Your search keyword '"Key, Robert M."' showing total 350 results

51. Upwelling in the Ocean Basins North of the ACC: 2. How Cool Subantarctic Water Reaches the Surface in the Tropics

Author

Toggweiler, J. R., primary, Druffel, Ellen R. M., additional, Key, Robert M., additional, and Galbraith, Eric D., additional

Published

2019

52. Upwelling in the Ocean Basins North of the ACC: 1. On the Upwelling Exposed by the Surface Distribution of Δ14C

Author

Toggweiler, J. R., primary, Druffel, Ellen R. M., additional, Key, Robert M., additional, and Galbraith, Eric D., additional

Published

2019

53. The oceanic sink for anthropogenic CO 2 from 1994 to 2007

Author

Gruber, Nicolas, primary, Clement, Dominic, additional, Carter, Brendan R., additional, Feely, Richard A., additional, van Heuven, Steven, additional, Hoppema, Mario, additional, Ishii, Masao, additional, Key, Robert M., additional, Kozyr, Alex, additional, Lauvset, Siv K., additional, Lo Monaco, Claire, additional, Mathis, Jeremy T., additional, Murata, Akihiko, additional, Olsen, Are, additional, Perez, Fiz F., additional, Sabine, Christopher L., additional, Tanhua, Toste, additional, and Wanninkhof, Rik, additional

Published

2019

54. Dissociation constants for carbonic acid determined from field measurements

Author

Millero, Frank J., Pierrot, Denis, Lee, Kitack, Wanninkhof, Rik, Feely, Richard, Sabine, Christopher L., Key, Robert M., and Takahashi, Taro

Published

2002

55. Current CaCO3 dissolution at the seafloor caused by anthropogenic CO2

Author

non-UU output of UU-AW members, Sulpis, Olivier, Boudreau, Bernard P., Mucci, Alfonso, Jenkins, Chris, Trossman, David S., Arbic, Brian K., Key, Robert M., non-UU output of UU-AW members, Sulpis, Olivier, Boudreau, Bernard P., Mucci, Alfonso, Jenkins, Chris, Trossman, David S., Arbic, Brian K., and Key, Robert M.

Published

2018

56. A global monthly climatology of total alkalinity: a neural network approach

Author

Broullón, Daniel, Pérez, Fiz F., Velo, Antón, Hoppema, Mario, Olsen, Are, Takahashi, Taro, Key, Robert M., González-Dávila, Melchor, Tanhua, Toste, Jeansson, Emil, Kozyr, Alex, van Heuven, Steven M. A. C., Broullón, Daniel, Pérez, Fiz F., Velo, Antón, Hoppema, Mario, Olsen, Are, Takahashi, Taro, Key, Robert M., González-Dávila, Melchor, Tanhua, Toste, Jeansson, Emil, Kozyr, Alex, and van Heuven, Steven M. A. C.

Published

2018

57. A global monthly climatology of total alkalinity: a neural network approach (Discussions version) [Dataset]

Author

Ministerio de Economía y Competitividad (España), Broullón, Daniel, Pérez, Fiz F., Velo, A., Hoppema, Mario, Olsen, Are, Takahashi, Taro, Key, Robert M., González-Dávila, Melchor, Tanhua, Toste, Jeansson, Emil, Kozyr, Alex, van Heuven, Steven, Ministerio de Economía y Competitividad (España), Broullón, Daniel, Pérez, Fiz F., Velo, A., Hoppema, Mario, Olsen, Are, Takahashi, Taro, Key, Robert M., González-Dávila, Melchor, Tanhua, Toste, Jeansson, Emil, Kozyr, Alex, and van Heuven, Steven

Published

2018

58. Possible biological or physical explanations for decadal scale trends in North Pacific nutrient concentrations and oxygen utilization

Author

Keller, Klaus, Slater, Richard D., Bender, Michael, and Key, Robert M.

Published

2001

59. GLODAPv2.2020 - the second update of GLODAPv2.

Author

Olsen, Are, Lange, Nico, Key, Robert M., Tanhua, Toste, Bittig, Henry C., Kozyr, Alex, Àlvarez, Marta, Azetsu-Scott, Kumiko, Becker, Susan, Brown, Peter J., Carter, Brendan R., Cunha, Leticia Cotrim da, Feely, Richard A., Heuven, Steven van, Hoppema, Mario, Ishii, Masao, Jeansson, Emil, Jutterström, Sara, Landa, Camilla S., and Lauvset, Siv K.

Subjects

TRACERS (Chemistry), MEASUREMENT errors, INORGANIC chemistry, OCEAN bottom, WATER analysis

Abstract

The Global Ocean Data Analysis Project (GLODAP) is a synthesis effort providing regular compilations of surface to bottom ocean biogeochemical data, with an emphasis on seawater inorganic carbon chemistry and related variables determined through chemical analysis of water samples. GLODAPv2.2020 is an update of the previous version, GLODAPv2.2019. The major changes are: data from 106 more cruises added, extension of time coverage until 2019, and the inclusion of available discrete fugacity of CO2 (fCO2) values in the merged product files. GLODAPv2.2020 includes measurements from more than 1.2 million water samples from the global oceans collected on 946 cruises. The data for the 12 GLODAP core variables (salinity, oxygen, nitrate, silicate, phosphate, dissolved inorganic carbon, total alkalinity, pH, CFC-11, CFC-12, CFC-113, and CCl4) have undergone extensive quality control, especially systematic evaluation of bias. The data are available in two formats: (i) as submitted by the data originator but updated to WOCE exchange format and (ii) as a merged data product with adjustments applied to minimize bias. These adjustments were derived by comparing the data from the 106 new cruises with the data from the 840 quality-controlled cruises of the GLODAPv2.2019 data product. They correct for errors related to measurement, calibration, and data handling practices, while taking into account any known or likely time trends or variations in the variables evaluated. The compiled and adjusted data product is believed to be consistent to better than 0.005 in salinity, 1 % in oxygen, 2 % in nitrate, 2 % in silicate, 2 % in phosphate, 4 μmol kg-1 in dissolved inorganic carbon, 4 μmol kg-1 in total alkalinity, 0.01-0.02, depending on region, in pH, and 5 % in the halogenated transient tracers. The other variables included in the compilation, such as isotopic tracers and discrete fCO2 were not subjected to bias comparison or adjustments. The original data, their documentation and doi codes are available at the Ocean Carbon Data System of NOAA NCEI (https://www.nodc.noaa.gov/ocads/oceans/GLODAPv2%5F2020/, last access: 22 June 2020). This site also provides access to the merged data product, which is provided as a single global file and as four regional ones - the Arctic, Atlantic, Indian, and Pacific oceans - under https://doi.org/10.25921/2c8h-sa89 (Olsen et al., 2020). The bias corrected product files also include significant ancillary and approximated data. These were obtained by interpolation of, or calculation from, measured data. This living data update documents the GLODAPv2.2020 methods and provides a broad overview of the secondary quality control procedures and results. [ABSTRACT FROM AUTHOR]

Published

2020

60. Current CaCO 3 dissolution at the seafloor caused by anthropogenic CO 2

Author

Sulpis, Olivier, primary, Boudreau, Bernard P., additional, Mucci, Alfonso, additional, Jenkins, Chris, additional, Trossman, David S., additional, Arbic, Brian K., additional, and Key, Robert M., additional

Published

2018

61. A global monthly climatology of total alkalinity: a neural network approach

Author

Broullón, Daniel, primary, Pérez, Fiz F., additional, Velo, Antón, additional, Hoppema, Mario, additional, Olsen, Are, additional, Takahashi, Taro, additional, Key, Robert M., additional, González-Dávila, Melchor, additional, Tanhua, Toste, additional, Jeansson, Emil, additional, Kozyr, Alex, additional, and van Heuven, Seven M. A. C., additional

Published

2018

62. Supplementary material to "A global monthly climatology of total alkalinity: a neural network approach"

Author

Broullón, Daniel, primary, Pérez, Fiz F., additional, Velo, Antón, additional, Hoppema, Mario, additional, Olsen, Are, additional, Takahashi, Taro, additional, Key, Robert M., additional, González-Dávila, Melchor, additional, Tanhua, Toste, additional, Jeansson, Emil, additional, Kozyr, Alex, additional, and van Heuven, Seven M. A. C., additional

Published

2018

63. A new global interior ocean mapped climatology: the 1 degrees x 1 degrees GLODAP version 2

Author

Lauvset, Siv K., Key, Robert M., Olsen, Are, Van Heuven, Steven, Velo, Anton, Lin, Xiaohua, Schirnick, Carsten, Kozyr, Alex, Tanhua, Toste, Hoppema, Mario, Jutterstrom, Sara, Steinfeldt, Reiner, Jeansson, Emil, Ishii, Masao, Perez, Florian, Suzuki, Toru, and Watelet, Sylvain

Abstract

We present a mapped climatology (GLODAPv2.2016b) of ocean biogeochemical variables based on the new GLODAP version 2 data product (Olsen et al., 2016; Key et al., 2015), which covers all ocean basins over the years 1972 to 2013. The quality- controlled and internally consistent GLODAPv2 was used to create global 1 degrees x 1 degrees mapped climatologies of salinity, temperature, oxygen, nitrate, phosphate, silicate, total dissolved inorganic carbon (TCO2), total alkalinity (TAlk), pH, and CaCO3 saturation states using the DataInterpolating Variational Analysis (DIVA) mapping method. Improving on maps based on an earlier but similar dataset, GLODAPv1.1, this climatology also covers the Arctic Ocean. Climatologies were created for 33 standard depth surfaces. The conceivably confounding temporal trends in TCO2 and pH due to anthropogenic influence were removed prior to mapping by normalizing these data to the year 2002 using first- order calculations of anthropogenic carbon accumulation rates. We additionally provide maps of accumulated anthropogenic carbon in the year 2002 and of preindustrial TCO2. For all parameters, all data from the full 1972- 2013 period were used, including data that did not receive full secondary quality control. The GLODAPv2.2016b global 1 degrees x 1 degrees mapped climatologies, including error fields and ancillary information, are available at the GLODAPv2 web page at the Carbon Dioxide Information Analysis Center (CDIAC; doi: 10.3334/ CDIAC/ OTG. NDP093_ GLODAPv2).

Published

2016

64. Age Constraints on Gulf of Mexico Deep Water Ventilation as Determined by14C Measurements

Author

Chapman, Piers, primary, DiMarco, Steven F, additional, Key, Robert M, additional, Previti, Connie, additional, and Yvon-Lewis, Shari, additional

Published

2017

65. Global synthesis products enable quantification of the ocean carbon sink and ocean acidification

Author

Bakker, Dorothee C. E., Olsen, Are, O'Brien, Kevin M., Hoppema, Mario, Key, Robert M., Landa, Camilla S., Lauvset, Siv K., Kozyr, Alex, Metzl, Nicolas, Nojiri, Yukihiro, Pfeil, Benjamin, Rödenbeck, Christian, Schuster, Ute, Tilbrook, Bronte, van Heuven, Steven M. A. C., Wanninkhof, Rik H., Watson, Andrew J., (team), All International Socat, Glodap2 And Socom Contributors, University of East Anglia [Norwich] (UEA), University of Leeds, Joint Institute for the Study of the Atmosphere and Ocean (JISAO), University of Washington [Seattle], Bjerknes Centre for Climate Research (BCCR), Department of Biological Sciences [Bergen] (BIO / UiB), University of Bergen (UiB)-University of Bergen (UiB), Geophysical Institute [Bergen] (GFI / BiU), University of Bergen (UiB), Carbon Dioxide Information Analysis Center [Oak Ridge] (CDIAC), U.S. Department of Energy [Washington] (DOE), Équipe CO2 (E-CO2), Laboratoire d'Océanographie et du Climat : Expérimentations et Approches Numériques (LOCEAN), Institut de Recherche pour le Développement (IRD)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Muséum national d'Histoire naturelle (MNHN)-Institut Pierre-Simon-Laplace (IPSL (FR_636)), École normale supérieure - Paris (ENS Paris), 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)-Université Paris Diderot - Paris 7 (UPD7)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS Paris), 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)-Université Paris Diderot - Paris 7 (UPD7)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Muséum national d'Histoire naturelle (MNHN)-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)-Université Paris Diderot - Paris 7 (UPD7)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Max-Planck-Institut für Biogeochemie (MPI-BGC), College of Life and Environmental Sciences [Exeter], University of Exeter, Commonwealth Scientific and Industrial Research Organisation [Canberra] (CSIRO), Centre for Isotope Research [Groningen] (CIO), University of Groningen [Groningen], Muséum national d'Histoire naturelle (MNHN)-Institut de Recherche pour le Développement (IRD)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-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)-Université Paris Diderot - Paris 7 (UPD7)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS-PSL), and 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)-Université Paris Diderot - Paris 7 (UPD7)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Muséum national d'Histoire naturelle (MNHN)-Institut de Recherche pour le Développement (IRD)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Institut Pierre-Simon-Laplace (IPSL (FR_636))

Subjects

[PHYS.PHYS.PHYS-GEO-PH]Physics [physics]/Physics [physics]/Geophysics [physics.geo-ph], ComputingMilieux_MISCELLANEOUS

Abstract

International audience

Published

2015

66. Upwelling in the Ocean Basins North of the ACC: 1. On the Upwelling Exposed by the Surface Distribution of Δ14C.

Author

Toggweiler, J. R., Druffel, Ellen R. M., Key, Robert M., and Galbraith, Eric D.

Subjects

UPWELLING (Oceanography), OCEAN currents, OCEAN circulation, OCEAN temperature, RADIOISOTOPES

Abstract

The upwelling associated with the ocean's overturning circulation is hard to observe directly. Here, a large data set of surface Δ14C measurements is compiled in order to show where deep water is brought back up to the surface in the ocean basins north of the Antarctic Circumpolar Current (ACC). Maps constructed from the data set show that low‐Δ14C deep water from the ACC is drawn up to the surface in or near the upwelling zones off Northwest Africa and Namibia in the Atlantic, off Costa Rica and Peru in the Pacific, and in the northern Arabian Sea in the Indian Ocean. Deep water also seems to be reaching the surface in the subarctic Pacific gyre near the Kamchatka Peninsula. The low‐Δ14C water drawn up to the surface in the upwelling zones is also shown to spread across the ocean basins. It is easily seen, for example, in the western Atlantic off Florida and in the western Pacific off New Guinea and Palau. The spreading allows one to estimate the volumes of upwelling, which, it turns out, are similar to the volumes of large‐scale upwelling derived from inverse box models. This means that very large volumes of cool subsurface water are reaching the surface in and near the upwelling zones—much larger volumes than would be expected from the local winds. Plain Language Summary: The deep layers of the ocean are filled with cold dense water that sinks from the surface near Antarctica and in the northern North Atlantic. This process is understood reasonably well. The countervailing process—the way that the dense water is brought back up to the surface—is not as well understood. Oceanographers now agree that the ocean's deep water is drawn back up to the surface ("upwelled") mainly around Antarctica as part of the wind‐driven overturning in the Antarctic Circumpolar Current (ACC). But cool water is also known to reach the surface in upwelling zones around the ocean's margins. Here we map the upwelling north of the ACC with the radioactive isotope carbon‐14 and show that the deep water upwelled to the surface around Antarctica seems to be drawn up to the surface a second time in the upwelling zones. The water drawn up to the surface in the upwelling zones then flows back to the North Atlantic and sinks again to complete the cycle. Key Points: Low‐delta14C surface waters are found in upwelling zones along the margins and in the subarctic Pacific gyreThe low‐delta14C water in most of the upwelling zones appears to be mode or intermediate water from the ACCThe volumes of upwelling in these areas exceed the volumes that would be drawn up to the surface by the local winds [ABSTRACT FROM AUTHOR]

Published

2019

67. The Global Ocean Data Analysis Project version 2 (GLODAPv2) - an internally consistent data product for the world ocean

Author

Olsen, Are, Key, Robert M., Van Heuven, Steven, Lauvset, Siv K., Velo, Anton, Lin, Xiaohua, Schirnick, Carsten, Kozyr, Alex, Tanhua, Toste, Hoppema, Mario, Jutterstrom, Sara, Steinfeldt, Reiner, Jeansson, Emil, Ishii, Masao, Perez, Florian, Suzuki, Toru, Olsen, Are, Key, Robert M., Van Heuven, Steven, Lauvset, Siv K., Velo, Anton, Lin, Xiaohua, Schirnick, Carsten, Kozyr, Alex, Tanhua, Toste, Hoppema, Mario, Jutterstrom, Sara, Steinfeldt, Reiner, Jeansson, Emil, Ishii, Masao, Perez, Florian, and Suzuki, Toru

Abstract

Version 2 of the Global Ocean Data Analysis Project (GLODAPv2) data product is composed of data from 724 scientific cruises covering the global ocean. It includes data assembled during the previous efforts GLODAPv1.1 ( Global Ocean Data Analysis Project version 1.1) in 2004, CARINA (CARbon IN the Atlantic) in 2009/2010, and PACIFICA (PACIFic ocean Interior CArbon) in 2013, as well as data from an additional 168 cruises. Data for 12 core variables ( salinity, oxygen, nitrate, silicate, phosphate, dissolved inorganic carbon, total alkalinity, pH, CFC-11, CFC-12, CFC-113, and CCl4) have been subjected to extensive quality control, including systematic evaluation of bias. The data are available in two formats: (i) as submitted but updated to WOCE exchange format and (ii) as a merged and internally consistent data product. In the latter, adjustments have been applied to remove significant biases, respecting occurrences of any known or likely time trends or variations. Adjustments applied by previous efforts were re-evaluated. Hence, GLODAPv2 is not a simple merging of previous products with some new data added but a unique, internally consistent data product. This compiled and adjusted data product is believed to be consistent to better than 0.005 in salinity, 1% in oxygen, 2% in nitrate, 2% in silicate, 2% in phosphate, 4 mu mol kg(-1) in dissolved inorganic carbon, 6 mu mol kg(-1) in total alkalinity, 0.005 in pH, and 5% for the halogenated transient tracers. The original data and their documentation and doi codes are available at the Carbon Dioxide Information Analysis Center (http://cdiac.ornl.gov/oceans/GLODAPv2/). This site also provides access to the calibrated data product, which is provided as a single global file or four regional ones - the Arctic, Atlantic, Indian, and Pacific oceans - under the doi: 10.3334/CDIAC/OTG.NDP093_GLODAPv2. The product files also include significant ancillary and approximated data. These were obtained by interpolation of, or calcula

Published

2016

68. Changes in ocean heat, carbon content, and ventilation : a review of the first decade of GO-SHIP Global Repeat Hydrography

Author

Talley, Lynne D., Feely, Richard A., Sloyan, Bernadette M., Wanninkhof, Rik, Baringer, Molly O., Bullister, John L., Carlson, Craig A., Doney, Scott C., Fine, Rana A., Firing, Eric, Gruber, Nicolas, Hansell, Dennis A., Ishii, Masayoshi, Johnson, Gregory, Katsumata, K., Key, Robert M., Kramp, Martin, Langdon, Chris, Macdonald, Alison M., Mathis, Jeremy T., McDonagh, Elaine L., Mecking, Sabine, Millero, Frank J., Mordy, Calvin W., Nakano, T., Sabine, Chris L., Smethie, William M., Swift, James H., Tanhua, Toste, Thurnherr, Andreas M., Warner, Mark J., Zhang, Jia-Zhong, Talley, Lynne D., Feely, Richard A., Sloyan, Bernadette M., Wanninkhof, Rik, Baringer, Molly O., Bullister, John L., Carlson, Craig A., Doney, Scott C., Fine, Rana A., Firing, Eric, Gruber, Nicolas, Hansell, Dennis A., Ishii, Masayoshi, Johnson, Gregory, Katsumata, K., Key, Robert M., Kramp, Martin, Langdon, Chris, Macdonald, Alison M., Mathis, Jeremy T., McDonagh, Elaine L., Mecking, Sabine, Millero, Frank J., Mordy, Calvin W., Nakano, T., Sabine, Chris L., Smethie, William M., Swift, James H., Tanhua, Toste, Thurnherr, Andreas M., Warner, Mark J., and Zhang, Jia-Zhong

Abstract

Author Posting. © The Author(s), 2015. This is the author's version of the work. It is posted here for personal use, not for redistribution. The definitive version was published in Annual Review of Marine Science 8 (2016): 185-215, doi:10.1146/annurev-marine-052915-100829., The ocean, a central component of Earth’s climate system, is changing. Given the global scope of these changes, highly accurate measurements of physical and biogeochemical properties need to be conducted over the full water column, spanning the ocean basins from coast to coast, and repeated every decade at a minimum, with a ship-based observing system. Since the late 1970s, when the Geochemical Ocean Sections Study (GEOSECS) conducted the first global survey of this kind, the World Ocean Circulation Experiment (WOCE) and Joint Global Ocean Flux Study (JGOFS), and now the Global Ocean Ship-based Hydrographic Investigations Program (GO-SHIP) have collected these “reference standard” data that allow quantification of ocean heat and carbon uptake, and variations in salinity, oxygen, nutrients, and acidity on basin scales. The evolving GO-SHIP measurement suite also provides new global information about dissolved organic carbon, a large bioactive reservoir of carbon., Climate Observations Division of the U.S. NOAA Climate Program Office and NOAA Research; Joint Institute for the Study of the Atmosphere and Ocean (JISAO) under NOAA Cooperative Agreement NA10OAR4320148; U.S. National Science Foundation [OCE- 0223869; OCE-0752970; OCE-0825163; OCE-1434000; OCE 0752972; OCE-0752980; OCE-1232962; OCE-1155983; OCE-1436748]; U.S. CLIVAR Project Office; Global Environment and Marine Department, Japan Meteorological Agency; Australian Climate Change Science Program (Australian Department of Environment and CSIRO); U.K. Natural Environment Research Council; European Union’s FP7 grant agreement 264879 (CarboChange); Horizon 2020 grant agreement No 633211; ETH Zurich Switzerland.

Published

2016

69. The formation of the ocean’s anthropogenic carbon reservoir

Author

Iudicone, Daniele, Rodgers, Keith B., Plancherel, Yves, Aumont, Olivier, Ito, Takamitsu, Key, Robert M., Madec, Gurvan, Ishii, Masao, Iudicone, Daniele, Rodgers, Keith B., Plancherel, Yves, Aumont, Olivier, Ito, Takamitsu, Key, Robert M., Madec, Gurvan, and Ishii, Masao

Abstract

The shallow overturning circulation of the oceans transports heat from the tropics to the mid-latitudes. This overturning also influences the uptake and storage of anthropogenic carbon (Cant). We demonstrate this by quantifying the relative importance of ocean thermodynamics, circulation and biogeochemistry in a global biochemistry and circulation model. Almost 2/3 of the Cant ocean uptake enters via gas exchange in waters that are lighter than the base of the ventilated thermocline. However, almost 2/3 of the excess Cant is stored below the thermocline. Our analysis shows that subtropical waters are a dominant component in the formation of subpolar waters and that these water masses essentially form a common Cant reservoir. This new method developed and presented here is intrinsically Lagrangian, as it by construction only considers the velocity or transport of waters across isopycnals. More generally, our approach provides an integral framework for linking ocean thermodynamics with biogeochemistry.

Published

2016

70. The formation of the ocean’s anthropogenic carbon reservoir

Author

Iudicone, Daniele, primary, Rodgers, Keith B., additional, Plancherel, Yves, additional, Aumont, Olivier, additional, Ito, Takamitsu, additional, Key, Robert M., additional, Madec, Gurvan, additional, and Ishii, Masao, additional

Published

2016

71. A new global interior ocean mapped climatology: the 1° × 1° GLODAP version 2

Author

Lauvset, Siv K., primary, Key, Robert M., additional, Olsen, Are, additional, van Heuven, Steven, additional, Velo, Anton, additional, Lin, Xiaohua, additional, Schirnick, Carsten, additional, Kozyr, Alex, additional, Tanhua, Toste, additional, Hoppema, Mario, additional, Jutterström, Sara, additional, Steinfeldt, Reiner, additional, Jeansson, Emil, additional, Ishii, Masao, additional, Perez, Fiz F., additional, Suzuki, Toru, additional, and Watelet, Sylvain, additional

Published

2016

72. The Global Ocean Data Analysis Project version 2 (GLODAPv2) – an internally consistent data product for the world ocean

Author

Olsen, Are, primary, Key, Robert M., additional, van Heuven, Steven, additional, Lauvset, Siv K., additional, Velo, Anton, additional, Lin, Xiaohua, additional, Schirnick, Carsten, additional, Kozyr, Alex, additional, Tanhua, Toste, additional, Hoppema, Mario, additional, Jutterström, Sara, additional, Steinfeldt, Reiner, additional, Jeansson, Emil, additional, Ishii, Masao, additional, Pérez, Fiz F., additional, and Suzuki, Toru, additional

Published

2016

73. Current CaCO3 dissolution at the seafloor caused by anthropogenic CO2.

Author

Sulpis, Olivier, Boudreau, Bernard P., Mucci, Alfonso, Jenkins, Chris, Trossman, David S., Arbic, Brian K., and Key, Robert M.

Subjects

OCEAN bottom, CALCIUM carbonate, WATER chemistry, BENTHIC ecology, OCEAN acidification

Abstract

Oceanic uptake of anthropogenic CO2 leads to decreased pH, carbonate ion concentration, and saturation state with respect to CaCO3 minerals, causing increased dissolution of these minerals at the deep seafloor. This additional dissolution will figure prominently in the neutralization of man-made CO2. However, there has been no concerted assessment of the current extent of anthropogenic CaCO3. dissolution at the deep seafloor. Here, recent databases of bottom-water chemistry, benthic currents, and CaCO3. content of deep-sea sediments are combined with a rate model to derive the global distribution of benthic calcite dissolution rates and obtain primary confirmation of an anthropogenic component. By comparing preindustrial with present-day rates, we determine that significant anthropogenic dissolution now occurs in the western North Atlantic, amounting to 40-100% of the total seafloor dissolution at its most intense locations. At these locations, the calcite compensation depth has risen ~300 m. Increased benthic dissolution was also revealed at various hot spots in the southern extent of the Atlantic, Indian, and Pacific Oceans. Our findings place constraints on future predictions of ocean acidification, are consequential to the fate of benthic calcifiers, and indicate that a by-product of human activities is currently altering the geological record of the deep sea. [ABSTRACT FROM AUTHOR]

Published

2018

74. Biology and air-sea gas exchange controls on the distribution of carbon isotope ratios (delta C-13) in the ocean

Author

Schmittner, Andreas, Gruber, Nicolas, Mix, Alan C., Key, Robert M., Tagliabue, Alessandro, and Westberry, Toby K.

Abstract

Analysis of observations and sensitivity experiments with a new three-dimensional global model of stable carbon isotope cycling elucidate processes that control the distribution of δ13C of dissolved inorganic carbon (DIC) in the contemporary and preindustrial ocean. Biological fractionation and the sinking of isotopically light δ13C organic matter from the surface into the interior ocean leads to low δ13CDIC values at depths and in high latitude surface waters and high values in the upper ocean at low latitudes with maxima in the subtropics. Air–sea gas exchange has two effects. First, it acts to reduce the spatial gradients created by biology. Second, the associated temperature-dependent fractionation tends to increase (decrease) δ13CDIC values of colder (warmer) water, which generates gradients that oppose those arising from biology. Our model results suggest that both effects are similarly important in influencing surface and interior δ13CDIC distributions. However, since air–sea gas exchange is slow in the modern ocean, the biological effect dominates spatial δ13CDIC gradients both in the interior and at the surface, in contrast to conclusions from some previous studies. Calcium carbonate cycling, pH dependency of fractionation during air–sea gas exchange, and kinetic fractionation have minor effects on δ13CDIC. Accumulation of isotopically light carbon from anthropogenic fossil fuel burning has decreased the spatial variability of surface and deep δ13CDIC since the industrial revolution in our model simulations. Analysis of a new synthesis of δ13CDIC measurements from years 1990 to 2005 is used to quantify preformed and remineralized contributions as well as the effects of biology and air–sea gas exchange. The model reproduces major features of the observed large-scale distribution of δ13CDIC as well as the individual contributions and effects. Residual misfits are documented and analyzed. Simulated surface and subsurface δ13CDIC are influenced by details of the ecosystem model formulation. For example, inclusion of a simple parameterization of iron limitation of phytoplankton growth rates and temperature-dependent zooplankton grazing rates improves the agreement with δ13CDIC observations and satellite estimates of phytoplankton growth rates and biomass, suggesting that δ13C can also be a useful test of ecosystem models. ISSN:1726-4170 ISSN:1726-4170

Published

2013

75. Evaluation of changes in global pH and CaCO3 from WOCE to CLIVAR

Author

Lauvset, Siv K., Olsen, Are, Key, Robert M., Lin, Xiaohua, Tanhua, Toste, Hoppema, Mario, Jutterström, Sara, Steinfeldt, Reiner, Jeansson, Emil, van Heuven, Steven, Ishii, Masao, Suzuki, Toru, Velo, Anton, Kozyr, Alexander, Pfeil, Benjamin, Schirnick, Carsten, Lauvset, Siv K., Olsen, Are, Key, Robert M., Lin, Xiaohua, Tanhua, Toste, Hoppema, Mario, Jutterström, Sara, Steinfeldt, Reiner, Jeansson, Emil, van Heuven, Steven, Ishii, Masao, Suzuki, Toru, Velo, Anton, Kozyr, Alexander, Pfeil, Benjamin, and Schirnick, Carsten

Published

2014

76. Presenting GLODAPv2, ocean biogeochemical time trends and future plans

Author

Olsen, Are, Key, Robert M., Lauvset, Siv K., Lin, Xiaohua, Tanhua, Toste, van Heuven, Steven, Hoppema, Mario, Jutterström, Sara, Steinfeldt, Reiner, Jeansson, Emil, Ishii, Masao, Suzuki, Toru, Velo, Anton, Kozyr, Alexander, Pfeil, Benjamin, Schirnick, Carsten, Olsen, Are, Key, Robert M., Lauvset, Siv K., Lin, Xiaohua, Tanhua, Toste, van Heuven, Steven, Hoppema, Mario, Jutterström, Sara, Steinfeldt, Reiner, Jeansson, Emil, Ishii, Masao, Suzuki, Toru, Velo, Anton, Kozyr, Alexander, Pfeil, Benjamin, and Schirnick, Carsten

Published

2014

77. An empirical estimate of the Southern Ocean air-sea CO2 flux

Author

Mcneil, Ben I., Metzl, Nicolas, Key, Robert M., Matear, Richard J., Corbière, Antoine, Laboratoire d'Océanographie et du Climat : Expérimentations et Approches Numériques (LOCEAN), Muséum national d'Histoire naturelle (MNHN)-Institut de Recherche pour le Développement (IRD)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-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)-Université Paris Diderot - Paris 7 (UPD7)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-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)-Université Paris Diderot - Paris 7 (UPD7)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Institut de Recherche pour le Développement (IRD)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Muséum national d'Histoire naturelle (MNHN)-Institut Pierre-Simon-Laplace (IPSL (FR_636)), École normale supérieure - Paris (ENS Paris), and 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)-Université Paris Diderot - Paris 7 (UPD7)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS Paris)

Subjects

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

Abstract

International audience

Published

2007

78. Low helium flux from the mantle inferred from simulations of oceanic helium isotope data

Author

Bianchi, Daniele, Sarmiento, Jorge L., Gnanadesikan, Anand, Key, Robert M., Schlosser, Peter, and Newton, Robert

Published

2010

79. GLODAPv2 – a global and quality controlled ocean biogeochemical data product

Author

Lauvset, Siv Kari, Key, Robert M., Olsen, Are, Tanhua, Toste, Hoppema, Mario, Jutterström, Sara, Steinfeldt, Reiner, Jeansson, Emil, Kozyr, Alexander, Pfeil, Benjamin, Suzuki, Toru, Ishii, Masao, Lauvset, Siv Kari, Key, Robert M., Olsen, Are, Tanhua, Toste, Hoppema, Mario, Jutterström, Sara, Steinfeldt, Reiner, Jeansson, Emil, Kozyr, Alexander, Pfeil, Benjamin, Suzuki, Toru, and Ishii, Masao

Published

2013

80. Report from the Working Group on Model Development and Data Assimilation

Author

Beismann, Jens-Olaf, Baringer, Molly, Doney, Scott, Gnanadesikan, Anand, Key, Robert M., Monfray, Patrice, Orr, James, Richards, Kelvin, Rintoul, Steven, Sloyan, Bernadette, Spall, Steve, Staneva, Johanna, Volker, Christopher, Wallace, Douglas W.R., Wanninkhof, Rik, Wijffels, Susan, and Wolf-Gladrow, Dieter

Published

2001

81. A model of the Arctic Ocean carbon cycle

Author

Manizza, Manfredi, Follows, Michael J., Dutkiewicz, Stephanie, Menemenlis, Dimitris, McClelland, James W., Hill, C. N., Peterson, Bruce J., Key, Robert M., Manizza, Manfredi, Follows, Michael J., Dutkiewicz, Stephanie, Menemenlis, Dimitris, McClelland, James W., Hill, C. N., Peterson, Bruce J., and Key, Robert M.

Abstract

Author Posting. © American Geophysical Union, 2011. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research 116 (2011): C12020, doi:10.1029/2011JC006998., A three dimensional model of Arctic Ocean circulation and mixing, with a horizontal resolution of 18 km, is overlain by a biogeochemical model resolving the physical, chemical and biological transport and transformations of phosphorus, alkalinity, oxygen and carbon, including the air-sea exchange of dissolved gases and the riverine delivery of dissolved organic carbon. The model qualitatively captures the observed regional and seasonal trends in surface ocean PO4, dissolved inorganic carbon, total alkalinity, and pCO2. Integrated annually, over the basin, the model suggests a net annual uptake of 59 Tg C a−1, within the range of published estimates based on the extrapolation of local observations (20–199 Tg C a−1). This flux is attributable to the cooling (increasing solubility) of waters moving into the basin, mainly from the subpolar North Atlantic. The air-sea flux is regulated seasonally and regionally by sea-ice cover, which modulates both air-sea gas transfer and the photosynthetic production of organic matter, and by the delivery of riverine dissolved organic carbon (RDOC), which drive the regional contrasts in pCO2 between Eurasian and North American coastal waters. Integrated over the basin, the delivery and remineralization of RDOC reduces the net oceanic CO2 uptake by ~10%., This study has been carried out as part of ECCO2 and SASS (Synthesis of the Arctic System Science) projects funded by NASA and NSF, respectively. MM and MJF are grateful for support from the National Science Foundation (ARC-0531119 and ARC-0806229) for financial support. MM also acknowledges NASA for providing computer time, the use of the computing facilities at NAS center and also the Scripps post-doctoral program for further financial support that helped to complete the manuscript. RMK also acknowledges NOAA for support (NA08OAR4310820 and NA08OAR4320752)., 2012-06-15

Published

2012

82. Moving from GLODAP, CARINA and PACIFICA to the Global Ocean Data Analysis v2, GLODAPv2

Author

Olsen, Are, Key, Robert M., Tanhua, Toste, Hoppema, Mario, Lauvset, Siv, Jutterström, Sara, Kozyr, Alexander, Steinfeldt, Reiner, Jeansson, Emil, Pfeil, Benjamin, Ishi, Masao, Suzuki, Toru, Olsen, Are, Key, Robert M., Tanhua, Toste, Hoppema, Mario, Lauvset, Siv, Jutterström, Sara, Kozyr, Alexander, Steinfeldt, Reiner, Jeansson, Emil, Pfeil, Benjamin, Ishi, Masao, and Suzuki, Toru

Published

2012

83. Total alkalinity estimation using MLR and neural network techniques

Author

Velo, A., Pérez, Fiz F., Tanhua, Toste, Gilcoto, Miguel, Ríos, Aida F., Key, Robert M., Velo, A., Pérez, Fiz F., Tanhua, Toste, Gilcoto, Miguel, Ríos, Aida F., and Key, Robert M.

Abstract

During the last decade, two important collections of carbon relevant hydrochemical data have become available: GLODAP and CARINA. These collections comprise a synthesis of bottle data for all ocean depths from many cruises collected over several decades. For a majority of the cruises at least two carbon parameters were measured. However, for a large number of stations, samples or even cruises, the carbonate system is under-determined (i.e., only one or no carbonate parameterwas measured) resulting in data gaps for the carbonate system in these collections. A method for filling these gaps would be very useful, as it would help with estimations of the anthropogenic carbon (Cant) content or quantification of oceanic acidification. The aim of this work is to apply and describe, a 3D moving window multilinear regression algorithm (MLR) to fill gaps in total alkalinity (AT) of the CARINA and GLODAP data collections for the Atlantic. In addition to filling data gaps, the estimated AT values derived from the MLR are useful in quality control of the measurements of the carbonate system, as they can aid in the identification of outliers. For comparison, a neural network algorithm able to performnon-linear predictionswas also designed. The goal herewas to design an alternative approach to accomplish the sametask of filling AT gaps. Bothmethods return internally consistent results, thereby giving confidence in our approach.

Published

2012

84. Using altimetry to help explain patchy changes in hydrographic carbon measurements

Author

Rodgers, Keith B., Key, Robert M., Gnanadesikan, Anand, Sarmiento, Jorge L., Aumont, Olivier, Bopp, Laurent, Doney, Scott C., Dunne, John P., Glover, David M., Ishida, Akio, Ishii, Masao, Jacobson, Andrew R., Monaco, Claire Lo, Maier-Reimer, Ernst, Mercier, Herlé, Metzl, Nicolas, Perez, Fiz F., Rios, Aida F., Wanninkhof, Rik, Wetzel, Patrick, Winn, Christopher D., Yamanaka, Yasuhiro, Rodgers, Keith B., Key, Robert M., Gnanadesikan, Anand, Sarmiento, Jorge L., Aumont, Olivier, Bopp, Laurent, Doney, Scott C., Dunne, John P., Glover, David M., Ishida, Akio, Ishii, Masao, Jacobson, Andrew R., Monaco, Claire Lo, Maier-Reimer, Ernst, Mercier, Herlé, Metzl, Nicolas, Perez, Fiz F., Rios, Aida F., Wanninkhof, Rik, Wetzel, Patrick, Winn, Christopher D., and Yamanaka, Yasuhiro

Abstract

Author Posting. © American Geophysical Union, 2009. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research 114 (2009): C09013, doi:10.1029/2008JC005183., Here we use observations and ocean models to identify mechanisms driving large seasonal to interannual variations in dissolved inorganic carbon (DIC) and dissolved oxygen (O2) in the upper ocean. We begin with observations linking variations in upper ocean DIC and O2 inventories with changes in the physical state of the ocean. Models are subsequently used to address the extent to which the relationships derived from short-timescale (6 months to 2 years) repeat measurements are representative of variations over larger spatial and temporal scales. The main new result is that convergence and divergence (column stretching) attributed to baroclinic Rossby waves can make a first-order contribution to DIC and O2 variability in the upper ocean. This results in a close correspondence between natural variations in DIC and O2 column inventory variations and sea surface height (SSH) variations over much of the ocean. Oceanic Rossby wave activity is an intrinsic part of the natural variability in the climate system and is elevated even in the absence of significant interannual variability in climate mode indices. The close correspondence between SSH and both DIC and O2 column inventories for many regions suggests that SSH changes (inferred from satellite altimetry) may prove useful in reducing uncertainty in separating natural and anthropogenic DIC signals (using measurements from Climate Variability and Predictability's CO2/Repeat Hydrography program)., This report was prepared by K.B.R. under awards NA17RJ2612 and NA08OAR4320752, which includes support through the NOAA Office of Climate Observations (OCO). The statements, findings, conclusions, and recommendations are those of the authors and do not necessarily reflect the views of the National Oceanic and Atmospheric Administration or the U.S. Department of Commerce. Support for K.B.R. was also provided by the Carbon Mitigation Initiative (CMI) through the support of BP, Amaco, and Ford. R.M.K. was supported by NOAA grants NA17RJ2612, NA08OAR4320752, and NA08OAR4310820. F.F.P. was supported by the European Union FP6 CARBOOCEAN Integrated project (contract 51176), the French OVIDE project, and the Spanish Salvador de Madariaga program (PR2006– 0523). This work was also supported by the European NOCES project (EVK2-CT201-00134). Y.Y. and A.I. are partly supported by CREST, JST of Japan. The long-term OISO observational program in the South Indian Ocean is supported by the following three French institutes: INSU (Institut National des Sciences de l’Univers), IPSL (Institute Pierre-Simon Laplace), and IPEV (Institut Paul-Emile Victor).

Published

2010

85. Correction to “Using altimetry to help explain patchy changes in hydrographic carbon measurements”

Author

Rodgers, Keith B., Key, Robert M., Gnanadesikan, Anand, Sarmiento, Jorge L., Aumont, Olivier, Bopp, Laurent, Doney, Scott C., Dunne, John P., Glover, David M., Ishida, Akio, Ishii, Masao, Jacobson, Andrew R., Monaco, Claire Lo, Maier-Reimer, Ernst, Mercier, Herlé, Metzl, Nicolas, Perez, Fiz F., Rios, Aida F., Wanninkhof, Rik, Wetzel, Patrick, Winn, Christopher D., Yamanaka, Yasuhiro, Rodgers, Keith B., Key, Robert M., Gnanadesikan, Anand, Sarmiento, Jorge L., Aumont, Olivier, Bopp, Laurent, Doney, Scott C., Dunne, John P., Glover, David M., Ishida, Akio, Ishii, Masao, Jacobson, Andrew R., Monaco, Claire Lo, Maier-Reimer, Ernst, Mercier, Herlé, Metzl, Nicolas, Perez, Fiz F., Rios, Aida F., Wanninkhof, Rik, Wetzel, Patrick, Winn, Christopher D., and Yamanaka, Yasuhiro

Abstract

Author Posting. © American Geophysical Union, 2009. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research 114 (2009): C12099, doi:10.1029/2009JC005835.

Published

2010

86. Evaluation of ocean carbon cycle models with data-based metrics

Author

Matsumoto, K., Sarmiento, Jorge L., Key, Robert M., Aumont, Olivier, Bullister, John L., Caldeira, Ken, Campin, J.-M., Doney, Scott C., Drange, Helge, Dutay, J.-C., Follows, Michael J., Gao, Y., Gnanadesikan, Anand, Gruber, Nicolas, Ishida, Akio, Joos, Fortunat, Lindsay, Keith, Maier-Reimer, Ernst, Marshall, John C., Matear, Richard J., Monfray, Patrick, Mouchet, Anne, Najjar, Raymond G., Plattner, Gian-Kasper, Schlitzer, Reiner, Slater, Richard D., Swathi, P. S., Totterdell, Ian J., Weirig, Marie-France, Yamanaka, Yasuhiro, Yool, Andrew, Orr, James C., Matsumoto, K., Sarmiento, Jorge L., Key, Robert M., Aumont, Olivier, Bullister, John L., Caldeira, Ken, Campin, J.-M., Doney, Scott C., Drange, Helge, Dutay, J.-C., Follows, Michael J., Gao, Y., Gnanadesikan, Anand, Gruber, Nicolas, Ishida, Akio, Joos, Fortunat, Lindsay, Keith, Maier-Reimer, Ernst, Marshall, John C., Matear, Richard J., Monfray, Patrick, Mouchet, Anne, Najjar, Raymond G., Plattner, Gian-Kasper, Schlitzer, Reiner, Slater, Richard D., Swathi, P. S., Totterdell, Ian J., Weirig, Marie-France, Yamanaka, Yasuhiro, Yool, Andrew, and Orr, James C.

Abstract

Author Posting. © American Geophysical Union, 2004. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Geophysical Research Letters 31 (2004): L07303, doi:10.1029/2003GL018970., New radiocarbon and chlorofluorocarbon-11 data from the World Ocean Circulation Experiment are used to assess a suite of 19 ocean carbon cycle models. We use the distributions and inventories of these tracers as quantitative metrics of model skill and find that only about a quarter of the suite is consistent with the new data-based metrics. This should serve as a warning bell to the larger community that not all is well with current generation of ocean carbon cycle models. At the same time, this highlights the danger in simply using the available models to represent the state-of-the-art modeling without considering the credibility of each model., K. Matsumoto was supported by NSF grants OCE-9819144 and OCE0097316.

Published

2010

87. Quality control procedures and methods of the CARINA database

Author

Tanhua, Toste, van Heuven, Steven, Key, Robert M., Velo, A., Olsen, Are, Schirnick, Carsten, Tanhua, Toste, van Heuven, Steven, Key, Robert M., Velo, A., Olsen, Are, and Schirnick, Carsten

Abstract

Data on the carbon and carbon relevant hydrographic and hydrochemical parameters from previously not publicly available cruises in the Arctic, Atlantic and Southern Ocean have been retrieved and merged to a new data base: CARINA (CARbon IN the Atlantic). These data have gone through rigorous quality control (QC) procedures to assure the highest possible quality and consistency. All CARINA data were subject to primary QC; a process in which data are studied in order to identify outliers and obvious errors. Additionally, secondary QC was performed for several of the measured parameters in the CARINA data base. Secondary QC is a process in which the data are objectively studied in order to quantify systematic differences in the reported values. This process involved crossover analysis, and as a second step the offsets derived from the crossover analysis were used to calculate corrections of the parameters measured on individual cruises using least square models. Significant biases found in the data have been corrected in the data products, i.e. three merged data files containing measured, calculated and interpolated data for each of the three regions (i.e. Arctic Mediterranean Seas, Atlantic, and Southern Ocean). Here we report on the technical details of the quality control and on tools that have been developed and used during the project, including procedures for crossover analysis and least square models. Furthermore, an interactive website for uploading of results, plots, comments etc. was developed and was of critical importance for the success of the project, this is also described here.

Published

2010

88. CARINA data synthesis project: pH data scale unification and cruise adjustments

Author

Velo, A., Pérez, Fiz F., Lin, X., Key, Robert M., Tanhua, Toste, Paz, M. de la, Olsen, Are, van Heuven, Steven, Jutterström, S., Ríos, Aida F., Velo, A., Pérez, Fiz F., Lin, X., Key, Robert M., Tanhua, Toste, Paz, M. de la, Olsen, Are, van Heuven, Steven, Jutterström, S., and Ríos, Aida F.

Abstract

Data on carbon and carbon-relevant hydrographic and hydrochemical parameters from 188 previously non-publicly available cruise data sets in the Artic Mediterranean Seas (AMS), Atlantic Ocean and Southern Ocean have been retrieved and merged to a new database: CARINA (CARbon IN the Atlantic Ocean). These data have gone through rigorous quality control (QC) procedures to assure the highest possible quality and consistency. The data for most of the measured parameters in the CARINA database were objectively examined in order to quantify systematic differences in the reported values. Systematic biases found in the data have been corrected in the data products, three merged data files with measured, calculated and interpolated data for each of the three CARINA regions; AMS, Atlantic Ocean and Southern Ocean. Out of a total of 188 cruise entries in the CARINA database, 59 reported pH measured values. All reported pH data have been unified to the Sea-Water Scale (SWS) at 25 °C. Here we present details of the secondary QC of pH in the CARINA database and the scale unification to SWS at 25 °C. The pH scale has been converted for 36 cruises. Procedures of quality control, including crossover analysis between cruises and inversion analysis are described. Adjustments were applied to the pH values for 21 of the cruises in the CARINA dataset. With these adjustments the CARINA database is consistent both internally as well as with the GLODAP data, an oceanographic data set based on the World Hydrographic Program in the 1990s. Based on our analysis we estimate the internal consistency of the CARINA pH data to be 0.005 pH units. The CARINA data are now suitable for accurate assessments of, for example, oceanic carbon inventories and uptake rates, for ocean acidification assessment and for model validation.

Published

2010

89. The CARINA data synthesis project: introduction and overview

Author

Key, Robert M., Velo, A., Key, Robert M., and Velo, A.

Abstract

The original goal of the CARINA (Carbon in Atlantic Ocean) data synthesis project was to create a merged calibrated data set from open ocean subsurface measurements by European scientists that would be generally useful for biogeochemical investigations in the North Atlantic and in particular, studies involving the carbon system. Over time the geographic extent expanded to include the entire Atlantic, the Arctic and the Southern Ocean and the international collaboration broadened significantly. In this paper we give a brief history of the project, a general overview of data included and an outline of the procedures used during the synthesis. The end result of this project was a set of 3 data products, one for each of the listed ocean regions. It is critical that anyone who uses any of the CARINA data products recognize that the data products are not simply concatenations of the originally measured values. Rather, the data have been through an extensive calibration procedure designed to remove measurement bias and bad data. Also a significant fraction of the individual values in the data products were derived either by direct calculation or some means of approximation. These data products were constructed for basin scale biogeochemical investigations and may be inappropriate for investigations involving small areal extent or similar detailed analyses. More information on specific parts of this project can be found in companion articles in this issue. In particular, Tanhua et al. (2010) and Tanhua (2009) describe the procedures and software used to remove measurement bias from the original data. The three data products and a significant volume of supporting information are available from the CARINA web site hosted by the Carbon Dioxide Information Analysis Center (CDIAC: http://cdiac.esd.ornl.gov/oceans/CARINA/Carina_inv.html). Anyone wanting to use the data is advised to get the highest version number of each data product. Incremental versions represent either correct

Published

2010

90. Using altimetry to help explain patchy changes in hydrographic carbon measurements

Author

Rodgers, Keith B., Key, Robert M., Gnanadesikan, Anand, Sarmiento, Jorge L., Aumont, Olivier, Bopp, Laurent, Doney, Scott C., Dunne, John P., Glover, David M., Ishida, Akio, Ishii, Masao, Jacobson, Andrew R., Lo Monaco, Claire, Maier-reimer, Ernst, Mercier, Herle, Metzl, Nicolas, Perez, Fiz F., Rios, Aida F., Wanninkhof, Rik, Wetzel, Patrick, Winn, Christopher D., Yamanaka, Yasuhiro, Rodgers, Keith B., Key, Robert M., Gnanadesikan, Anand, Sarmiento, Jorge L., Aumont, Olivier, Bopp, Laurent, Doney, Scott C., Dunne, John P., Glover, David M., Ishida, Akio, Ishii, Masao, Jacobson, Andrew R., Lo Monaco, Claire, Maier-reimer, Ernst, Mercier, Herle, Metzl, Nicolas, Perez, Fiz F., Rios, Aida F., Wanninkhof, Rik, Wetzel, Patrick, Winn, Christopher D., and Yamanaka, Yasuhiro

Abstract

Here we use observations and ocean models to identify mechanisms driving large seasonal to interannual variations in dissolved inorganic carbon (DIC) and dissolved oxygen (O-2) in the upper ocean. We begin with observations linking variations in upper ocean DIC and O-2 inventories with changes in the physical state of the ocean. Models are subsequently used to address the extent to which the relationships derived from short-timescale (6 months to 2 years) repeat measurements are representative of variations over larger spatial and temporal scales. The main new result is that convergence and divergence (column stretching) attributed to baroclinic Rossby waves can make a first-order contribution to DIC and O-2 variability in the upper ocean. This results in a close correspondence between natural variations in DIC and O-2 column inventory variations and sea surface height (SSII) variations over much of the ocean. Oceanic Rossby wave activity is an intrinsic part of the natural variability in the climate system and is elevated even in the absence of significant interannual variability in climate mode indices. The close correspondence between SSII and both DIC and O-2 column inventories for many regions suggests that SSII changes (inferred from satellite altimetry) may prove useful in reducing uncertainty in separating natural and anthropogenic DIC signals (using measurements from Climate Variability and Predictability's CO2/Repeat Hydrography program).

Published

2009

91. new global interior ocean mapped climatology: the 1°x1° GLODAP version 2.

Author

Lauvset, Siv K., Key, Robert M., Olsen, Are, van Heuven, Steven, Velo, Anton, Xiaohua Lin, Schirnick, Carsten, Kozyr, Alex, Tanhua, Toste, Hoppema, Mario, Jutterström, Sara, Steinfeldt, Reiner, Jeansson, Emil, Ishii, Masao, Perez, Fiz F., Suzuki, Toru, and Watelet, Sylvain

Subjects

*CLIMATOLOGY, *SEAWATER composition, *BIOGEOCHEMICAL cycles

Abstract

We present a mapped climatology (GLODAPv2.2016b) of ocean biogeochemical variables based on the new GLODAP version 2 data product (Olsen et al., 2016; Key et al., 2015), which covers all ocean basins over the years 1972 to 2013. The quality-controlled and internally consistent GLODAPv2 was used to create global 1°x 1° mapped climatologies of salinity, temperature, oxygen, nitrate, phosphate, silicate, total dissolved inorganic carbon (TCO2), total alkalinity (TAlk), pH, and CaCO3 saturation states using the Data-Interpolating Variational Analysis (DIVA) mapping method. Improving on maps based on an earlier but similar dataset, GLODAPv1.1, this climatology also covers the Arctic Ocean. Climatologies were created for 33 standard depth surfaces. The conceivably confounding temporal trends in TCO2 and pH due to anthropogenic influence were removed prior to mapping by normalizing these data to the year 2002 using first-order calculations of anthropogenic carbon accumulation rates. We additionally provide maps of accumulated anthropogenic carbon in the year 2002 and of preindustrial TCO2. For all parameters, all data from the full 1972-2013 period were used, including data that did not receive full secondary quality control. [ABSTRACT FROM AUTHOR]

Published

2016

92. Anthropogenic ocean acidification over the twenty-first century and its impact on calcifying organisms

Author

Orr, James C., Fabry, Victoria J., Aumont, Olivier, Bopp, Laurent, Doney, Scott C., Feely, Richard A., Gnanadesikan, Anand, Gruber, Nicolas, Ishida, Akio, Joos, Fortunat, Key, Robert M., Lindsay, Keith, Maier-Reimer, Ernst, Matear, Richard J., Monfray, Patrick, Mouchet, Anne, Najjar, Raymond G., Plattner, Gian-Kasper, Rodgers, Keith B., Sabine, Christopher L., Sarmiento, Jorge L., Schlitzer, Reiner, Slater, Richard D., Totterdell, Ian J., Weirig, Marie-France, Yamanaka, Yasuhiro, Yool, Andrew, Orr, James C., Fabry, Victoria J., Aumont, Olivier, Bopp, Laurent, Doney, Scott C., Feely, Richard A., Gnanadesikan, Anand, Gruber, Nicolas, Ishida, Akio, Joos, Fortunat, Key, Robert M., Lindsay, Keith, Maier-Reimer, Ernst, Matear, Richard J., Monfray, Patrick, Mouchet, Anne, Najjar, Raymond G., Plattner, Gian-Kasper, Rodgers, Keith B., Sabine, Christopher L., Sarmiento, Jorge L., Schlitzer, Reiner, Slater, Richard D., Totterdell, Ian J., Weirig, Marie-France, Yamanaka, Yasuhiro, and Yool, Andrew

Abstract

Author Posting. © The Authors, 2005. This is the author's version of the work. It is posted here by permission of Nature Publishing Group for personal use, not for redistribution. The definitive version was published in Nature 437 (2005): 681-686, doi:10.1038/nature04095., The surface ocean is everywhere saturated with respect to calcium carbonate (CaCO3). Yet increasing atmospheric CO2 reduces ocean pH and carbonate ion concentrations [CO32−] and thus the level of saturation. Reduced saturation states are expected to affect marine calcifiers even though it has been estimated that all surface waters will remain saturated for centuries. Here we show, however, that some surface waters will become undersaturated within decades. When atmospheric CO2 reaches 550 ppmv, in year 2050 under the IS92a business-as-usual scenario, Southern Ocean surface waters begin to become undersaturated with respect to aragonite, a metastable form of CaCO3. By 2100 as atmospheric CO2 reaches 788 ppmv, undersaturation extends throughout the entire Southern Ocean (< 60°S) and into the subarctic Pacific. These changes will threaten high-latitude aragonite secreting organisms including cold-water corals, which provide essential fish habitat, and shelled pteropods, an abundant food source for marine predators., All but the climate simulations were made as part of the OCMIP project, which was launched in 1995 by the Global Analysis, Interpretation, and Modeling (GAIM) Task Force of the International Geosphere-Biosphere Program (IGBP) with funding from NASA. OCMIP-2 was supported by the EU GOSAC project and the U.S. JGOFS SMP funded through NASA. The interannual simulation was supported by the EU NOCES project, which is part of OCMIP-3.

Published

2006

93. Tracing Southwest Pacific Bottom Water Using Potential Vorticity and Helium-3

Author

Downes, Stephanie M., primary, Key, Robert M., additional, Orsi, Alejandro H., additional, Speer, Kevin G., additional, and Swift, James H., additional

Published

2012

94. The Oceanic Sink for Anthropogenic CO2

Author

Sabine, Christopher L., Feely, Richard A., Gruber, Nicolas, Key, Robert M., Lee, Kitack, Bullister, John L., Wanninkhof, Rik, Wong, C.S., Wallace, Douglas W.R., Tilbrook, Bronte, Millero, Frank J., Peng, Tsung-Hung, Kozyr, Alexander, Ono, Tsueno, Rios, Aida F., Sabine, Christopher L., Feely, Richard A., Gruber, Nicolas, Key, Robert M., Lee, Kitack, Bullister, John L., Wanninkhof, Rik, Wong, C.S., Wallace, Douglas W.R., Tilbrook, Bronte, Millero, Frank J., Peng, Tsung-Hung, Kozyr, Alexander, Ono, Tsueno, and Rios, Aida F.

Abstract

Using inorganic carbon measurements from an international survey effort in the 1990s and a tracer-based separation technique, we estimate a global oceanic anthropogenic carbon dioxide (CO2) sink for the period from 1800 to 1994 of 118 ± 19 petagrams of carbon. The oceanic sink accounts for ∼48% of the total fossil-fuel and cement-manufacturing emissions, implying that the terrestrial biosphere was a net source of CO2 to the atmosphere of about 39 ± 28 petagrams of carbon for this period. The current fraction of total anthropogenic CO2 emissions stored in the ocean appears to be about one-third of the long-term potential.

Published

2004

95. Expanding Carbon Data Collection From the Ocean's Interior

Author

Tanhua, Toste, primary, Key, Robert M., additional, Hoppema, Mario, additional, Olsen, Are, additional, Ishii, Masao, additional, and Sabine, Christopher L., additional

Published

2010

96. Correction to “Using altimetry to help explain patchy changes in hydrographic carbon measurements”

Author

Rodgers, Keith B., primary, Key, Robert M., additional, Gnanadesikan, Anand, additional, Sarmiento, Jorge L., additional, Aumont, Olivier, additional, Bopp, Laurent, additional, Doney, Scott C., additional, Dunne, John P., additional, Glover, David M., additional, Ishida, Akio, additional, Ishii, Masao, additional, Jacobson, Andrew R., additional, Monaco, Claire Lo, additional, Maier‐Reimer, Ernst, additional, Mercier, Herlé, additional, Metzl, Nicolas, additional, Pérez, Fiz F., additional, Rios, Aida F., additional, Wanninkhof, Rik, additional, Wetzel, Patrick, additional, Winn, Christopher D., additional, and Yamanaka, Yasuhiro, additional

Published

2009

97. Using altimetry to help explain patchy changes in hydrographic carbon measurements

Author

Rodgers, Keith B., primary, Key, Robert M., additional, Gnanadesikan, Anand, additional, Sarmiento, Jorge L., additional, Aumont, Olivier, additional, Bopp, Laurent, additional, Doney, Scott C., additional, Dunne, John P., additional, Glover, David M., additional, Ishida, Akio, additional, Ishii, Masao, additional, Jacobson, Andrew R., additional, Lo Monaco, Claire, additional, Maier‐Reimer, Ernst, additional, Mercier, Herlé, additional, Metzl, Nicolas, additional, Pérez, Fiz F., additional, Rios, Aida F., additional, Wanninkhof, Rik, additional, Wetzel, Patrick, additional, Winn, Christopher D., additional, and Yamanaka, Yasuhiro, additional

Published

2009

98. Submarine groundwater discharge revealed by 228Ra distribution in the upper Atlantic Ocean

Author

Moore, Willard S., primary, Sarmiento, Jorge L., additional, and Key, Robert M., additional

Published

2008

99. Influence of geology on radon in ground water supplies of the New Jersey Highlands

Author

Litt, Barbara R., Korn, Leo R., Moser, Fredrika C., Bell, Christy, Clare, April K., Uptegrove, Jane, and Key, Robert M.

Abstract

Ground water radon concentrations were determined in three types of Middle Proterozoic rocks in the New Jersey Highlands. The rock types (hornblende granite, quartz-oligoclase gneiss, and pyroxene granite) were selected because of their suspected uranium contents (high, low, and low, respectively). It was hypothesized that high ground water radon concentrations might be associated with uranium-bearing rock units. Radon concentrations in 154 wells ranged from 36 pCi/L to 24,000 pci/L (picocuries per liter) with a geometric mean and a median of 1600 pci/L. Radon levels were greater than 300 pci/L (USEPA's proposed MCL for radon in drinking water) in 90% of the wells. None of the rock units studied had ground water radon levels consistently low enough to be regarded as a low priority for testing. Local mineralogy and structure were found to influence ground water radon concentrations. In highly deformed rock units, such as those in the New Jersey Highlands, there is considerable heterogeneity. Migmatites, alaskites and pegmatites which may not appear on a geologic quadrangle map due to their small size or because they are not exposed can affect radioactivity on a local scale.

Published

1992

100. Constraining global air‐sea gas exchange for CO2 with recent bomb 14C measurements

Author

Sweeney, Colm, primary, Gloor, Emanuel, additional, Jacobson, Andrew R., additional, Key, Robert M., additional, McKinley, Galen, additional, Sarmiento, Jorge L., additional, and Wanninkhof, Rik, additional

Published

2007