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2. Ocean Heat Convergence and North Atlantic Multidecadal Heat Content Variability

Author

Moat, B. I., Sinha, B., Berry, D. I., Drijfhout, S. S., Fraser, N., Hermanson, L., Jones, D. C., Josey, S. A., King, B., Macintosh, C., Megann, A., Oltmanns, M., Sanders, R., Williams, S., Moat, B. I., Sinha, B., Berry, D. I., Drijfhout, S. S., Fraser, N., Hermanson, L., Jones, D. C., Josey, S. A., King, B., Macintosh, C., Megann, A., Oltmanns, M., Sanders, R., and Williams, S.

Abstract

We construct an upper ocean (0–1000 m) North Atlantic heat budget (26°–67°N) for the period 1950–2020 using multiple observational datasets and an eddy-permitting global ocean model. On multidecadal time scales, ocean heat transport convergence controls ocean heat content (OHC) tendency in most regions of the North Atlantic with little role for diffusive processes. In the subpolar North Atlantic (45°–67°N), heat transport convergence is explained by geostrophic currents, whereas ageostrophic currents make a significant contribution in the subtropics (26°–45°N). The geostrophic contribution in all regions is dominated by anomalous advection across the time-mean temperature gradient although other processes make a significant contribution, particularly in the subtropics. The time scale and spatial distribution of the anomalous geostrophic currents are consistent with a simple model of basin-scale thermal Rossby waves propagating westward/northwestward in the subpolar gyre, and multidecadal variations in regional OHC are explained by geostrophic currents periodically coming into alignment with the mean temperature gradient as the Rossby wave passes through. The global ocean model simulation shows that multidecadal variations in the Atlantic meridional overturning circulation are synchronized with the ocean heat transport convergence consistent with modulation of the west–east pressure gradient by the propagating Rossby wave.

Published
2024

5. Developing an Observing Air–Sea Interactions Strategy (OASIS) for the global ocean

Author

Cronin, M F, Swart, S, Marandino, Christa A., Anderson, C, Browne, P, Chen, S, Joubert, W R, Schuster, U, Venkatesan, R, Addey, C I, Alves, O, Ardhuin, F, Battle, S, Bourassa, M A, Chen, Z, Chory, M, Clayson, C, de Souza, R B, du Plessis, M, Edmondson, M, Edson, J B, Gille, S T, Hermes, J, Hormann, V, Josey, S A, Kurz, M, Lee, T, Maicu, F, Moustahfid, E H, Nicholson, S-A, Nyadjro, E S, Palter, J, Patterson, R G, Penny, S G, Pezzi, L P, Pinardi, N, Reeves Eyre, J E J, Rome, N, Subramanian, A C, Stienbarger, C, Steinhoff, Tobias, Sutton, A J, Tomita, H, Wills, S M, Wilson, C, Yu, L, Browman, Howard, Cronin, MF, Swart, S, Marandino, CA, Anderson, C, Browne, P, Chen, S, Joubert, WR, Schuster, U, Venkatesan, R, Addey, CI, Alves, O, Ardhuin, F, Battle, S, Bourassa, MA, Chen, Z, Chory, M, Clayson, C, de Souza, RB, du Plessis, M, Edmondson, M, Edson, JB, Gille, ST, Hermes, J, Hormann, V, Josey, SA, Kurz, M, Lee, T, Maicu, F, Moustahfid, EH, Nicholson, SA, Nyadjro, ES, Palter, J, Patterson, RG, Penny, SG, Pezzi, LP, Pinardi, N, Eyre, JEJR, Rome, N, Subramanian, AC, Stienbarger, C, Steinhoff, T, Sutton, AJ, Tomita, H, Wills, SM, Wilson, C, and Yu, L

Subjects
observation, Ecology, carbon dioxide uptake, air-sea flux, satellite, Aquatic Science, global, Observing Air-Sea Interactions Strategy (OASIS), Oceanography, multi-stressor, UN Decade of Ocean Sciences for Sustainable Development, weather, climate, Ecology, Evolution, Behavior and Systematics
Abstract

The Observing Air–Sea Interactions Strategy (OASIS) is a new United Nations Decade of Ocean Science for Sustainable Development programme working to develop a practical, integrated approach for observing air–sea interactions globally for improved Earth system (including ecosystem) forecasts, CO2 uptake assessments called for by the Paris Agreement, and invaluable surface ocean information for decision makers. Our “Theory of Change” relies upon leveraged multi-disciplinary activities, partnerships, and capacity strengthening. Recommendations from >40 OceanObs’19 community papers and a series of workshops have been consolidated into three interlinked Grand Ideas for creating #1: a globally distributed network of mobile air–sea observing platforms built around an expanded array of long-term time-series stations; #2: a satellite network, with high spatial and temporal resolution, optimized for measuring air–sea fluxes; and #3: improved representation of air–sea coupling in a hierarchy of Earth system models. OASIS activities are organized across five Theme Teams: (1) Observing Network Design & Model Improvement; (2) Partnership & Capacity Strengthening; (3) UN Decade OASIS Actions; (4) Best Practices & Interoperability Experiments; and (5) Findable–Accessible–Interoperable–Reusable (FAIR) models, data, and OASIS products. Stakeholders, including researchers, are actively recruited to participate in Theme Teams to help promote a predicted, safe, clean, healthy, resilient, and productive ocean.

Published
2022
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6. Developing an Observing Air–Sea Interactions Strategy (OASIS) for the global ocean

Author

Cronin, M F, Swart, S, Marandino, C A, Anderson, C, Browne, P, Chen, S, Joubert, W R, Schuster, U, Venkatesan, R, Addey, C I, Alves, O, Ardhuin, F, Battle, S, Bourassa, M A, Chen, Z, Chory, M, Clayson, C, De souza, R B, Du plessis, M, Edmondson, M, Edson, J B, Gille, S T, Hermes, J, Hormann, V, Josey, S A, Kurz, M, Lee, T, Maicu, F, Moustahfid, E H, Nicholson, S-a, Nyadjro, E S, Palter, J, Patterson, R G, Penny, S G, Pezzi, L P, Pinardi, N, Reeves eyre, J E J, Rome, N, Subramanian, A C, Stienbarger, C, Steinhoff, T, Sutton, A J, Tomita, H, Wills, S M, Wilson, C, Yu, L, Cronin, M F, Swart, S, Marandino, C A, Anderson, C, Browne, P, Chen, S, Joubert, W R, Schuster, U, Venkatesan, R, Addey, C I, Alves, O, Ardhuin, F, Battle, S, Bourassa, M A, Chen, Z, Chory, M, Clayson, C, De souza, R B, Du plessis, M, Edmondson, M, Edson, J B, Gille, S T, Hermes, J, Hormann, V, Josey, S A, Kurz, M, Lee, T, Maicu, F, Moustahfid, E H, Nicholson, S-a, Nyadjro, E S, Palter, J, Patterson, R G, Penny, S G, Pezzi, L P, Pinardi, N, Reeves eyre, J E J, Rome, N, Subramanian, A C, Stienbarger, C, Steinhoff, T, Sutton, A J, Tomita, H, Wills, S M, Wilson, C, and Yu, L

Abstract

The Observing Air–Sea Interactions Strategy (OASIS) is a new United Nations Decade of Ocean Science for Sustainable Development programme working to develop a practical, integrated approach for observing air–sea interactions globally for improved Earth system (including ecosystem) forecasts, CO2 uptake assessments called for by the Paris Agreement, and invaluable surface ocean information for decision makers. Our “Theory of Change” relies upon leveraged multi-disciplinary activities, partnerships, and capacity strengthening. Recommendations from >40 OceanObs’19 community papers and a series of workshops have been consolidated into three interlinked Grand Ideas for creating #1: a globally distributed network of mobile air–sea observing platforms built around an expanded array of long-term time-series stations; #2: a satellite network, with high spatial and temporal resolution, optimized for measuring air–sea fluxes; and #3: improved representation of air–sea coupling in a hierarchy of Earth system models. OASIS activities are organized across five Theme Teams: (1) Observing Network Design & Model Improvement; (2) Partnership & Capacity Strengthening; (3) UN Decade OASIS Actions; (4) Best Practices & Interoperability Experiments; and (5) Findable–Accessible–Interoperable–Reusable (FAIR) models, data, and OASIS products. Stakeholders, including researchers, are actively recruited to participate in Theme Teams to help promote a predicted, safe, clean, healthy, resilient, and productive ocean.

Published
2023
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7. Southern ocean carbon and heat impact on climate

Author

Sallée, J. B., Abrahamsen, E. P., Allaigre, C., Auger, M., Ayres, H., Badhe, R., Boutin, J., Brearley, J. A., de Lavergne, C., ten Doeschate, A. M. M., Droste, E. S., du Plessis, M. D., Ferreira, D., Giddy, I. S., Gülk, B., Gruber, N., Hague, M., Hoppema, M., Josey, S. A., Kanzow, T., Kimmritz, M., Lindeman, M. R., Llanillo, P. J., Lucas, N. S., Madec, G., Marshall, D. P., Meijers, A. J. S., Meredith, M. P., Mohrmann, M., Monteiro, P. M. S., Mosneron Dupin, C., Naeck, K., Narayanan, A., Naveira Garabato, A. C., Nicholson, S-A., Novellino, A., Ödalen, Malin, Østerhus, S., Park, Wonsun, Patmore, R. D., Piedagnel, E., Roquet, F., Rosenthal, H. S., Roy, T., Saurabh, R., Silvy, Y., Spira, T., Steiger, N., Styles, A. F., Swart, S., Vogt, L., Ward, B., Zhou, S., Sallée, J. B., Abrahamsen, E. P., Allaigre, C., Auger, M., Ayres, H., Badhe, R., Boutin, J., Brearley, J. A., de Lavergne, C., ten Doeschate, A. M. M., Droste, E. S., du Plessis, M. D., Ferreira, D., Giddy, I. S., Gülk, B., Gruber, N., Hague, M., Hoppema, M., Josey, S. A., Kanzow, T., Kimmritz, M., Lindeman, M. R., Llanillo, P. J., Lucas, N. S., Madec, G., Marshall, D. P., Meijers, A. J. S., Meredith, M. P., Mohrmann, M., Monteiro, P. M. S., Mosneron Dupin, C., Naeck, K., Narayanan, A., Naveira Garabato, A. C., Nicholson, S-A., Novellino, A., Ödalen, Malin, Østerhus, S., Park, Wonsun, Patmore, R. D., Piedagnel, E., Roquet, F., Rosenthal, H. S., Roy, T., Saurabh, R., Silvy, Y., Spira, T., Steiger, N., Styles, A. F., Swart, S., Vogt, L., Ward, B., and Zhou, S.

Abstract

The Southern Ocean greatly contributes to the regulation of the global climate by controlling important heat and carbon exchanges between the atmosphere and the ocean. Rates of climate change on decadal timescales are therefore impacted by oceanic processes taking place in the Southern Ocean, yet too little is known about these processes. Limitations come both from the lack of observations in this extreme environment and its inherent sensitivity to intermittent processes at scales that are not well captured in current Earth system models. The Southern Ocean Carbon and Heat Impact on Climate programme was launched to address this knowledge gap, with the overall objective to understand and quantify variability of heat and carbon budgets in the Southern Ocean through an investigation of the key physical processes controlling exchanges between the atmosphere, ocean and sea ice using a combination of observational and modelling approaches. Here, we provide a brief overview of the programme, as well as a summary of some of the scientific progress achieved during its first half. Advances range from new evidence of the importance of specific processes in Southern Ocean ventilation rate (e.g. storm-induced turbulence, sea-ice meltwater fronts, wind-induced gyre circulation, dense shelf water formation and abyssal mixing) to refined descriptions of the physical changes currently ongoing in the Southern Ocean and of their link with global climate.This article is part of a discussion meeting issue 'Heat and carbon uptake in the Southern Ocean: the state of the art and future priorities'.

Published
2023
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8. Developing an Observing Air-Sea Interactions Strategy (OASIS) for the global ocean

Author

Cronin, M. F., Swart, S., Marandino, C. A., Anderson, C., Browne, P., Chen, S., Joubert, W. R., Schuster, U., Venkatesan, R., Addey, C. I., Alves, O., Ardhuin, F., Battle, S., Bourassa, M. A., Chen, Z., Chory, M., Clayson, C., De Souza, R. B., Du Plessis, M., Edmondson, M., Edson, J. B., Gille, S. T., Hermes, J., Hormann, V., Josey, S. A., Kurz, M., Lee, T., Maicu, F., Moustahfid, E. H., Nicholson, S. A., Nyadjro, E. S., Palter, J., Patterson, R. G., Penny, S. G., Pezzi, L. P., Pinardi, N., Cronin, M. F., Swart, S., Marandino, C. A., Anderson, C., Browne, P., Chen, S., Joubert, W. R., Schuster, U., Venkatesan, R., Addey, C. I., Alves, O., Ardhuin, F., Battle, S., Bourassa, M. A., Chen, Z., Chory, M., Clayson, C., De Souza, R. B., Du Plessis, M., Edmondson, M., Edson, J. B., Gille, S. T., Hermes, J., Hormann, V., Josey, S. A., Kurz, M., Lee, T., Maicu, F., Moustahfid, E. H., Nicholson, S. A., Nyadjro, E. S., Palter, J., Patterson, R. G., Penny, S. G., Pezzi, L. P., and Pinardi, N.

Abstract

The Observing Air-Sea Interactions Strategy (OASIS) is a new United Nations Decade of Ocean Science for Sustainable Development programme working to develop a practical, integrated approach for observing air-sea interactions globally for improved Earth system (including ecosystem) forecasts, CO2 uptake assessments called for by the Paris Agreement, and invaluable surface ocean information for decision makers. Our "Theory of Change"relies upon leveraged multi-disciplinary activities, partnerships, and capacity strengthening. Recommendations from >40 OceanObs'19 community papers and a series of workshops have been consolidated into three interlinked Grand Ideas for creating #1: a globally distributed network of mobile air-sea observing platforms built around an expanded array of long-term time-series stations; #2: a satellite network, with high spatial and temporal resolution, optimized for measuring air-sea fluxes; and #3: improved representation of air-sea coupling in a hierarchy of Earth system models. OASIS activities are organized across five Theme Teams: (1) Observing Network Design & Model Improvement; (2) Partnership & Capacity Strengthening; (3) UN Decade OASIS Actions; (4) Best Practices & Interoperability Experiments; and (5) Findable-Accessible-Interoperable-Reusable (FAIR) models, data, and OASIS products. Stakeholders, including researchers, are actively recruited to participate in Theme Teams to help promote a predicted, safe, clean, healthy, resilient, and productive ocean.

Published
2023

9. Southern ocean carbon and heat impact on climate

Author

Sallée, Jean-Baptiste, Abrahamsen, E. P., Allaigre, C., Auger, Matthis, Ayres, H., Badhe, R., Boutin, Jacqueline, Brearley, J. A., de Lavergne, Casimir, ten Doeschate, A. M. M., Droste, E. S., Du Plessis, M. D., Ferreira, D., Giddy, I. S., Gülk, B., Gruber, N., Hague, M., Hoppema, M., Josey, S. A., Kanzow, T., Kimmritz, M., Lindeman, M. R., Llanillo, P. J., Lucas, N. S., Madec, Gurvan, Marshall, D. P., Meijers, A. J. S., Meredith, M. P., Mohrmann, M., Monteiro, P. M. S., Mosneron Dupin, Cosme, Naeck, Kirtana, Narayanan, A., Naveira Garabato, A. C., Nicholson, S. -A., Novellino, A., Ödalen, M., Østerhus, S., Park, W., Patmore, R. D., Piedagnel, Évéa, Roquet, Fabien, Rosenthal, H. S., Roy, T., Saurabh, Rathore, Silvy, Yona, Spira, T., Steiger, Nadine, Styles, A. F., Swart, S., Vogt, Linus, Ward, B., Zhou, S., Processus et interactions de fine échelle océanique (PROTEO), Laboratoire d'Océanographie et du Climat : Expérimentations et Approches Numériques (LOCEAN), Muséum national d'Histoire naturelle (MNHN)-Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut Pierre-Simon-Laplace (IPSL (FR_636)), École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité)-École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité)-Muséum national d'Histoire naturelle (MNHN)-Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut Pierre-Simon-Laplace (IPSL (FR_636)), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), Nucleus for European Modeling of the Ocean (NEMO R&D ), Océan et variabilité du climat (VARCLIM), and European Project: 821001,SO-CHIC(2019)

Subjects
[SDU]Sciences of the Universe [physics]
Abstract

International audience; The Southern Ocean greatly contributes to the regulation of the global climate by controlling important heat and carbon exchanges between the atmosphere and the ocean. Rates of climate change on decadal timescales are therefore impacted by oceanic processes taking place in the Southern Ocean, yet too little is known about these processes. Limitations come both from the lack of observations in this extreme environment and its inherent sensitivity to intermittent processes at scales that are not well captured in current Earth system models. The Southern Ocean Carbon and Heat Impact on Climate programme was launched to address this knowledge gap, with the overall objective to understand and quantify variability of heat and carbon budgets in the Southern Ocean through an investigation of the key physical processes controlling exchanges between the atmosphere, ocean and sea ice using a combination of observational and modelling approaches. Here, we provide a brief overview of the programme, as well as a summary of some of the scientific progress achieved during its first half. Advances range from new evidence of the importance of specific processes in Southern Ocean ventilation rate (e.g. storm-induced turbulence, sea-ice meltwater fronts, wind-induced gyre circulation, dense shelf water formation and abyssal mixing) to refined descriptions of the physical changes currently ongoing in the Southern Ocean and of their link with global climate. This article is part of a discussion meeting issue `Heat and carbon uptake in the Southern Ocean: the state of the art and future priorities'.

Published
2023
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10. Supplementary material for ‘Southern Ocean Carbon and Heat Impact on Climate’ from Southern ocean carbon and heat impact on climate

Author

Sallée, J. B., Abrahamsen, E. P., Allaigre, C., Auger, M., Ayres, H., Badhe, R., Boutin, J., Brearley, J. A., de Lavergne, C., ten Doeschate, A. M. M., Droste, E. S., du Plessis, M. D., Ferreira, D., Giddy, I. S., Gülk, B., Gruber, N., Hague, M., Hoppema, M., Josey, S. A., Kanzow, T., Kimmritz, M., Lindeman, M. R., Llanillo, P. J., Lucas, N. S., Madec, G., Marshall, D. P., Meijers, A. J. S., Meredith, M. P., Mohrmann, M., Monteiro, P. M. S., Mosneron Dupin, C., Naeck, K., Narayanan, A., Naveira Garabato, A. C., Nicholson, S-A., Novellino, A., Ödalen, M., Østerhus, S., Park, W., Patmore, R. D., Piedagnel, E., Roquet, F., Rosenthal, H. S., Roy, T., Saurabh, R., Silvy, Y., Spira, T., Steiger, N., Styles, A. F., Swart, S., Vogt, L., Ward, B., and Zhou, S.

Abstract

The Southern Ocean greatly contributes to the regulation of the global climate by controlling important heat and carbon exchanges between the atmosphere and the ocean. Rates of climate change on decadal time scales are therefore impacted by oceanic processes taking place in the Southern Ocean, yet too little is known about these processes. Limitations come both from the lack of observations in this extreme environment and its inherent sensitivity to intermittent processes at scales that are not well captured in current Earth system models. The Southern Ocean Carbon and Heat Impact on Climate programme was launched to address this knowledge gap, with the overall objective to understand and quantify variability of heat and carbon budgets in the Southern Ocean through an investigation of the key physical processes controlling exchanges between the atmosphere, ocean, and sea ice using a combination of observational and modelling approaches. Here, we provide a brief overview of the programme, as well as a summary of some of the scientific progress achieved during its first half. Advances range from new evidence of the importance of specific processes in Southern Ocean ventilation rate (e.g. storm-induced turbulence, sea–ice meltwater fronts, wind-induced gyre circulation, dense shelf water formation and abyssal mixing) to refined descriptions of the physical changes currently ongoing in the Southern Ocean and of their link with global climate.This article is part of the theme issue ‘Heat and carbon uptake in the Southern Ocean: the state of the art and future priorities’.

Published
2023
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12. Satellite‐Based Sea Surface Salinity Designed for Ocean and Climate Studies

Author

Boutin, J., primary, Reul, N., additional, Koehler, J., additional, Martin, A., additional, Catany, R., additional, Guimbard, S., additional, Rouffi, F., additional, Vergely, J. L., additional, Arias, M., additional, Chakroun, M., additional, Corato, G., additional, Estella‐Perez, V., additional, Hasson, A., additional, Josey, S., additional, Khvorostyanov, D., additional, Kolodziejczyk, N., additional, Mignot, J., additional, Olivier, L., additional, Reverdin, G., additional, Stammer, D., additional, Supply, A., additional, Thouvenin‐Masson, C., additional, Turiel, A., additional, Vialard, J., additional, Cipollini, P., additional, Donlon, C., additional, Sabia, R., additional, and Mecklenburg, S., additional

Published
2021
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14. Satellite‐Based Sea Surface Salinity Designed for Ocean and Climate Studies

Author

Boutin, J., Reul, N., Koehler, J., Martin, A., Catany, R., Guimbard, S., Rouffi, F., Vergely, J. L., Arias, M., Chakroun, M., Corato, G., Estella‐Perez, V., Hasson, A., Josey, S., Khvorostyanov, D., Kolodziejczyk, N., Mignot, J., Olivier, L., Reverdin, G., Stammer, D., Supply, A., Thouvenin‐Masson, C., Turiel, A., Vialard, J., Cipollini, P., Donlon, C., Sabia, R., Mecklenburg, S., Boutin, J., Reul, N., Koehler, J., Martin, A., Catany, R., Guimbard, S., Rouffi, F., Vergely, J. L., Arias, M., Chakroun, M., Corato, G., Estella‐Perez, V., Hasson, A., Josey, S., Khvorostyanov, D., Kolodziejczyk, N., Mignot, J., Olivier, L., Reverdin, G., Stammer, D., Supply, A., Thouvenin‐Masson, C., Turiel, A., Vialard, J., Cipollini, P., Donlon, C., Sabia, R., and Mecklenburg, S.

Abstract

Sea Surface Salinity (SSS) is an increasingly used Essential Ocean and Climate Variable. The Soil Moisture and Ocean Salinity (SMOS), Aquarius, and Soil Moisture Active Passive (SMAP) satellite missions all provide SSS measurements, with very different instrumental features leading to specific measurement characteristics. The Climate Change Initiative Salinity project (CCI + SSS) aims to produce a SSS Climate Data Record (CDR) that addresses well-established user needs based on those satellite measurements. To generate a homogeneous CDR, instrumental differences are carefully adjusted based on in-depth analysis of the measurements themselves, together with some limited use of independent reference data. An optimal interpolation in the time domain without temporal relaxation to reference data or spatial smoothing is applied. This allows preserving the original datasets variability. SSS CCI fields are well suited for monitoring weekly to interannual signals, at spatial scales ranging from 50 km to the basin scale. They display large year-to-year seasonal variations over the 2010–2019 decade, sometimes by more than ±0.4 over large regions. The robust standard deviation of the monthly CCI SSS minus in situ Argo salinities is 0.15 globally, while it is at least 0.20 with individual satellite SSS fields. r2 is 0.97, similar or better than with original datasets. The correlation with independent ship thermosalinographs SSS further highlights the CCI data set excellent performance, especially near land areas. During the SMOS-Aquarius period, when the representativity uncertainties are the largest, r2 is 0.84 with CCI while it is 0.48 with the Aquarius original data set. SSS CCI data are freely available and will be updated and extended as more satellite data become available.

Published
2021

18. Importance of boundary processes for heat uptake in the Subpolar North Atlantic

Author

Desbruyères, Damien, Sinha, B., Mcdonagh, E. L., Josey, S. A., Holliday, N. P., Smeed, D. A., New, A. L., Megann, A., Moat, B. I., Desbruyères, Damien, Sinha, B., Mcdonagh, E. L., Josey, S. A., Holliday, N. P., Smeed, D. A., New, A. L., Megann, A., and Moat, B. I.

Abstract

The decadal to multi‐decadal temperature variability of the intermediate (700 – 2000 m) North Atlantic Subpolar Gyre (SPG) significantly imprints the global pattern of ocean heat uptake. Here, the origins and dominant pathways of this variability are investigated with an ocean analysis product (EN4), an ocean state estimate (ECCOv4), and idealized modeling approaches. Sustained increases and decreases of intermediate temperature in the SPG correlate with long‐lasting warm and cold states of the upper ocean with the largest anomalous vertical heat exchanges confined to the vicinity of continental boundaries and strong ocean currents. In particular, vertical diffusive processes along the boundaries of the Labrador, Irminger, and Newfoundland basins are important drivers of the recent intermediate depth warming trend observed during 1996‐2014. The overall effect of those processes is captured by a 1‐dimensional diffusive model with appropriate boundary‐like parametrization and demonstrated through the boundary‐focused downward propagation of a passive tracer in a 3D numerical simulation. Our results imply that the slow and quasi‐periodic ventilation of intermediate thermohaline properties and associated heat uptake in the SPG are not strictly driven by convection‐restratification events in the open seas but also receives a key contribution from boundary sinking and mixing. Increased skill for modelling and predicting intermediate‐depth ocean properties in the North Atlantic will hence require the appropriate representation of surface‐deep dynamical connections within the boundary currents encircling Greenland and Newfoundland. Plain language summary The subarctic basins of the North Atlantic Ocean play a fundamental role in regulating the climate system. This occurs notably throughout direct connections between the ocean surface (and hence the atmosphere) and deep oceanic layers, which enable the long‐term sequestration and subsequent propagation of physical and biogeo

Published
2020
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19. The major role of air‐sea heat fluxes in driving interannual variations of Gulf Stream transport

Author

Jacobs, Z. L., Grist, J. P., Marsh, R., Sinha, B., Josey, S. A., Jacobs, Z. L., Grist, J. P., Marsh, R., Sinha, B., and Josey, S. A.

Abstract

The Gulf Stream (GS) is central to the global redistribution of heat due to the transport of large volumes of warm water from the tropics to high latitudes and the extreme ocean heat loss to the atmosphere. This study assesses the extent to which winter surface heat fluxes and wind stress curl can drive interannual variations of the full‐depth GS transport. Intensification of the GS has been observed (e.g., April 1977) immediately after a winter of frequent cold air outbreaks that led to a deepening of the mixed layer and subsequent steepening of meridional temperature gradients to the south of the GS. This forcing process is further investigated here using the ORCA12 hindcast (1978–2010) from the global, eddy‐resolving, ocean‐only Nucleus for European Modeling of the Ocean model in order to understand GS forcing mechanisms. Lagrangian analysis is also undertaken to examine the impact on the southern recirculation gyre. Results show that surface heat fluxes and wind stress curl can act in concert to effect year‐to‐year changes of up to 38% of the spring GS transport at 70°W. However, anomalous heat losses (∼200 Wm‐2) over the western Subtropical Gyre are found to be the dominant cause of peaks in GS transport via two mechanisms: (1) a strengthening of cross‐stream density gradients on the northern flank of the GS from an intense cooling (up to 4°C) in the Slope Water and (2) a westward intensification of the southern recirculation, which can also limit the formation of deeper mixed layers to the south of the GS near 70°W.

Published
2020

20. Rapid cooling and increased storminess triggered by freshwater in the North Atlantic

Author

Oltmanns, M., Karstensen, J., Moore, G. W. K., Josey, S. A., Oltmanns, M., Karstensen, J., Moore, G. W. K., and Josey, S. A.

Abstract

Recent winters have been unique due to the rapid and extreme cooling of the subpolar North Atlantic. Here, we present a novel view on its causes and consequences. Combining in‐situ observations with remote sensing and atmospheric reanalysis data, we show that increased freshening of the subpolar region gives rise to a faster surface cooling in fall and winter. Large freshwater events, in particular, result in pronounced cold anomalies with sharp temperature gradients that promote an enhanced storminess. The storms reinforce the cooling by driving stronger heat losses and modulating the surface flow. Consistent with this mechanism, past freshwater events have been followed by cold anomalies in winter of ~‐2°C and increases in the North Atlantic Oscillation index of up to~0.6 within 3 years. We expect that future freshwater discharges into the North Atlantic will amplify the cold anomaly and trigger an enhanced wintertime storminess with far‐reaching climatic implications.

Published
2020

21. Importance of boundary processes for heat uptake in the Subpolar North Atlantic

Author

Desbruyères, D. G., Sinha, B., McDonagh, E. L., Josey, S. A., Holliday, N. P., Smeed, D. A., New, A. L., Megann, A., Moat, B. I., Desbruyères, D. G., Sinha, B., McDonagh, E. L., Josey, S. A., Holliday, N. P., Smeed, D. A., New, A. L., Megann, A., and Moat, B. I.

Abstract

The decadal to multi‐decadal temperature variability of the intermediate (700 – 2000 m) North Atlantic Subpolar Gyre (SPG) significantly imprints the global pattern of ocean heat uptake. Here, the origins and dominant pathways of this variability are investigated with an ocean analysis product (EN4), an ocean state estimate (ECCOv4), and idealized modeling approaches. Sustained increases and decreases of intermediate temperature in the SPG correlate with long‐lasting warm and cold states of the upper ocean with the largest anomalous vertical heat exchanges confined to the vicinity of continental boundaries and strong ocean currents. In particular, vertical diffusive processes along the boundaries of the Labrador, Irminger, and Newfoundland basins are important drivers of the recent intermediate depth warming trend observed during 1996‐2014. The overall effect of those processes is captured by a 1‐dimensional diffusive model with appropriate boundary‐like parametrization and demonstrated through the boundary‐focused downward propagation of a passive tracer in a 3D numerical simulation. Our results imply that the slow and quasi‐periodic ventilation of intermediate thermohaline properties and associated heat uptake in the SPG are not strictly driven by convection‐restratification events in the open seas but also receives a key contribution from boundary sinking and mixing. Increased skill for modelling and predicting intermediate‐depth ocean properties in the North Atlantic will hence require the appropriate representation of surface‐deep dynamical connections within the boundary currents encircling Greenland and Newfoundland.

Published
2020

22. Rapid Cooling and Increased Storminess Triggered by Freshwater in the North Atlantic

Author

Oltmanns, Marilena, Karstensen, Johannes, Moore, G. W. K., Josey, S. A., Oltmanns, Marilena, Karstensen, Johannes, Moore, G. W. K., and Josey, S. A.

Abstract

Recent winters have been unique due to the rapid and extreme cooling of the subpolar North Atlantic. Here, we present a novel view on its causes and consequences. Combining in-situ observations with remote sensing and atmospheric reanalysis data, we show that increased freshening of the subpolar region gives rise to a faster surface cooling in fall and winter. Large freshwater events, in particular, result in pronounced cold anomalies with sharp temperature gradients that promote an enhanced storminess. The storms reinforce the cooling by driving stronger heat losses and modulating the surface flow. Consistent with this mechanism, past freshwater events have been followed by cold anomalies in winter of approximately −2°C and increases in the North Atlantic Oscillation index of up to ∼0.6 within 3 years. We expect that future freshwater discharges into the North Atlantic will amplify the cold anomaly and trigger an enhanced wintertime storminess with far-reaching climatic implications.

Published
2020
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23. Recent observed changes in the North Atlantic climate system with a focus on 2005-2016

Author

Robson, J, Sutton, RT, Archibald, A, Cooper, F, Christensen, M, Grey, LJ, Holliday, NP, Macintosh, C, McMillan, M, Moat, B, Russo, M, Tilling, R, Carslaw, K, Desbruyères, D, Embury, O, Feltham, D, Grosvenor, D, Josey, S, King, B, Lewis, A, McCarthy, GD, Merchant, C, New, AL, O'Reilly, CH, Osprey, SM, Read, K, Scaife, A, Shepherd, A, Sinha, B, Smeed, D, Smith, D, Ridout, A, Woollings, TJ, and Yang, M

Abstract

Major changes are occurring across the North Atlantic climate system, including in the atmosphere, ocean and cryosphere, and many observed changes are unprecedented in instrumental records. As the changes in the North Atlantic directly affect the climate and air quality of the surrounding continents, it is important to fully understand how and why the changes are taking place, not least to predict how the region will change in the future. To this end, this article characterizes the recent observed changes in the North Atlantic region, especially in the period 2005–2016, across many different aspects of the system including: atmospheric circulation; atmospheric composition; clouds and aerosols; ocean circulation and properties; and the cryosphere. Recent changes include: an increase in the speed of the North Atlantic jet stream in winter; a southward shift in the North Atlantic jet stream in summer, associated with a weakening summer North Atlantic Oscillation; increases in ozone and methane; increases in net absorbed radiation in the mid‐latitude western Atlantic, linked to an increase in the abundance of high level clouds and a reduction in low level clouds; cooling of sea surface temperatures in the North Atlantic subpolar gyre, concomitant with increases in the western subtropical gyre, and a decline in the Atlantic Ocean's overturning circulation; a decline in Atlantic sector Arctic sea ice and rapid melting of the Greenland Ice Sheet. There are many interactions between these changes, but these interactions are poorly understood. This article concludes by highlighting some of the key outstanding questions.

Published
2018

25. Extreme variability in Irminger Sea winter heat loss revealed by ocean observatories initiative mooring and the ERA5 reanalysis

Author

Josey, S. A., de Jong, M. F., Oltmanns, M., Moore, G. K., Weller, R. A., Josey, S. A., de Jong, M. F., Oltmanns, M., Moore, G. K., and Weller, R. A.

Abstract

Ground‐breaking measurements from the ocean observatories initiative Irminger Sea surface mooring (60°N, 39°30′W) are presented that provide the first in situ characterization of multiwinter surface heat exchange at a high latitude North Atlantic site. They reveal strong variability (December 2014 net heat loss nearly 50% greater than December 2015) due primarily to variations in frequency of intense short timescale (1–3 days) forcing. Combining the observations with the new high resolution European Centre for Medium Range Weather Forecasts Reanalysis 5 (ERA5) atmospheric reanalysis, the main source of multiwinter variability is shown to be changes in the frequency of Greenland tip jets (present on 15 days in December 2014 and 3 days in December 2015) that can result in hourly mean heat loss exceeding 800 W/m2. Furthermore, a new picture for atmospheric mode influence on Irminger Sea heat loss is developed whereby strongly positive North Atlantic Oscillation conditions favor increased losses only when not outweighed by the East Atlantic Pattern.

Published
2019

31. Signatures of the 1976-1977 Regime Shift in the North Pacific Revealed by Statistical Analysis

Author

Giamalaki, K., Beaulieu, C., Faranda, D., Henson, S. A., Josey, S. A., Martin, A.P., Giamalaki, K., Beaulieu, C., Faranda, D., Henson, S. A., Josey, S. A., and Martin, A.P.

Abstract

Regime shifts are abrupt changes in an ecosystem that may propagate through multiple trophic levels and have pronounced effects on the biotic and abiotic environment, potentially resulting in ecosystem reorganization. There are multiple mechanisms that could cause such abrupt events including natural and anthropogenic factors. In the North Pacific, a major shift in the physics of the system, including a sudden increase in sea surface temperature, was reported in 1977 with a prominent biological response in the lower trophic levels and subsequent effects on the fisheries and economy of the region. Here we investigate the statistics of physical processes that could have triggered and maintained the late 1970s shift. The hypothesis of an extreme sea level pressure event abruptly changing the oceanic conditions in winter 1976–1977, which was maintained by long‐term changes in air‐sea interaction processes, is tested. Using dynamical proxies, we show the occurrence of an extreme atmospheric event, specifically a persistent Aleutian Low during winter 1976–1977, which constitutes a substantial part of the triggering mechanism of the regime shift. Subsequent sudden changes in the net heat flux occurred in the western North Pacific, particularly in the Kuroshio Extension region, which contributed to the maintenance of the new regime.

Published
2018

32. Gulf Stream variability in the context of quasi-decadal and multidecadal Atlantic climate variability

Author

McCarthy, G. D., Joyce, T. M., Josey, S. A., McCarthy, G. D., Joyce, T. M., and Josey, S. A.

Abstract

The Gulf Stream plays an important role in North Atlantic climate variability on a range of timescales. The North Atlantic is notable for large decadal variability in sea surface temperatures (SST). Whether this variability is driven by atmospheric or oceanic influences is a disputed point. Long time series of atmospheric and ocean variables, in particular long time series of Gulf Stream position, reveal differing sources of SST variability on quasi‐decadal and multidecadal timescales. On quasi‐decadal timescales, an oscillatory signal identified in the North Atlantic Oscillation (NAO) controls SST evolution directly via air‐sea heat fluxes. However, on multidecadal timescales, this relationship between the NAO and SST changes, while the relationship between the NAO and Gulf Stream position remains consistent in phase and resonant in amplitude. Recent changes in the Gulf Stream Extension show a weakening and broadening of the current, consistent with increased instability. We consider these changes in the context of a weakening Atlantic overturning circulation. Plain Language Summary The North Atlantic Ocean is a region of remarkable variability in surface temperatures on timescales of decades and longer. Much debate surrounds whether this variability is driven by the atmosphere or by ocean currents, such as the Gulf Stream, moving heat around. In this study, we show that on timescales around 10 years, the atmosphere is the likely cause of Atlantic temperature variability but that this changes when multidecadal variability is considered. Changes ongoing in the Gulf Stream coincide with changes in the broader Atlantic—changes that imply a relatively cooler Atlantic in the coming decades.

Published
2018

33. The North Atlantic Ocean Is in a State of Reduced Overturning

Author

Smeed, D. A., primary, Josey, S. A., additional, Beaulieu, C., additional, Johns, W. E., additional, Moat, B. I., additional, Frajka‐Williams, E., additional, Rayner, D., additional, Meinen, C. S., additional, Baringer, M. O., additional, Bryden, H. L., additional, and McCarthy, G. D., additional

Published
2018
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35. Review and assessment of latent and sensible heat flux accuracy over the global oceans

Author

Bentamy, Abderrahim, Piolle, Jean-francois, Grouazel, Antoine, Danielson, R., Gulev, S., Paul, Frederic, Azelmat, Hamza, Mathieu, P. P., Von Schuckmann, Karina, Sathyendranath, S., Evers-king, H., Esau, I., Johannessen, J. A., Clayson, C. A., Pinker, R. T., Grodsky, S. A., Bourassa, M., Smith, S. R., Haines, K., Valdivieso, M., Merchant, C. J., Chapron, Bertrand, Anderson, A., Hollmann, R., Josey, S. A., Bentamy, Abderrahim, Piolle, Jean-francois, Grouazel, Antoine, Danielson, R., Gulev, S., Paul, Frederic, Azelmat, Hamza, Mathieu, P. P., Von Schuckmann, Karina, Sathyendranath, S., Evers-king, H., Esau, I., Johannessen, J. A., Clayson, C. A., Pinker, R. T., Grodsky, S. A., Bourassa, M., Smith, S. R., Haines, K., Valdivieso, M., Merchant, C. J., Chapron, Bertrand, Anderson, A., Hollmann, R., and Josey, S. A.

Abstract

For over a decade, several research groups have been developing air-sea heat flux information over the global ocean, including latent (LHF) and sensible (SHF) heat fluxes over the global ocean. This paper aims to provide new insight into the quality and error characteristics of turbulent heat flux estimates at various spatial and temporal scales (from daily upwards). The study is performed within the European Space Agency (ESA) Ocean Heat Flux (OHF) project. One of the main objectives of the OHF project is to meet the recommendations and requirements expressed by various international programs such as the World Research Climate Program (WCRP) and Climate and Ocean Variability, Predictability, and Change (CLIVAR), recognizing the need for better characterization of existing flux errors with respect to the input bulk variables (e.g. surface wind, air and sea surface temperatures, air and surface specific humidities), and to the atmospheric and oceanic conditions (e.g. wind conditions and sea state). The analysis is based on the use of daily averaged LHF and SHF and the associated bulk variables derived from major satellite-based and atmospheric reanalysis products. Inter-comparisons of heat flux products indicate that all of them exhibit similar space and time patterns. However, they also reveal significant differences in magnitude in some specific regions such as the western ocean boundaries during the Northern Hemisphere winter season, and the high southern latitudes. The differences tend to be closely related to large differences in surface wind speed and/or specific air humidity (for LHF) and to air and sea temperature differences (for SHF). Further quality investigations are performed through comprehensive comparisons with daily-averaged LHF and SHF estimated from moorings. The resulting statistics are used to assess the error of each OHF product. Consideration of error correlation between products and observations (e.g., by their assimilation) is also given. Thi

Published
2017
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36. Rapid response to climate change in a marginal sea

Author

Schroeder, K., Chiggiato, J., Josey, S., Borghini, M., Aracri, S., Sparnocchia, S., Schroeder, K., Chiggiato, J., Josey, S., Borghini, M., Aracri, S., and Sparnocchia, S.

Abstract

The Mediterranean Sea is a mid-latitude marginal sea, particularly responsive to climate change as reported by recent studies. The Sicily Channel is a choke point separating the sea in two main basins, the Eastern Mediterranean Sea and the Western Mediterranean Sea. Here, we report and analyse a long-term record (1993–2016) of the thermohaline properties of the Intermediate Water that crosses the Sicily Channel, showing increasing temperature and salinity trends much stronger than those observed at intermediate depths in the global ocean. We investigate the causes of the observed trends and in particular determine the role of a changing climate over the Eastern Mediterranean, where the Intermediate Water is formed. The long-term Sicily record reveals how fast the response to climate change can be in a marginal sea like the Mediterranean Sea compared to the global ocean, and demonstrates the essential role of long time series in the ocean.

Published
2017

40. An imperative to monitor Earth's energy imbalance

Author

von Schuckmann, K., primary, Palmer, M. D., additional, Trenberth, K. E., additional, Cazenave, A., additional, Chambers, D., additional, Champollion, N., additional, Hansen, J., additional, Josey, S. A., additional, Loeb, N., additional, Mathieu, P.-P., additional, Meyssignac, B., additional, and Wild, M., additional

Published
2016
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42. Abrupt warming and salting of the Western Mediterranean Deep Water: atmospheric forcings and lateral advection

Author

Schroeder, Katrin, Josey, S. A., Herrmann, Marine, Grignon, Laure, Gasparini, G. P., Bryden, H. L., Istituto di Scienze Marine [La Spezia] (CNR-ISMAR-SP), Istituto di Science Marine (ISMAR ), National Research Council of Italy | Consiglio Nazionale delle Ricerche (CNR)-National Research Council of Italy | Consiglio Nazionale delle Ricerche (CNR), National Oceanography Centre [Southampton] (NOC), University of Southampton, Centre national de recherches météorologiques (CNRM), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS), CNR Istituto per lo studio dell'Oceanografia Fisica, National Research Council of Italy | Consiglio Nazionale delle Ricerche (CNR), Consiglio Nazionale delle Ricerche (CNR)-Consiglio Nazionale delle Ricerche (CNR), Groupe d'étude de l'atmosphère météorologique (CNRM-GAME), Institut national des sciences de l'Univers (INSU - CNRS)-Météo France-Centre National de la Recherche Scientifique (CNRS), Consiglio Nazionale delle Ricerche (CNR), Istituto di Scienze Marine, Consiglio Nazionale delle Ricerche ( CNR ), National Oceanography Centre [Southampton] ( NOC ), University of Southampton [Southampton], Groupe d'étude de l'atmosphère météorologique ( CNRM-GAME ), Institut national des sciences de l'Univers ( INSU - CNRS ) -Météo France-Centre National de la Recherche Scientifique ( CNRS ), National Oceanography Centre, National Oceanographic Centre [Southampton] ( NOC ), CNR ? Istituto per lo studio dell'Oceanografia Fisica, and Empress Dock

Subjects
[ SDU.OCEAN ] Sciences of the Universe [physics]/Ocean, Atmosphere, [SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere
Abstract

International audience; The recent major production of anomalously warm, salty deep water in the northwestern Mediterranean Sea (winters 2004–2005 and 2005–2006) is linked to extreme winter air-sea heat and freshwater forcing of the basin. Fields of heat and density fluxes are determined both from the National Centers for Environmental Prediction-National Center for Atmospheric Research reanalysis and a daily high-resolution downscaling of the European Centre for Medium-Range Weather Forecasts reanalysis and analysis data set ARPERA. In the deep water formation region, during winter 2004–2005, the net heat loss exceeds 300 W m−2 compared with typical values of 200 W m−2. The relationship between the deep water formation episodes and large-scale atmospheric patterns is investigated and found to be more closely related to the East Atlantic Pattern than the North Atlantic Oscillation. The contributions of atmospheric forcing and lateral advection of anomalously warm, salty water to the convection region are discussed in order to determine their relative roles in causing massive renewal of Western Mediterranean Deep Water and its anomalous properties. The main result shows that the net evaporation during winter 2004–2005, even if very high compared to the climatology, could have induced only 49% of the actual observed increase in the salt content of the deep layer. Thus, lateral advection played a major role in setting the new deep water properties.

Published
2010
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43. HyMeX Science Plan, Version 2.3, May 2010

Author

Ducrocq, Vincent, Roussot, Odile, Béranger, K., Braud, Isabelle, Chanzy, Andre, Delrieu, G., Drobinski, Philippe, Estournel, C., Ivenna Picek, B., Josey, S., Lagouvardos, K., Lionello, P., Llasat, M.C., Ludwig, Wolfgang, Lutoff, Céline, Mariotti, André, Montanari, Andrea, Romero, R., Ruin, I., Somot, S., Météo France, École Nationale Supérieure de Techniques Avancées (ENSTA Paris), Hydrologie-Hydraulique (UR HHLY), Centre national du machinisme agricole, du génie rural, des eaux et forêts (CEMAGREF), Institut National de la Recherche Agronomique (INRA), Laboratoire d'étude des transferts en hydrologie et environnement (LTHE), Institut National Polytechnique de Grenoble (INPG)-Centre National de la Recherche Scientifique (CNRS)-Observatoire des Sciences de l'Univers de Grenoble (OSUG), Centre National de la Recherche Scientifique (CNRS)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry]), Laboratoire d'aérologie (LAERO), Centre National de la Recherche Scientifique (CNRS)-Observatoire Midi-Pyrénées (OMP), Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées, irstea, Météo-France Direction Interrégionale Sud-Est (DIRSE), Météo-France, Observatoire des Sciences de l'Univers de Grenoble (OSUG), Université Joseph Fourier - Grenoble 1 (UJF)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut national des sciences de l'Univers (INSU - CNRS)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut national des sciences de l'Univers (INSU - CNRS)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Institut National Polytechnique de Grenoble (INPG)-Centre National de la Recherche Scientifique (CNRS), Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Observatoire Midi-Pyrénées (OMP), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), and Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS)

Subjects
[SDE]Environmental Sciences, BASSIN MEDITERRANEEN
Abstract

[Departement_IRSTEA]Eaux [TR1_IRSTEA]ARCEAU; The Mediterranean basin has quite a unique character that results both from physiographic conditions and historical and societal developments. The region features a nearly enclosed sea surrounded by very urbanized littorals and mountains from which numerous rivers originate. This results in many interactions and feedback between ocean-atmosphere-land processes that play a prominent role in climate and high-impact weather. The Mediterranean area actually concentrates the major natural risks related to the water cycle, including heavy precipitation and flash-flooding during the fall season, severe cyclogenesis associated with strong winds and large sea waves during winter, and heat waves and droughts accompanied by forest fires during summer. Such natural hazards highly impact the populations living in the area. The capability to predict such high-impact events remains weak because of the contribution of very fine-scale processes and their non-linear interactions with the larger scale processes. Water resource is a critical issue for a large part of the Mediterranean basin. Freshwater is rare and unevenly distributed in time and space with few short duration heavy precipitation and long drought periods. Such situation occurs against a background of increasing water demand and aggravates with climate change. The Mediterranean region has indeed been identified as one of the two main hot-spots of climate change, which means that its climate is especially responsive to global change. Large decrease in mean precipitation and increase in precipitation variability during dry (warm) season are expected, as well as large increase in temperature. Climate evolution in the Mediterranean is however still largely uncertain. This region is also characterized by a rapid increase of population and urbanization, putting higher pressure on water resources. Progress has to be made in the monitoring and modelling of the Mediterranean coupled climate system (atmosphere-land-ocean) in order to quantify the ongoing changes and to better predict their future evolution in order to provide guidelines for the development of adaptation measures. These societal and science issues motivate the HyMeX (Hydrological cycle in the Mediterranean Experiment, http://www.hymex.org/) experimental programme. HyMeX aims at a better quantification and understanding of the water cycle in the Mediterranean with emphasis on intense events. HyMeX proposes to monitor and model the Mediterranean atmosphere-land-ocean coupled system, as well as the social vulnerability related to water resources and extreme event impacts. The variability of the system will be monitored from the event to the seasonal and interannual scales, and its characteristics over one decade (2010-2020) in the context of global change. HyMeX science is organized along five major topics.

Published
2010

44. On the forcing of sea level in the Black Sea

Author

Tsimplis, M. N., Josey, S. A., Rixen, M., and Stanev, E. V.

Subjects
Black Sea, steric sea level, climatology, North Atlantic Oscillation, interbasin water and salt exchange
Abstract

[1] Forcing mechanisms for sea level variability in the Black Sea are investigated in the [context of an observed increase in the sea level of this basin by 2.5 mm/yr over the last 60 years. Temperature and salinity variations computed from the Mediterranean Data Archeology and Rescue (MEDAR) data set exhibit significant interdecadal variability. However, the corresponding steric height variation does not show a long-term increase and thus cannot account for the observed change in sea level. The impact of surface freshwater flux (P-E) changes is also investigated using two independent data sets. The first data set, which is based on measurements collected in the basin, can explain most of the sea level variability, with only 0.8 mm/yr remaining unexplained. The second data set, output from the National Centers for Environmental Prediction/National Center for Atmospheric Research (NCEP/NCAR) reanalysis, is unable to explain any of the observed trend. Potential contributions from changes in river runoff and surface pressure are quantified but found to be minor terms. By comparing the observed salinity changes with the sea level rise and the P-E variability in the first data set, we infer that the P-E variations are the primary cause for the observed sea level rise, while land movements are likely to partly contribute, too. The relationship of Black Sea temperature and salinity variability with corresponding variability in the connected Aegean Sea has also been explored. A significant correlation is found between the salinity of the upper water of the Aegean Sea and the layer between 50 and 300 m in the Black Sea, indicating that the latter layer is a product of the Mediterranean inflow.

Published
2004

45. Unexpected impacts of the Tropical Pacific array on reanalysis surface meteorology and heat fluxes

Author

Josey, S. A., Yu, L., Gulev, S., Jin, X., Tilinina, N., Barnier, B., Brodeau, Laurent, Josey, S. A., Yu, L., Gulev, S., Jin, X., Tilinina, N., Barnier, B., and Brodeau, Laurent

Abstract

The Tropical Pacific mooring array has been a key component of the climate observing system since the early 1990s. We identify a pattern of strong near surface humidity anomalies, colocated with the array, in the widely used European Center for Medium Range Weather Forecasting Interim atmospheric reanalysis. The pattern generates large, previously unrecognized latent and net air-sea heat flux anomalies, up to 50 Wm−2 in the annual mean, in reanalysis derived data sets employed for climate studies (TropFlux) and ocean model forcing (the Drakkar Forcing Set). As a consequence, uncertainty in Tropical Pacific ocean heat uptake between the 1990s and early 2000s at the mooring sites is significant with mooring colocated differences in decadally averaged ocean heat uptake as large as 20 Wm−2. Furthermore, these results have major implications for the dual use of air-sea flux buoys as reference sites and sources of assimilation data that are discussed.

Published
2014
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46. Impact of Barents Sea winter air-sea exchanges on Fram Strait dense water transport

Author

Moat, B.I., Josey, S., Sinha, B., Moat, B.I., Josey, S., and Sinha, B.

Abstract

Impacts of extreme Barents Sea air-sea exchanges are examined using the HadCM3 coupled ocean-atmosphere model. Variability in the Barents Sea winter air-sea density flux is found to be a potentially significant factor in determining changes in the southward transport of dense water through Fram Strait. The density flux variability is primarily driven by the thermal term, FT, due to heat loss to the atmosphere. The other two terms (haline flux and ice formation) play a relatively minor role. The difference in ocean circulation between winters with extreme strong and weak Barents Sea surface density flux anomalies is analysed. This reveals an increase in strong winters of both the north-westwards intermediate depth flow out of the basin and the east-west deep flows north of Spitsbergen and south through the Fram Strait. A linear fit yields a Fram Strait southward transport increase of 1.22 Sv for an increase in FT of 1x10-6 kg m-2 s-1. For the ten strongest Barents Sea surface density flux winters, the Fram Strait winter southward transport increases by 2.4 Sv. This compares with a reduction of 1.0 Sv for the corresponding weakest winters. Furthermore, the properties of the southwards flowing water are modified in strong density flux winters. In such winters, the Fram Strait water below 250 m is colder by up to 0.5 �C and fresher by 0.05 than the climatological winter mean.

Published
2014

49. Impacts of climate change on air-sea exchanges of heat and water

Author

Baxter, J.M., Buckley, P.J., Wallace, C.J., Josey, S., Berry, D.I., Baxter, J.M., Buckley, P.J., Wallace, C.J., Josey, S., and Berry, D.I.

Abstract

Changes in the air-sea fluxes of heat and freshwater are expected as a result of anthropogenic climate change. Studies of increasing observed ocean heat content place a limit of about 0.5 W m-2 on the increase in the global ocean mean net surface heat flux. Given the high level of uncertainty in available flux datasets this signal is likely to be very difficult to detect. A similar situation holds for the surface freshwater flux, for which there are additional problems associated with obtaining reliable long-term estimates of precipitation. Observations of changing ocean salinity suggest a strengthening of the hydrological cycle but further research is required to link this to changing freshwater flux. Variations in freshwater exchanges in the UK marine environment may also occur as a result of shifts in the spatial patterns of the major modes of atmospheric variability.

Published
2013

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