role in the Earth�s climate system is the study of ocean and sea-ice physical processes, including its interactions with the atmosphere, cryosphere, land, and biosphere. These processes include those linked to ocean circulation; the storage and redistribution of heat, carbon, salt and other water properties; and air-sea exchanges of heat, momentum, freshwater, carbon, and other gasses. Measurements of ocean physics variables are fundamental to reliable earth prediction systems for a range of applications and users. In addition, knowledge of the physical environment is fundamental to growing understanding of the ocean�s biogeochemistry and biological/ecosystem variability and function. Through the progress from OceanObs�99 to OceanObs�09, the ocean observing system has evolved from a platform centric perspective to an integrated observing system. The challenge now is for the observing system to evolve to respond to an increasingly diverse end user group. The Ocean Observations Physics and Climate panel (OOPC), formed in 1995, has undertaken many activities that led to observing system-related agreements. Here, OOPC will explore the opportunities and challenges for the development of a fit-for-purpose, sustained and prioritized ocean observing system, focusing on physical variables that maximize support for fundamental research, climate monitoring, forecasting on different timescales, and society. OOPC recommendations are guided by the Framework for Ocean Observing which emphasizes identifying user requirements by considering time and space scales of the Essential Ocean Variables. This approach provides a framework for reviewing the adequacy of the observing system, looking for synergies in delivering an integrated observing system for a range of applications and focusing innovation in ar

Published
2019

8. OceanGliders: A component of the integrated GOOS

Author

Testor, Pierre, de Young, Brad, Rudnick, Daniel L., Glenn, Scott, Hayes, Daniel J., Lee, Craig M., Pattiaratchi, Charitha, Hill, Katherine Louise, Heslop, Emma, Turpin, Victor, Alenius, Pekka, Barrera, Carlos, Barth, John A., Beaird, Nicholas, Bécu, Guislain, Bosse, Anthony, Bourrin, François, Brearley, J. Alexander, Chao, Yi, Chen, Sue, Chiggiato, Jacopo, Coppola, Laurent, Crout, Richard, Cummings, James A., Curry, Beth, Curry, Ruth G., Davis, Richard F., Desai, Kruti, DiMarco, Steven F., Edwards, Catherine, Fielding, Sophie, Fer, Ilker, Frajka-Williams, Eleanor, Gildor, Hezi, Goni, Gustavo J., Gutierrez, Dimitri, Haugan, Peter M., Hebert, David, Heiderich, Joleen, Henson, Stephanie A., Heywood, Karen J., Hogan, Patrick, Houpert, Loïc, Huh, Sik, Inall, Mark E., Ishii, Masao, Ito, Shin-ichi, Itoh, Sachihiko, Jan, Sen, Kaiser, Jan, Karstensen, Johannes, Kirkpatrick, Barbara, Klymak, Jody M., Kohut, Josh, Krahmann, Gerd, Krug, Marjolaine, McClatchie, Sam, Marin, Frédéric, Mauri, Elena, Mehra, Avichal, Meredith, Michael P., Meunier, Thomas, Miles, Travis, Morell, Julio M., Mortier, Laurent, Nicholson, Sarah, O'Callaghan, Joanne, O'Conchubhair, Diarmuid, Oke, Peter, Pallás-Sanz, Enric, Palmer, Matthew D., Park, Jong Jin, Perivoliotis, Leonidas, Poulain, Pierre Marie, Perry, Ruth, Queste, Bastien, Rainville, Luc, Rehm, Eric, Roughan, Moninya, Rome, Nicholas, Ross, Tetjana, Ruiz, Simon, Saba, Grace, Schaeffer, Amandine, Schönau, Martha, Schroeder, Katrin, Shimizu, Yugo, Sloyan, Bernadette M., Smeed, David A., Snowden, Derrick, Song, Yumi, Swart, Sebastiaan, Tenreiro, Miguel, Thompson, Andrew, Tintore, Joaquin, Todd, Robert E., Toro, Cesar, Venables, Hugh J., Wagawa, Taku, Waterman, Stephanie N., Watlington, Roy A., Wilson, Doug, Testor, Pierre, de Young, Brad, Rudnick, Daniel L., Glenn, Scott, Hayes, Daniel J., Lee, Craig M., Pattiaratchi, Charitha, Hill, Katherine Louise, Heslop, Emma, Turpin, Victor, Alenius, Pekka, Barrera, Carlos, Barth, John A., Beaird, Nicholas, Bécu, Guislain, Bosse, Anthony, Bourrin, François, Brearley, J. Alexander, Chao, Yi, Chen, Sue, Chiggiato, Jacopo, Coppola, Laurent, Crout, Richard, Cummings, James A., Curry, Beth, Curry, Ruth G., Davis, Richard F., Desai, Kruti, DiMarco, Steven F., Edwards, Catherine, Fielding, Sophie, Fer, Ilker, Frajka-Williams, Eleanor, Gildor, Hezi, Goni, Gustavo J., Gutierrez, Dimitri, Haugan, Peter M., Hebert, David, Heiderich, Joleen, Henson, Stephanie A., Heywood, Karen J., Hogan, Patrick, Houpert, Loïc, Huh, Sik, Inall, Mark E., Ishii, Masao, Ito, Shin-ichi, Itoh, Sachihiko, Jan, Sen, Kaiser, Jan, Karstensen, Johannes, Kirkpatrick, Barbara, Klymak, Jody M., Kohut, Josh, Krahmann, Gerd, Krug, Marjolaine, McClatchie, Sam, Marin, Frédéric, Mauri, Elena, Mehra, Avichal, Meredith, Michael P., Meunier, Thomas, Miles, Travis, Morell, Julio M., Mortier, Laurent, Nicholson, Sarah, O'Callaghan, Joanne, O'Conchubhair, Diarmuid, Oke, Peter, Pallás-Sanz, Enric, Palmer, Matthew D., Park, Jong Jin, Perivoliotis, Leonidas, Poulain, Pierre Marie, Perry, Ruth, Queste, Bastien, Rainville, Luc, Rehm, Eric, Roughan, Moninya, Rome, Nicholas, Ross, Tetjana, Ruiz, Simon, Saba, Grace, Schaeffer, Amandine, Schönau, Martha, Schroeder, Katrin, Shimizu, Yugo, Sloyan, Bernadette M., Smeed, David A., Snowden, Derrick, Song, Yumi, Swart, Sebastiaan, Tenreiro, Miguel, Thompson, Andrew, Tintore, Joaquin, Todd, Robert E., Toro, Cesar, Venables, Hugh J., Wagawa, Taku, Waterman, Stephanie N., Watlington, Roy A., and Wilson, Doug

Abstract

© The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Testor, P., de Young, B., Rudnick, D. L., Glenn, S., Hayes, D., Lee, C. M., Pattiaratchi, C., Hill, K., Heslop, E., Turpin, V., Alenius, P., Barrera, C., Barth, J. A., Beaird, N., Becu, G., Bosse, A., Bourrin, F., Brearley, J. A., Chao, Y., Chen, S., Chiggiato, J., Coppola, L., Crout, R., Cummings, J., Curry, B., Curry, R., Davis, R., Desai, K., DiMarco, S., Edwards, C., Fielding, S., Fer, I., Frajka-Williams, E., Gildor, H., Goni, G., Gutierrez, D., Haugan, P., Hebert, D., Heiderich, J., Henson, S., Heywood, K., Hogan, P., Houpert, L., Huh, S., Inall, M. E., Ishii, M., Ito, S., Itoh, S., Jan, S., Kaiser, J., Karstensen, J., Kirkpatrick, B., Klymak, J., Kohut, J., Krahmann, G., Krug, M., McClatchie, S., Marin, F., Mauri, E., Mehra, A., Meredith, M. P., Meunier, T., Miles, T., Morell, J. M., Mortier, L., Nicholson, S., O'Callaghan, J., O'Conchubhair, D., Oke, P., Pallas-Sanz, E., Palmer, M., Park, J., Perivoliotis, L., Poulain, P., Perry, R., Queste, B., Rainville, L., Rehm, E., Roughan, M., Rome, N., Ross, T., Ruiz, S., Saba, G., Schaeffer, A., Schonau, M., Schroeder, K., Shimizu, Y., Sloyan, B. M., Smeed, D., Snowden, D., Song, Y., Swart, S., Tenreiro, M., Thompson, A., Tintore, J., Todd, R. E., Toro, C., Venables, H., Wagawa, T., Waterman, S., Watlington, R. A., & Wilson, D. OceanGliders: A component of the integrated GOOS. Frontiers in Marine Science, 6, (2019): 422, doi:10.3389/fmars.2019.00422., The OceanGliders program started in 2016 to support active coordination and enhancement of global glider activity. OceanGliders contributes to the international efforts of the Global Ocean Observation System (GOOS) for Climate, Ocean Health, and Operational Services. It brings together marine scientists and engineers operating gliders around the world: (1) to observe the long-term physical, biogeochemical, and biological ocean processes and phenomena that are relevant for societal applications; and, (2) to contribute to the GOOS through real-time and delayed mode data dissemination. The OceanGliders program is distributed across national and regional observing systems and significantly contributes to integrated, multi-scale and multi-platform sampling strategies. OceanGliders shares best practices, requirements, and scientific knowledge needed for glider operations, data collection and analysis. It also monitors global glider activity and supports the dissemination of glider data through regional and global databases, in real-time and delayed modes, facilitating data access to the wider community. OceanGliders currently supports national, regional and global initiatives to maintain and expand the capabilities and application of gliders to meet key global challenges such as improved measurement of ocean boundary currents, water transformation and storm forecast., The editorial team would like to recognize the support of the global glider community to this paper. Our requests for data and information were met with enthusiasm and welcome contributions from around the globe, clearly demonstrating to us a point made in this paper that there are many active and dedicated teams of glider operators and users. We should also acknowledge the support that OceanGliders has received from the WMO/IOC JCOMM-OCG and JCOMMOPS that have allowed this program to develop, encouraging us to articulate a vision for the role of gliders in the GOOS. We acknowledge support from the EU Horizon 2020 AtlantOS project funded under grant agreement No. 633211 and gratefully acknowledge the many agencies and programs that have supported underwater gliders: AlterEco, ANR, CFI, CIGOM, CLASS Ellet Array, CNES, CNRS/INSU, CONACyT, CSIRO, DEFRA, DFG/SFB-754, DFO, DGA, DSTL, ERC, FCO, FP7, and H2020 Europen Commission, HIMIOFoTS, Ifremer, IMOS, IMS, IOOS, IPEV, IRD, Israel MOST, JSPS, MEOPAR, NASA, NAVOCEANO (Navy), NERC, NFR, NJDEP, NOAA, NRC, NRL, NSF, NSERC, ONR, OSNAP, Taiwan MOST, SANAP-NRF, SENER, SIMS, Shell Exploration and Production Company, Sorbonne Université, SSB, UKRI, UNSW, Vettleson, Wallenberg Academy Fellowship, and WWF.

Published
2019

9. Air-sea fluxes with a focus on heat and momentum

Author

Cronin, Meghan F., Gentemann, Chelle L., Edson, James, Ueki, Iwao, Bourassa, Mark, Brown, Shannon, Clayson, Carol Anne, Fairall, Chris W., Farrar, J. Thomas, Gille, Sarah T., Gulev, Sergey, Josey, Simon A., Kato, Seiji, Katsumata, Masaki, Kent, Elizabeth, Krug, Marjolaine, Minnett, Peter J., Parfitt, Rhys, Pinker, Rachel T., Stackhouse, Paul W., Swart, Sebastiaan, Tomita, Hiroyuki, Vandemark, Douglas, Weller, A. Robert, Yoneyama, Kunio, Yu, Lisan, Zhang, Dongxiao, Cronin, Meghan F., Gentemann, Chelle L., Edson, James, Ueki, Iwao, Bourassa, Mark, Brown, Shannon, Clayson, Carol Anne, Fairall, Chris W., Farrar, J. Thomas, Gille, Sarah T., Gulev, Sergey, Josey, Simon A., Kato, Seiji, Katsumata, Masaki, Kent, Elizabeth, Krug, Marjolaine, Minnett, Peter J., Parfitt, Rhys, Pinker, Rachel T., Stackhouse, Paul W., Swart, Sebastiaan, Tomita, Hiroyuki, Vandemark, Douglas, Weller, A. Robert, Yoneyama, Kunio, Yu, Lisan, and Zhang, Dongxiao

Abstract

Turbulent and radiative exchanges of heat between the ocean and atmosphere (hereafter heat fluxes), ocean surface wind stress, and state variables used to estimate them, are Essential Ocean Variables (EOVs) and Essential Climate Variables (ECVs) influencing weather and climate. This paper describes an observational strategy for producing 3-hourly, 25-km (and an aspirational goal of hourly at 10-km) heat flux and wind stress fields over the global, ice-free ocean with breakthrough 1-day random uncertainty of 15 W m–2 and a bias of less than 5 W m–2. At present this accuracy target is met only for OceanSITES reference station moorings and research vessels (RVs) that follow best practices. To meet these targets globally, in the next decade, satellite-based observations must be optimized for boundary layer measurements of air temperature, humidity, sea surface temperature, and ocean wind stress. In order to tune and validate these satellite measurements, a complementary global in situ flux array, built around an expanded OceanSITES network of time series reference station moorings, is also needed. The array would include 500–1000 measurement platforms, including autonomous surface vehicles, moored and drifting buoys, RVs, the existing OceanSITES network of 22 flux sites, and new OceanSITES expanded in 19 key regions. This array would be globally distributed, with 1–3 measurement platforms in each nominal 10° by 10° box. These improved moisture and temperature profiles and surface data, if assimilated into Numerical Weather Prediction (NWP) models, would lead to better representation of cloud formation processes, improving state variables and surface radiative and turbulent fluxes from these models. The in situ flux array provides globally distributed measurements and metrics for satellite algorithm development, product validation, and for improving satellite-based, NWP and blended flux products. In addition, some of these flux platforms will also measure direct turbulen

Published
2019

10. Global perspectives on observing ocean boundary current systems

Author

Todd, Robert E., Chavez, Francisco P., Clayton, Sophie A., Cravatte, Sophie, Goes, Marlos Pereira, Graco, Michelle, Lin, Xiaopei, Sprintall, Janet, Zilberman, Nathalie, Archer, Matthew, Arístegui, Javier, Balmaseda, Magdalena A., Bane, John M., Baringer, Molly O., Barth, John A., Beal, Lisa M., Brandt, Peter, Calil, Paulo H. R., Campos, Edmo, Centurioni, Luca R., Chidichimo, Maria Paz, Cirano, Mauro, Cronin, Meghan F., Curchitser, Enrique N., Davis, Russ E., Dengler, Marcus, deYoung, Brad, Dong, Shenfu, Escribano, Ruben, Fassbender, Andrea, Fawcett, Sarah E., Feng, Ming, Goni, Gustavo J., Gray, Alison R., Gutiérrez, Dimitri, Hebert, Dave, Hummels, Rebecca, Ito, Shin-ichi, Krug, Marjolaine, Lacan, Francois, Laurindo, Lucas, Lazar, Alban, Lee, Craig M., Lengaigne, Matthieu, Levine, Naomi M., Middleton, John, Montes, Ivonne, Muglia, Michael, Nagai, Takeyoshi, Palevsky, Hilary I., Palter, Jaime B., Phillips, Helen E., Piola, Alberto R., Plueddemann, Albert J., Qiu, Bo, Rodrigues, Regina, Roughan, Moninya, Rudnick, Daniel L., Rykaczewski, Ryan R., Saraceno, Martin, Seim, Harvey E., Sen Gupta, Alexander, Shannon, Lynne, Sloyan, Bernadette M., Sutton, Adrienne J., Thompson, LuAnne, van der Plas, Anja K., Volkov, Denis L., Wilkin, John L., Zhang, Dongxiao, Zhang, Linlin, Todd, Robert E., Chavez, Francisco P., Clayton, Sophie A., Cravatte, Sophie, Goes, Marlos Pereira, Graco, Michelle, Lin, Xiaopei, Sprintall, Janet, Zilberman, Nathalie, Archer, Matthew, Arístegui, Javier, Balmaseda, Magdalena A., Bane, John M., Baringer, Molly O., Barth, John A., Beal, Lisa M., Brandt, Peter, Calil, Paulo H. R., Campos, Edmo, Centurioni, Luca R., Chidichimo, Maria Paz, Cirano, Mauro, Cronin, Meghan F., Curchitser, Enrique N., Davis, Russ E., Dengler, Marcus, deYoung, Brad, Dong, Shenfu, Escribano, Ruben, Fassbender, Andrea, Fawcett, Sarah E., Feng, Ming, Goni, Gustavo J., Gray, Alison R., Gutiérrez, Dimitri, Hebert, Dave, Hummels, Rebecca, Ito, Shin-ichi, Krug, Marjolaine, Lacan, Francois, Laurindo, Lucas, Lazar, Alban, Lee, Craig M., Lengaigne, Matthieu, Levine, Naomi M., Middleton, John, Montes, Ivonne, Muglia, Michael, Nagai, Takeyoshi, Palevsky, Hilary I., Palter, Jaime B., Phillips, Helen E., Piola, Alberto R., Plueddemann, Albert J., Qiu, Bo, Rodrigues, Regina, Roughan, Moninya, Rudnick, Daniel L., Rykaczewski, Ryan R., Saraceno, Martin, Seim, Harvey E., Sen Gupta, Alexander, Shannon, Lynne, Sloyan, Bernadette M., Sutton, Adrienne J., Thompson, LuAnne, van der Plas, Anja K., Volkov, Denis L., Wilkin, John L., Zhang, Dongxiao, and Zhang, Linlin

Abstract

© The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Todd, R. E., Chavez, F. P., Clayton, S., Cravatte, S., Goes, M., Greco, M., Ling, X., Sprintall, J., Zilberman, N., V., Archer, M., Aristegui, J., Balmaseda, M., Bane, J. M., Baringer, M. O., Barth, J. A., Beal, L. M., Brandt, P., Calil, P. H. R., Campos, E., Centurioni, L. R., Chidichimo, M. P., Cirano, M., Cronin, M. F., Curchitser, E. N., Davis, R. E., Dengler, M., deYoung, B., Dong, S., Escribano, R., Fassbender, A. J., Fawcett, S. E., Feng, M., Goni, G. J., Gray, A. R., Gutierrez, D., Hebert, D., Hummels, R., Ito, S., Krug, M., Lacan, F., Laurindo, L., Lazar, A., Lee, C. M., Lengaigne, M., Levine, N. M., Middleton, J., Montes, I., Muglia, M., Nagai, T., Palevsky, H., I., Palter, J. B., Phillips, H. E., Piola, A., Plueddemann, A. J., Qiu, B., Rodrigues, R. R., Roughan, M., Rudnick, D. L., Rykaczewski, R. R., Saraceno, M., Seim, H., Sen Gupta, A., Shannon, L., Sloyan, B. M., Sutton, A. J., Thompson, L., van der Plas, A. K., Volkov, D., Wilkin, J., Zhang, D., & Zhang, L. Global perspectives on observing ocean boundary current systems. Frontiers in Marine Science, 6, (2010); 423, doi: 10.3389/fmars.2019.00423., Ocean boundary current systems are key components of the climate system, are home to highly productive ecosystems, and have numerous societal impacts. Establishment of a global network of boundary current observing systems is a critical part of ongoing development of the Global Ocean Observing System. The characteristics of boundary current systems are reviewed, focusing on scientific and societal motivations for sustained observing. Techniques currently used to observe boundary current systems are reviewed, followed by a census of the current state of boundary current observing systems globally. The next steps in the development of boundary current observing systems are considered, leading to several specific recommendations., RT was supported by The Andrew W. Mellon Foundation Endowed Fund for Innovative Research at WHOI. FC was supported by the David and Lucile Packard Foundation. MGo was funded by NSF and NOAA/AOML. XL was funded by China’s National Key Research and Development Projects (2016YFA0601803), the National Natural Science Foundation of China (41490641, 41521091, and U1606402), and the Qingdao National Laboratory for Marine Science and Technology (2017ASKJ01). JS was supported by NOAA’s Global Ocean Monitoring and Observing Program (Award NA15OAR4320071). DZ was partially funded by the Joint Institute for the Study of the Atmosphere and Ocean (JISAO) under NOAA Cooperative Agreement NA15OAR4320063. BS was supported by IMOS and CSIRO’s Decadal Climate Forecasting Project. We gratefully acknowledge the wide range of funding sources from many nations that have enabled the observations and analyses reviewed here.

Published
2019

11. OceanGliders: A Component of the Integrated GOOS

Author

Testor, Pierre, primary, de Young, Brad, additional, Rudnick, Daniel L., additional, Glenn, Scott, additional, Hayes, Daniel, additional, Lee, Craig M., additional, Pattiaratchi, Charitha, additional, Hill, Katherine, additional, Heslop, Emma, additional, Turpin, Victor, additional, Alenius, Pekka, additional, Barrera, Carlos, additional, Barth, John A., additional, Beaird, Nicholas, additional, Bécu, Guislain, additional, Bosse, Anthony, additional, Bourrin, François, additional, Brearley, J. Alexander, additional, Chao, Yi, additional, Chen, Sue, additional, Chiggiato, Jacopo, additional, Coppola, Laurent, additional, Crout, Richard, additional, Cummings, James, additional, Curry, Beth, additional, Curry, Ruth, additional, Davis, Richard, additional, Desai, Kruti, additional, DiMarco, Steve, additional, Edwards, Catherine, additional, Fielding, Sophie, additional, Fer, Ilker, additional, Frajka-Williams, Eleanor, additional, Gildor, Hezi, additional, Goni, Gustavo, additional, Gutierrez, Dimitri, additional, Haugan, Peter, additional, Hebert, David, additional, Heiderich, Joleen, additional, Henson, Stephanie, additional, Heywood, Karen, additional, Hogan, Patrick, additional, Houpert, Loïc, additional, Huh, Sik, additional, E. Inall, Mark, additional, Ishii, Masso, additional, Ito, Shin-ichi, additional, Itoh, Sachihiko, additional, Jan, Sen, additional, Kaiser, Jan, additional, Karstensen, Johannes, additional, Kirkpatrick, Barbara, additional, Klymak, Jody, additional, Kohut, Josh, additional, Krahmann, Gerd, additional, Krug, Marjolaine, additional, McClatchie, Sam, additional, Marin, Frédéric, additional, Mauri, Elena, additional, Mehra, Avichal, additional, P. Meredith, Michael, additional, Meunier, Thomas, additional, Miles, Travis, additional, Morell, Julio M., additional, Mortier, Laurent, additional, Nicholson, Sarah, additional, O'Callaghan, Joanne, additional, O'Conchubhair, Diarmuid, additional, Oke, Peter, additional, Pallàs-Sanz, Enric, additional, Palmer, Matthew, additional, Park, JongJin, additional, Perivoliotis, Leonidas, additional, Poulain, Pierre-Marie, additional, Perry, Ruth, additional, Queste, Bastien, additional, Rainville, Luc, additional, Rehm, Eric, additional, Roughan, Moninya, additional, Rome, Nicholas, additional, Ross, Tetjana, additional, Ruiz, Simon, additional, Saba, Grace, additional, Schaeffer, Amandine, additional, Schönau, Martha, additional, Schroeder, Katrin, additional, Shimizu, Yugo, additional, Sloyan, Bernadette M., additional, Smeed, David, additional, Snowden, Derrick, additional, Song, Yumi, additional, Swart, Sebastian, additional, Tenreiro, Miguel, additional, Thompson, Andrew, additional, Tintore, Joaquin, additional, Todd, Robert E., additional, Toro, Cesar, additional, Venables, Hugh, additional, Wagawa, Taku, additional, Waterman, Stephanie, additional, Watlington, Roy A., additional, and Wilson, Doug, additional

Published
2019
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12. Evolving the Physical Global Ocean Observing System for Research and Application Services Through International Coordination

Author

Sloyan, Bernadette M., primary, Wilkin, John, additional, Hill, Katherine Louise, additional, Chidichimo, Maria Paz, additional, Cronin, Meghan F., additional, Johannessen, Johnny A., additional, Karstensen, Johannes, additional, Krug, Marjolaine, additional, Lee, Tong, additional, Oka, Eitarou, additional, Palmer, Matthew D., additional, Rabe, Benjamin, additional, Speich, Sabrina, additional, von Schuckmann, Karina, additional, Weller, Robert A., additional, and Yu, Weidong, additional

Published
2019
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13. Air-Sea Fluxes With a Focus on Heat and Momentum

Author

Cronin, Meghan F., primary, Gentemann, Chelle L., additional, Edson, James, additional, Ueki, Iwao, additional, Bourassa, Mark, additional, Brown, Shannon, additional, Clayson, Carol Anne, additional, Fairall, Chris W., additional, Farrar, J. Thomas, additional, Gille, Sarah T., additional, Gulev, Sergey, additional, Josey, Simon A., additional, Kato, Seiji, additional, Katsumata, Masaki, additional, Kent, Elizabeth, additional, Krug, Marjolaine, additional, Minnett, Peter J., additional, Parfitt, Rhys, additional, Pinker, Rachel T., additional, Stackhouse, Paul W., additional, Swart, Sebastiaan, additional, Tomita, Hiroyuki, additional, Vandemark, Douglas, additional, Weller, A. Robert, additional, Yoneyama, Kunio, additional, Yu, Lisan, additional, and Zhang, Dongxiao, additional

Published
2019
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14. A synthesis of three decades of socio-ecological change in False Bay, South Africa: setting the scene for multidisciplinary research and management

Author

Pfaff, Maya C., primary, Logston, Renae C., additional, Raemaekers, Serge J. P. N., additional, Hermes, Juliet C., additional, Blamey, Laura K., additional, Cawthra, Hayley C., additional, Colenbrander, Darryl R., additional, Crawford, Robert J. M., additional, Day, Elizabeth, additional, du Plessis, Nicole, additional, Elwen, Simon H., additional, Fawcett, Sarah E., additional, Jury, Mark R., additional, Karenyi, Natasha, additional, Kerwath, Sven E., additional, Kock, Alison A., additional, Krug, Marjolaine, additional, Lamberth, Stephen J., additional, Omardien, Aaniyah, additional, Pitcher, Grant C., additional, Rautenbach, Christo, additional, Robinson, Tamara B., additional, Rouault, Mathieu, additional, Ryan, Peter G., additional, Shillington, Frank A., additional, Sowman, Merle, additional, Sparks, Conrad C., additional, Turpie, Jane K., additional, van Niekerk, Lara, additional, Waldron, Howard N., additional, Yeld, Eleanor M., additional, and Kirkman, Stephen P., additional

Published
2019
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15. Observations of the vertical and temporal evolution of a Natal Pulse along the Eastern Agulhas Bank

Author

Pivan, Xavier, Krug, Marjolaine, Herbette, Steven, Pivan, Xavier, Krug, Marjolaine, and Herbette, Steven

Abstract

This study re-investigates the work of Lutjeharms et al. [2001,2003] who documented the properties of a Natal Pulse using isopycnal Lagrangian floats. We combined Lagrangian analyses and Eulerian maps derived from objective analysis to better describe the evolution of a Natal Pulse along three density surfaces referred to as the surface (satellite-observed), shallow (isopycnal-1026.8 kg.m−3) and deep (isopycnal-1027.2 kg.m−3) layer. Our observations show that this Natal Pulse extended to a depth of 1000m and was associated with cyclonic relative vorticity values of about 6.5 to 8.5x10−5.s−1 in the surface and shallow layer and 4x10−5.s−1 in the deep layer. This Natal Pulse contributed to cross-shelf exchange through the offshore advection of Eastern Agulhas Bank water near the surface, onshore advection of South Indian Central Water and/or Indian Equatorial Water in the shallow layer and Antarctic Intermediate Water in the deep layer. Sea Surface Temperature maps showed that the downstream progression of the Natal Pulse along the 3000m isobath was related to a readjustment of its rotation axis. This readjustment advected Eastern Agulhas Bank water into the Natal Pulse eddy and triggered a SST cooling of about 3°C in the cyclonic area. The importance of a warm recirculating Agulhas plume originating from the Natal Pulse was highlighted. This warm water plume extended to a depth of 700m and was associated with onshore velocities exceeding those experienced within the Natal Pulse eddy by a factor of two. Our observations indicate that the June/July 1998 Natal Pulse and its associated plumes enhanced cross-shelf exchanges. This article is protected by copyright. All rights reserved.

Published
2016
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17. Surface circulation in the KwaZulu-Natal Bight and its impact on the connectivity of marine protected areas

Author

Heye, Sonia, Krug, Marjolaine, Hart-Davis, Michael, Penven, Pierrick, and Rouault, Mathieu

Subjects
Oceanography
Abstract

The KwaZulu-Natal Bight is a small, coastal region along South Africa's north-east coast. It stretches from Richards Bay to Durban and has a wide shelf compared to the surrounding coastline. As a result, the Agulhas Current is forced offshore, allowing the formation of complex circulation features on the KwaZulu-Natal Bight's shelf that assist with recruitment and retention of marine organisms in this region. This study aims to gain a deeper understanding of the surface circulation within the KwaZulu-Natal Bight and its impact on the connectivity between several surrounding Marine Protected Areas. These include iSimangaliso, uThukela Banks, Aliwal Shoal and Protea Banks and the information about their connectivity contributes to the CAPTOR (Connectivity And disPersal beTween prOtected aReas) project. The aim of this study is met by using high-resolution CROCO model output over a 10-year period, in combination with particle tracking tools, wind and surface drifter data. According to the model's mean circulation, the KwaZulu-Natal Bight's surface currents have a strong south-westward flow on the continental shelf slope where the effects of the Agulhas Current are strongly felt, butare weak and variable on the shelf. Observed variabilities of the mean flow have no distinct seasonal pattern and include a north- eastward current that repeatedly dominates the shelf. It is referred to as the Natal Bight Coastal Counter Current, which originates within the semi-permanent Durban Eddy in the southern KwaZulu- Natal Bight, where it extends throughout the water column. The Natal Bight Coastal Counter Current stretches along the mid-shelf into the northern KwaZulu-Natal Bight, gradually becoming shallower, weaker and narrower. When anticyclonic eddies offshore of the Agulhas Current pass this region, they occasionally replace the Durban Eddy and its associated Natal Bight Coastal Counter Current with a southward flow on the KwaZulu-Natal Bight's shelf. Therefore, the circulation in the KwaZulu-Natal Bight appears to be primarily driven by perturbations at the Agulhas Current front. However, there is also some indication of a direct wind-driven influence in coastal waters inshore of the 50 m isobath. To investigate the impact of the KwaZulu-Natal Bight's circulation on the connectivity between the above-mentioned Marine Protected Areas, particle tracking tools are used. Virtual particles are released in each Marine Protected Area within the model, during multiple northward and southward KwaZulu-Natal Bight surface circulation events. Their pathways are tracked for 30 days and reveal an overall strong southward Marine Protected Area connectivity, which is driven by the Agulhas Current, while a northward connection is less commonly observed. The northward flow of the Natal Bight Coastal Counter Current increases the water retention within uThukela Banks, but it does not extend into iSimangaliso to establish a northward Marine Protected Area connection. However, when the Natal Bight Coastal Counter Current originates within Aliwal Shoal, it may result in a northward Marine Protected Area connection between Aliwal Shoal and uThukela Banks. In this study, the virtual particles represent passively drifting larvae that are buoyant. To make these simulations more realistic, the virtual particles should be able to sink and appropriate swimming behaviours could be considered. However, swimming abilities will likely be overpowered by the surrounding circulation and observations on these behaviours are difficult to make. Therefore, the passive dispersion used in this study to mimic their trajectories may be sufficient and provides valuable insight into the impact of the KwaZulu-Natal Bight's surface circulation on Marine Protected Area connectivity and larval dispersion. The virtual particle tracking tools used in this study are not limited to biological applications. Future studies could use them to investigate the path and accumulation regions of virtual pollutants, such as microplastics, to determine the regions in which clean-ups would be most effective.

Published
2022

18. Resolving cross-shelf dynamics in the Agulhas Current from GlobCurrent and glider observations

Author

Maja, Tumelo, Krug, Marjolaine, Rouault, Mathieu, and Johannessen, Johnny A

Subjects
Oceanography
Abstract

The Agulhas Current is the strongest Western Boundary Current of the Southern Hemisphere and it plays a significant role in the circulation of the shelf and coastal waters, whereby mesoscale (50- 500 km) and submesoscale (1 -10 km) instabilities in the Agulhas Current impact the local oceanography of the shelf region. The main objective of this study is to evaluate the ability of a gap-free and merged gridded satellite ocean current dataset, GlobCurrent, to resolve and monitor the variability of the Agulhas Current’s cross-shelf dynamics. In this study, GlobCurrent is compared to in-situ observations collected from underwater gliders through mapping and correlation analysis to assess the product’s accuracy in different subdomains and water depths of the Agulhas Current’s main area domain. We also investigate the value of using a higher resolution satellite and gap-free Sea Surface Temperature (SST) dataset to complement the GlobCurrent dataset in observing the Agulhas Current’s flow processes and features. The results show that GlobCurrent is adequate for describing large mesoscale features and deep water flows but the product has limitations in capturing fast-evolving and small mesoscale features, particularly the Durban Eddy in the KZN bight region. GlobCurrent also exhibits, at times, directional errors in addition to the current speed discrepancies. This research study demonstrates the limitation of the GlobCurrent product for monitoring ocean current variability in shallow, coastal waters and regions dominated by small mesoscale variability. This study also provides new insights on the joint use of other merged satellite products i.e. merged ODYSSEA SST, which may compensate for some of the GlobCurrent product’s shortfalls. Future studies should consider complementing altimetry-based satellite products like GlobCurrent with other merged satellite observation products such as ODYSSEA SST for better imaging of small mesoscale processes and features in shallow coastal waters.

Published
2019

19. Impact of Wind Driven Variability on Sea Surface Temperature and Ocean Colour in False Bay

Author

Seymour, Sian, Krug, Marjolaine, Smith, Marie, Mouche, Alexis, and Rouault, Mathieu

Subjects
Applied Ocean Sciences
Abstract

False Bay is the largest true bay in South Africa and is an important area for conservation, the local fishing industry and marine based recreational activities. A large amount of studies, both recent and historical, have been carried out on the biology of the bay, but studies on the physics of the bay are very few in comparison. In this study high resolution satellite imagery is used to investigate wind variability and its impact on sea surface temperature (SST) and chlorophyll concentration (Chl-a) variability within False Bay and the Cape Peninsula region. High resolution (1 km) coastal winds derived from the Sentinel-1 satellite Synthetic Aperture Radar (SAR) show that winds are strongly influenced by topography under the predominantly south-easterly wind regime. The Hottentots Holland mountain range and Cape Peninsula mountain range create wind shadows as well as areas of increased wind speed within False Bay and west of the Cape Peninsula. Our observations also show that global atmospheric models, such as ECMWF, are not able to capture the spatial variability in the wind fields driven by the orography. Analyses of the SST and ocean colour imagery show that wind shadows are generally associated with warmer surface waters and higher Chl-a. In contrast, regions of enhanced wind speeds show colder surface waters and decreased chlorophyll concentration. Our results suggest that spatial variation in the horizontal wind fields have direct and significant impact on the water properties within False Bay. This study highlights the need for high resolution wind observations and simulations to force regional oceanic models of False Bay and the Cape Peninsula region.

Published
2019

20. A study of Mesoscale Eddies, the Agulhas current and the evolution of its meanders using satellite observations and numerical modelling experiments

Author

Braby, Laura, Backeberg Björn, Krug, Marjolaine, and Reason, Christopher

Subjects
Oceanography
Abstract

The Agulhas Current is the strongest western boundary current in the Southern Hemisphere and plays an important role in the exchange of heat and salt between the Indian and South Atlantic Ocean basins, thereby affecting global climate. The variability in the northern Agulhas Current is influenced by both cyclonic and anticyclonic mesoscale eddies, originating from the Mozambique Channel and south of Madagascar (known as source region eddies) and which propagate toward the offshore edge of the Agulhas Current. Using a combination of an eddy-tracking data set with in-situ surface drifter observations and altimetry-derived geostrophic currents, it is shown that source region eddies dissipate upon approaching the Agulhas Current. Their entrainment into the Agulhas Current affects its mean velocity and offshore position through a transfer of momentum, with anti-cyclonic eddies consistently increasing the Agulhas Current’s velocity by 0.16 ± 0.17 m.s -1 . In contrast, entrainment of cyclonic eddies results in a decrease in velocity by 0.13 ± 0.16 m.s-1 and shifting the current up to 144 ± 85 km offshore. These velocity anomalies propagate downstream at rates of 44 km.d-1 (anti-cyclonic eddies) and 23 km.d-1 (cyclonic eddies). Whilst existing numerical models are successfully able to capture many aspects of the Agulhas Current, many models are unable to accurately represent the observed eddy dissipation and interaction processes, affecting our understanding of mesoscale variability within in the current. In this study, we compare two simulation experiments in a regional Hybrid Coordinate Ocean Model (HYCOM), where we change the wind forcing, and using an eddy tracking algorithm assess the local effect of the changed wind stress on source region eddies and their interaction with the northern Agulhas Current. There is an overall reduction in eddy kinetic energy (EKE) of 33% over the Agulhas Current domain. Changes in eddy pathways, properties and energy conversion terms, resulting from the change in forcing from absolute to relative winds (the wind speed relative to the current speed) have resulted in significantly different mesoscale eddies in the regional HYCOM. The effects of the change in wind forcing on the variability within the Agulhas Current were examined and the differences between the two simulations were found to be very small. Finally, the evolution of meanders in the Agulhas Current, including the properties and dissipation of smaller meanders as well as mesoscale Natal Pulses type meanders, were assessed using both HYCOM experiments and compared to satellite observations. The representation of smaller meanders (under 50km in size) improved with the changed in wind forcing. However, larger Agulhas Current meanders (greater than or equal to 50km) which previously occurred too frequently in the regional HYCOM, are now too infrequent in the regional HYCOM, with an average of 1.1 meanders occurring each year. A decrease in the frequency of larger meanders was observed from the location offshore of Port Edward (30.22° E, 31.05° S) to the region of the ACT array (27.48° E, 33.35° S), in the satellite data as well as both model experiments, indicating that some of the meanders have dissipated and that both regional HYCOM models are able to resolve this.

Published
2019

21. Variability of coastal upwelling south of Madagascar

Author

Ramanantsoa, Heriniaina Juliano Dani, Krug, Marjolaine, Rouault, Mathieu, and Penven, Pierrick

Subjects
Oceanography
Abstract

Madagascar’s southern coastal marine zone is a region of high biological productivity which supports a wide range of marine ecosystems, including fisheries. This high biological productivity is attributed to coastal upwelling. The thesis seeks to characterise the variability of the coastal upwelling south of Madagascar. The first part of the thesis provides new insights on the structure, variability and drivers of the coastal upwelling south of Madagascar. Satellite remote sensing is used to characterize the spatial extent and strength of the coastal upwelling. A front detection algorithm is applied to thirteen years of Multi-scale Ultra-high Resolution (MUR) Sea Surface Temperatures (SST) and an upwelling index is calculated. The influence of winds and ocean currents as drivers of the upwelling are investigated using satellite, in-situ observations, and a numerical model. Results reveal the presence of two well-defined upwelling cells. The first cell (Core 1) is located in the southeastern corner of Madagascar, and the second cell (Core 2) is west of the southern tip of Madagascar. These two cores are characterized by different seasonal variability, different intensities, different upwelled water mass origins, and distinct forcing mechanisms. Core 1 is associated with a dynamical upwelling forced by the detachment of the East Madagascar Current (EMC), which is reinforced by upwelling favourable winds. Core 2 which appears to be primarily forced by upwelling favourable winds, is also influenced by a poleward eastern boundary flow coming from the Mozambique Channel. This intrusion of Mozambique Channel warm waters could result in an asynchronicity in seasonality between upwelling surface signature and upwelling favourables winds. The second part of the thesis focuses on the interaction between the intrusion of warm water from Mozambique channel and the upwelling cell in Core 2. Cruise datasets, satellite remote sensing observations and model data analyses are combined to highlight the existence of a coastal surface poleward flow in the south-west of Madagascar: the South-west MAdagascar iv Coastal Current (SMACC). The SMACC is a relatively shallow (Coastal Current (SMACC). The SMACC is a relatively shallow (

Published
2018

22. Annual cycle of the Benguela Jet

Author

Kamwi, Blessing K, Veitch, Jennifer Anne, Hermes, Juliet C, and Krug, Marjolaine

Subjects
InformationSystems_INFORMATIONSTORAGEANDRETRIEVAL, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries)
Abstract

Includes bibliographical references, The Benguela Jet is a north-westward flowing current in the southern Benguela region. It is known to have an important influence on the fish recruitment yet little is known about the physical properties of the jet. In this study the ability of satellite data (SST and altimetry) to resolve the Jet was investigated. Following this, the annual cycle of the Benguela Jet was investigated using monthly climatological means computed from both remotely sensed and model output data (from the Regional Ocean Modelling System). Two altimeter tracks were identified as best suited to study the Benguela Jet: the Topex-A / Jason-1A Track number 209 which crosses the Benguela Jet current in its northern region off the Cape Columbine and the Topex-B / Jason-1B track number 31, which crosses the Benguela Jet current in the southern region. The month of January and July were chosen due to the fact that they represent the peaks of summer and winter. The surface geostrophic currents derived from both the model and satellite data reproduced the existence of the jet current off Cape Columbine and the Cape Peninsula. The jet was narrow and strong in January off Cape Columbine and off the Cape Peninsula and was situated farther offshore based on the model, relative to the altimeter data. Outputs from the numerical model showed that in July the jet was confined to the coast and was stronger off the Cape Peninsula (0.5 m.s-1) compared to Cape Columbine (0.4 m.s-1). A comparison between the regions of strong velocity gradient and the position of the upwelling front were in agreement in depicting the position of the jet. Altimetry, which suffers from imitation in coastal regions, could not reveal the jet in July due to its proximity to the shore at this season. The offshore boundary of the jet is resolved by altimetry in January. The interannual variability of the Benguela Jet has been identified.

Published
2014

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