{"id":1327,"date":"2017-08-28T09:58:10","date_gmt":"2017-08-28T07:58:10","guid":{"rendered":"http:\/\/beta.glodap.info\/?page_id=1327"},"modified":"2025-12-27T13:38:35","modified_gmt":"2025-12-27T12:38:35","slug":"glodap-impact","status":"publish","type":"page","link":"https:\/\/glodap.info\/index.php\/glodap-impact\/","title":{"rendered":"Publications using GLODAPv2"},"content":{"rendered":"
\n

Peer-reviewed journal articles<\/h3>\n

Last updated: 2023-02-07<\/em><\/p>\n

2025 (91)<\/span><\/strong><\/h6>\n

Adebayo, M. B., Bolton, C. T., Bassinot, F. and de Garidel\u2010Thoron, T.(2025). A Comparison of New and Established Foraminiferal Dissolution Proxies in Tropical Indian Ocean Deep\u2010Sea Sediments.<\/span> Paleoceanography and Paleoclimatology<\/span>, 40(6)<\/span>. doi:10.1029\/2024PA005053<\/a>.<\/p>\n

\u00c5rthun, M., Dinh, K. V., D\u00f6rr, J., Dupont, N., Fransner, F., Nilsen, I., Renaud, P. E., Skogen, M. D., Assmy, P., Chierici, M., Duarte, P., Fransson, A., Hansen, C., Nascimento, M. C., Pedersen, T., Smedsrud, L. H., Varpe, \u00d8. and Cnossen, F.(2025). The future Barents Sea\u2014A synthesis of physical, biogeochemical, and ecological changes toward 2050 and 2100.<\/span> Elem Sci Anth<\/span>, 13(1)<\/span>. doi:10.1525\/elementa.2024.00046<\/a>.<\/p>\n

Banerjee, P.(2025). The role of atmospheric iron deposition in driving carbon uptake over the Indian Ocean.<\/span> Progress in Oceanography<\/span>, 231<\/span>, 103419. doi:10.1016\/j.pocean.2025.103419<\/a>.<\/p>\n

Belgacem, M., Schroeder, K., \u00c1lvarez, M., Lauvset, S. K., Chiggiato, J., Borghini, M., Cantoni, C., Ciuffardi, T. and Sparnocchia, S.(2025). A consistent regional dataset of dissolved oxygen in the western Mediterranean Sea (2004\u20132023): CTD-O 2<\/sub> WMED.<\/span> Earth System Science Data<\/span>, 17(10)<\/span>, 5315‑5336. doi:10.5194\/essd‑17‑5315‑2025<\/a>.<\/p>\n

Boteler, C., Dowd, M., Oliver, E. C. J. and Wallace, D. W. R.(2025). An observation-based method to estimate carbonate system variations in the Labrador Sea.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1500225<\/a>.<\/p>\n

Buchanan, P. J., Reddy, P. J., Matear, R. J., Chamberlain, M. A., Rohr, T., Squire, D. and Shadwick, E. H.(2025). Optimisation of the World Ocean Model of Biogeochemistry and Trophic-dynamics (WOMBAT) using surrogate machine learning methods.<\/span> . doi:10.5194\/egusphere‑2024‑4026<\/a>.<\/p>\n

Buchanan, P. J., Sun, X., Weissman, J. L., McCoy, D., Bianchi, D. and Zakem, E. J.(2025). Oxygen intrusions sustain aerobic nitrite-oxidizing bacteria in anoxic marine zones.<\/span> Science<\/span>, 388(6751)<\/span>, 1069‑1074. doi:10.1126\/science.ado0742<\/a>.<\/p>\n

Bunsen, F., Hauck, J., Torres-Vald\u00e9s, S. and Nerger, L.(2025). Ocean carbon sink assessment via temperature and salinity data assimilation into a global ocean biogeochemistry model.<\/span> Ocean Science<\/span>, 21(1)<\/span>, 437‑471. doi:10.5194\/os‑21‑437‑2025<\/a>.<\/p>\n

Bushinsky, S. M., Nachod, Z., Fassbender, A. J., Tamsitt, V., Takeshita, Y. and Williams, N.(2025). Offset Between Profiling Float and Shipboard Oxygen Observations at Depth Imparts Bias on Float pH and Derived p<\/i>CO2<\/sub>.<\/span> Global Biogeochemical Cycles<\/span>, 39(5)<\/span>. doi:10.1029\/2024GB008185<\/a>.<\/p>\n

Caero, T., Wang, H. and Jersild, A.(2025). Pacific\u2010Arctic Ocean Acidification: Decadal Trends and Drivers.<\/span> Global Biogeochemical Cycles<\/span>, 39(4)<\/span>. doi:10.1029\/2024GB008249<\/a>.<\/p>\n

Carter, B. R., Schwinger, J., Sonnerup, R., Fassbender, A. J., Sharp, J. D., Dias, L. M. and Sandborn, D. E.(2025). Tracer-based Rapid Anthropogenic Carbon Estimation (TRACE).<\/span> Earth System Science Data<\/span>, 17(6)<\/span>, 3073‑3088. doi:10.5194\/essd‑17‑3073‑2025<\/a>.<\/p>\n

Chien, C.‑T., Pahlow, M., Somes, C. J., Schartau, M. and Oschlies, A.(2025). Ensemble simulation of the Last Glacial Maximum marine biogeochemistry and atmospheric pCO2<\/sub> drawdown due to the soft-tissue biological carbon pump.<\/span>. doi:10.5194\/egusphere‑2025‑4907<\/a>.<\/p>\n

Clark, A. J., Jaggi, M., Bernasconi, S. M., Fiebig, J. and Stoll, H. M.(2025). Clumped Isotope Temperatures of Coccolithophores From Global Sediment Traps.<\/span> Paleoceanography and Paleoclimatology<\/span>, 40(6)<\/span>. doi:10.1029\/2024PA005054<\/a>.<\/p>\n

Couplet, V., Mart\u00ednez Montero, M. and Crucifix, M.(2025). SURFER v3.0: a fast model with ice sheet tipping points and carbon cycle feedbacks for short and long-term climate scenarios.<\/span> . doi:10.5194\/egusphere‑2024‑2279<\/a>.<\/p>\n

Cui, G., Yuen, K.‑V., Cai, Z., Liu, Z. and Zhang, G.(2025). Research on adaptive ocean remote sensing target detection framework: An efficient solution based on the broad learning system.<\/span> ISPRS Journal of Photogrammetry and Remote Sensing<\/span>, 229<\/span>, 188‑210. doi:10.1016\/j.isprsjprs.2025.08.020<\/a>.<\/p>\n

Da, F., Stock, C. A., Dunne, J. P., Liu, X., Luo, J. Y., Lee, M. and Shevliakova, E.(2025). A Global Perspective on River Alkalinity: Drivers and Implications for Coastal Ocean Carbonate Chemistry.<\/span> Global Biogeochemical Cycles<\/span>, 39(11)<\/span>. doi:10.1029\/2025GB008528<\/a>.<\/p>\n

de la Paz, M., Velo, A., Steinfeldt, R. and P\u00e9rez, F. F.(2025). The Unaccounted Oceanic Sink of Anthropogenic Nitrous Oxide and Its Relationship With Anthropogenic Carbon Dioxide.<\/span> Global Biogeochemical Cycles<\/span>, 39(5)<\/span>. doi:10.1029\/2024GB008417<\/a>.<\/p>\n

Dias, L. M. and Carter, B. R.(2025). PyESPERv1.01.01: A Python implementation of empirical seawater property estimation routines (ESPERs).<\/span> . doi:10.5194\/egusphere‑2025‑458<\/a>.<\/p>\n

Du, J., Haley, B. A., McManus, J., Blaser, P., Rickli, J. and Vance, D.(2025). Abyssal seafloor as a key driver of ocean trace-metal biogeochemical cycles.<\/span> Nature<\/span>, 642(8068)<\/span>, 620‑627. doi:10.1038\/s41586‑025‑09038‑3<\/a>.<\/p>\n

Dutch, V. R., Bakker, D. C. E., Roobaert, A., Landsch\u00fctzer, P., Roden, N. P., Hoppema, M. and Kaiser, J.(2025). The Arctic Ocean CO2<\/sub> Sink: Trends, Uncertainties, and the Impact of Sea Ice.<\/span> Global Biogeochemical Cycles<\/span>, 39(8)<\/span>. doi:10.1029\/2025GB008576<\/a>.<\/p>\n

Fang, H. and Luo, Y.(2025). Shifting Carbonate Saturation Depth in the Deep Western Pacific and Its Implications for Sedimentary Carbonate Preservation.<\/span> Geophysical Research Letters<\/span>, 52(22)<\/span>. doi:10.1029\/2025GL117868<\/a>.<\/p>\n

Findlay, H. S., Feely, R. A., Jiang, L.‑Q., Pelletier, G. and Bednar\u0161ek, N.(2025). Ocean Acidification: Another Planetary Boundary Crossed.<\/span> Global Change Biology<\/span>, 31(6)<\/span>. doi:10.1111\/gcb.70238<\/a>.<\/p>\n

Frawley, T., Provost, M., Bellquist, L., Ben-Aderet, N., Blondin, H., Brodie, S., Buil, M. P., Jacox, M., Bograd, S. J., Hazen, E. L., McGonigal, H. and Ramey, K.(2025). A collaborative climate vulnerability assessment of California marine fishery species.<\/span> PLOS Climate<\/span>, 4(2)<\/span>, e0000574. doi:10.1371\/journal.pclm.0000574<\/a>.<\/p>\n

Gerace, S. D., Yu, J., Moore, J. K. and Martiny, A. C.(2025). Observed declines in upper ocean phosphate-to-nitrate availability.<\/span> Proceedings of the National Academy of Sciences<\/span>, 122(6)<\/span>. doi:10.1073\/pnas.2411835122 <\/a>.<\/p>\n

Glaubke, R. H., Sikes, E. L., Umling, N. E., Allen, K. A. and Schmidt, M. W.(2025). Core-top constraints on the ecology and paleothermometry of planktic foraminifera in the Indian Ocean.<\/span> Palaeogeography, Palaeoclimatology, Palaeoecology<\/span>, 677<\/span>, 113190. doi:10.1016\/j.palaeo.2025.113190<\/a>.<\/p>\n

Graham, O. A., Witkowski, C. R., Stevenson, M. A., Peterse, F. and Naafs, B. D. A.(2025). A phytol \u03b5p-based core-top calibration to reconstruct past changes in atmospheric CO2.<\/span> Geochimica et Cosmochimica Acta<\/span>, 398<\/span>, 178‑192. doi:10.1016\/j.gca.2025.04.014<\/a>.<\/p>\n

Guo, H., Koeve, W., Oschlies, A., He, Y.‑C., Kemena, T. P., Gerke, L. and Kriest, I.(2025). Dual-tracer constraints on the inverse Gaussian transit time distribution improve the estimation of water mass ages and their temporal trends in the tropical thermocline.<\/span> Ocean Science<\/span>, 21(3)<\/span>, 1167‑1182. doi:10.5194\/os‑21‑1167‑2025<\/a>.<\/p>\n

Guti\u00e9rrez-Z\u00e1rate, C., Gori, A., Veiga, A., \u00c1lvarez, M., Gonz\u00e1lez-Pola, C., Rakka, M., Movilla, J., Beck, K. K., Atienza, E. M. S., Acerbi, R. and Orejas, C.(2025). Resistance of the cold-water coral Dendrophyllia cornigera to single and combined global change stressors.<\/span> Scientific Reports<\/span>, 15(1)<\/span>. doi:10.1038\/s41598‑025‑24028‑1<\/a>.<\/p>\n

Han, M. and Zhou, Y.(2025). Reconstructing Global Monthly Ocean Dissolved Oxygen (1960\u20132023) to Nearly 6000 m Depth Using Bayesian Ensemble Machine Learning.<\/span> . doi:10.5194\/essd‑2025‑273<\/a>.<\/p>\n

Hayashida, H., Strutton, P. G., Hashihama, F., Horimoto-Miyazaki, N., Katano, T. and Yasui-Tamura, S.(2025). Status and prospects of biogeochemical Argo observations of chlorophyll-a in the northwest Pacific.<\/span> Journal of Oceanography<\/span>, 81(4)<\/span>, 289‑299. doi:10.1007\/s10872‑025‑00750‑2<\/a>.<\/p>\n

Hayward, A., Wright, S. W., Carroll, D., Law, C. S., Wongpan, P., Guti\u00e9rrez-Rodriguez, A. and Pinkerton, M. H.(2025). Antarctic phytoplankton communities restructure under shifting sea-ice regimes.<\/span> Nature Climate Change<\/span>, 15(8)<\/span>, 889‑896. doi:10.1038\/s41558‑025‑02379‑x<\/a>.<\/p>\n

Hirsh, H. K., Oliver, T. A., Dobbelaere, T., Palacio-Castro, A. M., Barkley, H. C., Webb, A. E., Hanert, E. and Enochs, I. C.(2025). Statistical Prediction of In Situ Coral Reef Carbonate Dynamics Using Endmember Chemistry, Hydrodynamic Models, And Benthic Composition.<\/span> Aquatic Geochemistry<\/span>, 31(1)<\/span>. doi:10.1007\/s10498‑025‑09438‑x<\/a>.<\/p>\n

Hoffman, F. M., Hassler, B., Swaminathan, R., Lewis, J., Andela, B., Collier, N., Heged\u0171s, D., Lee, J., Pascoe, C., Pfl\u00fcger, M., Stockhause, M., Ullrich, P., Xu, M., Bock, L., Chun, F., Gier, B. K., Kelley, D. I., Lauer, A., Lenhardt, J., Schlund, M., Sreeush, M. G., Weigel, K., Blockley, E., Beadling, R., Beucher, R., Dugassa, D. D., Lembo, V., Lu, J., Brands, S., Tjiputra, J., Malinina, E., Mederios, B., Scoccimarro, E., Walton, J., Kershaw, P., Marquez, A. L., Roberts, M. J., O\u2019Rourke, E., Dingley, E., Turner, B., Hewitt, H. and Dunne, J. P.(2025). Rapid Evaluation Framework for the CMIP7 Assessment Fast Track.<\/span> . doi:10.5194\/egusphere‑2025‑2685<\/a>.<\/p>\n

Holdsworth, A. M., Shao, A. and Christian, J. R.(2025). Clustering to Characterize Extreme Marine Conditions for the Benthic Region of the Northeastern Pacific Continental Margin.<\/span> Geophysical Research Letters<\/span>, 52(10)<\/span>. doi:10.1029\/2024GL112591<\/a>.<\/p>\n

Ishii, M., Carter, B. R., Toyama, K., Rodgers, K. B., Feely, R. A., Chau, T.‑T.‑T., Chevallier, F., Desmet, F., Gregor, L., Iida, Y., Kitamura, Y., M\u00fcller, J. D. and Tsujino, H.(2025). CO2<\/sub> Uptake in the Pacific From 1985 to 2018: A Comparative Assessment of Observation\u2010 and Model\u2010Based Estimates.<\/span> Global Biogeochemical Cycles<\/span>, 39(5)<\/span>. doi:10.1029\/2024GB008355<\/a>.<\/p>\n

Jin, M., Chen, Z., Lin, X., Li, C. and Qi, D.(2025). Influences of Global Warming and Upwelling on the Acidification in the Beaufort Sea.<\/span> Remote Sensing<\/span>, 17(5)<\/span>, 866. doi:10.3390\/rs17050866<\/a>.<\/p>\n

Jouanno, J., Berthet, S., Muller-Karger, F., Aumont, O. and Sheinbaum, J.(2025). An extreme North Atlantic Oscillation event drove the pelagic Sargassum tipping point.<\/span> Communications Earth & Environment<\/span>, 6(1)<\/span>. doi:10.1038\/s43247‑025‑02074‑x<\/a>.<\/p>\n

Jung, J., Duprey, N. N., Foreman, A. D., D\u2019Olivo, J. P., Pellio, C., Ryu, Y., Murphy, E. L., Romshoo, B., Kersting, D. K., Cardoso, G. O., Wald, T., Fripiat, F., Jimenez, C., Gischler, E., Montagna, P., Alonso-Hern\u00e1ndez, C., Gomez-Batista, M., Treinen-Crespo, C., Carriquiry, J., Ong, M. R., Goodkin, N. F., Guppy, R., Aardema, H., Slagter, H., Heins, L., de Angelis, I. H., Bieler, A. L., Yehudai, M., No\u00ebl, T. P., James, K., Scholz, D., Hu, C., Barnes, B. B., Pozzer, A., P\u00f6hlker, C., Lelieveld, J., P\u00f6schl, U., Vonhof, H., Haug, G. H., Schiebel, R., Sigman, D. M. and Mart\u00ednez-Garc\u00eda, A.(2025). Equatorial upwelling of phosphorus drives Atlantic N2 fixation and Sargassum blooms.<\/span> Nature Geoscience<\/span>, 18(12)<\/span>, 1259‑1265. doi:10.1038\/s41561‑025‑01812‑2<\/a>.<\/p>\n

Jutras, M., Bushinsky, S. M., Cerove\u010dki, I. and Briggs, N.(2025). Mixing Accounts for More Than Half of Biogeochemical Changes Along Mode Water Ventilation Pathways.<\/span> Geophysical Research Letters<\/span>, 52(7)<\/span>. doi:10.1029\/2024GL113789<\/a>.<\/p>\n

Karaku\u015f, O., Nissen, C., V\u00f6lker, C., Hagen, W., Iversen, M., Oziel, L., G\u00fcrses, \u00d6. and Hauck, J.(2025). The Role of Ballasting, Seawater Viscosity and Oxygen\u2010Dependent Remineralization for Export and Transfer Efficiencies in the Global Ocean.<\/span> Global Biogeochemical Cycles<\/span>, 39(5)<\/span>. doi:10.1029\/2024GB008403<\/a>.<\/p>\n

Karancz, S., de Nooijer, L. J., van der Wagt, B., van der Meer, M. T. J., Misra, S., Hennekam, R., Erdem, Z., Lattaud, J., Haghipour, N., Schouten, S. and Reichart, G.‑J.(2025). Contrasts in the marine inorganic carbon chemistry of the Benguela Upwelling System since the Last Glacial Maximum.<\/span> Climate of the Past<\/span>, 21(3)<\/span>, 679‑704. doi:10.5194\/cp‑21‑679‑2025<\/a>.<\/p>\n

Kim, D., Jung, H.‑C., Moon, J.‑H. and Lee, N.‑H.(2025). Development and assessment of the physical\u2013biogeochemical ocean regional model in the Northwest Pacific: NPRT v1.0 (ROMS v3.9\u2013TOPAZ v2.0).<\/span> Geoscientific Model Development<\/span>, 18(12)<\/span>, 3941‑3964. doi:10.5194\/gmd‑18‑3941‑2025<\/a>.<\/p>\n

Lai, Y., Ma, W., Zhao, Z., Xiu, P. and Jiao, N.(2025). Incorporating Recalcitrant Dissolved Organic Carbon and Microbial Carbon Pump Processes into the cGENIE Earth System Model (cGENIEv0.9.35-MCP).<\/span> . doi:10.5194\/egusphere‑2025‑2967<\/a>.<\/p>\n

Lavoie, D., Bourgault-Brunelle, C., Brickman, D., Gibb, O., Guyondet, T., Niemi, A., Pe\u00f1a, A., Shen, H., amd Soontiens, Nancy (2025). Biogeochemical modelling at DFO: overview and recommendations of the biogeochemical modelling working group.<\/span> Canadian technical report of hydrography and ocean sciences<\/span>, 388<\/span>. https:\/\/publications.gc.ca\/site\/eng\/9.946353\/publication.html<\/a>.<\/p>\n

Law, C. S. and Miller, L. A.(2025). The air-sea interface in a changing climate: Research advances and future directions.<\/span> Elem Sci Anth<\/span>, 13(1)<\/span>. doi:10.1525\/elementa.2025.00022<\/a>.<\/p>\n

Lentz, S. J., Cohen, A. L., Mollica, N. R., Fox, M., Zhang, W. (G.), Poemnamthip, P. and McCorkle, D. C.(2025). Impact of El Ni\u00f1o\u2010Southern Oscillation on the Alkalinity and Salinity of a Coral Reef Lagoon in the Equatorial Pacific\u2014Observations and a Model.<\/span> Journal of Geophysical Research: Oceans<\/span>, 130(6)<\/span>. doi:10.1029\/2024JC021843<\/a>.<\/p>\n

Lewis, C. B., Corran, R., Mikaloff-Fletcher, S., Behrens, E., Moss, R., Brailsford, G., Lorrey, A., Norris, M. and Turnbull, J.(2025). Southern Hemisphere tree-rings as proxies to reconstruct Southern Ocean upwelling.<\/span> . doi:10.5194\/egusphere‑2024‑4107<\/a>.<\/p>\n

Liao, E., Resplandy, L., Yang, F., Zhao, Y., Ditkovsky, S., Malsang, M., Pearson, J., Ross, A. C., Hallberg, R. and Stock, C.(2025). A high-resolution physical-biogeochemical model for marine resource applications in the Northern Indian Ocean (MOM6-COBALT-IND12 v1.0).<\/span> . doi:10.5194\/egusphere‑2024‑3646<\/a>.<\/p>\n

L\u00f3pez\u2010Mozos, M., P\u00e9rez, F. F., Carracedo, L. I., Gebbie, G. and Velo, A.(2025). A Novel Back\u2010Calculation Approach to Estimate Ocean Anthropogenic Carbon Using Carbon\u2010Based Data and a Total Matrix Intercomparison Method.<\/span> Journal of Advances in Modeling Earth Systems<\/span>, 17(1)<\/span>. doi:10.1029\/2024MS004330<\/a>.<\/p>\n

Lovecchio, E., Henson, S., Carvalho, F., Briggs, N., Hilder, H., Wolff, G. A., Giering, S. L. C., Cook, K., Baker, C. A., Fielding, S., Preece, C. and Stinchcombe, M.(2025). Mesopelagic Particle Layers in the Dynamic Hypoxic Northern Benguela Are Shaped by Zooplankton Activity.<\/span> Journal of Geophysical Research: Oceans<\/span>, 130(3)<\/span>. doi:10.1029\/2024JC021039<\/a>.<\/p>\n

Maffre, P., Godd\u00e9ris, Y., Le Hir, G., Nardin, \u00c9., Sarr, A.‑C. and Donnadieu, Y.(2025). GEOCLIM7, an Earth system model for multi-million-year evolution of the geochemical cycles and climate.<\/span> Geoscientific Model Development<\/span>, 18(18)<\/span>, 6367‑6413. doi:10.5194\/gmd‑18‑6367‑2025<\/a>.<\/p>\n

Mayer, B., Hagemann, S., Zhou, Y., Chen, Y., Ang, S. B. H., P\u00e4tsch, J. and Martin, P.(2025). Modeling Terrestrial Dissolved Organic Carbon and Its Effect on the Carbonate System in the Sunda Shelf Seas, Southeast Asia.<\/span> Global Biogeochemical Cycles<\/span>, 39(4)<\/span>. doi:10.1029\/2024GB008433<\/a>.<\/p>\n

Metzl, N., Fin, J., Lo Monaco, C., Mignon, C., Alliouane, S., Bombled, B., Boutin, J., Bozec, Y., Comeau, S., Conan, P., Coppola, L., Cuet, P., Ferreira, E., Gattuso, J.‑P., Gazeau, F., Goyet, C., Grossteffan, E., Lansard, B., Lef\u00e8vre, D., Lef\u00e8vre, N., Leseurre, C., Petton, S., Pujo-Pay, M., Rabouille, C., Reverdin, G., Ridame, C., Rimmelin-Maury, P., Ternon, J.‑F., Touratier, F., Tribollet, A., Wagener, T. and Wimart-Rousseau, C. (2025). An updated synthesis of ocean total alkalinity and dissolved inorganic carbon measurements from 1993 to 2023: the SNAPO-CO2<\/sub>-v2 dataset.<\/span> Earth System Science Data<\/span>, 17(3)<\/span>, 1075‑1100. doi:10.5194\/essd‑17‑1075‑2025<\/a>.<\/p>\n

Misumi, K., Tsubono, T., Tsumune, D., Yoshimura, T. and Ueda, S.(2025). Simulating CO2 dynamics in Brackish Lake Obuchi, Japan: Low pCO2 maintenance through diverse nutrient inputs.<\/span> Progress in Earth and Planetary Science<\/span>, 12(1)<\/span>. doi:10.1186\/s40645‑025‑00751‑1<\/a>.<\/p>\n

Mohanty, S., Patara, L., Kazempour, D. and Kr\u00f6ger, P.(2025). Detection and tracking of carbon biomes via integrated machine learning.<\/span> Ocean Science<\/span>, 21(2)<\/span>, 587‑617. doi:10.5194\/os‑21‑587‑2025<\/a>.<\/p>\n

M\u00fcller, W. A., Lorenz, S., Pham, T. V., Schneidereit, A., Brokopf, R., Brovkin, V., Br\u00fcggemann, N., Chegini, F., Dommenget, D., Fr\u00f6hlich, K., Fr\u00fch, B., Gayler, V., Haak, H., Hagemann, S., Hanke, M., Ilyina, T., Jungclaus, J., K\u00f6hler, M., Korn, P., Kornbl\u00fch, L., Kroll, C., Kr\u00fcger, J., Castro-Morales, K., Niemeier, U., Pohlmann, H., Polkova, I., Potthast, R., Riddick, T., Schlund, M., Stacke, T., Wirth, R., Yu, D. and Marotzke, J.(2025). The ICON-based Earth System Model for Climate Predictions and Projections (ICON XPP v1.0).<\/span> . doi:10.5194\/egusphere‑2025‑2473<\/a>.<\/p>\n

Nauter\u2010Alves, A., Evans, D., Katz, M. E., Gray, W. R., Rae, J. W. B. and Borrelli, C.(2025). Thermal and Non\u2010Thermal Controls on Benthic Foraminiferal Mg\/Ca, Sr\/Ca, B\/Ca, and Mg\/Li: Global Core\u2010Top Compilation, Revised Calibrations, and Application to the Geologic Record.<\/span> Paleoceanography and Paleoclimatology<\/span>, 40(12)<\/span>. doi:10.1029\/2025PA005176<\/a>.<\/p>\n

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Shen, Y. and Wang, W.‑L.(2025). Autotrophic Dissolved Organic Phosphorus Uptake Stimulates Nitrogen Fixation in Subtropical Gyres.<\/span> Geophysical Research Letters<\/span>, 52(2)<\/span>. doi:10.1029\/2024GL112439<\/a>.<\/p>\n

Silbiger, N. J., Donahue, M. J., Hagedorn, B., Barnas, D. M., Jorissen, H., Kerlin, J. R., McClintock, R., Nixon, E., Sparagon, W. J., Zeff, M. and Nelson, C. E.(2025). Terrestrial nutrient inputs restructure coral reef dissolved carbon fluxes via direct and indirect effects.<\/span> Ecological Monographs<\/span>, 95(2)<\/span>. doi:10.1002\/ecm.70020<\/a>.<\/p>\n

Stock, C. A., Dunne, J. P., Luo, J. Y., Ross, A. C., Van Oostende, N., Zadeh, N., Cordero, T. J., Liu, X. and Teng, Y.‑C.(2025). Photoacclimation and Photoadaptation Sensitivity in a Global Ocean Ecosystem Model.<\/span> Journal of Advances in Modeling Earth Systems<\/span>, 17(6)<\/span>. doi:10.1029\/2024MS004701<\/a>.<\/p>\n

Sun, C., Liao, E. and Zhu, X.(2025). Asymmetrical Ocean Carbon Responses in the Tropical Pacific Ocean to La Ni\u00f1a and El Ni\u00f1o.<\/span> Geophysical Research Letters<\/span>, 52(4)<\/span>. doi:10.1029\/2024GL112039<\/a>.<\/p>\n

Tan, Z., von Schuckmann, K., Speich, S., Bopp, L., Zhu, J. and Cheng, L.(2025). Observed large-scale and deep-reaching compound ocean state changes over the past 60 years.<\/span> Nature Climate Change<\/span>. doi:10.1038\/s41558‑025‑02484‑x<\/a>.<\/p>\n

Tierney, J. E., King, J., Osman, M. B., Abell, J. T., Burls, N. J., Erfani, E., Cooper, V. T. and Feng, R.(2025). Pliocene Warmth and Patterns of Climate Change Inferred From Paleoclimate Data Assimilation.<\/span> AGU Advances<\/span>, 6(1)<\/span>. doi:10.1029\/2024AV001356<\/a>.<\/p>\n

Tokoro, T., Nakaoka, S.‑I., Takao, S., Saito, S., Sasano, D., Enyo, K., Ishii, M., Kosugi, N., Ono, T., Tadokoro, K. and Nojiri, Y.(2025). Assessing the impact of landwater on the Northwest Pacific using normalized Total Alkalinity.<\/span> . doi:10.5194\/egusphere‑2024‑3792<\/a>.<\/p>\n

von Jackowski, A.(2025). Navigating the current landscape of ocean observations: an overview from platform infrastructures to networks related to ocean time series.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1363863<\/a>.<\/p>\n

Wallhead, P. J., Schwinger, J., Tjiputra, J., Kristiansen, T. and Bellerby, R. G. J.(2025). NorESM-bcoi-v1: A bias-corrected reanalysis of ocean biogeochemistry at \u2009>\u2009\u200940\u00b0\u2009N, 1980\u20132020, based on a global ocean model hindcast.<\/span> Earth System Science Data<\/span>, 17(12)<\/span>, 6763‑6805. doi:10.5194\/essd‑17‑6763‑2025<\/a>.<\/p>\n

Wang, C., Su, B., Sun, J., Hu, X. and Liu, J.(2025). A regional ocean database for the Coastal China Sea.<\/span> Scientific Data<\/span>, 12(1)<\/span>. doi:10.1038\/s41597‑025‑05840‑w<\/a>.<\/p>\n

Wefing, A.‑M., Payne, A., Scheiwiller, M., Vockenhuber, C., Christl, M., Tanhua, T. and Casacuberta, N.(2025). Changes in Atlantic Water circulation in the central Arctic Ocean between 2011 and 2021 inferred from tracer observations.<\/span> . doi:10.5194\/egusphere‑2025‑1322<\/a>.<\/p>\n

Wong, J., M\u00fcnnich, M. and Gruber, N.(2025). Compound Marine Heatwaves and Acidity Extremes in the Southern Ocean.<\/span> Global Biogeochemical Cycles<\/span>, 39(10)<\/span>. doi:10.1029\/2025GB008630<\/a>.<\/p>\n

Woosley, R. J., Bruno, J. A., Neithardt, D., Wang, Z. A., Fujiki, N., Shigemitsu, M. and Murata, A.(2025). Comparison of open cell and single\u2010step total alkalinity titration methods and implications for organic alkalinity.<\/span> Limnology and Oceanography: Methods<\/span>, 23(12)<\/span>, 960‑972. doi:10.1002\/lom3.70002<\/a>.<\/p>\n

Wu, C., Wang, Q., Zhao, Z. and Zhang, K.(2025). Extreme CO2<\/sub> Release and Its Mechanism in the Subarctic North Pacific During the Winters of 1999\u20132001.<\/span> Journal of Geophysical Research: Oceans<\/span>, 130(4)<\/span>. doi:10.1029\/2024JC021708<\/a>.<\/p>\n

Wu, Y., Zheng, Z., Chen, X., Zhong, W., Yuan, X., Zhong, W., Lei, R., Li, C., Zhuang, Y., Gao, X., Li, X., Lin, H., Chen, L., Cai, W.‑J. and Qi, D.(2025). Amplified warming accelerates deoxygenation in the Arctic Ocean.<\/span> Nature Climate Change<\/span>, 15(8)<\/span>, 859‑865. doi:10.1038\/s41558‑025‑02376‑0<\/a>.<\/p>\n

Yang, Y., Wang, H. and Li, X.(2025). Deep Learning for Enhanced Ocean Color Remote Sensing: A Foundation Model Approach.<\/span> IEEE Transactions on Geoscience and Remote Sensing<\/span>, 63<\/span>, 1‑18. doi:10.1109\/TGRS.2025.3600411<\/a>.<\/p>\n

Yang, Z., Lear, C. H., Barker, S., Elsey, J., Gasson, E., Rosenthal, Y., Slater, S. M. and Thomas-Sparkes, A.(2025). Major sea level fall during the Pliocene M2 glaciation.<\/span> Nature Communications<\/span>, 16(1)<\/span>. doi:10.1038\/s41467‑025‑62446‑x <\/a>.<\/p>\n

Yankovsky, E., Zhou, M., Tyka, M., Bachman, S., Ho, D. T., Karspeck, A. and Long, M. C.(2025). Impulse response functions as a framework for quantifying ocean-based carbon dioxide removal.<\/span> Biogeosciences<\/span>, 22(20)<\/span>, 5723‑5739. doi:10.5194\/bg‑22‑5723‑2025<\/a>.<\/p>\n

Yu, J., Krumhardt, K. M., Keith Moore, J., Letscher, R. T., Wang, S., Wiseman, N. A., Long, M. C., Lindsay, K., Levy, M., Petrik, C. M. and Martiny, A. C.(2025). Simulating Marine Ecosystem Dynamics and Biogeochemical Cycling With Multiple Plankton Functional Types.<\/span> Journal of Advances in Modeling Earth Systems<\/span>, 17(7)<\/span>. doi:10.1029\/2024MS004521<\/a>.<\/p>\n

Zhang, L. and Liao, E.(2025). Unprecedented Carbon Accumulation in the Indian Ocean During 2016\u20132017.<\/span> Geophysical Research Letters<\/span>, 52(20)<\/span>. doi:10.1029\/2025GL117199<\/a>.<\/p>\n

Zhang, S., Wu, Y., Zhong, W., Chen, L. and Qi, D.(2025). Anthropogenic Forcing and Upwelling Accelerate Aragonite Undersaturation in the Prydz Bay, East Antarctica.<\/span> Journal of Geophysical Research: Oceans<\/span>, 130(11)<\/span>. doi:10.1029\/2025JC023039<\/a>.<\/p>\n

Zhong, G., Li, X., Song, J., Qu, B., Wang, F., Wang, Y., Zhang, B., Cheng, L., Ma, J., Yuan, H., Duan, L., Li, N., Wang, Q., Xing, J. and Dai, J.(2025). A global monthly 3D field of seawater pH over 3 decades: a machine learning approach.<\/span> Earth System Science Data<\/span>, 17(2)<\/span>, 719‑740. doi:10.5194\/essd‑17‑719‑2025<\/a>.<\/p>\n

Zhong, W., Ma, X., Wu, Y., Li, C., Shi, T., Gong, W. and Qi, D.(2025). High-resolution spatiotemporal fields of Southern Ocean interior carbonate system parameters integrated from float- and ship-based observations.<\/span> . doi:10.5194\/essd‑2025‑473<\/a>.<\/p>\n

2024 (79)<\/span><\/strong><\/h6>\n

Andrews, A. H., Eveson, J. P., Welte, C., Okamoto, K., Satoh, K., Krusic-Golub, K., Lougheed, B. C., Macdonald, J. I., Roupsard, F. and Farley, J. H. (2024). Age validation of yellowfin and bigeye tuna using post-peak bomb radiocarbon dating confirms long lifespans in the western and central Pacific Ocean.<\/span> ICES Journal of Marine Science<\/span>, 81(6)<\/span>, 1137‑1149. doi:10.1093\/icesjms\/fsae074<\/a>.<\/p>\n

Asselot, R., Carracedo, L. I., Thierry, V., Mercier, H., Bajon, R. and P\u00e9rez, F. F. (2024). Anthropogenic carbon pathways towards the North Atlantic interior revealed by Argo-O2, neural networks and back-calculations.<\/span> Nature Communications<\/span>, 15(1)<\/span>. doi:10.1038\/s41467‑024‑46074‑5<\/a>.<\/p>\n

Asselot, R., Thierry, V., Carracedo, L. I., Mercier, H., Velo, A., Bajon, R. and P\u00e9rez, F. F. (2024). Temporal evolution of anthropogenic carbon in the subpolar North Atlantic gyre between 2011 – 2021.<\/span> . doi:10.22541\/essoar.172901267.76656819\/v1<\/a>.<\/p>\n

Assis, J., Fern\u00e1ndez\u00a0Bejarano, S. J., Salazar, V. W., Schepers, L., Gouv\u00eaa, L., Fragkopoulou, E., Leclercq, F., Vanhoorne, B., Tyberghein, L., Serr\u00e3o, E. A., Verbruggen, H. and De\u00a0Clerck, O. (2024). Bio\u2010ORACLE<\/scp> v3.0. Pushing marine data layers to the CMIP6<\/scp> Earth System Models of climate change research.<\/span> Global Ecology and Biogeography<\/span>, 33(4)<\/span>. doi:10.1111\/geb.13813<\/a>.<\/p>\n

Atobatele, A. J. and Olaleye, S. A. (2024). Policy Interventions on Arctic Marine Ecosystems and Regulatory Framework.<\/span> Arctic Marine Ecotoxicology<\/span>, 515‑537. doi:10.1007\/978‑3‑031‑73584‑4_25<\/a>.<\/p>\n

Atwood, T. B., Romanou, A., DeVries, T., Lerner, P. E., Mayorga, J. S., Bradley, D., Cabral, R. B., Schmidt, G. A. and Sala, E. (2024). Atmospheric CO2 emissions and ocean acidification from bottom-trawling.<\/span> Frontiers in Marine Science<\/span>, 10<\/span>. doi:10.3389\/fmars.2023.1125137<\/a>.<\/p>\n

Baldry, K., Johnson, R., Strutton, P. G. and Boyd, P. W. (2024). A biological ocean data reformatting effort.<\/span> Scientific Data<\/span>, 11(1)<\/span>. doi:10.1038\/s41597‑024‑03038‑0<\/a>.<\/p>\n

Baldry, K., Strutton, P. G., Hill, N. A. and Boyd, P. W. (2024). Subsurface chlorophyll maxima reduce the performance of non-photochemical quenching corrections in the Southern Ocean.<\/span> Frontiers in Marine Science<\/span>, 10<\/span>. doi:10.3389\/fmars.2023.1302999<\/a>.<\/p>\n

Bunsen, F., Nissen, C. and Hauck, J. (2024). The Impact of Recent Climate Change on the Global Ocean Carbon Sink.<\/span> Geophysical Research Letters<\/span>, 51(4)<\/span>. doi:10.1029\/2023GL107030<\/a>.<\/p>\n

B\u00fcscher, J. V., Juva, K., Fl\u00f6gel, S., Wisshak, M., R\u00fcggeberg, A., Riebesell, U. and Form, A. U. (2024). Water mass characteristics and hydrodynamics at an inshore versus an offshore mid-Norwegian cold-water coral reef habitat.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1363542<\/a>.<\/p>\n

Butzin, M., Ye, Y., V\u00f6lker, C., G\u00fcrses, \u00d6., Hauck, J. and K\u00f6hler, P. (2024). Carbon isotopes in the marine biogeochemistry model FESOM2.1-REcoM3.<\/span> Geoscientific Model Development<\/span>, 17(4)<\/span>, 1709‑1727. doi:10.5194\/gmd‑17‑1709‑2024<\/a>.<\/p>\n

Cala, B. A., Sulpis, O., Wolthers, M. and Humphreys, M. P. (2024). Synthesis of In Situ Marine Calcium Carbonate Dissolution Kinetic Measurements in the Water Column.<\/span> Global Biogeochemical Cycles<\/span>, 38(9)<\/span>. doi:10.1029\/2023GB008009<\/a>.<\/p>\n

Chang, N., Nicholson, S.‑A., du Plessis, M., Lebehot, A. D., Mashifane, T. B., Moalusi, T. C., Mongwe, P. and Monteiro, P. M. S. (2025). BIOPERIANT12: a mesoscale-resolving coupled physics\u2013biogeochemical model for the Southern Ocean.<\/span> Geoscientific Model Development<\/span>, 18(18)<\/span>, 6415‑6438. doi:10.5194\/gmd‑18‑6415‑2025<\/a>.<\/p>\n

Chau, T.‑T.‑T., Gehlen, M., Metzl, N. and Chevallier, F. (2024). CMEMS-LSCE: a global, 0.25\u00b0, monthly reconstruction of the surface ocean carbonate system.<\/span> Earth System Science Data<\/span>, 16(1)<\/span>, 121‑160. doi:10.5194\/essd‑16‑121‑2024<\/a>.<\/p>\n

Chen, Y., Zhao, H. and Gao, H. (2024). Spatiotemporal Evolution of Air\u2013Sea CO2 Flux in the South China Sea and Its Response to Environmental Factors.<\/span> Remote Sensing<\/span>, 16(24)<\/span>, 4724. doi:10.3390\/rs16244724<\/a>.<\/p>\n

Chu, W. U., Mazloff, M. R., Verdy, A., Purkey, S. G. and Cornuelle, B. D. (2024). Optimizing observational arrays for biogeochemistry in the tropical Pacific by estimating correlation lengths.<\/span> Limnology and Oceanography: Methods<\/span>, 22(11)<\/span>, 840‑852. doi:10.1002\/lom3.10641<\/a>.<\/p>\n

Damien, P., Bianchi, D., Kessouri, F. and McWilliams, J. C. (2024). Extremes and Short\u2010Term Fluctuations in Coastal Ocean Acidification and Hypoxia.<\/span> Journal of Geophysical Research: Oceans<\/span>, 129(11)<\/span>. doi:10.1029\/2024JC021197<\/a>.<\/p>\n

de Mora, L., Galli, G., Artioli, Y., Broszeit, S., Garrard, S. L., Baum, D., Weber, S. and Blackford, J. (2024). Impacts of Climate Change on the Ascension Island Marine Protected Area and Its Ecosystem Services.<\/span> Journal of Geophysical Research: Biogeosciences<\/span>, 129(5)<\/span>. doi:10.1029\/2023JG007395<\/a>.<\/p>\n

Diz, P., Gonz\u00e1lez-Villanueva, R. and Garc\u00eda-Rosell\u00f3, E. (2024). Diversity and endemism of hard-shelled benthic foraminifera in permanently oxygen-depleted bottom waters: An analysis from the eastern Pacific.<\/span> Progress in Oceanography<\/span>, 225<\/span>, 103277. doi:10.1016\/j.pocean.2024.103277<\/a>.<\/p>\n

Ellison, E., Mazloff, M. and Mashayek, A. (2024). The Rapid Response of Southern Ocean Biological Productivity to Changes in Background Small Scale Turbulence.<\/span> Journal of Geophysical Research: Oceans<\/span>, 129(10)<\/span>. doi:10.1029\/2024JC021158<\/a>.<\/p>\n

Frenger, I., Landolfi, A., Kvale, K., Somes, C. J., Oschlies, A., Yao, W. and Koeve, W. (2024). Misconceptions of the marine biological carbon pump in a changing climate: Thinking outside the \u201cexport\u201d box.<\/span> Global Change Biology<\/span>, 30(1)<\/span>. doi:10.1111\/gcb.17124<\/a>.<\/p>\n

Friedrich, T., Powell, B. S., Gunnarson, J. L., Liu, G., Giardina, S. F., Stuecker, M. F., Ho\u0161ekov\u00e1, L., Feloy, K. and Stock, C. A. (2024). Submesoscale\u2010Permitting Physical\/Biogeochemical Future Projections for the Main Hawaiian Islands.<\/span> Journal of Advances in Modeling Earth Systems<\/span>, 16(2)<\/span>. doi:10.1029\/2023ms003855<\/a>.<\/p>\n

Garc\u00eda-Ib\u00e1\u00f1ez, M. I., Guallart, E. F., Lucas, A., Pascual, J., Gasol, J. M., Marras\u00e9, C., Calvo, E. and Pelejero, C. (2024). Two new coastal time-series of seawater carbonate system variables in the NW Mediterranean Sea: rates and mechanisms controlling pH changes.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1348133\/<\/a>.<\/p>\n

Glaubke, R. H. (2004). A Late Quaternary history of interior ocean circulation and ventilation from the Indian Sector of the Southern Ocean.<\/span> Retrieved from https:\/\/doi.org\/doi:10.7282\/t3-xsqy-nz12<\/a>.<\/p>\n

Gray, A. R. (2024). The Four-Dimensional Carbon Cycle of the Southern Ocean.<\/span> Annual Review of Marine Science<\/span>, 16(1)<\/span>, 163‑190. doi:10.1146\/annurev‑marine‑041923‑104057<\/a>.<\/p>\n

Hagstrom, G. I., Stock, C. A., Luo, J. Y. and Levin, S. A. (2024). Impact of Dynamic Phytoplankton Stoichiometry on Global Scale Patterns of Nutrient Limitation, Nitrogen Fixation, and Carbon Export.<\/span> Global Biogeochemical Cycles<\/span>, 38(5)<\/span>. doi:10.1029\/2023GB007991<\/a>.<\/p>\n

Hassoun, A. E. R., Tanhua, T., Lips, I., Heslop, E., Petihakis, G. and Karstensen, J. (2024). The European Ocean Observing Community: urgent gaps and recommendations to implement during the UN Ocean Decade.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1394984<\/a>.<\/p>\n

Hauksson, N. E., Xu, X., Pedron, S., Martinez, H. A., Lewis, C. B., Glynn, D. S., Glynn, C., Garcia, N., Flaherty, A., Thomas, K., Griffin, S. and Druffel, E. R. M. (2024). TIME SERIES OF SURFACE WATER DISSOLVED INORGANIC CARBON ISOTOPES FROM THE SOUTHERN CALIFORNIA BIGHT.<\/span> Radiocarbon<\/span>, 66(5)<\/span>, 863‑878. doi:10.1017\/RDC.2023.73<\/a>.<\/p>\n

Hayward, A., Wright, S. W., Carroll, D., Law, C., Wongpan, P., Guti\u00e9rrez-Rodriguez, A. and Pinkerton, M. H. (2024). Climate driven shifts in Antarctic phytoplankton groups: Implications of widespread diatom decline.<\/span> . doi:10.21203\/rs.3.rs‑5188031\/v1<\/a>.<\/p>\n

Hofmann\u00a0Elizondo, U., Vogt, M., Bednar\u0161ek, N., M\u00fcnnich, M. and Gruber, N. (2024). The impact of aragonite saturation variability on shelled pteropods: An attribution study in the California Current System.<\/span> Global Change Biology<\/span>, 30(6)<\/span>. doi:10.1111\/gcb.17345<\/a>.<\/p>\n

Hollitzer, H. A. L., Patara, L., Terhaar, J. and Oschlies, A. (2024). Competing effects of wind and buoyancy forcing on ocean oxygen trends in recent decades.<\/span> Nature Communications<\/span>, 15(1)<\/span>. doi:10.1038\/s41467‑024‑53557‑y<\/a>.<\/p>\n

Humphreys, M. P. (2024). Temperature effect on seawater f<\/i>CO2<\/sub> revisited: theoretical basis, uncertainty analysis and implications for parameterising carbonic acid equilibrium constants.<\/span> Ocean Science<\/span>, 20(5)<\/span>, 1325‑1350. doi:10.5194\/os‑20‑1325‑2024<\/a>.<\/p>\n

Jiang, L.‑Q., Boyer, T. P., Paver, C. R., Yoo, H., Reagan, J. R., Alin, S. R., Barbero, L., Carter, B. R., Feely, R. A. and Wanninkhof, R. (2024). Climatological distribution of ocean acidification variables along the North American ocean margins.<\/span> Earth System Science Data<\/span>, 16(7)<\/span>, 3383‑3390. doi:10.5194\/essd‑16‑3383‑2024<\/a>.<\/p>\n

Judd, E. J., Tierney, J. E., Lunt, D. J., Monta\u00f1ez, I. P., Huber, B. T., Wing, S. L. and Valdes, P. J. (2024). A 485-million-year history of Earth\u2019s surface temperature.<\/span> Science<\/span>, 385(6715)<\/span>. doi:10.1126\/science.adk3705<\/a>.<\/p>\n

Kossack, J., Mathis, M., Daewel, U., Liu, F., Demir, K. T., Thomas, H. and Schrum, C. (2024). Tidal impacts on air-sea CO2 exchange on the North-West European shelf.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1406896<\/a>.<\/p>\n

Kwon, E. Y., Dunne, J. P. and Lee, K. (2024). Biological export production controls upper ocean calcium carbonate dissolution and CO2<\/sub> buffer capacity.<\/span> Science Advances<\/span>, 10(13)<\/span>. doi:10.1126\/sciadv.adl0779<\/a>.<\/p>\n

Lachkar, Z., Mehari, M., Paparella, F. and Burt, J. A. (2024). Acceleration of Warming, Deoxygenation, and Acidification in the Arabian Gulf Driven by Weakening of Summer Winds.<\/span> Geophysical Research Letters<\/span>, 51(24)<\/span>. doi:10.1029\/2024GL109898<\/a>.<\/p>\n

Lange, N., Fiedler, B., \u00c1lvarez, M., Benoit-Cattin, A., Benway, H., Buttigieg, P. L., Coppola, L., Currie, K., Flecha, S., Gerlach, D. S., Honda, M., Huertas, I. E., Lauvset, S. K., Muller-Karger, F., K\u00f6rtzinger, A., O’Brien, K. M., \u00d3lafsd\u00f3ttir, S. R., Pacheco, F. C., Rueda-Roa, D., Skjelvan, I., Wakita, M., White, A. and Tanhua, T. (2024). Synthesis Product for Ocean Time Series (SPOTS) \u2013 a ship-based biogeochemical pilot.<\/span> Earth System Science Data<\/span>, 16(4)<\/span>, 1901‑1931. doi:10.5194\/essd‑16‑1901‑2024<\/a>.<\/p>\n

Lerner, P., Romanou, A., Nicholson, D., Kelley, M., Ruedy, R. and Russell, G. (2024). The sensitivity of the equatorial pacific ODZ to particulate organic matter remineralization in a climate model under pre-industrial conditions.<\/span> Ocean Modelling<\/span>, 188<\/span>, 102303. doi:10.1016\/j.ocemod.2023.102303<\/a>.<\/p>\n

Lerner, P., Romanou, A., Nicholson, D., Kelley, M., Ruedy, R. and Russell, G. (2024). The sensitivity of the equatorial pacific ODZ to particulate organic matter remineralization in a climate model under pre-industrial conditions.<\/span> Ocean Modelling<\/span>, 188<\/span>, 102303. doi:10.1016\/j.ocemod.2023.102303<\/a>.<\/p>\n

Liang, H., Zhang, J., Zhang, J., Zhang, P., Deng, X., Chen, J., Wang, Z., Long, C., Lu, C., Wang, D. and Liang, Y. (2024). Unveiling the eutrophication crisis: 20 years of nutrient development in Zhanjiang Bay, China.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1373716<\/a>.<\/p>\n

Liu, B., Maerz, J. and Ilyina, T. (2024). Glacial Atlantic Carbon Storage Enhanced by a Shallow AMOC and Marine Aggregates Sinking.<\/span> Geophysical Research Letters<\/span>, 51(24)<\/span>. doi:10.1029\/2024GL109736<\/a>.<\/p>\n

Luo, X., Dong, C., Wei, H., Zhao, W. and Nie, H. (2024). Modeling the Responses of Phytoplankton Assemblage and Biological Pump Efficiency to Environmental Changes in the Chukchi Borderland, Western Arctic Ocean.<\/span> Journal of Geophysical Research: Oceans<\/span>, 129(8)<\/span>. doi:10.1029\/2023JC020780<\/a>.<\/p>\n

Major, W., Giering, S. L. C., Ainsworth, J., Belcher, A., Blackbird, S., Bridger, M., Briggs, N., Carvalho, F., Cl\u00e9ment, L., Cook, K., Dumousseaud, C., Espinola, B., Evans, C., Fielding, S., Hartmann, M., Henson, S., Iversen, M., Kiriakoulakis, K., Lampitt, R., Lovecchio, E., Martin, A., Mayor, D., Moore, M., Pabortsava, K., Pebody, C., Peel, K., Preece, C., Poulton, A., Rayne, R., Saw, K., Stinchcombe, M., Stowasser, G., Tarling, G. A., Thomalla, S., Villa-Alfageme, M., Wolff, G. A. and Sanders, R. (2024). Active and passive organic carbon fluxes during a bloom in the Southern Ocean (South Georgia).<\/span> Scientific Data<\/span>, 11(1)<\/span>. doi:10.1038\/s41597‑024‑04151‑w<\/a>.<\/p>\n

Malsang, M., Resplandy, L., Bopp, L., Zhao, Y., Ditkovsky, S., Yang, F., Paulot, F. and L\u00e9vy, M. (2024). Contemporary decline in northern Indian Ocean primary production offset by rising atmospheric nitrogen deposition.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1418634<\/a>.<\/p>\n

McCoy, D., Damien, P., Yang, S. and Bianchi, D. (2024). Mesoscale Eddy Variability Enhances Fixed Nitrogen Loss and Suppresses Nitrous Oxide Production in Oxygen Minimum Zones.<\/span> Geophysical Research Letters<\/span>, 51(7)<\/span>. doi:10.1029\/2023GL106179<\/a>.<\/p>\n

Millet, B., Gray, W. R., de Lavergne, C. and Roche, D. M. (2024). Oxygen isotope constraints on the ventilation of the modern and glacial Pacific.<\/span> Climate Dynamics<\/span>, 62(1)<\/span>, 649‑664. doi:10.1007\/s00382‑023‑06910‑8<\/a>.<\/p>\n

Mogoll\u00f3n, R., Colas, F., Echevin, V., Tam, J. and Espinoza-Morriber\u00f3n, D. (2024). Spatiotemporal variability and drivers of modeled primary production rates in the Northern Humboldt Current System.<\/span> Ocean Modelling<\/span>, 189<\/span>, 102347. doi:10.1016\/j.ocemod.2024.102347<\/a>.<\/p>\n

M\u00fcller, J. D. and Gruber, N. (2024). Progression of ocean interior acidification over the industrial era.<\/span> Science Advances<\/span>, 10(48)<\/span>. doi:10.1126\/sciadv.ado3103<\/a>.<\/p>\n

Myers, P. G., Barber, D., Braun, M., Buchart, L., de la Guardia, L. C., Deschepper, I., Dupont, F., Ehn, J., Garcia-Quintana, Y., Gillard, L. C., Grivault, N., Hu, X., Kirillov, S. A., Jafarikhasragh, S., Lukovich, J., Maps, F., Marson, J. M., Papakyriakou, T., Pennelly, C., Ridenour, N., Stadnyk, T. A., Sydor, K., Tao, R., Tefs, A., Tremblay, J.‑\u00c9. and Xu, Y. (2024). An overview of the NEMO modelling for the BaySys project.<\/span> Elem Sci Anth<\/span>, 12(1)<\/span>. doi:10.1525\/elementa.2022.00111<\/a>.<\/p>\n

Nowicki, M., DeVries, T. and Siegel, D. A. (2024). The Influence of Air\u2010Sea CO2<\/sub> Disequilibrium on Carbon Sequestration by the Ocean’s Biological Pump.<\/span> Global Biogeochemical Cycles<\/span>, 38(2)<\/span>. doi:10.1029\/2023GB007880<\/a>.<\/p>\n

Osborne, E., Xu, Y.‑Y., Soden, M., McWhorter, J., Barbero, L. and Wanninkhof, R. (2024). A neural network algorithm for quantifying seawater pH using Biogeochemical-Argo floats in the open Gulf of Mexico.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1468909<\/a>.<\/p>\n

Pelle, T., Myers, P. G., Hamilton, A., Mazloff, M., Soderlund, K., Beem, L., Blankenship, D. D., Grima, C., Habbal, F., Skidmore, M. and Greenbaum, J. S. (2024). Ocean circulation, sea ice, and productivity simulated in Jones Sound, Canadian Arctic Archipelago, between 2003\u20132016.<\/span> . doi:10.5194\/egusphere‑2024‑3751<\/a>.<\/p>\n

Pe\u00f1a, M. A. and Fine, I. (2024). Future Physical and Biogeochemical Ocean Conditions under Climate Change along the British Columbia Continental Margin.<\/span> Atmosphere-Ocean<\/span>, 62(1)<\/span>, 2‑23. doi:10.1080\/07055900.2023.2239186<\/a>.<\/p>\n

Resplandy, L., Hogikyan, A., M\u00fcller, J. D., Najjar, R. G., Bange, H. W., Bianchi, D., Weber, T., Cai, W.‑J., Doney, S. C., Fennel, K., Gehlen, M., Hauck, J., Lacroix, F., Landsch\u00fctzer, P., Le Qu\u00e9r\u00e9, C., Roobaert, A., Schwinger, J., Berthet, S., Bopp, L., Chau, T. T. T., Dai, M., Gruber, N., Ilyina, T., Kock, A., Manizza, M., Lachkar, Z., Laruelle, G. G., Liao, E., Lima, I. D., Nissen, C., R\u00f6denbeck, C., S\u00e9f\u00e9rian, R., Toyama, K., Tsujino, H. and Regnier, P. (2024). A Synthesis of Global Coastal Ocean Greenhouse Gas Fluxes.<\/span> Global Biogeochemical Cycles<\/span>, 38(1)<\/span>. doi:10.1029\/2023GB007803<\/a>.<\/p>\n

Rodgers, K. B., Aumont, O., Toyama, K., Resplandy, L., Ishii, M., Nakano, T., Sasano, D., Bianchi, D. and Yamaguchi, R. (2024). Low-latitude mesopelagic nutrient recycling controls productivity and export.<\/span> Nature<\/span>, 632(8026)<\/span>, 802‑807. doi:10.1038\/s41586‑024‑07779‑1<\/a>.<\/p>\n

Roobaert, A., Resplandy, L., Laruelle, G. G., Liao, E. and Regnier, P. (2024). Unraveling the Physical and Biological Controls of the Global Coastal CO2<\/sub> Sink.<\/span> Global Biogeochemical Cycles<\/span>, 38(3)<\/span>. doi:10.1029\/2023GB007799<\/a>.<\/p>\n

Schmittner, A. and Fillman, N. J. (2024). Carbon and carbon-13 in the preindustrial and glacial ocean.<\/span> PLOS Climate<\/span>, 3(7)<\/span>, e0000434. doi:10.1371\/journal.pclm.0000434<\/a>.<\/p>\n

Schultz, C., Dunne, J. P., Liu, X., Drenkard, E. and Carter, B. (2024). Characterizing Subsurface Oxygen Variability in the California Current System (CCS) and Its Links to Water Mass Distribution.<\/span> Journal of Geophysical Research: Oceans<\/span>, 129(2)<\/span>. doi:10.1029\/2023JC020000<\/a>.<\/p>\n

Shaik, I., Yadav, S., Krishna, G., Mahesh, P., Nagamani, P. V., Begum, S. K., Manmode, Y. and Srinivasa Rao, G. (2024). Global Surface Ocean Total Alkalinity Estimation: The Machine Learning Approach.<\/span> IEEE Geoscience and Remote Sensing Letters<\/span>, 21<\/span>, 1‑5. doi:10.1109\/LGRS.2024.3398048<\/a>.<\/p>\n

Steenbeek, J., Ortega, P., Bernardello, R., Christensen, V., Coll, M., Exarchou, E., Fuster\u2010Alonso, A., Heneghan, R., Juli\u00e0 Melis, L., Pennino, M. G., Rivas, D. and Keenlyside, N. (2024). Making Ecosystem Modeling Operational\u2013A Novel Distributed Execution Framework to Systematically Explore Ecological Responses to Divergent Climate Trajectories.<\/span> Earth’s Future<\/span>, 12(3)<\/span>. doi:10.1029\/2023EF004295<\/a>.<\/p>\n

Steiner, N. S. and Reader, C. M. (2024). Trends and Projections in Climate\u2010Related Stressors Impacting Arctic Marine Ecosystems\u2014A CMIP6 Model Analysis.<\/span> Journal of Geophysical Research: Oceans<\/span>, 129(11)<\/span>. doi:10.1029\/2024JC020970<\/a>.<\/p>\n

Steinfeldt, R., Rhein, M. and Kieke, D. (2024). Anthropogenic carbon storage and its decadal changes in the Atlantic between 1990\u20132020.<\/span> Biogeosciences<\/span>, 21(16)<\/span>, 3839‑3867. doi:10.5194\/bg‑21‑3839‑2024<\/a>.<\/p>\n

Sullivan, M. R., Primeau, F. W., Hagstrom, G. I., Wang, W.‑L. and Martiny, A. C. (2024). Integrating Trait\u2010Based Stoichiometry in a Biogeochemical Inverse Model Reveals Links Between Phytoplankton Physiology and Global Carbon Export.<\/span> Global Biogeochemical Cycles<\/span>, 38(3)<\/span>. doi:10.1029\/2023GB007986<\/a>.<\/p>\n

Terhaar, J., Goris, N., M\u00fcller, J. D., DeVries, T., Gruber, N., Hauck, J., Perez, F. F. and S\u00e9f\u00e9rian, R. (2024). Assessment of Global Ocean Biogeochemistry Models for Ocean Carbon Sink Estimates in RECCAP2 and Recommendations for Future Studies.<\/span> Journal of Advances in Modeling Earth Systems<\/span>, 16(3)<\/span>. doi:10.1029\/2023MS003840<\/a>.<\/p>\n

Tsiaras, K., Frangoulis, C. and Stamataki, N. (2024). Carbonate system variability in the Mediterranean Sea: a modelling study.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1347990<\/a>.<\/p>\n

Tsujino, H., Nakano, H., Sakamoto, K., Urakawa, L. S., Toyama, K., Kosugi, N., Kitamura, Y., Ishii, M., Nishikawa, S., Nishikawa, H., Sugiyama, T. and Ishikawa, Y. (2024). Impact of Increased Horizontal Resolution of an Ocean Model on Carbon Circulation in the North Pacific Ocean.<\/span> Journal of Advances in Modeling Earth Systems<\/span>, 16(1)<\/span>. doi:10.1029\/2023MS003720<\/a>.<\/p>\n

Wang, Y., Chassignet, E. P. and Speer, K. (2024). On the dynamics of the Ross Gyre: the relative importance of wind, buoyancy, eddies, and the Antarctic Circumpolar Current.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1465808<\/a>.<\/p>\n

Wang, Z., Xue, C. and Ping, B. (2024). A Reconstructing Model Based on Time\u2013Space\u2013Depth Partitioning for Global Ocean Dissolved Oxygen Concentration.<\/span> Remote Sensing<\/span>, 16(2)<\/span>, 228. doi:10.3390\/rs16020228<\/a>.<\/p>\n

Wimart-Rousseau, C., Steinhoff, T., Klein, B., Bittig, H. and K\u00f6rtzinger, A. (2024). Technical note: Assessment of float pH data quality control methods \u2013 a case study in the subpolar northwest Atlantic Ocean.<\/span> Biogeosciences<\/span>, 21(5)<\/span>, 1191‑1211. doi:10.5194\/bg‑21‑1191‑2024<\/a>.<\/p>\n

Wong, J., M\u00fcnnich, M. and Gruber, N. (2024). Column\u2010Compound Extremes in the Global Ocean.<\/span> AGU Advances<\/span>, 5(3)<\/span>. doi:10.1029\/2023AV001059<\/a>.<\/p>\n

Xue, C., Wang, Z., Yue, L. and Niu, C. (2024). A global four\u2010dimensional gridded dataset of ocean dissolved oxygen concentration retrieval from Argo profiles.<\/span> Geoscience Data Journal<\/span>. doi:10.1002\/gdj3.251<\/a>.<\/p>\n

Yamamoto, K., DeVries, T. and Siegel, D. A. (2024). Metrics for quantifying the efficiency of atmospheric CO2<\/sub> reduction by marine carbon dioxide removal (mCDR).<\/span> Environmental Research Letters<\/span>, 19(10)<\/span>, 104053. doi:10.1088\/1748‑9326\/ad7477<\/a>.<\/p>\n

Yang, G. G., Wang, Q., Feng, J., He, L., Li, R., Lu, W., Liao, E. and Lai, Z. (2024). Can three-dimensional nitrate structure be reconstructed from surface information with artificial intelligence? \u2014 A proof-of-concept study.<\/span> Science of The Total Environment<\/span>, 924<\/span>, 171365. doi:10.1016\/j.scitotenv.2024.171365<\/a>.<\/p>\n

Yang, X., Wynn\u2010Edwards, C. A., Strutton, P. G. and Shadwick, E. H. (2024). Drivers of Air\u2010Sea CO2<\/sub> Flux in the Subantarctic Zone Revealed by Time Series Observations.<\/span> Global Biogeochemical Cycles<\/span>, 38(1)<\/span>. doi:10.1029\/2023GB007766<\/a>.<\/p>\n

Yoder, M. F., Palevsky, H. I. and Fogaren, K. E. (2024). Net Community Production and Inorganic Carbon Cycling in the Irminger Sea.<\/span> . doi:10.22541\/au.170870172.26090018\/v1<\/a>.<\/p>\n

Zhang, X., Wang, L., Yan, J. and Wang, S. (2024). High-spatiotemporal reconstruction of biogeochemical dynamics in Australia integrating satellites products and in-situ observations (2000\u20132022).<\/span> . doi:10.5194\/essd‑2024‑219<\/a>.<\/p>\n

Zhao, X., Gong, X., Gong, X., Liu, J., Wang, G., Wang, L., Guo, X. and Gao, H. (2024). Evolution of 3-D chlorophyll in the northwestern Pacific Ocean using a Gaussian-activation deep neural network model.<\/span> Frontiers in Marine Science<\/span>, 11<\/span>. doi:10.3389\/fmars.2024.1378488<\/a>.<\/p>\n

Bernardello, R., Sicardi, V., Lapin, V., Ortega, P., Ruprich-Robert, Y., Tourigny, E. and Ferrer, E. (2024). Ocean biogeochemical reconstructions to estimate historical ocean CO2<\/sub> uptake.<\/span> Earth System Dynamics<\/span>, 15(5)<\/span>, 1255‑1275. doi:10.5194\/esd‑15‑1255‑2024<\/a>.<\/p>\n

2023 (98)<\/span><\/strong><\/h6>\n

Arroyo, M. C., Fassbender, A. J., Carter, B. R., Edwards, C. A., Fiechter, J., Norgaard, A. and Feely, R. A.(2023). Dissimilar Sensitivities of Ocean Acidification Metrics to Anthropogenic Carbon Accumulation in the Central North Pacific Ocean and California Current Large Marine Ecosystem.<\/span> Geophysical Research Letters<\/span>, 49(15)<\/span>. doi:10.1029\/2022GL097835<\/a>.<\/p>\n

Beadling, R. L., Russell, J. L., Stouffer, R. J. and Goodman, P. J.(2023). Evaluation of Subtropical North Atlantic Ocean Circulation in CMIP5 Models against the Observational Array at 26.5\u00b0N and Its Changes under Continued Warming.<\/span> Journal of Climate<\/span>, 31(23)<\/span>, 9697‑9718. doi:10.1175\/JCLI‑D‑17‑0845.1<\/a>.<\/p>\n

Beaton, A. D., Schaap, A. M., Pascal, R., Hanz, R., Martincic, U., Cardwell, C. L., Morris, A., Clinton-Bailey, G., Saw, K., Hartman, S. E. and Mowlem, M. C.(2023). Lab-on-Chip for In Situ Analysis of Nutrients in the Deep Sea.<\/span> ACS Sensors<\/span>, 7(1)<\/span>, 89‑98. doi:10.1021\/acssensors.1c01685<\/a>.<\/p>\n

Boteler, C., Dowd, M., Oliver, E. C. J., Krainski, E. T. and Wallace, D. W. R. (2023). Trends of Anthropogenic Dissolved Inorganic Carbon in the Northwest Atlantic Ocean Estimated Using a State Space Model.<\/span> Journal of Geophysical Research: Oceans<\/span>, 128(7)<\/span>. doi:10.1029\/2022JC019483<\/a>.<\/p>\n

Brakstad, A., Gebbie, G., V\u00e5ge, K., Jeansson, E. and \u00d3lafsd\u00f3ttir, S. R.(2023). Formation and pathways of dense water in the Nordic Seas based on a regional inversion.<\/span> Progress in Oceanography<\/span>, 102981. doi:10.1016\/j.pocean.2023.102981<\/a>.<\/p>\n

Carroll, D., Menemenlis, D., Dutkiewicz, S., Lauderdale, J. M., Adkins, J. F., Bowman, K. W., Brix, H., Fenty, I., Gierach, M. M., Hill, C., Jahn, O., Landsch\u00fctzer, P., Manizza, M., Mazloff, M. R., Miller, C. E., Schimel, D. S., Verdy, A., Whitt, D. B. and Zhang, H.(2023). Attribution of Space\u2010Time Variability in Global\u2010Ocean Dissolved Inorganic Carbon.<\/span> Global Biogeochemical Cycles<\/span>, 36(3)<\/span>. doi:10.1029\/2021GB007162<\/a>.<\/p>\n

Chen, H., Haumann, F. A., Talley, L. D., Johnson, K. S. and Sarmiento, J. L.(2023). The Deep Ocean’s Carbon Exhaust.<\/span> Global Biogeochemical Cycles<\/span>, 36(7)<\/span>. doi:10.1029\/2021GB007156<\/a>.<\/p>\n

Chmiel, R., Lanning, N., Laubach, A., Lee, J.‑M., Fitzsimmons, J., Hatta, M., Jenkins, W., Lam, P., McIlvin, M., Tagliabue, A. and Saito, M.(2023). Major processes of the dissolved cobalt cycle in the North and equatorial Pacific Ocean.<\/span> Biogeosciences<\/span>, 19(9)<\/span>, 2365‑2395. doi:10.5194\/bg‑19‑2365‑2022<\/a>.<\/p>\n

Crisp, D., Dolman, H., Tanhua, T., McKinley, G. A., Hauck, J., Bastos, A., Sitch, S., Eggleston, S. and Aich, V.(2023). How Well Do We Understand the Land\u2010Ocean\u2010Atmosphere Carbon Cycle?.<\/span> Reviews of Geophysics<\/span>, 60(2)<\/span>. doi:10.1029\/2021RG000736<\/a>.<\/p>\n

Curbelo-Hern\u00e1ndez, D., Gonz\u00e1lez-D\u00e1vila, M. and Santana-Casiano, J.\u00a0M. (2023). The carbonate system and air-sea CO2 fluxes in coastal and open-ocean waters of the Macaronesia.<\/span> Frontiers in Marine Science<\/span>, 10<\/span>. doi:10.3389\/fmars.2023.1094250<\/a>.<\/p>\n

Davila, X., Gebbie, G., Brakstad, A., Lauvset, S. K., McDonagh, E. L., Schwinger, J. and Olsen, A.(2023). How Is the Ocean Anthropogenic Carbon Reservoir Filled?.<\/span> Global Biogeochemical Cycles<\/span>, 36(5)<\/span>. doi:10.1029\/2021GB007055<\/a>.<\/p>\n

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Quay, P. (2023). Organic Matter Export Rates and the Pathways of Nutrient Supply in the Ocean.<\/span> Global Biogeochemical Cycles<\/span>, 37(8)<\/span>. doi:10.1029\/2023GB007855<\/a>.<\/p>\n

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Taucher, J., Bach, L. T., Prowe, A. E. F., Boxhammer, T., Kvale, K. and Riebesell, U.(2023). Enhanced silica export in a future ocean triggers global diatom decline.<\/span> Nature<\/span>, 605(7911)<\/span>, 696‑700. doi:10.1038\/s41586‑022‑04687‑0<\/a>.<\/p>\n

Terhaar, J., Fr\u00f6licher, T. L. and Joos, F.(2023). Observation-constrained estimates of the global ocean carbon sink from Earth system models.<\/span> Biogeosciences<\/span>, 19(18)<\/span>, 4431‑4457. doi:10.5194\/bg‑19‑4431‑2022<\/a>.<\/p>\n

Thomas, M. D. and Zhang, R.(2023). Two Sources of Deep Decadal Variability in the Central Labrador Sea Open\u2010Ocean Convection Region.<\/span> Geophysical Research Letters<\/span>, 49(11)<\/span>. doi:10.1029\/2022GL098825<\/a>.<\/p>\n

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2022 (46)<\/span><\/strong><\/h6>\n

Bennington, V., Galjanic, T. and McKinley, G. A.(2022). Explicit Physical Knowledge in Machine Learning for Ocean Carbon Flux Reconstruction: The pCO2<\/sub>\u2010Residual Method.<\/span> Journal of Advances in Modeling Earth Systems<\/span>, 14(10)<\/span>. doi:10.1029\/2021MS002960<\/a>.<\/p>\n

Buck, V., St\u00e4bler, F., Mohrmann, J., Gonz\u00e1lez, E. and Greinert, J.(2022). Visualising geospatial time series datasets in realtime with the Digital Earth Viewer.<\/span> Computers & Graphics<\/span>, 103<\/span>, 121‑128. doi:10.1016\/j.cag.2022.01.010<\/a>.<\/p>\n

Buchart, L., Castro de la Guardia, L., Xu, Y., Ridenour, N., Marson, J. M., Deschepper, I., Hamilton, A. K., Grivault, N. and Myers, P. G.(2022). Future Climate Scenarios for Northern Baffin Bay and the Pikialasorsuaq (North Water Polynya) Region.<\/span> Atmosphere-Ocean<\/span>, 60(2)<\/span>, 102‑123. doi:10.1080\/07055900.2022.2067028<\/a>.<\/p>\n

Ca\u00ednzos, V.., Velo, A.., P\u00e9rez, F. F. and Hern\u00e1ndez\u2010Guerra, A.(2022). Anthropogenic Carbon Transport Variability in the Atlantic Ocean Over Three Decades.<\/span> Global Biogeochemical Cycles<\/span>, 36(11)<\/span>. doi:10.1029\/2022GB007475<\/a>.<\/p>\n

Chanda, A., Das, S., and Ghosh, T. (Eds.) (2022). Blue Carbon Dynamics of the Indian Ocean: The Present State of the Art<\/span>, 338pp. Springer Switzerland<\/span>.<\/p>\n

Chien, C.‑T., Durgadoo, J. V., Ehlert, D., Frenger, I., Keller, D. P., Koeve, W., Kriest, I., Landolfi, A., Patara, L., Wahl, S. and Oschlies, A.(2022). FOCI-MOPS v1 \u2013 integration of marine biogeochemistry within the Flexible Ocean and Climate Infrastructure version 1 (FOCI 1) Earth system model.<\/span> Geoscientific Model Development<\/span>, 15(15)<\/span>, 5987‑6024. doi:10.5194\/gmd‑15‑5987‑2022<\/a>.<\/p>\n

Cole, D. B., Ozaki, K. and Reinhard, C. T.(2022). Atmospheric Oxygen Abundance, Marine Nutrient Availability, and Organic Carbon Fluxes to the Seafloor.<\/span> Global Biogeochemical Cycles<\/span>, 36(1)<\/span>. doi:10.1029\/2021GB007052<\/a>.<\/p>\n

Dinauer, A., Laufk\u00f6tter, C., Doney, S. C. and Joos, F.(2022). What Controls the Large\u2010Scale Efficiency of Carbon Transfer Through the Ocean’s Mesopelagic Zone? Insights From a New, Mechanistic Model (MSPACMAM).<\/span> Global Biogeochemical Cycles<\/span>, 36(10)<\/span>. doi:10.1029\/2021GB007131<\/a>.<\/p>\n

Di\u015fa, D., M\u00fcnnich, M., Vogt, M. and Gruber, N.(2022). A space-time mosaic of seawater carbonate chemistry conditions in the north-shore Moorea coral reef system.<\/span> Frontiers in Marine Science<\/span>, 9<\/span>. doi:10.3389\/fmars.2022.1004107<\/a>.<\/p>\n

Fransner, F., Fr\u00f6b, F., Tjiputra, J., Goris, N., Lauvset, S. K., Skjelvan, I., Jeansson, E., Omar, A., Chierici, M., Jones, E., Fransson, A., \u00d3lafsd\u00f3ttir, S. R., Johannessen, T. and Olsen, A.(2022). Acidification of the Nordic Seas.<\/span> Biogeosciences<\/span>, 19(3)<\/span>, 979‑1012. doi:10.5194\/bg‑19‑979‑2022<\/a>.<\/p>\n

Fontela, M., Velo, A., Brown, P. J. and P\u00e9rez, F. F.(2022). Carbonate System Species and pH.<\/span> Marine Analytical Chemistry<\/span>, 1‑37. doi:10.1007\/978‑3‑031‑14486‑8_1<\/a>.<\/p>\n

Fu, W., Moore, J. K., Primeau, F., Collier, N., Ogunro, O. O., Hoffman, F. M. and Randerson, J. T.(2022). Evaluation of Ocean Biogeochemistry and Carbon Cycling in CMIP Earth System Models With the International Ocean Model Benchmarking (IOMB) Software System.<\/span> Journal of Geophysical Research: Oceans<\/span>, 127(10)<\/span>. doi:10.1029\/2022JC018965<\/a>.<\/p>\n

Ge, T., Luo, C., Ren, P., Zhang, H., Fan, D., Chen, H., Chen, Z., Zhang, J. and Wang, X.(2022). Stable carbon isotopes of dissolved inorganic carbon in the Western North Pacific Ocean: Proxy for water mixing and dynamics.<\/span> Frontiers in Marine Science<\/span>, 9<\/span>. doi:https:\/\/doi.org\/10.3389\/fmars.2022.998437<\/a>.<\/p>\n

Holzer, M.(2022). The Fate of Oxygen in the Ocean and Its Sensitivity to Local Changes in Biological Production.<\/span> Journal of Geophysical Research: Oceans<\/span>, 127(8)<\/span>. doi:10.1029\/2022JC018802<\/a>.<\/p>\n

Jarn\u00edkov\u00e1, T., Ianson, D., Allen, S. E., Shao, A. E. and Olson, E. M.(2022). Anthropogenic Carbon Increase has Caused Critical Shifts in Aragonite Saturation Across a Sensitive Coastal System.<\/span> Global Biogeochemical Cycles<\/span>, 36(7)<\/span>. doi:10.1029\/2021GB007024<\/a>.<\/p>\n

Jiang, L.‑Q., Pierrot, D., Wanninkhof, R., Feely, R. A., Tilbrook, B., Alin, S., Barbero, L., Byrne, R. H., Carter, B. R., Dickson, A. G., Gattuso, J.‑P., Greeley, D., Hoppema, M., Humphreys, M. P., Karstensen, J., Lange, N., Lauvset, S. K., Lewis, E. R., Olsen, A., P\u00e9rez, F. F., Sabine, C., Sharp, J. D., Tanhua, T., Trull, T. W., Velo, A., Allegra, A. J., Barker, P., Burger, E., Cai, W.‑J., Chen, C.‑T. A., Cross, J., Garcia, H., Hernandez-Ayon, J. M., Hu, X., Kozyr, A., Langdon, C., Lee, K., Salisbury, J., Wang, Z. A. and Xue, L.(2022). Best Practice Data Standards for Discrete Chemical Oceanographic Observations.<\/span> Frontiers in Marine Science<\/span>, 8<\/span>. doi:10.3389\/fmars.2021.705638<\/a>.<\/p>\n

Jiang, Z., Song, Z., Bai, Y., He, X., Yu, S., Zhang, S. and Gong, F.(2022). Remote Sensing of Global Sea Surface pH Based on Massive Underway Data and Machine Learning.<\/span> Remote Sensing<\/span>, 14(10)<\/span>, 2366. doi:10.3390\/rs14102366<\/a>.<\/p>\n

Johnson, G. C., Lumpkin, R., Boyer, T., Bringas, F., Cetini\u0107, I., Chambers, D. P., Cheng, L., Dong, S., Feely, R. A., Fox-Kemper, B., Frajka-Williams, E., Franz, B. A., Fu, Y., Gao, M., Garg, J., Gilson, J., Goni, G., Hamlington, B. D., Hewitt, H. T., Hobbs, W. R., Hu, Z.‑Z., Huang, B., Jevrejeva, S., Johns, W. E., Katsunari, S., Kennedy, J. J., Kersal\u00e9, M., Killick, R. E., Leuliette, E., Locarnini, R., Lozier, M. S., Lyman, J. M., Merrifield, M. A., Mishonov, A., Mitchum, G. T., Moat, B. I., Nerem, R. S., Notz, D., Perez, R. C., Purkey, S. G., Rayner, D., Reagan, J., Schmid, C., Siegel, D. A., Smeed, D. A., Stackhouse, P. W., Sweet, W., Thompson, P. R., Volkov, D. L., Wanninkhof, R., Weller, R. A., Wen, C., Westberry, T. K., Widlansky, M. J., Willis, J. K., Yu, L. and Zhang, H.‑M. (2022). Global Oceans.<\/span> Bulletin of the American Meteorological Society<\/span>, 103(8)<\/span>, S143‑S192. doi:10.1175\/BAMS‑D‑22‑0072.1<\/a>.<\/p>\n

Katsumata, K., Purkey, S. G., Cowley, R., Sloyan, B. M., Diggs, S. C., Moore, T. S., Talley, L. D. and Swift, J. H.(2022). GO-SHIP Easy Ocean: Gridded ship-based hydrographic section of temperature, salinity, and dissolved oxygen.<\/span> Scientific Data<\/span>, 9(1)<\/span>. doi:10.1038\/s41597‑022‑01212‑w <\/a>.<\/p>\n

Krasting, J. P., De Palma, M., Sonnewald, M., Dunne, J. P. and John, J. G.(2022). Regional sensitivity patterns of Arctic Ocean acidification revealed with machine learning.<\/span> Communications Earth & Environment<\/span>, 3(1)<\/span>. doi:10.1038\/s43247‑022‑00419‑4<\/a>.<\/p>\n

Kwon, E. Y., Holzer, M., Timmermann, A. and Primeau, F..(2022). Estimating Three\u2010Dimensional Carbon\u2010To\u2010Phosphorus Stoichiometry of Exported Marine Organic Matter.<\/span> Global Biogeochemical Cycles<\/span>, 36(3)<\/span>. doi:10.1029\/2021GB007154<\/a>.<\/p>\n

Leseurre, C., Lo Monaco, C., Reverdin, G., Metzl, N., Fin, J., Mignon, C. and Benito, L.(2022). Summer trends and drivers of sea surface fCO2<\/sub> and pH changes observed in the southern Indian Ocean over the last two decades (1998\u20132019).<\/span> Biogeosciences<\/span>, 19(10)<\/span>, 2599‑2625. doi:10.5194\/bg‑19‑2599‑2022<\/a>.<\/p>\n

Li, X., Xu, Y.\u2010Y., Kirchman, D. L. and Cai, W.\u2010J.(2022). Carbonate Parameter Estimation and Its Application in Revealing Temporal and Spatial Variation in the South and Mid\u2010Atlantic Bight, USA.<\/span> Journal of Geophysical Research: Oceans<\/span>, 127(7)<\/span>. doi:10.1029\/2022JC018811<\/a>.<\/p>\n

Ma, R., S\u00e9pulcre, S., Licari, L., Haurine, F.., Bassinot, F., Yu, Z. and Colin, C.(2022). Changes in productivity and intermediate circulation in the northern Indian Ocean since the last deglaciation: new insights from benthic foraminiferal Cd\u2009\u2215\u2009Ca records and benthic assemblage analyses.<\/span> Climate of the Past<\/span>, 18(8)<\/span>, 1757‑1774. doi:10.5194\/cp‑18‑1757‑2022<\/a>.<\/p>\n

Mamnun, N., V\u00f6lker, C., Vrekoussis, M. and Nerger, L.(2022). Uncertainties in ocean biogeochemical simulations: Application of ensemble data assimilation to a one-dimensional model.<\/span> Frontiers in Marine Science<\/span>, 9<\/span>. doi:10.3389\/fmars.2022.984236<\/a>.<\/p>\n

Mdutyana, M., Marshall, T., Sun, X., Burger, J. M., Thomalla, S. J., Ward, B. B. and Fawcett, S. E.(2022). Controls on nitrite oxidation in the upper Southern Ocean: insights from winter kinetics experiments in the Indian sector.<\/span> Biogeosciences<\/span>, 19(14)<\/span>, 3425‑3444. doi:10.5194\/bg‑19‑3425‑2022<\/a>.<\/p>\n

Metzl, N., Lo Monaco, C., Leseurre, C., Ridame, C., Fin, J., Mignon, C., Gehlen, M. and Chau, T. T. T.(2022). The impact of the South-East Madagascar Bloom on the oceanic CO2<\/sub> sink.<\/span> Biogeosciences<\/span>, 19(5)<\/span>, 1451‑1468. doi:10.5194\/bg‑19‑1451‑2022<\/a>.<\/p>\n

Mo, A., Kim, D., Yang, E. J., Jung, J., Ko, Y. H., Kang, S.‑H., Cho, K.‑H., Park, K. and Kim, T.‑W.(2022). Factors affecting the subsurface aragonite undersaturation layer in the Pacific Arctic region.<\/span> Marine Pollution Bulletin<\/span>, 183<\/span>, 114060. doi:10.1016\/j.marpolbul.2022.114060<\/a>.<\/p>\n

Na, T., Hwang, J., Kim, S.‑Y., Jeong, S., Rho, T.K. and Lee, T.(2022). Large Increase in Dissolved Inorganic Carbon in the East Sea (Japan Sea) From 1999 to 2019.<\/span> Frontiers in Marine Science<\/span>, 9<\/span>. doi:10.3389\/fmars.2022.825206<\/a>.<\/p>\n

Pearman, T. R. R., Brewin, P. E., Baylis, A. M. M. and Brickle, P.(2022). Deep-Sea Epibenthic Megafaunal Assemblages of the Falkland Islands, Southwest Atlantic.<\/span> Diversity<\/span>, 14(8)<\/span>, 637. doi:10.3390\/d14080637<\/a>.<\/p>\n

Reuning, L., Deik, H., Petrick, B., Auer, G., Takayanagi, H., Iryu, Y., Courtillat, M. and Bassetti, M.\u2010A.(2022). Contrasting intensity of aragonite dissolution and dolomite cementation in glacial versus interglacial intervals of a subtropical carbonate succession.<\/span> Sedimentology<\/span>, 69(5)<\/span>, 2131‑2150. doi:10.1111\/sed.12985<\/a>.<\/p>\n

Roobaert, A.., Resplandy, L., Laruelle, G. G., Liao, E. and Regnier, P.(2022). A framework to evaluate and elucidate the driving mechanisms of coastal sea surface pCO2<\/sub> seasonality using an ocean general circulation model (MOM6-COBALT).<\/span> Ocean Science<\/span>, 18(1)<\/span>, 67‑88. doi:10.5194\/os‑18‑67‑2022<\/a>.<\/p>\n

Samuelsen, A., Schrum, C., Yumruktepe, V. \u00c7.., Daewel, U. and Roberts, E. M.(2022). Environmental Change at Deep-Sea Sponge Habitats Over the Last Half Century: A Model Hindcast Study for the Age of Anthropogenic Climate Change.<\/span> Frontiers in Marine Science<\/span>, 9<\/span>. doi:10.3389\/fmars.2022.737164<\/a>.<\/p>\n

Sims, R. P., Holding, T. M., Land, P. E., Piolle, J.‑F., Green, H. L. and Shutler, J. D.(2022). OceanSODA-UNEXE: A multi-year gridded Amazon and Congo River outflow surface ocean carbonate system dataset.<\/span> . doi:10.5194\/essd‑2022‑294<\/a>.<\/p>\n

Sulpis, O., Humphreys, M. P., Wilhelmus, M. M., Carroll, D., Berelson, W. M., Menemenlis, D., Middelburg, J. J. and Adkins, J. F.(2022). RADIv1: a non-steady-state early diagenetic model for ocean sediments in Julia and MATLAB\/GNU Octave.<\/span> Geoscientific Model Development<\/span>, 15(5)<\/span>, 2105‑2131. doi:10.5194\/gmd‑15‑2105‑2022<\/a>.<\/p>\n

Tanioka, T., Garcia, C. A., Larkin, A. A., Garcia, N. S., Fagan, A. J. and Martiny, A. C.(2022). Global patterns and predictors of C:N:P in marine ecosystems.<\/span> Communications Earth & Environment<\/span>, 3(1)<\/span>. doi:10.1038\/s43247‑022‑00603‑6<\/a>.<\/p>\n

Terhaar, J., Fr\u00f6licher, T. L. and Joos, F.(2023). Ocean acidification in emission-driven temperature stabilization scenarios: the role of TCRE and non-CO2<\/sub> greenhouse gases.<\/span> Environmental Research Letters<\/span>, 18(2)<\/span>, 024033. doi:10.1088\/1748‑9326\/acaf91<\/a>.<\/p>\n

Thompson, D., McCulloch, M., Cole, J. E., Reed, E. V., D\u2019Olivo, J. P., Dyez, K., Lofverstrom, M., Lough, J., Cantin, N., Tudhope, A. W., Cheung, A. H., Vetter, L. and Edwards, R. L.(2022). Marginal Reefs Under Stress: Physiological Limits Render Gal\u00e1pagos Corals Susceptible to Ocean Acidification and Thermal Stress.<\/span> AGU Advances<\/span>, 3(1)<\/span>. doi:10.1029\/2021AV000509<\/a>.<\/p>\n

Turner, C. E., Brown, P. J., Oliver, K. I. C. and McDonagh, E. L.(2022). Decomposing oceanic temperature and salinity change using ocean carbon change.<\/span> Ocean Science<\/span>, 18(2)<\/span>, 523‑548. doi:10.5194\/os‑18‑523‑2022<\/a>.<\/p>\n

Vaittinada Ayar, P., Bopp, L., Christian, J. R., Ilyina, T., Krasting, J. P., S\u00e9f\u00e9rian, R., Tsujino, H., Watanabe, M., Yool, A. and Tjiputra, J.(2022). Contrasting projections of the ENSO-driven CO2<\/sub> flux variability in the equatorial Pacific under high-warming scenario.<\/span> Earth System Dynamics<\/span>, 13(3)<\/span>, 1097‑1118. doi:10.5194\/esd‑13‑1097‑2022<\/a>.<\/p>\n

Wu, Y., Bakker, D. C. E., Achterberg, E. P., Silva, A. N., Pickup, D. D., Li, X., Hartman, S., Stappard, D., Qi, D. and Tyrrell, T.(2022). Integrated analysis of carbon dioxide and oxygen concentrations as a quality control of ocean float data.<\/span> Communications Earth & Environment<\/span>, 3(1)<\/span>. doi:10.1038\/s43247‑022‑00421‑w<\/a>.<\/p>\n

Yang, Z., Ni, J., Zheng, M., Qiu, Y., Chen, Q. and Chen, M.(2022). Reliability assessment and paleo-oceanographic signals of geochemical and isotopic indicators in the North Pacific Subtropical Gyre.<\/span> Marine Geology<\/span>, 446<\/span>, 106777. doi:10.1016\/j.margeo.2022.106777<\/a>.<\/p>\n

Zeng, J., Iida, Y., Matsunaga, T. and Shirai, T.(2022). Surface ocean CO2 concentration and air-sea flux estimate by machine learning with modelled variable trends.<\/span> Frontiers in Marine Science<\/span>, 9<\/span>. doi:10.3389\/fmars.2022.989233<\/a>.<\/p>\n

Zhang, H., Torres-Romero, I., Anjewierden, P., Jaggi, M. and Stoll, H. M.(2022). The DIC carbon isotope evolutions during CO2 bubbling: Implications for ocean acidification laboratory culture.<\/span> Frontiers in Marine Science<\/span>, 9<\/span>. doi:10.3389\/fmars.2022.1045634<\/a>.<\/p>\n

Zhao, Z., Zhang, Y., Shao, Y., Liu, C., Li, W., Fan, H., Dai, H., Yang, Y., Zheng, C. and Gao, X.(2022). Simulation of SO2 removal process from marine exhaust gas by hybrid exhaust gas cleaning systems (EGCS) using seawater and magnesium-based absorbent.<\/span> Separation and Purification Technology<\/span>, 287<\/span>, 120557. doi:10.1016\/j.seppur.2022.120557<\/a>.<\/p>\n

Zhou, Y., Gong, H. and Zhou, F.(2022). Responses of Horizontally Expanding Oceanic Oxygen Minimum Zones to Climate Change Based on Observations.<\/span> Geophysical Research Letters<\/span>, 49(6)<\/span>. doi:10.1029\/2022GL097724<\/a>.<\/p>\n

2021 (64)<\/span><\/strong><\/h6>\n

Asselot, R. (2021), The role of marine biota in the climate system – an Earth system model approach. DOI: 10.13140\/RG.2.2.13951.53928 <\/p>\n

Barth, A., Troupin, C., Reyes, E., Alvera-Azc\u00e1rate, A., Beckers, J.‑M. and Tintor\u00e9, J..(2021). Variational interpolation of high-frequency radar surface currents using DIVAnd.<\/span> Ocean Dynamics<\/span>, 71(3)<\/span>, 293‑308. doi:10.1007\/s10236‑020‑01432‑x<\/a>.<\/p>\n

Bednar\u0161ek, N., Naish, K.‑A., Feely, R. A., Hauri, C., Kimoto, K., Hermann, A. J., Michel, C., Niemi, A. and Pilcher, D.(2021). Integrated Assessment of Ocean Acidification Risks to Pteropods in the Northern High Latitudes: Regional Comparison of Exposure, Sensitivity and Adaptive Capacity.<\/span> Frontiers in Marine Science<\/span>, 8<\/span>. doi:10.3389\/fmars.2021.671497<\/a>.<\/p>\n

Belgacem, M., Schroeder, K., Barth, A., Troupin, C., Pavoni, B., Raimbault, P., Garcia, N., Borghini, M. and Chiggiato, J.(2021). Climatological distribution of dissolved inorganic nutrients in the western Mediterranean Sea (1981\u20132017).<\/span> Earth System Science Data<\/span>, 13(12)<\/span>, 5915‑5949. doi:10.5194\/essd‑13‑5915‑2021<\/a>.<\/p>\n

Burt, D. J., Fr\u00f6b, F. and Ilyina, T.(2021). The Sensitivity of the Marine Carbonate System to Regional Ocean Alkalinity Enhancement.<\/span> Frontiers in Climate<\/span>, 3<\/span>. doi:10.3389\/fclim.2021.624075<\/a>.<\/p>\n

Butensch\u00f6n, M., Lovato, T., Masina, S., Caserini, S. and Grosso, M.(2021). Alkalinization Scenarios in the Mediterranean Sea for Efficient Removal of Atmospheric CO2 and the Mitigation of Ocean Acidification.<\/span> Frontiers in Climate<\/span>, 3<\/span>. doi:10.3389\/fclim.2021.614537 <\/a>.<\/p>\n

Carter, B. R., Bittig, H. C., Fassbender, A. J., Sharp, J. D., Takeshita, Y., Xu, Y.\u2010Y., \u00c1lvarez, M., Wanninkhof, R., Feely, R. A. and Barbero, L.(2021). New and updated global empirical seawater property estimation routines.<\/span> Limnology and Oceanography: Methods<\/span>, 19(12)<\/span>, 785‑809. doi:10.1002\/lom3.10461<\/a>.<\/p>\n

Dunn, R. J. H., Aldred, F., Gobron, N., Miller, J. B., Willett, K. M., Ades, M., Adler, R., Allan, R., P., Allan, R., Anderson, J., Arg\u00fcez, A., Arosio, C., Augustine, J. A., Azorin-Molina, C., Barichivich, J., Beck, H. E., Becker, A., Bellouin, N., Benedetti, A., Berry, D. I., Blenkinsop, S., Bock, O., Bodin, X., Bosilovich, M. G., Boucher, O., Buehler, S. A., Calmettes, B., Carrea, L., Castia, L., Christiansen, H. H., Christy, J. R., Chung, E.‑S., Coldewey-Egbers, M., Cooper, O. R., Cornes, R. C., Covey, C., Cretaux, J.‑F., Crotwell, M., Davis, S. M., de Jeu, R. A. M., Degenstein, D., Delaloye, R., Di Girolamo, L., Donat, M. G., Dorigo, W. A., Durre, I., Dutton, G. S., Duveiller, G., Elkins, J. W., Fioletov, V. E., Flemming, J., Foster, M. J., Frith, S. M., Froidevaux, L., Garforth, J., Gentry, M., Gupta, S. K., Hahn, S., Haimberger, L., Hall, B. D., Harris, I., Hemming, D. L., Hirschi, M., Ho, S.‑. (B.), Hrbacek, F., Hubert, D., Hurst, D. F., Inness, A., Isaksen, K., John, V. O., Jones, P. D., Junod, R., Kaiser, J. W., Kaufmann, V., Kellerer-Pirklbauer, A., Kent, E. C., Kidd, R., Kim, H., Kipling, Z., Koppa, A., Kraemer, B. M., Kratz, D. P., Lan, X., Lantz, K. O., Lavers, D., Loeb, N. G., Loyola, D., Madelon, R., Mayer, M., McCabe, M. F., McVicar, T. R., Mears, C. A., Merchant, C. J., Miralles, D. G., Moesinger, L., Montzka, S. A., Morice, C., M\u00f6singer, L., M\u00fchle, J., Nicolas, J. P., Noetzli, J., Noll, B., O\u2019Keefe, J., Osborn, T. J., Park, T., Pasik, A. J., Pellet, C., Pelto, M. S., Perkins-Kirkpatrick, S. E., Petron, G., Phillips, C., Po-Chedley, S., Polvani, L., Preimesberger, W., Rains, D. G., Randel, W. J., Rayner, N. A., R\u00e9my, S., Ricciardulli, L., Richardson, A. D., Robinson, D. A., Rodell, M., Rodr\u00edguez-Fern\u00e1ndez, N. J., Rosenlof, K.H., Roth, C., Rozanov, A., Rutish\u00e4user, T., S\u00e1nchez-Lugo, A., Sawaengphokhai, P., Scanlon, T., Schenzinger, V., Schlegel, R. W., Sharma, S., Shi, L., Simmons, A. J., Siso, C., Smith, S. L., Soden, B. J., Sofieva, V., Sparks, T. H., Stackhouse, P. W., Steinbrecht, W., Stengel, M., Streletskiy, D. A., Sun-Mack, S., Tans, P., Thackeray, S. J., Thibert, E., Tokuda, D., Tourpali, K., Tye, M. R., van der A, R., van der Schalie, R., van der Schrier, G., van der Vliet, M., van der Werf, G. R., Vance, A., Vernier, J.‑P., Vimont, I. J., V\u00f6mel, H., Vose, R. S., Wang, R., Weber, M., Wiese, D., Wilber, A. C., Wild, J. D., Wong, T., Woolway, R. I., Zhou, X., Yin, X., Zhao, G., Zhao, L., Ziemke, J. R., Ziese, M. and Zotta, R. M. (2021). Global Climate.<\/span> Bulletin of the American Meteorological Society<\/span>, 102(8)<\/span>, S11‑S142. doi:10.1175\/BAMS‑D‑21‑0098.1<\/a>.<\/p>\n

Fassbender, A. J., Orr, J. C. and Dickson, A. G.(2021). Technical note: Interpreting pH changes.<\/span> Biogeosciences<\/span>, 18(4)<\/span>, 1407‑1415. doi:10.5194\/bg‑18‑1407‑2021<\/a>.<\/p>\n

Farmer, J. R., Hertzberg, J. E., Cardinal, D., Fietz, S., Hendry, K., Jaccard, S. L., Paytan, A., Rafter, P. A., Ren, H., Somes, C. J., Sutton, J. N. and (2021). Assessment of C, N, and Si Isotopes as Tracers of Past Ocean Nutrient and Carbon Cycling.<\/span> Global Biogeochemical Cycles<\/span>, 35(7)<\/span>. doi:10.1029\/2020GB006775<\/a><\/p>\n

Findlay, H. S. and Turley, C.(2021). Ocean acidification and climate change.<\/span> Climate Change<\/span>, 251‑279. doi:10.1016\/B978‑0‑12‑821575‑3.00013‑X<\/a>.<\/p>\n

Fourrier, M.(2021). Impact des for\u00e7ages physiques sur la dynamique des \u00e9l\u00e9ments biog\u00e9ochimiques en mer M\u00e9diterran\u00e9e: approche coupl\u00e9e observations in situ et r\u00e9seaux de neurones.<\/span> Sorbonne University.<\/span><\/p>\n

Gac, J.‑P., Marrec, P., Cariou, T., Grosstefan, E., Mac\u00e9, \u00c9., Rimmelin-Maury, P., Vernet, M. and Bozec, Y.(2021). Decadal Dynamics of the CO2 System and Associated Ocean Acidification in Coastal Ecosystems of the North East Atlantic Ocean.<\/span> Frontiers in Marine Science<\/span>, 8<\/span>. doi:10.3389\/fmars.2021.688008<\/a>.<\/p>\n

Gonz\u00e1lez\u2010Lanchas, A., Hern\u00e1ndez\u2010Alm\u00e9ida, I., Flores, J.\u2010A., Sierro, F. J., Guitian, J. and Stoll, H. M.(2021). Carbon Isotopic Fractionation of Alkenones and Gephyrocapsa Coccoliths Over the Late Quaternary (Marine Isotope Stages 12\u20139) Glacial\u2010Interglacial Cycles at the Western Tropical Atlantic.<\/span> Paleoceanography and Paleoclimatology<\/span>, 36(8)<\/span>. doi:10.1029\/2020PA004175<\/a>.<\/p>\n

Gonz\u00e1lez-Santana, D., Gonz\u00e1lez-D\u00e1vila, M., Lohan, M. C., Artigue, L., Planquette, H.., Sarthou, G., Tagliabue, A. and Santana-Casiano, J. M.(2021). Variability in iron (II) oxidation kinetics across diverse hydrothermal sites on the northern Mid Atlantic Ridge.<\/span> Geochimica et Cosmochimica Acta<\/span>, 297<\/span>, 143‑157. doi:10.1016\/j.gca.2021.01.013<\/a>.<\/p>\n

Gr\u00e9goire, M., Gar\u00e7on, V., Garcia, H., Breitburg, D., Isensee, K., Oschlies, A., Telszewski, M., Barth, A., Bittig, H. C., Carstensen, J., Carval, T., Chai, F., Chavez, F., Conley, D., Coppola, L., Crowe, S., Currie, K., Dai, M., Deflandre, B., Dewitte, B., Diaz, R., Garcia-Robledo, E., Gilbert, D., Giorgetti, A., Glud, R., Gutierrez, D., Hosoda, S., Ishii, M., Jacinto, G., Langdon, C., Lauvset, S. K., Levin, L. A., Limburg, K. E., Mehrtens, H., Montes, I., Naqvi, W., Paulmier, A.., Pfeil, B., Pitcher, G., Pouliquen, S., Rabalais, N., Rabouille, C., Recape, V., Roman, M.., Rose, K., Rudnick, D., Rummer, J., Schmechtig, C., Schmidtko, S., Seibel, B., Slomp, C., Sumalia, U. R., Tanhua, T., Thierry, V., Uchida, H., Wanninkhof, R. and Yasuhara, M.(2021). A Global Ocean Oxygen Database and Atlas for Assessing and Predicting Deoxygenation and Ocean Health in the Open and Coastal Ocean.<\/span> Frontiers in Marine Science<\/span>, 8<\/span>. doi:10.3389\/fmars.2021.724913<\/a>.<\/p>\n

Gregor, L. and Gruber, N.(2021). OceanSODA-ETHZ: a global gridded data set of the surface ocean carbonate system for seasonal to decadal studies of ocean acidification.<\/span> Earth System Science Data<\/span>, 13(2)<\/span>, 777‑808. doi:10.5194\/essd‑13‑777‑2021<\/a>.<\/p>\n

Hansen, C., van der Meeren, G. I., Loeng, H. and Skogen, M. D.(2021). Assessing the state of the Barents Sea using indicators: how, when, and where?.<\/span> ICES Journal of Marine Science<\/span>, 78(8)<\/span>, 2983‑2998. doi:10.1093\/icesjms\/fsab053<\/a>.<\/p>\n

Hayashida, H., Jin, M., Steiner, N. S., Swart, N. C., Watanabe, E., Fiedler, R., Hogg, A. M.C., Kiss, A. E., Matear, R. J. and Strutton, P. G.(2021). Ice Algae Model Intercomparison Project phase 2 (IAMIP2).<\/span> Geoscientific Model Development<\/span>, 14(11)<\/span>, 6847‑6861. doi:10.5194\/gmd‑14‑6847‑2021<\/a>.<\/p>\n

Hines, S. K. V., Bolge, L., Goldstein, S. L., Charles, C. D., Hall, I. R. and Hemming, S. R.(2021). Little Change in Ice Age Water Mass Structure From Cape Basin Benthic Neodymium and Carbon Isotopes.<\/span> Paleoceanography and Paleoclimatology<\/span>, 36(11)<\/span>. doi:10.1029\/2021PA004281<\/a>.<\/p>\n

Holdsworth, A. M., Zhai, L., Lu, Y. and Christian, J. R.(2021). Future Changes in Oceanography and Biogeochemistry Along the Canadian Pacific Continental Margin.<\/span> Frontiers in Marine Science<\/span>, 8<\/span>. doi:10.3389\/fmars.2021.602991<\/a>.<\/p>\n

Holzer, M., DeVries, T. and de Lavergne, C.(2021). Diffusion controls the ventilation of a Pacific Shadow Zone above abyssal overturning.<\/span> Nature Communications<\/span>, 12(1)<\/span>. doi:10.1038\/s41467‑021‑24648‑x<\/a>.<\/p>\n

Howarth, R. W., Chan, F., Swaney, D. P., Marino, R. M. and Hayn, M.(2021). Role of external inputs of nutrients to aquatic ecosystems in determining prevalence of nitrogen vs. phosphorus limitation of net primary productivity.<\/span> Biogeochemistry<\/span>. doi:10.1007\/s10533‑021‑00765‑z<\/a>.<\/p>\n

Hunt, C. W., Salisbury, J. E., Vandemark, D., A\u00dfmann, S., Fietzek, P., Melrose, C., Wanninkhof, R. and Azetsu-Scott, K.(2021). Variability of USA East Coast surface total alkalinity distributions revealed by automated instrument measurements.<\/span> Marine Chemistry<\/span>, 232<\/span>, 103960. doi:10.1016\/j.marchem.2021.103960<\/a>.<\/p>\n

Jiang, L.‑Q., Feely, R. A., Wanninkhof, R., Greeley, D., Barbero, L., Alin, S., Carter, B. R., Pierrot, D., Featherstone, C., Hooper, J., Melrose, C., Monacci, N., Sharp, J. D., Shellito, S., Xu, Y.‑Y., Kozyr, A., Byrne, R. H., Cai, W.‑J., Cross, J., Johnson, G. C., Hales, B., Langdon, C., Mathis, J., Salisbury, J. and Townsend, D. W.(2021). Coastal Ocean Data Analysis Product in North America (CODAP-NA) \u2013 an internally consistent data product for discrete inorganic carbon, oxygen, and nutrients on the North American ocean margins.<\/span> Earth System Science Data<\/span>, 13(6)<\/span>, 2777‑2799. doi:10.5194\/essd‑13‑2777‑2021<\/a>.<\/p>\n

Johnson, G. C., Lumpkin, R., Alin, S. R., Amaya, D. J., Baringer, M. O., Boyer, T., Brandt, P., Carter, B. R., Cetini\u0107, I., Chambers, D. P., Cheng, L., Collins, A. U., Cosca, C., Domingues, R., Dong, S., Feely, R. A., Frajka-Williams, E., Franz, B. A., Gilson, J., Goni, G., Hamlington, B. D., Herrford, J., Hu, Z.‑Z., Huang, B., Ishii, M., Jevrejeva, S., Kennedy, J. J., Kersal\u00e9, M., Killick, R. E., Landsch\u00fctzer, P., Lankhorst, M., Leuliette, E., Locarnini, R., Lyman, J. M., Marra, J. J., Meinen, C. S., Merrifield, M. A., Mitchum, G. T., Moat, B. I., Nerem, R. S., Perez, R. C., Purkey, S. G., Reagan, J., Sanchez-Franks, A., Scannell, H. A., Schmid, C., Scott, J. P., Siegel, D. A., Smeed, D. A., Stackhouse, P. W., Sweet, W., Thompson, P. R., Tri\u00f1anes, J. A., Volkov, D. L., Wanninkhof, R., Weller, R. A., Wen, C., Westberry, T. K., Widlansky, M. J., Wilber, A. C., Yu, L. and Zhang, H.‑M. (2021). Global Oceans.<\/span> Bulletin of the American Meteorological Society<\/span>, 102(8)<\/span>, S143‑S198. doi:10.1175\/BAMS‑D‑21‑0083.1<\/a>.<\/p>\n

Juva, K., Kutti, T., Chierici, M., Dullo, W.‑C. and Fl\u00f6gel, S.(2021). Cold-Water Coral Reefs in the Langenuen Fjord, Southwestern Norway\u2014A Window into Future Environmental Change.<\/span> Oceans<\/span>, 2(3)<\/span>, 583‑610. doi:10.3390\/oceans2030033<\/a>.<\/p>\n

Ko, Y. H., Park, G.‑H., Kim, D. and Kim, T.‑W.(2021). Variations in Seawater pCO2 Associated With Vertical Mixing During Tropical Cyclone Season in the Northwestern Subtropical Pacific Ocean.<\/span> Frontiers in Marine Science<\/span>, 8<\/span>. doi:10.3389\/fmars.2021.679314<\/a>.<\/p>\n

Lavoie, D., Lambert, N., Starr, M., Chass\u00e9, J.., Riche, O., Le Clainche, Y., Azetsu-Scott, K., B\u00e9jaoui, B., Christian, J. R. and Gilbert, D.(2021). The Gulf of St. Lawrence Biogeochemical Model: A Modelling Tool for Fisheries and Ocean Management.<\/span> Frontiers in Marine Science<\/span>, 8<\/span>. doi:10.3389\/fmars.2021.732269<\/a>.<\/p>\n

Lee, C.\u2010H., Lee, K., Ko, Y. H. and Lee, J.\u2010S.(2021). Contribution of Marine Phytoplankton and Bacteria to Alkalinity: An Uncharacterized Component.<\/span> Geophysical Research Letters<\/span>, 48(19)<\/span>. doi:10.1029\/2021GL093738<\/a>.<\/p>\n

Lerner, P., Romanou, A., Kelley, M., Romanski, J., Ruedy, R. and Russell, G.(2021). Drivers of Air\u2010Sea CO2 Flux Seasonality and its Long\u2010Term Changes in the NASA\u2010GISS Model CMIP6 Submission.<\/span> Journal of Advances in Modeling Earth Systems<\/span>, 13(2)<\/span>. doi:10.1029\/2019MS002028<\/a>.<\/p>\n

Li, S., Cui, Z., Bao, M., Luan, X., Teng, F., Li, S., Xu, T. and Zheng, L.(2021). Contrasting vertical distribution between prokaryotes and fungi in different water masses on the Ninety-East Ridge, Southern Indian Ocean.<\/span> Journal of Oceanology and Limnology<\/span>. doi:10.1007\/s00343‑021‑1046‑5<\/a>.<\/p>\n

Liu, B., Six, K. D. and Ilyina, T.(2021). Incorporating the stable carbon isotope 13<\/sup>C in the ocean biogeochemical component of the Max Planck Institute Earth System Model.<\/span> Biogeosciences<\/span>, 18(14)<\/span>, 4389‑4429. doi:10.5194\/bg‑18‑4389‑2021<\/a>.<\/p>\n

Liu, F., Daewel, U., Samuelsen, A., Brune, S., Hanz, U., Pohlmann, H., Baehr, J. and Schrum, C.(2021). Can Environmental Conditions at North Atlantic Deep-Sea Habitats Be Predicted Several Years Ahead? \u2014\u2014Taking Sponge Habitats as an Example.<\/span> Frontiers in Marine Science<\/span>, 8<\/span>. doi:10.3389\/fmars.2021.703297<\/a>.<\/p>\n

Liu, X., Stock, C. A., Dunne, J. P., Lee, M., Shevliakova, E., Malyshev, S. and Milly, P. C. D.(2021). Simulated Global Coastal Ecosystem Responses to a Half\u2010Century Increase in River Nitrogen Loads.<\/span> Geophysical Research Letters<\/span>, 48(17)<\/span>. doi:10.1029\/2021GL094367<\/a>.<\/p>\n

Lotterhos, K. E., L\u00e1ruson, \u00c1. J. and Jiang, L.‑Q.(2021). Novel and disappearing climates in the global surface ocean from 1800 to 2100.<\/span> Scientific Reports<\/span>, 11(1)<\/span>. doi:10.1038\/s41598‑021‑94872‑4<\/a>.<\/p>\n

Mart\u00ednez-Cabanas, M.., Esposito, M., Gros, J., Linke, P., Schmidt, M., Triest, J. and Achterberg, E. P.(2021). Deviations from environmental baseline: Detection of subsea CO2 release in the water column from real-time measurements at a potential offshore Carbon Dioxide Storage site.<\/span> International Journal of Greenhouse Gas Control<\/span>, 109<\/span>, 103369. doi:10.1016\/j.ijggc.2021.103369<\/a>.<\/p>\n

Nissen, C., Gruber, N., M\u00fcnnich, M. and Vogt, M.(2021). Southern Ocean Phytoplankton Community Structure as a Gatekeeper for Global Nutrient Biogeochemistry.<\/span> Global Biogeochemical Cycles<\/span>, 35(8)<\/span>. doi:10.1029\/2021GB006991<\/a>.<\/p>\n

Nissen, C., Timmermann, R., Hoppema, M., G\u00fcrses, \u00d6.. and Hauck, J.(2023). Abruptly attenuated carbon sequestration with Weddell Sea dense waters by 2100.<\/span> Nature Communications<\/span>, 13(1)<\/span>. doi:10.1038\/s41467‑022‑30671‑3<\/a>.<\/p>\n

Nissen, C. and Vogt, M.(2021). Factors controlling the competition between Phaeocystis<\/i> and diatoms in the Southern Ocean and implications for carbon export fluxes.<\/span> Biogeosciences<\/span>, 18(1)<\/span>, 251‑283. doi:10.5194\/bg‑18‑251‑2021<\/a>.<\/p>\n

Omar, A. M., Garc\u00eda-Ib\u00e1\u00f1ez, M. I., Schaap, A., Oleynik, A., Esposito, M., Jeansson, E., Loucaides, S., Thomas, H. and Alendal, G.(2021). Detection and quantification of CO2 seepage in seawater using the stoichiometric Cseep method: Results from a recent subsea CO2 release experiment in the North Sea.<\/span> International Journal of Greenhouse Gas Control<\/span>, 108<\/span>, 103310. doi:10.1016\/j.ijggc.2021.103310<\/a>.<\/p>\n

Osman, M. B., Tierney, J. E., Zhu, J., Tardif, R., Hakim, G. J., King, J. and Poulsen, C. J.(2021). Globally resolved surface temperatures since the Last Glacial Maximum.<\/span> Nature<\/span>, 599(7884)<\/span>, 239‑244. doi:10.1038\/s41586‑021‑03984‑4<\/a>.<\/p>\n

P\u00e9rez, F. F., Olafsson, J., \u00d3lafsd\u00f3ttir, S. R., Fontela, M. and Takahashi, T.(2021). Contrasting drivers and trends of ocean acidification in the subarctic Atlantic.<\/span> Scientific Reports<\/span>, 11(1)<\/span>. doi:10.1038\/s41598‑021‑93324‑3<\/a>.<\/p>\n

Phelps, S. R., Stoll, H. M., Bolton, C. T., Beaufort, L. and Polissar, P. J.(2021). Controls on Alkenone Carbon Isotope Fractionation in the Modern Ocean.<\/span> Geochemistry, Geophysics, Geosystems<\/span>, 22(12)<\/span>. doi:10.1029\/2021GC009658<\/a>.<\/p>\n

Possenti, L., Skjelvan, I., Atamanchuk, D., Tengberg, A., Humphreys, M. P., Loucaides, S., Fernand, L. and Kaiser, J.(2021). Norwegian Sea net community production estimated from O2<\/sub> and prototype CO2<\/sub> optode measurements on a Seaglider.<\/span> Ocean Science<\/span>, 17(2)<\/span>, 593‑614. doi:10.5194\/os‑17‑593‑2021<\/a>.<\/p>\n

Quay, P.(2021). Impact of the Elemental Composition of Exported Organic Matter on the Observed Dissolved Nutrient and Trace Element Distributions in the Upper Layer of the Ocean.<\/span> Global Biogeochemical Cycles<\/span>, 35(10)<\/span>. doi:10.1029\/2020GB006902<\/a>.<\/p>\n

Samperiz, A., Robinson, L. F., Stewart, J. A., Strawson, I., Leng, M. J., Rosenheim, B. E., Ciscato, E. R., Hendry, K. R. and Santodomingo, N.(2020). Stylasterid corals: A new paleotemperature archive.<\/span> Earth and Planetary Science Letters<\/span>, 545<\/span>, 116407. doi:10.1016\/j.epsl.2020.116407<\/a>.<\/p>\n

Sarkar, A., Mishra, R., Bhaskar, P. V., Anilkumar, N., Sabu, P. and Soares, M.(2021). Potential Role of Major Phytoplankton Communities on pCO2 Modulation in the Indian Sector of Southern Ocean.<\/span> Thalassas: An International Journal of Marine Sciences<\/span>. doi:10.1007\/s41208‑021‑00323‑2<\/a>.<\/p>\n

Schultz, C., Doney, S. C., Hauck, J., Kavanaugh, M. T. and Schofield, O.(2021). Modeling Phytoplankton Blooms and Inorganic Carbon Responses to Sea\u2010Ice Variability in the West Antarctic Peninsula.<\/span> Journal of Geophysical Research: Biogeosciences<\/span>, 126(4)<\/span>. doi:10.1029\/2020JG006227<\/a>.<\/p>\n

Seland, \u00d8., Bentsen, M., Olivi\u00e9, D., Toniazzo, T., Gjermundsen, A., Graff, L. S., Debernard, J. B., Gupta, A. K., He, Y.‑C., Kirkev\u00e5g, A., Schwinger, J., Tjiputra, J., Aas, K. S., Bethke, I., Fan, Y., Griesfeller, J., Grini, A., Guo, C., Ilicak, M., Karset, I. H. H., Landgren, O., Liakka, J., Moseid, K. O., Nummelin, A., Spensberger, C., Tang, H., Zhang, Z., Heinze, C., Iversen, T. and Schulz, M.(2020). Overview of the Norwegian Earth System Model (NorESM2) and key climate response of CMIP6 DECK, historical, and scenario simulations.<\/span> Geoscientific Model Development<\/span>, 13(12)<\/span>, 6165‑6200. doi:10.5194\/gmd‑13‑6165‑2020<\/a>.<\/p>\n

Seok, M.‑W., Kim, D., Park, G.‑H., Lee, K., Kim, T.‑H., Jung, J., Kim, K., Park, K.‑T., Kim, Y.‑H., Mo, A., Park, S., Ko, Y. H., Kang, J., Kim, H. and Kim, T.‑W.(2021). Atmospheric deposition of inorganic nutrients to the Western North Pacific Ocean.<\/span> Science of The Total Environment<\/span>, 793<\/span>, 148401. doi:10.1016\/j.scitotenv.2021.148401<\/a>.<\/p>\n

Sk\u00e1kala, J., Ford, D., Bruggeman, J., Hull, T., Kaiser, J., King, R. R., Loveday, B., Palmer, M. R., Smyth, T., Williams, C. A. J. and Ciavatta, S.(2021). Towards a Multi\u2010Platform Assimilative System for North Sea Biogeochemistry.<\/span> Journal of Geophysical Research: Oceans<\/span>, 126(4)<\/span>. doi:10.1029\/2020JC016649<\/a>.<\/p>\n

Smoli\u0144ski, S., Denechaud, C., von Leesen, G., Geffen, A. J., Gr\u00f8nkj\u00e6r, P., Godiksen, J. A. and Campana, S. E.(2021). Differences in metabolic rate between two Atlantic cod (Gadus morhua) populations estimated with carbon isotopic composition in otoliths.<\/span> PLOS ONE<\/span>, 16(4)<\/span>, e0248711. doi:10.1371\/journal.pone.0248711<\/a>.<\/p>\n

Sulpis, O., Jeansson, E., Dinauer, A., Lauvset, S. K. and Middelburg, J. J.(2021). Calcium carbonate dissolution patterns in the ocean.<\/span> Nature Geoscience<\/span>, 14(6)<\/span>, 423‑428. doi:10.1038\/s41561‑021‑00743‑y<\/a>.<\/p>\n

Stewart, J. A., Li, T., Spooner, P. T., Burke, A., Chen, T., Roberts, J., Rae, J. W. B., Peck, V., Kender, S., Liu, Q. and Robinson, L. F.(2021). Productivity and Dissolved Oxygen Controls on the Southern Ocean Deep\u2010Sea Benthos During the Antarctic Cold Reversal.<\/span> Paleoceanography and Paleoclimatology<\/span>, 36(10)<\/span>. doi:10.1029\/2021PA004288<\/a>.<\/p>\n

Swierczek, S., Mazloff, M. R., Morzfeld, M. and Russell, J. L.(2021). The Effect of Resolution on Vertical Heat and Carbon Transports in a Regional Ocean Circulation Model of the Argentine Basin.<\/span> Journal of Geophysical Research: Oceans<\/span>, 126(7)<\/span>. doi:10.1029\/2021JC017235<\/a>.<\/p>\n

Takahashi, H. A., Handa, H. and Minami, M.(2021). A SIMPLE CO2 EXTRACTION METHOD FOR RADIOCARBON ANALYSES OF DISSOLVED INORGANIC CARBON IN WATER SAMPLES WITHOUT A CARRIER GAS.<\/span> Radiocarbon<\/span>, 63(4)<\/span>, 1339‑1353. doi:10.1017\/RDC.2021.48<\/a>.<\/p>\n

Tan, Z., Zhang, B., Wu, X., Dong, M. and Cheng, L.(2021). Quality control for ocean observations: From present to future.<\/span> Science China Earth Sciences<\/span>. doi:10.1007\/s11430‑021‑9846‑7<\/a>.<\/p>\n

Tanhua, T., Lauvset, S. K., Lange, N., Olsen, A., \u00c1lvarez, M., Diggs, S., Bittig, H. C., Brown, P. J., Carter, B. R., da Cunha, L. C., Feely, R. A., Hoppema, M., Ishii, M., Jeansson, E., Kozyr, A., Murata, A., P\u00e9rez, F. F., Pfeil, B., Schirnick, C., Steinfeldt, R., Telszewski, M., Tilbrook, B., Velo, A., Wanninkhof, R., Burger, E., O\u2019Brien, K. and Key, R. M.(2021). A vision for FAIR ocean data products.<\/span> Communications Earth & Environment<\/span>, 2(1)<\/span>. doi:10.1038\/s43247‑021‑00209‑4<\/a>.<\/p>\n

Terhaar, J., Fr\u00f6licher, T. L. and Joos, F.(2021). Southern Ocean anthropogenic carbon sink constrained by sea surface salinity.<\/span> Science Advances<\/span>, 7(18)<\/span>, eabd5964. doi:10.1126\/sciadv.abd5964<\/a>.<\/p>\n

Terhaar, J., Torres, O., Bourgeois, T.. and Kwiatkowski, L.(2021). Arctic Ocean acidification over the 21st century co-driven by anthropogenic carbon increases and freshening in the CMIP6 model ensemble.<\/span> Biogeosciences<\/span>, 18(6)<\/span>, 2221‑2240. doi:10.5194\/bg‑18‑2221‑2021<\/a>.<\/p>\n

Valsala, V., Sreeush, M.G., Anju, M., Sreenivas, P., Tiwari, Y. K., Chakraborty, K. and Sijikumar, S.(2021). An observing system simulation experiment for Indian Ocean surface pCO2 measurements.<\/span> Progress in Oceanography<\/span>, 194<\/span>, 102570. doi:10.1016\/j.pocean.2021.102570<\/a>.<\/p>\n

Yin, T., Papadimitriou, S., R\u00e9rolle, V. M.C., Arundell, M., Cardwell, C. L., Walk, J., Palmer, M. R., Fowell, S. E., Schaap, A., Mowlem, M. C. and Loucaides, S.(2021). A Novel Lab-on-Chip Spectrophotometric pH Sensor for Autonomous In Situ Seawater Measurements to 6000 m Depth on Stationary and Moving Observing Platforms.<\/span> Environmental Science & Technology<\/span>, 55(21)<\/span>, 14968‑14978. doi:10.1021\/acs.est.1c03517<\/a>.<\/p>\n

Yool, A., Palmi\u00e9ri, J., Jones, C. G., de Mora, L., Kuhlbrodt, T., Popova, E. E., Nurser, A. J. G., Hirschi, J., Blaker, A. T., Coward, A. C., Blockley, E. W. and Sellar, A. A.(2021). Evaluating the physical and biogeochemical state of the global ocean component of UKESM1 in CMIP6 historical simulations.<\/span> Geoscientific Model Development<\/span>, 14(6)<\/span>, 3437‑3472. doi:10.5194\/gmd‑14‑3437‑2021<\/a>.<\/p>\n

2020 (29)<\/span><\/strong><\/h6>\n

Ades, M., Adler, R., Allan, R., Allan, R. P., Anderson, J., Arg\u00fcez, A., Arosio, C., Augustine, J. A., Azorin-Molina, C., Barichivich, J., Barnes, J., Beck, H. E., Becker, A., Bellouin, N., Benedetti, A., Berry, D. I., Blenkinsop, S., Bock, O., Bosilovich, M. G., Boucher, O., Buehler, S. A., Carrea, L., Christiansen, H. H., Chouza, F., Christy, J. R., Chung, E.‑S., Coldewey-Egbers, M., Compo, G. P., Cooper, O. R., Covey, C., Crotwell, A., Davis, S. M., de Eyto, E., de Jeu, R. A. M., VanderSat, B.V., DeGasperi, C. L., Degenstein, D., Di Girolamo, L., Dokulil, M. T., Donat, M. G., Dorigo, W. A., Durre, I., Dutton, G. S., Duveiller, G., Elkins, J. W., Fioletov, V. E., Flemming, J., Foster, M. J., Frey, R. A., Frith, S. M., Froidevaux, L., Garforth, J., Gupta, S. K., Haimberger, L., Hall, B. D., Harris, I., Heidinger, A. K., Hemming, D. L., Ho, S.‑. (B.), Hubert, D., Hurst, D. F., H\u00fcser, I., Inness, A., Isaksen, K., John, V., Jones, P. D., Kaiser, J. W., Kelly, S., Khaykin, S., Kidd, R., Kim, H., Kipling, Z., Kraemer, B. M., Kratz, D. P., La Fuente, R. S., Lan, X., Lantz, K. O., Leblanc, T., Li, B., Loeb, N. G., Long, C. S., Loyola, D., Marszelewski, W., Martens, B., May, L., Mayer, M., McCabe, M. F., McVicar, T. R., Mears, C. A., Menzel, W. P., Merchant, C. J., Miller, B. R., Miralles, D. G., Montzka, S. A., Morice, C., Mu\u0308hle, J., Myneni, R., Nicolas, J. P., Noetzli, J., Osborn, T. J., Park, T., Pasik, A., Paterson, A. M., Pelto, M. S., Perkins-Kirkpatrick, S., P\u00e9tron, G., Phillips, C., Pinty, B., Po-Chedley, S., Polvani, L., Preimesberger, W., Pulkkanen, M., Randel, W. J., R\u00e9my, S., Ricciardulli, L., Richardson, A. D., Rieger, L., Robinson, D. A., Rodell, M., Rosenlof, K. H., Roth, C., Rozanov, A., Rusak, J. A., Rusanovskaya, O., Rutish\u00e4user, T., S\u00e1nchez-Lugo, A., Sawaengphokhai, P., Scanlon, T., Schenzinger, V., Schladow, S. G., Schlegel, R. W., Schmid, Martin, E., Selkirk, H. B., Sharma, S., Shi, L., Shimaraeva, S. V., Silow, E. A., Simmons, A. J., Smith, C. A., Smith, S. L., Soden, B. J., Sofieva, V., Sparks, T. H., Stackhouse, P. W., Steinbrecht, W., Streletskiy, D. A., Taha, G., Telg, H., Thackeray, S. J., Timofeyev, M. A., Tourpali, K., Tye, M. R., van der A, R. J., van der Schalie, R., V.S. B.V., van der SchrierW. Paul, G., van der Werf, G. R., Verburg, P., Vernier, J.‑P., V\u00f6mel, H., Vose, R. S., Wang, R., Watanabe, S. G., Weber, M., Weyhenmeyer, G. A., Wiese, D., Wilber, A. C., Wild, J. D., Wong, T., Woolway, R. I., Yin, X., Zhao, L., Zhao, G., Zhou, X., Ziemke, J. R. and Ziese, M.(2025). Global Climate.<\/span> Bulletin of the American Meteorological Society<\/span>, 101(8)<\/span>, S9‑S128. doi:10.1175\/BAMS‑D‑20‑0104.1<\/a>.<\/p>\n

Allen,\u00a0K. A., Sikes,\u00a0E. L., Anderson,\u00a0R. F. and Rosenthal,\u00a0Y.(2020). Rapid Loss of CO2 From the South Pacific Ocean During the Last Glacial Termination.<\/span> Paleoceanography and Paleoclimatology<\/span>, 35(2)<\/span>. doi:10.1029\/2019pa003766<\/a>.<\/p>\n

\u00c1lvarez, M., Fajar, N. M., Carter, B. R., Guallart, E. F., P\u00e9rez, F. F., Woosley, R. J. and Murata, A.(2020). Global Ocean Spectrophotometric pH Assessment: Consistent Inconsistencies.<\/span> Environmental Science & Technology<\/span>, 54(18)<\/span>, 10977‑10988. doi:10.1021\/acs.est.9b06932<\/a>.<\/p>\n

Aoyama,\u00a0M.(2020). Global certified-reference-material- or reference-material-scaled nutrient gridded dataset GND13.<\/span> Earth System Science Data<\/span>, 12(1)<\/span>, 487\u2011499. doi:10.5194\/essd\u201112\u2011487\u20112020<\/a>.<\/p>\n

Boudreau,\u00a0B. P., Sulpis,\u00a0O. and Mucci,\u00a0A.(2020). Control of CaCO3 dissolution at the deep seafloor and its consequences.<\/span> Geochimica et Cosmochimica Acta<\/span>, 268<\/span>, 90\u2011106. doi:10.1016\/j.gca.2019.09.037<\/a>.<\/p>\n

Bronselaer,\u00a0B., Russell,\u00a0J. L., Winton,\u00a0M., Williams,\u00a0N. L., Key,\u00a0R. M., Dunne,\u00a0J. P., Feely,\u00a0R. A., Johnson,\u00a0K. S. and Sarmiento,\u00a0J. L.(2020). Importance of wind and meltwater for observed chemical and physical changes in the Southern Ocean.<\/span> Nature Geoscience<\/span>, 13(1)<\/span>, 35\u201142. doi:10.1038\/s41561\u2011019\u20110502\u20118<\/a>.<\/p>\n

Chien, C.‑T., Pahlow, M., Schartau, M. and Oschlies, A.(2020). Optimality-based non-Redfield plankton\u2013ecosystem model (OPEM v1.1) in UVic-ESCM 2.9 \u2013 Part 2: Sensitivity analysis and model calibration.<\/span> Geoscientific Model Development<\/span>, 13(10)<\/span>, 4691‑4712. doi:10.5194\/gmd‑13‑4691‑2020<\/a>.<\/p>\n

Chiu,\u00a0W.-T. R., Yasuhara,\u00a0M., Cronin,\u00a0T. M., Hunt,\u00a0G., Gemery,\u00a0L. and Wei,\u00a0C.-L.(2020). Marine latitudinal diversity gradients, niche conservatism and out of the tropics and Arctic: Climatic sensitivity of small organisms.<\/span> Journal of Biogeography<\/span>, 47(4)<\/span>, 817\u2011828. doi:10.1111\/jbi.13793<\/a>.<\/p>\n

Demuynck,\u00a0P., Tyrrell,\u00a0T., Naveira Garabato,\u00a0A., Moore,\u00a0M. C. and Martin,\u00a0A. P.(2020). Spatial variations in silicate-to-nitrate ratios in Southern Ocean surface waters are controlled in the short term by physics rather than biology.<\/span> Biogeosciences<\/span>, 17(8)<\/span>, 2289\u20112314. doi:10.5194\/bg\u201117\u20112289\u20112020<\/a>.<\/p>\n

Dunne, J. P., Horowitz, L. W., Adcroft, A. J., Ginoux, P., Held, I. M., John, J. G., Krasting, J. P., Malyshev, S., Naik, V., Paulot, F., Shevliakova, E., Stock, C. A., Zadeh, N., Balaji, V., Blanton, C., Dunne, K. A., Dupuis, C., Durachta, J., Dussin, R., Gauthier, P. P. G., Griffies, S. M., Guo, H., Hallberg, R. W., Harrison, M., He, J., Hurlin, W., McHugh, C., Menzel, R., Milly, P. C. D., Nikonov, S., Paynter, D. J., Ploshay, J., Radhakrishnan, A., Rand, K., Reichl, B. G., Robinson, T., Schwarzkopf, D. M., Sentman, L. T., Underwood, S., Vahlenkamp, H., Winton, M., Wittenberg, A. T., Wyman, B., Zeng, Y. and Zhao, M.(2020). The GFDL Earth System Model Version 4.1 (GFDL\u2010ESM 4.1): Overall Coupled Model Description and Simulation Characteristics.<\/span> Journal of Advances in Modeling Earth Systems<\/span>, 12(11)<\/span>. doi:10.1029\/2019MS002015<\/a>.<\/p>\n

Ge,\u00a0J., Torres,\u00a0R., Chen,\u00a0C., Liu,\u00a0J., Xu,\u00a0Y., Bellerby,\u00a0R., Shen,\u00a0F., Bruggeman,\u00a0J. and Ding,\u00a0P.(2020). Influence of suspended sediment front on nutrients and phytoplankton dynamics off the Changjiang Estuary: A FVCOM-ERSEM coupled model experiment.<\/span> Journal of Marine Systems<\/span>, 204<\/span>, 103292. doi:10.1016\/j.jmarsys.2019.103292<\/a>.<\/p>\n

Geddie,\u00a0A. W. and Hall,\u00a0S. G.(2020). Development of a suitability assessment model for the cultivation of intertidal macroalgae in the United States.<\/span> Science of The Total Environment<\/span>, 699<\/span>, 134327. doi:10.1016\/j.scitotenv.2019.134327<\/a>.<\/p>\n

Gottschalk, J., Michel, E., Th\u00f6le, L. M., Studer, A. S., Hasenfratz, A. P., Schmid, N., Butzin, M., Mazaud, A., Mart\u00ednez-Garc\u00eda, A., Szidat, S. and Jaccard, S. L.(2020). Glacial heterogeneity in Southern Ocean carbon storage abated by fast South Indian deglacial carbon release.<\/span> Nature Communications<\/span>, 11(1)<\/span>. doi:10.1038\/s41467‑020‑20034‑1<\/a>.<\/p>\n

Hauck, J., Zeising, M., Le Qu\u00e9r\u00e9, C., Gruber, N., Bakker, D. C. E., Bopp, L., Chau, T. T. T., G\u00fcrses, \u00d6.., Ilyina, T., Landsch\u00fctzer, P., Lenton, A., Resplandy, L., R\u00f6denbeck, C., Schwinger, J. and S\u00e9f\u00e9rian, R.(2020). Consistency and Challenges in the Ocean Carbon Sink Estimate for the Global Carbon Budget.<\/span> Frontiers in Marine Science<\/span>, 7<\/span>. doi:10.3389\/fmars.2020.571720<\/a>.<\/p>\n

Humphreys, M.‑P., Artioli, Y., Bakker,  D.‑C.‑E., Hartman, S.‑E., Le\u00f3n, P., Wakelin, S., Walsham, P., and Williamson, P..(2021). Air\u2013sea CO2 exchange and ocean acidification in UK seas and adjacent waters.<\/span> MCCIP Science Review 2020<\/span>, <\/a>.<\/p>\n

Jin, X., Xu, J., Li, H., Li, Y., Qiao, P., Wu, L., Ling, C., Li, B. and Liu, C.(2020). Origin of the rhythmic reddish-brown and greenish-gray sediments in the abyssal South China Sea: Implications for oceanic circulation in the late Miocene.<\/span> Marine Geology<\/span>, 430<\/span>, 106378. doi:10.1016\/j.margeo.2020.106378<\/a>.<\/p>\n

John,\u00a0S. G., Liang,\u00a0H., Weber,\u00a0T., DeVries,\u00a0T., Primeau,\u00a0F., Moore,\u00a0K., Holzer,\u00a0M., Mahowald,\u00a0N., Gardner,\u00a0W., Mishonov,\u00a0A., Richardson,\u00a0M. J., Faugere,\u00a0Y. and Taburet,\u00a0G.(2020). AWESOME OCIM: A simple, flexible, and powerful tool for modeling elemental cycling in the oceans.<\/span> Chemical Geology<\/span>, 533<\/span>, 119403. doi:10.1016\/j.chemgeo.2019.119403<\/a>.<\/p>\n

Ko,\u00a0Y. H. and Quay,\u00a0P. D.(2020). Origin and Accumulation of an Anthropogenic CO2 and 13C Suess Effect in the Arctic Ocean.<\/span> Global Biogeochemical Cycles<\/span>, 34(2)<\/span>. doi:10.1029\/2019gb006423<\/a>.<\/p>\n

Lauvset,\u00a0S. K., Carter,\u00a0B. R., P\u00e8rez,\u00a0F. F., Jiang,\u00a0L.-Q., Feely,\u00a0R. A., Velo,\u00a0A. and Olsen,\u00a0A.(2020). Processes Driving Global Interior Ocean pH Distribution.<\/span> Global Biogeochemical Cycles<\/span>, 34(1)<\/span>. doi:10.1029\/2019gb006229<\/a>.<\/p>\n

Li, T., Robinson, L. F., Chen, T., Wang, X. T., Burke, A., Rae, J. W. B., Pegrum-Haram, A., Knowles, T. D. J., Li, G., Chen, J., Ng, H. C., Prokopenko, M., Rowland, G. H., Samperiz, A., Stewart, J. A., Southon, J. and Spooner, P. T.(2020). Rapid shifts in circulation and biogeochemistry of the Southern Ocean during deglacial carbon cycle events.<\/span> Science Advances<\/span>, 6(42)<\/span>, eabb3807. doi:10.1126\/sciadv.abb3807<\/a>.<\/p>\n

Mahieu, L., Lo Monaco, C., Metzl, N., Fin, J. and Mignon, C.(2020). Variability and stability of anthropogenic CO2<\/sub> in Antarctic Bottom Water observed in the Indian sector of the Southern Ocean, 1978\u20132018.<\/span> Ocean Science<\/span>, 16(6)<\/span>, 1559‑1576. doi:10.5194\/os‑16‑1559‑2020<\/a>.<\/p>\n

McClymont, E. L., Ford, H. L., Ho, S. L., Tindall, J. C., Haywood, A. M., Alonso-Garcia, M., Bailey, I., Berke, M. A., Littler, K., Patterson, M. O., Petrick, B., Peterse, F., Ravelo, A. C., Risebrobakken, B.., De Schepper, S., Swann, G. E. A., Thirumalai, K., Tierney, J. E., van der Weijst, C., White, S., Abe-Ouchi, A., Baatsen, M. L. J., Brady, E. C., Chan, W.‑L., Chandan, D., Feng, R., Guo, C., von der Heydt, A. S., Hunter, S., Li, X., Lohmann, G., Nisancioglu, K. H., Otto-Bliesner, B. L., Peltier, W. R., Stepanek, C. and Zhang, Z.(2020). Lessons from a high-CO2<\/sub> world: an ocean view from \u2009\u223c\u20093\u00a0million years ago.<\/span> Climate of the Past<\/span>, 16(4)<\/span>, 1599‑1615. doi:10.5194\/cp‑16‑1599‑2020<\/a>.<\/p>\n

Mengis, N., Keller, D. P., MacDougall, A. H., Eby, M., Wright, N., Meissner, K. J., Oschlies, A., Schmittner, A., MacIsaac, A. J., Matthews, H. D. and Zickfeld, K.(2020). Evaluation of the University of Victoria Earth System Climate Model version 2.10 (UVic ESCM 2.10).<\/span> Geoscientific Model Development<\/span>, 13(9)<\/span>, 4183‑4204. doi:10.5194\/gmd‑13‑4183‑2020<\/a>.<\/p>\n

Mogoll\u00f3n,\u00a0R.(2020). ENSO-driven CO2 efflux variability and the role of the upwelling region on the carbon exchange in the Northern Humboldt Current System.<\/span> Journal of Marine Systems<\/span>, 201<\/span>, 103240. doi:10.1016\/j.jmarsys.2019.103240<\/a>.<\/p>\n

Ng,\u00a0H. C., Cassarino,\u00a0L., Pickering,\u00a0R. A., Woodward,\u00a0E. M. S., Hammond,\u00a0S. J. and Hendry,\u00a0K. R.(2020). Sediment efflux of silicon on the Greenland margin and implications for the marine silicon cycle.<\/span> Earth and Planetary Science Letters<\/span>, 529<\/span>, 115877. doi:10.1016\/j.epsl.2019.115877<\/a>.<\/p>\n

Possenti, Luca (2020) Autonomous ocean carbon system observations from gliders. Doctoral thesis, University of East Anglia.<\/p>\n

Rae, J. W. B., Gray, W. R., Wills, R. C. J., Eisenman, I., Fitzhugh, B., Fotheringham, M., Littley, E. F. M., Rafter, P. A., Rees-Owen, R., Ridgwell, A., Taylor, B. and Burke, A.(2020). Overturning circulation, nutrient limitation, and warming in the Glacial North Pacific.<\/span> Science Advances<\/span>, 6(50)<\/span>, eabd1654. doi:10.1126\/sciadv.abd1654<\/a>.<\/p>\n

Tierney, J. E., Zhu, J., King, J., Malevich, S. B., Hakim, G. J. and Poulsen, C. J.(2025). Glacial cooling and climate sensitivity revisited.<\/span> Nature<\/span>, 584(7822)<\/span>, 569‑573. doi:10.1038\/s41586‑020‑2617‑x<\/a>.<\/p>\n

Woosley,\u00a0R. J. and Millero,\u00a0F. J.(2020). Freshening of the western Arctic negates anthropogenic carbon uptake potential.<\/span> Limnology and Oceanography<\/span>. doi:10.1002\/lno.11421<\/a>.<\/p>\n

2019 (67)<\/span><\/strong><\/h6>\n

Abram, N., Gattuso, J.-P., Prakash, A., Cheng,&nbspL., Chidichimo, M.P., Crate, S., Enomoto,&nbsp,H., Garschagen, M., Gruber, N., Harper, S., Holland, E., Kudela, R. M., Rice, J., Steffen, K., and von Schuckmann, K. (2019). Special Report On The Ocean and Cryosphere in a Changing Climate: Framing and Context of the Report.<\/span> IPCC<\/span>, 73‑130. doi:10.1017\/9781009157964.003<\/a>.<\/p>\n

Ardyna,\u00a0M., Lacour,\u00a0L., Sergi,\u00a0S., d\u2019Ovidio,\u00a0F., Sall\u00e9e,\u00a0J.\u2011B., Rembauville,\u00a0M., Blain,\u00a0S.., Tagliabue,\u00a0A., Schlitzer,\u00a0R., Jeandel,\u00a0C., Arrigo,\u00a0K. R. and Claustre,\u00a0H.(2019). Hydrothermal vents trigger massive phytoplankton blooms in the Southern Ocean.<\/span> Nature Communications<\/span>, 10(1)<\/span>. doi:10.1038\/s41467\u2011019\u201109973\u20116<\/a>.<\/p>\n

Benetti,\u00a0M., Reverdin,\u00a0G., Clarke,\u00a0J. S., Tynan,\u00a0E., Holliday,\u00a0N. P., Torres-Valdes,\u00a0S., Lherminier,\u00a0P. and Yashayaev,\u00a0I.(2019). Sources and Distribution of Fresh Water Around Cape Farewell in 2014.<\/span> Journal of Geophysical Research: Oceans<\/span>, 124(12)<\/span>, 9404\u20119416. doi:10.1029\/2019jc015080<\/a>.<\/p>\n

Bittig,\u00a0H. C., Maurer,\u00a0T. L., Plant,\u00a0J. N., Schmechtig,\u00a0C., Wong,\u00a0A. P. S., Claustre,\u00a0H., Trull,\u00a0T. W., Udaya Bhaskar,\u00a0T. V. S., Boss,\u00a0E., Dall\u2019Olmo,\u00a0G., Organelli,\u00a0E., Poteau,\u00a0A., Johnson,\u00a0K. S., Hanstein,\u00a0C., Leymarie,\u00a0E., Le Reste,\u00a0S., Riser,\u00a0S. C., Rupan,\u00a0A. R., Taillandier,\u00a0V., Thierry,\u00a0V. and Xing,\u00a0X.(2019). A BGC-Argo Guide: Planning, Deployment, Data Handling and Usage.<\/span> Frontiers in Marine Science<\/span>, 6<\/span>. doi:10.3389\/fmars.2019.00502<\/a>.<\/p>\n

Broull\u00f3n,\u00a0D., P\u00e9rez,\u00a0F. F., Velo,\u00a0A.., Hoppema,\u00a0M., Olsen,\u00a0A., Takahashi,\u00a0T., Key,\u00a0R. M., Tanhua,\u00a0T., Gonz\u00e1lez-D\u00e1vila,\u00a0M., Jeansson,\u00a0E., Kozyr,\u00a0A. and van Heuven,\u00a0S. M. A. C.(2019). A global monthly climatology of total alkalinity: a neural network approach.<\/span> Earth System Science Data<\/span>, 11(3)<\/span>, 1109\u20111127. doi:10.5194\/essd\u201111\u20111109\u20112019<\/a>.<\/p>\n

Buitenhuis,\u00a0E. T., Le Qu\u00e9r\u00e9,\u00a0C., Bednar\u0161ek,\u00a0N. and Schiebel,\u00a0R.(2019). Large Contribution of Pteropods to Shallow CaCO3 Export.<\/span> Global Biogeochemical Cycles<\/span>, 33(3)<\/span>, 458\u2011468. doi:10.1029\/2018gb006110<\/a>.<\/p>\n

Bushinsky,\u00a0S. M., Takeshita,\u00a0Y. and Williams,\u00a0N. L.(2019). Observing Changes in Ocean Carbonate Chemistry: Our Autonomous Future.<\/span> Current Climate Change Reports<\/span>, 5(3)<\/span>, 207\u2011220. doi:10.1007\/s40641\u2011019\u201100129\u20118<\/a>.<\/p>\n

Carter,\u00a0B. R., Feely,\u00a0R. A., Wanninkhof,\u00a0R., Kouketsu,\u00a0S., Sonnerup,\u00a0R. E., Pardo,\u00a0P. C., Sabine,\u00a0C. L., Johnson,\u00a0G. C., Sloyan,\u00a0B. M., Murata,\u00a0A., Mecking,\u00a0S., Tilbrook,\u00a0B., Speer,\u00a0K., Talley,\u00a0L. D., Millero,\u00a0F. J., Wijffels,\u00a0S. E., Macdonald,\u00a0A. M., Gruber,\u00a0N. and Bullister,\u00a0J. L.(2019). Pacific Anthropogenic Carbon Between 1991 and 2017.<\/span> Global Biogeochemical Cycles<\/span>. doi:10.1029\/2018gb006154<\/a>.<\/p>\n

Chalk,\u00a0T.B., Foster,\u00a0G.L. and Wilson,\u00a0P.A.(2019). Dynamic storage of glacial CO2 in the Atlantic Ocean revealed by boron [CO32-] and pH records.<\/span> Earth and Planetary Science Letters<\/span>, 510<\/span>, 1\u201111. doi:10.1016\/j.epsl.2018.12.022<\/a>.<\/p>\n

Chen,\u00a0G. and Wu,\u00a0J.(2019). Meridional distribution of dissolved manganese in the tropical and equatorial pacific.<\/span> Geochimica et Cosmochimica Acta<\/span>, 263<\/span>, 50\u201167. doi:10.1016\/j.gca.2019.06.048<\/a>.<\/p>\n

DeVries,\u00a0T. and Holzer,\u00a0M.(2019). Radiocarbon and Helium Isotope Constraints on Deep Ocean Ventilation and Mantle-3He Sources.<\/span> Journal of Geophysical Research: Oceans<\/span>, 124(5)<\/span>, 3036\u20113057. doi:10.1029\/2018jc014716<\/a>.<\/p>\n

Foltz,\u00a0G. R., Brandt,\u00a0P., Richter,\u00a0I., Rodr\u00edguez-Fonseca,\u00a0B., Hernandez,\u00a0F., Dengler,\u00a0M., Rodrigues,\u00a0R. R., Schmidt,\u00a0J. O., Yu,\u00a0L., Lefevre,\u00a0N., Da Cunha,\u00a0L. C., McPhaden,\u00a0M. J., Araujo,\u00a0M., Karstensen,\u00a0J., Hahn,\u00a0J., Mart\u00edn-Rey,\u00a0M., Patricola,\u00a0C. M., Poli,\u00a0P., Zuidema,\u00a0P., Hummels,\u00a0R., Perez,\u00a0R. C., Hatje,\u00a0V., L\u00fcbbecke,\u00a0J. F., Polo,\u00a0I., Lumpkin,\u00a0R., Bourl\u00e8s,\u00a0B., Asuquo,\u00a0F. E., Lehodey,\u00a0P., Conchon,\u00a0A., Chang,\u00a0P., Dandin,\u00a0P., Schmid,\u00a0C., Sutton,\u00a0A., Giordani,\u00a0H., Xue,\u00a0Y., Illig,\u00a0S., Losada,\u00a0T., Grodsky,\u00a0S. A., Gasparin,\u00a0F., Lee,\u00a0T., Mohino,\u00a0E., Nobre,\u00a0P., Wanninkhof,\u00a0R., Keenlyside,\u00a0N., Garcon,\u00a0V., S\u00e1nchez-G\u00f3mez,\u00a0E., Nnamchi,\u00a0H. C., Dr\u00e9villon,\u00a0M., Storto,\u00a0A., Remy,\u00a0E., Lazar,\u00a0A., Speich,\u00a0S., Goes,\u00a0M., Dorrington,\u00a0T., Johns,\u00a0W. E., Moum,\u00a0J. N., Robinson,\u00a0C., Perruche,\u00a0C., de Souza,\u00a0R. B., Gaye,\u00a0A. T., L\u00f3pez-Parages,\u00a0J., Monerie,\u00a0P.\u2011A., Castellanos,\u00a0P., Benson,\u00a0N. U., Hounkonnou,\u00a0M. N., Duh\u00e1,\u00a0J. T., Laxenaire,\u00a0R. and Reul,\u00a0N.(2019). The Tropical Atlantic Observing System.<\/span> Frontiers in Marine Science<\/span>, 6<\/span>. doi:10.3389\/fmars.2019.00206<\/a>.<\/p>\n

Fontela,\u00a0M., Mercier,\u00a0H. and P\u00e9rez,\u00a0F. F.(2019). Long-term integrated biogeochemical budget driven by circulation in the eastern subpolar North Atlantic.<\/span> Progress in Oceanography<\/span>, 173<\/span>, 51\u201165. doi:10.1016\/j.pocean.2019.02.004<\/a>.<\/p>\n

Fr\u00f6b,\u00a0F., Olsen,\u00a0A., Becker,\u00a0M., Chafik,\u00a0L., Johannessen,\u00a0T., Reverdin,\u00a0G. and Omar,\u00a0A.(2019). Wintertime fCO2 Variability in the Subpolar North Atlantic Since 2004.<\/span> Geophysical Research Letters<\/span>, 46(3)<\/span>, 1580\u20111590. doi:10.1029\/2018gl080554<\/a>.<\/p>\n

Gregor,\u00a0L., Lebehot,\u00a0A. D., Kok,\u00a0S. and Scheel Monteiro,\u00a0P. M.(2019). A comparative assessment of the uncertainties of global surface ocean CO2<\/sub> estimates using a machine-learning ensemble (CSIR-ML6 version 2019a) &#8211; have we hit the wall?.<\/span> Geoscientific Model Development<\/span>, 12(12)<\/span>, 5113\u20115136. doi:10.5194\/gmd\u201112\u20115113\u20112019<\/a>.<\/p>\n

Gruber,\u00a0N., Clement,\u00a0D., Carter,\u00a0B. R., Feely,\u00a0R. A., van Heuven,\u00a0S., Hoppema,\u00a0M., Ishii,\u00a0M., Key,\u00a0R. M., Kozyr,\u00a0A., Lauvset,\u00a0S. K., Lo Monaco,\u00a0C., Mathis,\u00a0J. T., Murata,\u00a0A., Olsen,\u00a0A., Perez,\u00a0F. F., Sabine,\u00a0C. L., Tanhua,\u00a0T. and Wanninkhof,\u00a0R.(2019). The oceanic sink for anthropogenic CO2from 1994 to 2007.<\/span> Science<\/span>, 363(6432)<\/span>, 1193\u20111199. doi:10.1126\/science.aau5153<\/a>.<\/p>\n

Gruber,\u00a0N., Landsch\u00fctzer,\u00a0P. and Lovenduski,\u00a0N. S.(2019). The Variable Southern Ocean Carbon Sink.<\/span> Annual Review of Marine Science<\/span>, 11(1)<\/span>, 159\u2011186. doi:10.1146\/annurev\u2011marine\u2011121916\u2011063407<\/a>.<\/p>\n

Guo,\u00a0C., Bentsen,\u00a0M., Bethke,\u00a0I., Ilicak,\u00a0M., Tjiputra,\u00a0J., Toniazzo,\u00a0T., Schwinger,\u00a0J. and Otter\u00e5,\u00a0O. H.(2019). Description and evaluation of NorESM1-F: a fast version of the Norwegian Earth System Model (NorESM).<\/span> Geoscientific Model Development<\/span>, 12(1)<\/span>, 343\u2011362. doi:10.5194\/gmd\u201112\u2011343\u20112019<\/a>.<\/p>\n

Guo,\u00a0J., Li,\u00a0T., Xiong,\u00a0Z., Qiu,\u00a0X. and Chang,\u00a0F.(2019). Revisiting the dependence of thermocline-dwelling foraminiferal B\/Ca on temperature and [CO3 2- ], and its application in reconstruction of the subsurface carbonate system in the tropical western Pacific since 24 ka.<\/span> Acta Oceanologica Sinica<\/span>, 38(9)<\/span>, 71\u201186. doi:10.1007\/s13131\u2011019\u20111476\u2011y<\/a>.<\/p>\n

Hayashida, H. (2019). Modelling sea-ice and oceanic dimethylsulfide production and emissions in the Arctic<\/span> PhD Thesis<\/span>, http:\/\/hdl.handle.net\/1828\/10486<\/a>.<\/p>\n

Heinze,\u00a0C., Eyring,\u00a0V., Friedlingstein,\u00a0P., Jones,\u00a0C., Balkanski,\u00a0Y., Collins,\u00a0W., Fichefet,\u00a0T., Gao,\u00a0S., Hall,\u00a0A., Ivanova,\u00a0D., Knorr,\u00a0W., Knutti,\u00a0R., L\u00f6w,\u00a0A., Ponater,\u00a0M., Schultz,\u00a0M. G., Schulz,\u00a0M., Siebesma,\u00a0P., Teixeira,\u00a0J., Tselioudis,\u00a0G. and Vancoppenolle,\u00a0M.(2019). ESD Reviews: Climate feedbacks in the Earth system and prospects for their evaluation.<\/span> Earth System Dynamics<\/span>, 10(3)<\/span>, 379\u2011452. doi:10.5194\/esd\u201110\u2011379\u20112019<\/a>.<\/p>\n

Humphreys,\u00a0M. P., Achterberg,\u00a0E. P., Hopkins,\u00a0J. E., Chowdhury,\u00a0M. Z.H., Griffiths,\u00a0A. M., Hartman,\u00a0S. E., Hull,\u00a0T., Smilenova,\u00a0A., Wihsgott,\u00a0J. U., Woodward,\u00a0E. M. S. and Moore,\u00a0C. M.(2019). Mechanisms for a nutrient-conserving carbon pump in a seasonally stratified, temperate continental shelf sea.<\/span> Progress in Oceanography<\/span>, 177<\/span>, 101961. doi:10.1016\/j.pocean.2018.05.001<\/a>.<\/p>\n

Hurley,\u00a0S. J., Close,\u00a0H. G., Elling,\u00a0F. J., Jasper,\u00a0C. E., Gospodinova,\u00a0K., McNichol,\u00a0A. P. and Pearson,\u00a0A.(2019). CO2-dependent carbon isotope fractionation in Archaea, Part II: The marine water column.<\/span> Geochimica et Cosmochimica Acta<\/span>, 261<\/span>, 383\u2011395. doi:10.1016\/j.gca.2019.06.043<\/a>.<\/p>\n

Jiang,\u00a0L.\u2011Q., Carter,\u00a0B. R., Feely,\u00a0R. A., Lauvset,\u00a0S. K. and Olsen,\u00a0A.(2019). Surface ocean pH and buffer capacity: past, present and future.<\/span> Scientific Reports<\/span>, 9(1)<\/span>. doi:10.1038\/s41598\u2011019\u201155039\u20114<\/a>.<\/p>\n

Johnson,\u00a0K. S., Riser,\u00a0S. C. and Ravichandran,\u00a0M.(2019). Oxygen Variability Controls Denitrification in the Bay of Bengal Oxygen Minimum Zone.<\/span> Geophysical Research Letters<\/span>, 46(2)<\/span>, 804\u2011811. doi:10.1029\/2018gl079881<\/a>.<\/p>\n

Kondrik,\u00a0D., Kazakov,\u00a0E. and Pozdnyakov,\u00a0D.(2019). A synthetic satellite dataset of the spatio-temporal distributions of Emiliania huxleyi blooms and their impacts on Arctic and sub-Arctic marine environments (1998\u20132016).<\/span> Earth System Science Data<\/span>, 11(1)<\/span>, 119\u2011128. doi:10.5194\/essd\u201111\u2011119\u20112019<\/a>.<\/p>\n

Land,\u00a0P. E., Findlay,\u00a0H. S., Shutler,\u00a0J. D., Ashton,\u00a0I. G.C., Holding,\u00a0T., Grouazel,\u00a0A., Girard-Ardhuin,\u00a0F., Reul,\u00a0N., Piolle,\u00a0J.\u2011F., Chapron,\u00a0B., Quilfen,\u00a0Y., Bellerby,\u00a0R. G.J., Bhadury,\u00a0P., Salisbury,\u00a0J., Vandemark,\u00a0D. and Sabia,\u00a0R.(2019). Optimum satellite remote sensing of the marine carbonate system using empirical algorithms in the global ocean, the Greater Caribbean, the Amazon Plume and the Bay of Bengal.<\/span> Remote Sensing of Environment<\/span>, 235<\/span>, 111469. doi:10.1016\/j.rse.2019.111469<\/a>.<\/p>\n

Long,\u00a0Y., Zhu,\u00a0X.-H. and Guo,\u00a0X.(2019). The Oyashio Nutrient Stream and Its Nutrient Transport to the Mixed Water Region.<\/span> Geophysical Research Letters<\/span>, 46(3)<\/span>, 1513\u20111520. doi:10.1029\/2018gl081497<\/a>.<\/p>\n

Macovei,\u00a0V. A., Torres-Vald\u00e9s,\u00a0S., Hartman,\u00a0S. E., Schuster,\u00a0U., Moore,\u00a0C. M., Brown,\u00a0P. J., Hydes,\u00a0D. J. and Sanders,\u00a0R. J.(2019). Temporal Variability in the Nutrient Biogeochemistry of the Surface North Atlantic: 15 Years of Ship of Opportunity Data.<\/span> Global Biogeochemical Cycles<\/span>, 33(12)<\/span>, 1674\u20111692. doi:10.1029\/2018gb006132<\/a>.<\/p>\n

Michel,\u00a0J., Laugi\u00e9,\u00a0M., Pohl,\u00a0A., Lanteaume,\u00a0C., Masse,\u00a0J.\u2011P., Donnadieu,\u00a0Y. and Borgomano,\u00a0J.(2019). Marine carbonate factories: a global model of carbonate platform distribution.<\/span> International Journal of Earth Sciences<\/span>, 108(6)<\/span>, 1773\u20111792. doi:10.1007\/s00531\u2011019\u201101742\u20116<\/a>.<\/p>\n

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Watanabe,\u00a0E., Jin,\u00a0M., Hayashida,\u00a0H., Zhang,\u00a0J. and Steiner,\u00a0N.(2019). Multi-Model Intercomparison of the Pan-Arctic Ice-Algal Productivity on Seasonal, Interannual, and Decadal Timescales.<\/span> Journal of Geophysical Research: Oceans<\/span>, 124(12)<\/span>, 9053\u20119084. doi:10.1029\/2019jc015100<\/a>.<\/p>\n

Wu,\u00a0Y., Hain,\u00a0M. P., Humphreys,\u00a0M. P., Hartman,\u00a0S. and Tyrrell,\u00a0T.(2019). What drives the latitudinal gradient in open-ocean surface dissolved inorganic carbon concentration?.<\/span> Biogeosciences<\/span>, 16(13)<\/span>, 2661\u20112681. doi:10.5194\/bg\u201116\u20112661\u20112019<\/a>.<\/p>\n

Yasunaka,\u00a0S., Kouketsu,\u00a0S., Strutton,\u00a0P.G., Sutton,\u00a0A.J., Murata,\u00a0A., Nakaoka,\u00a0S. and Nojiri,\u00a0Y.(2019). Spatio-temporal variability of surface water pCO2 and nutrients in the tropical Pacific from 1981 to 2015.<\/span> Deep Sea Research Part II: Topical Studies in Oceanography<\/span>, 169-170<\/span>, 104680. doi:10.1016\/j.dsr2.2019.104680<\/a>.<\/p>\n

2018 (66)<\/span><\/strong><\/h6>\n

Assis,\u00a0J., Tyberghein,\u00a0L., Bosch,\u00a0S., Verbruggen,\u00a0H., Serr\u00e3o,\u00a0E. A. and De Clerck,\u00a0O.(2018). Bio-ORACLE v2.0: Extending marine data layers for bioclimatic modelling.<\/span> Global Ecology and Biogeography<\/span>, 27(3)<\/span>, 277\u2011284. doi:10.1111\/geb.12693<\/a>.<\/p>\n

Beadling,\u00a0R. L., Russell,\u00a0J. L., Stouffer,\u00a0R. J. and Goodman,\u00a0P. J.(2018). Evaluation of Subtropical North Atlantic Ocean Circulation in CMIP5 Models against the Observational Array at 26.5\u00b0N and Its Changes under Continued Warming.<\/span> Journal of Climate<\/span>, 31(23)<\/span>, 9697\u20119718. doi:10.1175\/jcli\u2011d\u201117\u20110845.1<\/a>.<\/p>\n

Bittig,\u00a0H. C., Steinhoff,\u00a0T., Claustre,\u00a0H., Fiedler,\u00a0B.., Williams,\u00a0N. L., Sauz\u00e8de,\u00a0R.., K\u00f6rtzinger,\u00a0A. and Gattuso,\u00a0J.\u2011P.(2018). An Alternative to Static Climatologies: Robust Estimation of Open Ocean CO2 Variables and Nutrient Concentrations From T, S, and O2 Data Using Bayesian Neural Networks.<\/span> Frontiers in Marine Science<\/span>, 5<\/span>. doi:10.3389\/fmars.2018.00328<\/a>.<\/p>\n

Carracedo,\u00a0L.I., P\u00e9rez,\u00a0F.F., Gilcoto,\u00a0M., Velo,\u00a0A., Pad\u00edn,\u00a0A. and Ros\u00f3n,\u00a0G.(2018). Role of the circulation on the anthropogenic CO2 inventory in the North-East Atlantic: A climatological analysis.<\/span> Progress in Oceanography<\/span>, 161<\/span>, 78\u201186. doi:10.1016\/j.pocean.2018.01.009<\/a>.<\/p>\n

Carter,\u00a0B. R., Feely,\u00a0R. A., Williams,\u00a0N. L., Dickson,\u00a0A. G., Fong,\u00a0M. B. and Takeshita,\u00a0Y.(2018). Updated methods for global locally interpolated estimation of alkalinity, pH, and nitrate.<\/span> Limnology and Oceanography: Methods<\/span>, 16(2)<\/span>, 119\u2011131. doi:10.1002\/lom3.10232<\/a>.<\/p>\n

Clement,\u00a0D. and Gruber,\u00a0N.(2018). The eMLR(C*) Method to Determine Decadal Changes in the Global Ocean Storage of Anthropogenic CO2.<\/span> Global Biogeochemical Cycles<\/span>, 32(4)<\/span>, 654\u2011679. doi:10.1002\/2017gb005819<\/a>.<\/p>\n

Dahlke,\u00a0F. T., Butzin,\u00a0M., Nahrgang,\u00a0J., Puvanendran,\u00a0V., Mortensen,\u00a0A., P\u00f6rtner,\u00a0H.\u2011O. and Storch,\u00a0D.(2018). Northern cod species face spawning habitat losses if global warming exceeds 1.5\u00b0C.<\/span> Science Advances<\/span>, 4(11)<\/span>, eaas8821. doi:10.1126\/sciadv.aas8821<\/a>.<\/p>\n

de Baar,\u00a0H. J.W., Bruland,\u00a0K. W., Schijf,\u00a0J., van Heuven,\u00a0S. M.A.C. and Behrens,\u00a0M. K.(2018). Low cerium among the dissolved rare earth elements in the central North Pacific Ocean.<\/span> Geochimica et Cosmochimica Acta<\/span>, 236<\/span>, 5\u201140. doi:10.1016\/j.gca.2018.03.003<\/a>.<\/p>\n

Dellinger,\u00a0M., West,\u00a0A. J., Paris,\u00a0G., Adkins,\u00a0J. F., Pogge von Strandmann,\u00a0P. A.E., Ullmann,\u00a0C. V., Eagle,\u00a0R. A., Freitas,\u00a0P., Bagard,\u00a0M.\u2011L., Ries,\u00a0J. B., Corsetti,\u00a0F. A., Perez-Huerta,\u00a0A. and Kampf,\u00a0A. R.(2018). The Li isotope composition of marine biogenic carbonates: Patterns and mechanisms.<\/span> Geochimica et Cosmochimica Acta<\/span>, 236<\/span>, 315\u2011335. doi:10.1016\/j.gca.2018.03.014<\/a>.<\/p>\n

Deng,\u00a0H., Ke,\u00a0H., Huang,\u00a0P., Chen,\u00a0X. and Cai,\u00a0M.(2018). Ventilation time and anthropogenic CO2 in the Bering Sea and the Arctic Ocean based on carbon tetrachloride measurements.<\/span> Journal of Oceanography<\/span>, 74(5)<\/span>, 439\u2011452. doi:10.1007\/s10872\u2011018\u20110471\u20113<\/a>.<\/p>\n

Fisher,\u00a0J. A., Atlas,\u00a0E. L., Barletta,\u00a0B., Meinardi,\u00a0S., Blake,\u00a0D. R., Thompson,\u00a0C. R., Ryerson,\u00a0T. B., Peischl,\u00a0J., Tzompa-Sosa,\u00a0Z. A. and Murray,\u00a0L. T.(2018). Methyl, Ethyl, and Propyl Nitrates: Global Distribution and Impacts on Reactive Nitrogen in Remote Marine Environments.<\/span> Journal of Geophysical Research: Atmospheres<\/span>, 123(21)<\/span>, 12,429\u201112,451. doi:10.1029\/2018jd029046<\/a>.<\/p>\n

Fr\u00f6b,\u00a0F., Olsen,\u00a0A., P\u00e9rez,\u00a0F. F., Garc\u00eda-Ib\u00e1\u00f1ez,\u00a0M. I., Jeansson,\u00a0E., Omar,\u00a0A. and Lauvset,\u00a0S. K.(2018). Inorganic carbon and water masses in the Irminger Sea since\u00a01991.<\/span> Biogeosciences<\/span>, 15(1)<\/span>, 51\u201172. doi:10.5194\/bg\u201115\u201151\u20112018<\/a>.<\/p>\n

Franco,\u00a0A. C., Gruber,\u00a0N., Fr\u00f6licher,\u00a0T. L. and Kropuenske Artman,\u00a0L.(2018). Contrasting Impact of Future CO2 Emission Scenarios on the Extent of CaCO3 Mineral Undersaturation in the Humboldt Current System.<\/span> Journal of Geophysical Research: Oceans<\/span>, 123(3)<\/span>, 2018\u20112036. doi:10.1002\/2018jc013857<\/a>.<\/p>\n

Fripiat,\u00a0F., Declercq,\u00a0M., Sapart,\u00a0C. J., Anderson,\u00a0L. G., Bruechert,\u00a0V., Deman,\u00a0F., Fonseca-Batista,\u00a0D., Humborg,\u00a0C., Roukaerts,\u00a0A., Semiletov,\u00a0I. P. and Dehairs,\u00a0F.(2018). Influence of the bordering shelves on nutrient distribution in the Arctic halocline inferred from water column nitrate isotopes.<\/span> Limnology and Oceanography<\/span>, 63(5)<\/span>, 2154\u20112170. doi:10.1002\/lno.10930<\/a>.<\/p>\n

Gimenez,\u00a0A., Baklouti,\u00a0M., Wagener,\u00a0T. and Moutin,\u00a0T.(2018). Diazotrophy as the main driver of the oligotrophy gradient in the western tropical South Pacific Ocean: results from a one-dimensional biogeochemical\u2013physical coupled model.<\/span> Biogeosciences<\/span>, 15(21)<\/span>, 6573\u20116589. doi:10.5194\/bg\u201115\u20116573\u20112018<\/a>.<\/p>\n

Glock,\u00a0N., Erdem,\u00a0Z., Wallmann,\u00a0K., Somes,\u00a0C. J., Liebetrau,\u00a0V., Sch\u00f6nfeld,\u00a0J., Gorb,\u00a0S. and Eisenhauer,\u00a0A.(2018). Coupling of oceanic carbon and nitrogen facilitates spatially resolved quantitative reconstruction of nitrate inventories.<\/span> Nature Communications<\/span>, 9(1)<\/span>. doi:10.1038\/s41467\u2011018\u201103647\u20115<\/a>.<\/p>\n

Goris,\u00a0N., Tjiputra,\u00a0J. F., Olsen,\u00a0A., Schwinger,\u00a0J., Lauvset,\u00a0S. K. and Jeansson,\u00a0E.(2018). Constraining Projection-Based Estimates of the Future North Atlantic Carbon Uptake.<\/span> Journal of Climate<\/span>, 31(10)<\/span>, 3959\u20113978. doi:10.1175\/jcli\u2011d\u201117\u20110564.1<\/a>.<\/p>\n

Gray,\u00a0W. R., Weldeab,\u00a0S., Lea,\u00a0D. W., Rosenthal,\u00a0Y., Gruber,\u00a0N., Donner,\u00a0B. and Fischer,\u00a0G.(2018). The effects of temperature, salinity, and the carbonate system on Mg\/Ca in Globigerinoides ruber (white): A global sediment trap calibration.<\/span> Earth and Planetary Science Letters<\/span>, 482<\/span>, 607\u2011620. doi:10.1016\/j.epsl.2017.11.026<\/a>.<\/p>\n

Hartfield,\u00a0G., Blunden,\u00a0J. and Arndt,\u00a0D. S.(2018). State of the Climate in 2017.<\/span> Bulletin of the American Meteorological Society<\/span>, 99(8)<\/span>, Si\u2011S310. doi:10.1175\/2018BAMSStateoftheClimate.1<\/a>.<\/p>\n

He,\u00a0Y.\u2011C., Tjiputra,\u00a0J., Langehaug,\u00a0H. R., Jeansson,\u00a0E., Gao,\u00a0Y., Schwinger,\u00a0J. and Olsen,\u00a0A.(2018). A Model-Based Evaluation of the Inverse Gaussian Transit-Time Distribution Method for Inferring Anthropogenic Carbon Storage in the Ocean.<\/span> Journal of Geophysical Research: Oceans<\/span>, 123(3)<\/span>, 1777\u20111800. doi:10.1002\/2017jc013504<\/a>.<\/p>\n

Holzer,\u00a0M., Smethie,\u00a0W. M. and Ting,\u00a0Y.\u2011H.(2018). Ventilation of the Subtropical North Atlantic: Locations and Times of Last Ventilation Estimated Using Tracer Constraints From GEOTRACES Section GA03.<\/span> Journal of Geophysical Research: Oceans<\/span>, 123(4)<\/span>, 2332\u20112352. doi:10.1002\/2017jc013698<\/a>.<\/p>\n

Ko,\u00a0Y. H., Lee,\u00a0K., Takahashi,\u00a0T., Karl,\u00a0D. M., Kang,\u00a0S.\u2011H. and Lee,\u00a0E.(2018). Carbon-Based Estimate of Nitrogen Fixation-Derived Net Community Production in N-Depleted Ocean Gyres.<\/span> Global Biogeochemical Cycles<\/span>. doi:10.1029\/2017gb005634<\/a>.<\/p>\n

Kobayashi,\u00a0T.(2018). Rapid volume reduction in Antarctic Bottom Water off the Ad\u00e9lie\/George V Land coast observed by deep floats.<\/span> Deep Sea Research Part I: Oceanographic Research Papers<\/span>, 140<\/span>, 95\u2011117. doi:10.1016\/j.dsr.2018.07.014<\/a>.<\/p>\n

K\u00f6hler,\u00a0P., Hauck,\u00a0J., V\u00f6lker,\u00a0C., Wolf-Gladrow,\u00a0D. A., Butzin,\u00a0M., Halpern,\u00a0J. B., Rice,\u00a0K. and Zeebe,\u00a0R. E.(2018). Comment on \u201c Scrutinizing the carbon cycle and CO 2 residence time in the atmosphere \u201d by H. Harde.<\/span> Global and Planetary Change<\/span>, 164<\/span>, 67\u201171. doi:10.1016\/j.gloplacha.2017.09.015<\/a>.<\/p>\n

Kondrik,\u00a0D. V., Pozdnyakov,\u00a0D. V. and Johannessen,\u00a0O. M.(2018). Satellite Evidence that E. huxleyi Phytoplankton Blooms Weaken Marine Carbon Sinks.<\/span> Geophysical Research Letters<\/span>, 45(2)<\/span>, 846\u2011854. doi:10.1002\/2017gl076240<\/a>.<\/p>\n

Kubota,\u00a0K., Shirai,\u00a0K., Murakami-Sugihara,\u00a0N., Seike,\u00a0K., Minami,\u00a0M., Nakamura,\u00a0T. and Tanabe,\u00a0K.(2018). Bomb-14C Peak in the North Pacific Recorded in Long-Lived Bivalve Shells (Mercenaria stimpsoni).<\/span> Journal of Geophysical Research: Oceans<\/span>, 123(4)<\/span>, 2867\u20112881. doi:10.1002\/2017jc013678<\/a>.<\/p>\n

Landsch\u00fctzer,\u00a0P., Gruber,\u00a0N., Bakker,\u00a0D. C. E., Stemmler,\u00a0I. and Six,\u00a0K. D.(2018). Strengthening seasonal marine CO2 variations due to increasing atmospheric CO2.<\/span> Nature Climate Change<\/span>, 8(2)<\/span>, 146\u2011150. doi:10.1038\/s41558\u2011017\u20110057\u2011x<\/a>.<\/p>\n

Lauvset,\u00a0S. K., Brakstad,\u00a0A., V\u00e5ge,\u00a0K., Olsen,\u00a0A., Jeansson,\u00a0E. and Mork,\u00a0K. A.(2018). Continued warming, salinification and oxygenation of the Greenland Sea gyre.<\/span> Tellus A: Dynamic Meteorology and Oceanography<\/span>, 70(1)<\/span>, 1\u20119. doi:10.1080\/16000870.2018.1476434<\/a>.<\/p>\n

Letscher,\u00a0R. T. and Villareal,\u00a0T. A.(2018). Evaluation of the seasonal formation of subsurface negative preformed nitrate anomalies in the subtropical North Pacific and North Atlantic.<\/span> Biogeosciences<\/span>, 15(21)<\/span>, 6461\u20116480. doi:10.5194\/bg\u201115\u20116461\u20112018<\/a>.<\/p>\n

Liang,\u00a0Y.\u2011C., Mazloff,\u00a0M. R., Rosso,\u00a0I., Fang,\u00a0S.\u2011W. and Yu,\u00a0J.\u2011Y.(2018). A Multivariate Empirical Orthogonal Function Method to Construct Nitrate Maps in the Southern Ocean.<\/span> Journal of Atmospheric and Oceanic Technology<\/span>, 35(7)<\/span>, 1505\u20111519. doi:10.1175\/jtech\u2011d\u201118\u20110018.1<\/a>.<\/p>\n

Matear,\u00a0R. J. and Lenton,\u00a0A.(2018). Carbon\u2013climate feedbacks accelerate ocean acidification.<\/span> Biogeosciences<\/span>, 15(6)<\/span>, 1721\u20111732. doi:10.5194\/bg\u201115\u20111721\u20112018<\/a>.<\/p>\n

Menviel,\u00a0L., Spence,\u00a0P., Yu,\u00a0J., Chamberlain,\u00a0M. A., Matear,\u00a0R. J., Meissner,\u00a0K. J. and England,\u00a0M. H.(2018). Southern Hemisphere westerlies as a driver of the early deglacial atmospheric CO2 rise.<\/span> Nature Communications<\/span>, 9(1)<\/span>. doi:10.1038\/s41467\u2011018\u201104876\u20114<\/a>.<\/p>\n

Mogoll\u00f3n,\u00a0R. and Calil,\u00a0P. H.R.(2018). Modelling the mechanisms and drivers of the spatiotemporal variability of pCO2 and air\u2013sea CO2 fluxes in the Northern Humboldt Current System.<\/span> Ocean Modelling<\/span>, 132<\/span>, 61\u201172. doi:10.1016\/j.ocemod.2018.10.005<\/a>.<\/p>\n

Mogoll\u00f3n,\u00a0R. and R. Calil,\u00a0P. H.(2018). Counterintuitive effects of global warming-induced wind patterns on primary production in the Northern Humboldt Current System.<\/span> Global Change Biology<\/span>, 24(7)<\/span>, 3187\u20113198. doi:10.1111\/gcb.14171<\/a>.<\/p>\n

Mongwe,\u00a0N. P., Vichi,\u00a0M. and Monteiro,\u00a0P. M. S.(2018). The seasonal cycle of pCO2 and CO2 fluxes in the Southern Ocean: diagnosing anomalies in CMIP5 Earth system models.<\/span> Biogeosciences<\/span>, 15(9)<\/span>, 2851\u20112872. doi:10.5194\/bg\u201115\u20112851\u20112018<\/a>.<\/p>\n

M\u00fcller,\u00a0W. A., Jungclaus,\u00a0J. H., Mauritsen,\u00a0T., Baehr,\u00a0J., Bittner,\u00a0M., Budich,\u00a0R., Bunzel,\u00a0F., Esch,\u00a0M., Ghosh,\u00a0R., Haak,\u00a0H., Ilyina,\u00a0T., Kleine,\u00a0T., Kornblueh,\u00a0L., Li,\u00a0H., Modali,\u00a0K., Notz,\u00a0D., Pohlmann,\u00a0H., Roeckner,\u00a0E., Stemmler,\u00a0I., Tian,\u00a0F. and Marotzke,\u00a0J.(2018). A Higher-resolution Version of the Max Planck Institute Earth System Model (MPI-ESM1.2-HR).<\/span> Journal of Advances in Modeling Earth Systems<\/span>, 10(7)<\/span>, 1383\u20111413. doi:10.1029\/2017ms001217<\/a>.<\/p>\n

Nissen,\u00a0C., Vogt,\u00a0M., M\u00fcnnich,\u00a0M., Gruber,\u00a0N. and Haumann,\u00a0F. A.(2018). Factors controlling coccolithophore biogeography in the Southern Ocean.<\/span> Biogeosciences<\/span>, 15(22)<\/span>, 6997\u20117024. doi:10.5194\/bg\u201115\u20116997\u20112018<\/a>.<\/p>\n

Oka,\u00a0E., Ishii,\u00a0M., Nakano,\u00a0T., Suga,\u00a0T., Kouketsu,\u00a0S., Miyamoto,\u00a0M., Nakano,\u00a0H., Qiu,\u00a0B., Sugimoto,\u00a0S. and Takatani,\u00a0Y.(2018). Fifty years of the 137\u00b0E repeat hydrographic section in the western North Pacific Ocean.<\/span> Journal of Oceanography<\/span>, 74(2)<\/span>, 115\u2011145. doi:10.1007\/s10872\u2011017\u20110461\u2011x<\/a>.<\/p>\n

Panassa,\u00a0E., Santana-Casiano,\u00a0J. M., Gonz\u00e1lez-D\u00e1vila,\u00a0M., Hoppema,\u00a0M., van Heuven,\u00a0S. M.A.C., V\u00f6lker,\u00a0C., Wolf-Gladrow,\u00a0D. and Hauck,\u00a0J.(2018). Variability of nutrients and carbon dioxide in the Antarctic Intermediate Water between 1990 and 2014.<\/span> Ocean Dynamics<\/span>, 68(3)<\/span>, 295\u2011308. doi:10.1007\/s10236\u2011018\u20111131\u20112<\/a>.<\/p>\n

Perez,\u00a0F. F., Fontela,\u00a0M., Garc\u00eda-Ib\u00e1\u00f1ez,\u00a0M. I., Mercier,\u00a0H., Velo,\u00a0A., Lherminier,\u00a0P., Zunino,\u00a0P., de la Paz,\u00a0M., Alonso-P\u00e9rez,\u00a0F., Guallart,\u00a0E. F. and Padin,\u00a0X. A.(2018). Meridional overturning circulation conveys fast acidification to the deep Atlantic Ocean.<\/span> Nature<\/span>, 554(7693)<\/span>, 515\u2011518. doi:10.1038\/nature25493<\/a>.<\/p>\n

Perretti,\u00a0A. R., Albergaria-Barbosa,\u00a0A. C.. R. ., Kerr,\u00a0R. and Cunha,\u00a0L. C. .(2018). Ocean acidification studies and the uncertainties relevance on measurements of marine carbonate system properties.<\/span> Brazilian Journal of Oceanography<\/span>, 66(2)<\/span>, 234\u2011242. doi:10.1590\/s1679\u201187592018000706602<\/a>.<\/p>\n

Peters,\u00a0B. D., Jenkins,\u00a0W. J., Swift,\u00a0J. H., German,\u00a0C. R., Moffett,\u00a0J. W., Cutter,\u00a0G. A., Brzezinski,\u00a0M. A. and Casciotti,\u00a0K. L.(2018). Water mass analysis of the 2013 US GEOTRACES eastern Pacific zonal transect (GP16).<\/span> Marine Chemistry<\/span>, 201<\/span>, 6\u201119. doi:10.1016\/j.marchem.2017.09.007<\/a>.<\/p>\n

Purkey,\u00a0S. G., Smethie,\u00a0W. M., Gebbie,\u00a0G., Gordon,\u00a0A. L., Sonnerup,\u00a0R. E., Warner,\u00a0M. J. and Bullister,\u00a0J. L.(2018). A Synoptic View of the Ventilation and Circulation of Antarctic Bottom Water from Chlorofluorocarbons and Natural Tracers.<\/span> Annual Review of Marine Science<\/span>, 10(1)<\/span>, 503\u2011527. doi:10.1146\/annurev\u2011marine\u2011121916\u2011063414<\/a>.<\/p>\n

Racap\u00e9,\u00a0V., Zunino,\u00a0P., Mercier,\u00a0H., Lherminier,\u00a0P., Bopp,\u00a0L., P\u00e9r\u00e8z,\u00a0F. F. and Gehlen,\u00a0M.(2018). Transport and storage of anthropogenic C in the North Atlantic Subpolar Ocean.<\/span> Biogeosciences<\/span>, 15(14)<\/span>, 4661\u20114682. doi:10.5194\/bg\u201115\u20114661\u20112018<\/a>.<\/p>\n

Rae,\u00a0J. W. B., Burke,\u00a0A., Robinson,\u00a0L. F., Adkins,\u00a0J. F., Chen,\u00a0T., Cole,\u00a0C., Greenop,\u00a0R., Li,\u00a0T., Littley,\u00a0E. F. M., Nita,\u00a0D. C., Stewart,\u00a0J. A. and Taylor,\u00a0B. J.(2018). CO2 storage and release in the deep Southern Ocean on millennial to centennial timescales.<\/span> Nature<\/span>, 562(7728)<\/span>, 569\u2011573. doi:10.1038\/s41586\u2011018\u20110614\u20110<\/a>.<\/p>\n

Rae,\u00a0J. W. B. and Broecker,\u00a0W.(2018). What fraction of the Pacific and Indian oceans’ deep water is formed in the Southern Ocean?.<\/span> Biogeosciences<\/span>, 15(12)<\/span>, 3779\u20113794. doi:10.5194\/bg\u201115\u20113779\u20112018<\/a>.<\/p>\n

Reverdin,\u00a0G., Metzl,\u00a0N., Olafsdottir,\u00a0S., Racap\u00e9,\u00a0V., Takahashi,\u00a0T., Benetti,\u00a0M., Valdimarsson,\u00a0H., Benoit-Cattin,\u00a0A., Danielsen,\u00a0M., Fin,\u00a0J., Naamar,\u00a0A., Pierrot,\u00a0D., Sullivan,\u00a0K., Bringas,\u00a0F. and Goni,\u00a0G.(2018). SURATLANT: a 1993\u20132017 surface sampling in the central part of the North Atlantic subpolar gyre.<\/span> Earth System Science Data<\/span>, 10(4)<\/span>, 1901\u20111924. doi:10.5194\/essd\u201110\u20111901\u20112018<\/a>.<\/p>\n

Robinson,\u00a0J. P. W., Williams,\u00a0I. D., Yeager,\u00a0L. A., McPherson,\u00a0J. M., Clark,\u00a0J., Oliver,\u00a0T. A. and Baum,\u00a0J. K.(2018). Environmental conditions and herbivore biomass determine coral reef benthic community composition: implications for quantitative baselines.<\/span> Coral Reefs<\/span>, 37(4)<\/span>, 1157\u20111168. doi:10.1007\/s00338\u2011018\u201101737\u2011w<\/a>.<\/p>\n

Roshan,\u00a0S., DeVries,\u00a0T., Wu,\u00a0J. and Chen,\u00a0G.(2018). The Internal Cycling of Zinc in the Ocean.<\/span> Global Biogeochemical Cycles<\/span>, 32(12)<\/span>, 1833\u20111849. doi:10.1029\/2018gb006045<\/a>.<\/p>\n

Rusiecka,\u00a0D., Gledhill,\u00a0M., Milne,\u00a0A., Achterberg,\u00a0E. P., Annett,\u00a0A. L., Atkinson,\u00a0S., Birchill,\u00a0A., Karstensen,\u00a0J., Lohan,\u00a0M., Mariez,\u00a0C., Middag,\u00a0R., Rolison,\u00a0J. M., Tanhua,\u00a0T., Ussher,\u00a0S. and Connelly,\u00a0D.(2018). Anthropogenic Signatures of Lead in the Northeast Atlantic.<\/span> Geophysical Research Letters<\/span>, 45(6)<\/span>, 2734\u20112743. doi:10.1002\/2017gl076825<\/a>.<\/p>\n

Russell,\u00a0J. L., Kamenkovich,\u00a0I., Bitz,\u00a0C., Ferrari,\u00a0R., Gille,\u00a0S. T., Goodman,\u00a0P. J., Hallberg,\u00a0R., Johnson,\u00a0K., Khazmutdinova,\u00a0K., Marinov,\u00a0I., Mazloff,\u00a0M., Riser,\u00a0S., Sarmiento,\u00a0J. L., Speer,\u00a0K., Talley,\u00a0L. D. and Wanninkhof,\u00a0R.(2018). Metrics for the Evaluation of the Southern Ocean in Coupled Climate Models and Earth System Models.<\/span> Journal of Geophysical Research: Oceans<\/span>, 123(5)<\/span>, 3120\u20113143. doi:10.1002\/2017jc013461<\/a>.<\/p>\n

Sessford,\u00a0E. G., Tisserand,\u00a0A. A., Risebrobakken,\u00a0B., Andersson,\u00a0C., Dokken,\u00a0T. and Jansen,\u00a0E.(2018). High-Resolution Benthic Mg\/Ca Temperature Record of the Intermediate Water in the Denmark Strait Across D-O Stadial-Interstadial Cycles.<\/span> Paleoceanography and Paleoclimatology<\/span>, 33(11)<\/span>, 1169\u20111185. doi:10.1029\/2018pa003370<\/a>.<\/p>\n

Sk\u00e1kala,\u00a0J., Ford,\u00a0D., Brewin,\u00a0R. J.W., McEwan,\u00a0R., Kay,\u00a0S., Taylor,\u00a0B., Mora,\u00a0L. and Ciavatta,\u00a0S.(2018). The Assimilation of Phytoplankton Functional Types for Operational Forecasting in the Northwest European Shelf.<\/span> Journal of Geophysical Research: Oceans<\/span>, 123(8)<\/span>, 5230\u20115247. doi:10.1029\/2018jc014153<\/a>.<\/p>\n

Skogen,\u00a0M. D., Hj\u00f8llo,\u00a0S. S., Sand\u00f8,\u00a0A. B. and Tjiputra,\u00a0J.(2018). Future ecosystem changes in the Northeast Atlantic: a comparison between a global and a regional model system.<\/span> ICES Journal of Marine Science<\/span>, 75(7)<\/span>, 2355\u20112369. doi:10.1093\/icesjms\/fsy088<\/a>.<\/p>\n

Smith,\u00a0W. O. and Kaufman,\u00a0D. E.(2018). Climatological temporal and spatial distributions of nutrients and particulate matter in the Ross Sea.<\/span> Progress in Oceanography<\/span>, 168<\/span>, 182\u2011195. doi:10.1016\/j.pocean.2018.10.003<\/a>.<\/p>\n

Strassmann,\u00a0K. M. and Joos,\u00a0F.(2018). The Bern Simple Climate Model (BernSCM) v1.0: an extensible and fully documented open-source re-implementation of the Bern reduced-form model for global carbon cycle\u2013climate simulations.<\/span> Geoscientific Model Development<\/span>, 11(5)<\/span>, 1887\u20111908. doi:10.5194\/gmd\u201111\u20111887\u20112018<\/a>.<\/p>\n

Sulpis,\u00a0O., Boudreau,\u00a0B. P., Mucci,\u00a0A., Jenkins,\u00a0C., Trossman,\u00a0D. S., Arbic,\u00a0B. K. and Key,\u00a0R. M.(2018). Current CaCO3 dissolution at the seafloor caused by anthropogenic CO2.<\/span> Proceedings of the National Academy of Sciences<\/span>, 115(46)<\/span>, 11700\u201111705. doi:10.1073\/pnas.1804250115<\/a>.<\/p>\n

Swann,\u00a0G. E. A., Kendrick,\u00a0C. P., Dickson,\u00a0A. J. and Worne,\u00a0S.(2018). Late Pliocene MarinepCO2Reconstructions From the Subarctic Pacific Ocean.<\/span> Paleoceanography and Paleoclimatology<\/span>, 33(5)<\/span>, 457\u2011469. doi:10.1029\/2017pa003296<\/a>.<\/p>\n

Tjiputra,\u00a0J. F., Goris,\u00a0N., Lauvset,\u00a0S. K., Heinze,\u00a0C., Olsen,\u00a0A., Schwinger,\u00a0J. and Steinfeldt,\u00a0R.(2018). Mechanisms and Early Detections of Multidecadal Oxygen Changes in the Interior Subpolar North Atlantic.<\/span> Geophysical Research Letters<\/span>, 45(9)<\/span>, 4218\u20114229. doi:10.1029\/2018gl077096<\/a>.<\/p>\n

Umling,\u00a0N. E., Thunell,\u00a0R. C. and Bizimis,\u00a0M.(2018). Deepwater Expansion and Enhanced Remineralization in the Eastern Equatorial Pacific During the Last Glacial Maximum.<\/span> Paleoceanography and Paleoclimatology<\/span>, 33(6)<\/span>, 563\u2011578. doi:10.1029\/2017pa003221<\/a>.<\/p>\n

Wagener,\u00a0T., Metzl,\u00a0N., Caffin,\u00a0M., Fin,\u00a0J., Helias Nunige,\u00a0S., Lefevre,\u00a0D., Lo Monaco,\u00a0C., Rougier,\u00a0G. and Moutin,\u00a0T.(2018). Carbonate system distribution, anthropogenic carbon and acidification in the western tropical South Pacific (OUTPACE 2015 transect).<\/span> Biogeosciences<\/span>, 15(16)<\/span>, 5221\u20115236. doi:10.5194\/bg\u201115\u20115221\u20112018<\/a>.<\/p>\n

Ward,\u00a0B. A., Wilson,\u00a0J. D., Death,\u00a0R. M., Monteiro,\u00a0F. M., Yool,\u00a0A. and Ridgwell,\u00a0A.(2018). EcoGEnIE 1.0: plankton ecology in the cGEnIE Earth system model.<\/span> Geoscientific Model Development<\/span>, 11(10)<\/span>, 4241\u20114267. doi:10.5194\/gmd\u201111\u20114241\u20112018<\/a>.<\/p>\n

Woosley,\u00a0R. J.(2018). Complexity of Marine CO2 System Highlighted by Seasonal Asymmetries.<\/span> Global Biogeochemical Cycles<\/span>, 32(10)<\/span>, 1434\u20111436. doi:10.1029\/2018gb006081<\/a>.<\/p>\n

Xue,\u00a0L., Cai,\u00a0W.\u2011J., Takahashi,\u00a0T., Gao,\u00a0L., Wanninkhof,\u00a0R., Wei,\u00a0M., Li,\u00a0K., Feng,\u00a0L. and Yu,\u00a0W.(2018). Climatic modulation of surface acidification rates through summertime wind forcing in the Southern Ocean.<\/span> Nature Communications<\/span>, 9(1)<\/span>. doi:10.1038\/s41467\u2011018\u201105443\u20117<\/a>.<\/p>\n

Yasunaka,\u00a0S., Siswanto,\u00a0E., Olsen,\u00a0A., Hoppema,\u00a0M., Watanabe,\u00a0E., Fransson,\u00a0A., Chierici,\u00a0M., Murata,\u00a0A., Lauvset,\u00a0S. K., Wanninkhof,\u00a0R., Takahashi,\u00a0T., Kosugi,\u00a0N., Omar,\u00a0A. M., van Heuven,\u00a0S. and Mathis,\u00a0J. T.(2018). Arctic Ocean CO2 uptake: an improved multiyear estimate of the air\u2013sea CO2 flux incorporating chlorophyll\u00a0a concentrations.<\/span> Biogeosciences<\/span>, 15(6)<\/span>, 1643\u20111661. doi:10.5194\/bg\u201115\u20111643\u20112018<\/a>.<\/p>\n

Zakem,\u00a0E. J., Al-Haj,\u00a0A., Church,\u00a0M. J., van Dijken,\u00a0G. L., Dutkiewicz,\u00a0S., Foster,\u00a0S. Q., Fulweiler,\u00a0R. W., Mills,\u00a0M. M. and Follows,\u00a0M. J.(2018). Ecological control of nitrite in the upper ocean.<\/span> Nature Communications<\/span>, 9(1)<\/span>. doi:10.1038\/s41467\u2011018\u201103553\u2011w<\/a>.<\/p>\n

2017 (33)<\/span><\/strong><\/h6>\n

Bushinsky,\u00a0S. M., Gray,\u00a0A. R., Johnson,\u00a0K. S. and Sarmiento,\u00a0J. L.(2017). Oxygen in the Southern Ocean From Argo Floats: Determination of Processes Driving Air-Sea Fluxes.<\/span> Journal of Geophysical Research: Oceans<\/span>, 122(11)<\/span>, 8661\u20118682. doi:10.1002\/2017jc012923<\/a>.<\/p>\n

Cavanagh,\u00a0R. D., Murphy,\u00a0E. J., Bracegirdle,\u00a0T. J., Turner,\u00a0J., Knowland,\u00a0C. A., Corney,\u00a0S. P., Smith,\u00a0W. O., Waluda,\u00a0C. M., Johnston,\u00a0N. M., Bellerby,\u00a0R. G. J., Constable,\u00a0A. J., Costa,\u00a0D. P., Hofmann,\u00a0E. E., Jackson,\u00a0J. A., Staniland,\u00a0I. J., Wolf-Gladrow,\u00a0D. and Xavier,\u00a0J. C.(2017). A Synergistic Approach for Evaluating Climate Model Output for Ecological Applications.<\/span> Frontiers in Marine Science<\/span>, 4<\/span>. doi:10.3389\/fmars.2017.00308<\/a>.<\/p>\n

Chou,\u00a0W.\u2011C., Tishchenko,\u00a0P. Y., Chuang,\u00a0K.\u2011Y., Gong,\u00a0G.\u2011C., Shkirnikova,\u00a0E. M. and Tishchenko,\u00a0P. P.(2017). The contrasting behaviors of CO2 systems in river-dominated and ocean-dominated continental shelves: A case study in the East China Sea and the Peter the Great Bay of the Japan\/East Sea in summer 2014.<\/span> Marine Chemistry<\/span>, 195<\/span>, 50\u201160. doi:10.1016\/j.marchem.2017.04.005<\/a>.<\/p>\n

de Baar,\u00a0H. J.W., van Heuven,\u00a0S. M.A.C., Abouchami,\u00a0W., Xue,\u00a0Z., Galer,\u00a0S. J.G., Rehk\u00e4mper,\u00a0M., Middag,\u00a0R. and van Ooijen,\u00a0J.(2017). Interactions of dissolved CO2 with cadmium isotopes in the Southern Ocean.<\/span> Marine Chemistry<\/span>, 195<\/span>, 105\u2011121. doi:10.1016\/j.marchem.2017.06.010<\/a>.<\/p>\n

de Lavergne,\u00a0C., Madec,\u00a0G., Roquet,\u00a0F., Holmes,\u00a0R. M. and McDougall,\u00a0T. J.(2017). Abyssal ocean overturning shaped by seafloor distribution.<\/span> Nature<\/span>, 551(7679)<\/span>, 181\u2011186. doi:10.1038\/nature24472<\/a>.<\/p>\n

DeVries,\u00a0T., Holzer,\u00a0M. and Primeau,\u00a0F.(2017). Recent increase in oceanic carbon uptake driven by weaker upper-ocean overturning.<\/span> Nature<\/span>, 542(7640)<\/span>, 215\u2011218. doi:10.1038\/nature21068<\/a>.<\/p>\n

Eide,\u00a0M., Olsen,\u00a0A., Ninnemann,\u00a0U. S. and Johannessen,\u00a0T.(2017). A global ocean climatology of preindustrial and modern ocean d13C.<\/span> Global Biogeochemical Cycles<\/span>, 31(3)<\/span>, 515\u2011534. doi:10.1002\/2016gb005473<\/a>.<\/p>\n

Evans,\u00a0G.R., McDonagh,\u00a0E.L., King,\u00a0B.A., Bryden,\u00a0H.L., Bakker,\u00a0D.C.E., Brown,\u00a0P.J., Schuster,\u00a0U., Speer,\u00a0K.G. and van Heuven,\u00a0S.M.A.C.(2017). South Atlantic interbasin exchanges of mass, heat, salt and anthropogenic carbon.<\/span> Progress in Oceanography<\/span>, 151<\/span>, 62\u201182. doi:10.1016\/j.pocean.2016.11.005<\/a>.<\/p>\n

Fassbender,\u00a0A. J., Sabine,\u00a0C. L. and Palevsky,\u00a0H. I.(2017). Nonuniform ocean acidification and attenuation of the ocean carbon sink.<\/span> Geophysical Research Letters<\/span>, 44(16)<\/span>, 8404\u20118413. doi:10.1002\/2017gl074389<\/a>.<\/p>\n

Fassbender,\u00a0A. J., Sabine,\u00a0C. L., Cronin,\u00a0M. F. and Sutton,\u00a0A. J.(2017). Mixed-layer carbon cycling at the Kuroshio Extension Observatory.<\/span> Global Biogeochemical Cycles<\/span>. doi:10.1002\/2016gb005547<\/a>.<\/p>\n

Ganachaud,\u00a0A., Cravatte,\u00a0S., Sprintall,\u00a0J., Germineaud,\u00a0C., Alberty,\u00a0M., Jeandel,\u00a0C., Eldin,\u00a0G., Metzl,\u00a0N., Bonnet,\u00a0S., Benavides,\u00a0M., Heimburger,\u00a0L.\u2011E., Lef\u00e8vre,\u00a0J.., Michael,\u00a0S., Resing,\u00a0J., Qu\u00e9rou\u00e9,\u00a0F., Sarthou,\u00a0G., Rodier,\u00a0M., Berthelot,\u00a0H., Baurand,\u00a0F.., Grelet,\u00a0J., Hasegawa,\u00a0T., Kessler,\u00a0W., Kilepak,\u00a0M., Lacan,\u00a0F.., Privat,\u00a0E., Send,\u00a0U., Van Beek,\u00a0P., Souhaut,\u00a0M. and Sonke,\u00a0J. E.(2017). The Solomon Sea: its circulation, chemistry, geochemistry and biology explored during two oceanographic cruises.<\/span> Elem Sci Anth<\/span>, 5(0)<\/span>, 33. doi:10.1525\/elementa.221<\/a>.<\/p>\n

Jeansson,\u00a0E., Olsen,\u00a0A. and Jutterstr\u00f6m,\u00a0S.(2017). Arctic Intermediate Water in the Nordic Seas, 1991\u20132009.<\/span> Deep Sea Research Part I: Oceanographic Research Papers<\/span>, 128<\/span>, 82\u201197. doi:10.1016\/j.dsr.2017.08.013<\/a>.<\/p>\n

Johnson,\u00a0K. S., Plant,\u00a0J. N., Dunne,\u00a0J. P., Talley,\u00a0L. D. and Sarmiento,\u00a0J. L.(2017). Annual nitrate drawdown observed by SOCCOM profiling floats and the relationship to annual net community production.<\/span> Journal of Geophysical Research: Oceans<\/span>, 122(8)<\/span>, 6668\u20116683. doi:10.1002\/2017jc012839<\/a>.<\/p>\n

Johnson,\u00a0K. S., Plant,\u00a0J. N., Coletti,\u00a0L. J., Jannasch,\u00a0H. W., Sakamoto,\u00a0C. M., Riser,\u00a0S. C., Swift,\u00a0D. D., Williams,\u00a0N. L., Boss,\u00a0E., Ha\u00ebntjens,\u00a0N., Talley,\u00a0L. D. and Sarmiento,\u00a0J. L.(2017). Biogeochemical sensor performance in the SOCCOM profiling float array.<\/span> Journal of Geophysical Research: Oceans<\/span>, 122(8)<\/span>, 6416\u20116436. doi:10.1002\/2017jc012838<\/a>.<\/p>\n

Keul,\u00a0N., Peijnenburg,\u00a0K. T. C. A., Andersen,\u00a0N., Kitidis,\u00a0V., Goetze,\u00a0E. and Schneider,\u00a0R. R.(2017). Pteropods are excellent recorders of surface temperature and carbonate ion concentration.<\/span> Scientific Reports<\/span>, 7(1)<\/span>. doi:10.1038\/s41598\u2011017\u201111708\u2011w<\/a>.<\/p>\n

Krumhardt,\u00a0K. M., Lovenduski,\u00a0N. S., Iglesias-Rodriguez,\u00a0M. D. and Kleypas,\u00a0J. A.(2017). Coccolithophore growth and calcification in a changing ocean.<\/span> Progress in Oceanography<\/span>, 159<\/span>, 276\u2011295. doi:10.1016\/j.pocean.2017.10.007<\/a>.<\/p>\n

Ma,\u00a0W., Wang,\u00a0P. and Tian,\u00a0J.(2017). Modeling 400\u2013500-kyr Pleistocene carbon isotope cyclicity through variations in the dissolved organic carbon pool.<\/span> Global and Planetary Change<\/span>, 152<\/span>, 187\u2011198. doi:10.1016\/j.gloplacha.2017.04.001<\/a>.<\/p>\n

Manno,\u00a0C., Bednar\u0161ek,\u00a0N., Tarling,\u00a0G. A., Peck,\u00a0V. L., Comeau,\u00a0S., Adhikari,\u00a0D., Bakker,\u00a0D. C.E., Bauerfeind,\u00a0E., Bergan,\u00a0A. J., Berning,\u00a0M. I., Buitenhuis,\u00a0E., Burridge,\u00a0A. K., Chierici,\u00a0M., Fl\u00f6ter,\u00a0S., Fransson,\u00a0A., Gardner,\u00a0J., Howes,\u00a0E. L., Keul,\u00a0N., Kimoto,\u00a0K., Kohnert,\u00a0P., Lawson,\u00a0G. L., Lischka,\u00a0S., Maas,\u00a0A., Mekkes,\u00a0L., Oakes,\u00a0R. L., Pebody,\u00a0C., Peijnenburg,\u00a0K. T.C.A., Seifert,\u00a0M., Skinner,\u00a0J., Thibodeau,\u00a0P. S., Wall-Palmer,\u00a0D. and Ziveri,\u00a0P.(2017). Shelled pteropods in peril: Assessing vulnerability in a high CO 2 ocean.<\/span> Earth-Science Reviews<\/span>, 169<\/span>, 132\u2011145. doi:10.1016\/j.earscirev.2017.04.005<\/a>.<\/p>\n

Marconi,\u00a0D., Sigman,\u00a0D. M., Casciotti,\u00a0K. L., Campbell,\u00a0E. C., Alexandra Weigand,\u00a0M., Fawcett,\u00a0S. E., Knapp,\u00a0A. N., Rafter,\u00a0P. A., Ward,\u00a0B. B. and Haug,\u00a0G. H.(2017). Tropical Dominance of N2 Fixation in the North Atlantic Ocean.<\/span> Global Biogeochemical Cycles<\/span>, 31(10)<\/span>, 1608\u20111623. doi:10.1002\/2016gb005613<\/a>.<\/p>\n

McKinley,\u00a0G. A., Fay,\u00a0A. R., Lovenduski,\u00a0N. S. and Pilcher,\u00a0D. J.(2017). Natural Variability and Anthropogenic Trends in the Ocean Carbon Sink.<\/span> Annual Review of Marine Science<\/span>, 9(1)<\/span>, 125\u2011150. doi:10.1146\/annurev\u2011marine\u2011010816\u2011060529<\/a>.<\/p>\n

Moreau,\u00a0S., Penna,\u00a0A. D., Llort,\u00a0J., Patel,\u00a0R., Langlais,\u00a0C., Boyd,\u00a0P. W., Matear,\u00a0R. J., Phillips,\u00a0H. E., Trull,\u00a0T. W., Tilbrook,\u00a0B., Lenton,\u00a0A. and Strutton,\u00a0P. G.(2017). Eddy-induced carbon transport across the Antarctic Circumpolar Current.<\/span> Global Biogeochemical Cycles<\/span>, 31(9)<\/span>, 1368\u20111386. doi:10.1002\/2017gb005669<\/a>.<\/p>\n

Olsen,\u00a0A.(2017). Autonomous observing platform CO2 data shed new light on the Southern Ocean carbon cycle.<\/span> Global Biogeochemical Cycles<\/span>, 31(6)<\/span>, 1032\u20111035. doi:10.1002\/2017gb005676<\/a>.<\/p>\n

Orr,\u00a0J. C., Najjar,\u00a0R. G., Aumont,\u00a0O., Bopp,\u00a0L., Bullister,\u00a0J. L., Danabasoglu,\u00a0G., Doney,\u00a0S. C., Dunne,\u00a0J. P., Dutay,\u00a0J.\u2011C., Graven,\u00a0H., Griffies,\u00a0S. M., John,\u00a0J. G., Joos,\u00a0F., Levin,\u00a0I., Lindsay,\u00a0K., Matear,\u00a0R. J., McKinley,\u00a0G. A., Mouchet,\u00a0A., Oschlies,\u00a0A., Romanou,\u00a0A., Schlitzer,\u00a0R., Tagliabue,\u00a0A., Tanhua,\u00a0T. and Yool,\u00a0A.(2017). Biogeochemical protocols and diagnostics for the CMIP6 Ocean Model Intercomparison Project (OMIP).<\/span> Geoscientific Model Development<\/span>, 10(6)<\/span>, 2169\u20112199. doi:10.5194\/gmd\u201110\u20112169\u20112017<\/a>.<\/p>\n

Pardo,\u00a0P. C., Tilbrook,\u00a0B., Langlais,\u00a0C., Trull,\u00a0T. W. and Rintoul,\u00a0S. R.(2017). Carbon uptake and biogeochemical change in the Southern Ocean, south of Tasmania.<\/span> Biogeosciences<\/span>, 14(22)<\/span>, 5217\u20115237. doi:10.5194\/bg\u201114\u20115217\u20112017<\/a>.<\/p>\n

Quay,\u00a0P., Sonnerup,\u00a0R., Munro,\u00a0D. and Sweeney,\u00a0C.(2017). Anthropogenic CO2accumulation and uptake rates in the Pacific Ocean based on changes in the13C\/12C of dissolved inorganic carbon.<\/span> Global Biogeochemical Cycles<\/span>, 31(1)<\/span>, 59\u201180. doi:10.1002\/2016gb005460<\/a>.<\/p>\n

Rhein,\u00a0M., Steinfeldt,\u00a0R., Kieke,\u00a0D., Stendardo,\u00a0I. and Yashayaev,\u00a0I.(2017). Ventilation variability of Labrador Sea Water and its impact on oxygen and anthropogenic carbon: a review.<\/span> Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences<\/span>, 375(2102)<\/span>, 20160321. doi:10.1098\/rsta.2016.0321<\/a>.<\/p>\n

Rosso,\u00a0I., Mazloff,\u00a0M. R., Verdy,\u00a0A. and Talley,\u00a0L. D.(2017). Space and time variability of the Southern Ocean carbon budget.<\/span> Journal of Geophysical Research: Oceans<\/span>, 122(9)<\/span>, 7407\u20117432. doi:10.1002\/2016jc012646<\/a>.<\/p>\n

Sauz\u00e8de,\u00a0R.., Bittig,\u00a0H. C., Claustre,\u00a0H., Pasqueron de Fommervault,\u00a0O., Gattuso,\u00a0J.\u2011P., Legendre,\u00a0L. and Johnson,\u00a0K. S.(2017). Estimates of Water-Column Nutrient Concentrations and Carbonate System Parameters in the Global Ocean: A Novel Approach Based on Neural Networks.<\/span> Frontiers in Marine Science<\/span>, 4<\/span>. doi:10.3389\/fmars.2017.00128<\/a>.<\/p>\n

Tanhua,\u00a0T., Hoppema,\u00a0M., Jones,\u00a0E. M., St\u00f6ven,\u00a0T., Hauck,\u00a0J., D\u00e1vila,\u00a0M. G.., Santana-Casiano,\u00a0M., \u00c1lvarez,\u00a0M. and Strass,\u00a0V. H.(2017). Temporal changes in ventilation and the carbonate system in the Atlantic sector of the Southern Ocean.<\/span> Deep Sea Research Part II: Topical Studies in Oceanography<\/span>, 138<\/span>, 26\u201138. doi:10.1016\/j.dsr2.2016.10.004<\/a>.<\/p>\n

Turk,\u00a0D., Dowd,\u00a0M., Lauvset,\u00a0S. K., Koelling,\u00a0J., Alonso-P\u00e9rez,\u00a0F. and P\u00e9rez,\u00a0F. F.(2017). Can Empirical Algorithms Successfully Estimate Aragonite Saturation State in the Subpolar North Atlantic?.<\/span> Frontiers in Marine Science<\/span>, 4<\/span>. doi:10.3389\/fmars.2017.00385<\/a>.<\/p>\n

Verdy,\u00a0A. and Mazloff,\u00a0M. R.(2017). A data assimilating model for estimating Southern Ocean biogeochemistry.<\/span> Journal of Geophysical Research: Oceans<\/span>, 122(9)<\/span>, 6968\u20116988. doi:10.1002\/2016jc012650<\/a>.<\/p>\n

Wallhead,\u00a0P. J., Bellerby,\u00a0R. G. J., Silyakova,\u00a0A., Slagstad,\u00a0D. and Polukhin,\u00a0A. A.(2017). Bottom Water Acidification and Warming on the Western Eurasian Arctic Shelves: Dynamical Downscaling Projections.<\/span> Journal of Geophysical Research: Oceans<\/span>, 122(10)<\/span>, 8126\u20118144. doi:10.1002\/2017jc013231<\/a>.<\/p>\n

Zigah,\u00a0P. K., McNichol,\u00a0A. P., Xu,\u00a0L., Johnson,\u00a0C., Santinelli,\u00a0C., Karl,\u00a0D. M. and Repeta,\u00a0D. J.(2017). Allochthonous sources and dynamic cycling of ocean dissolved organic carbon revealed by carbon isotopes.<\/span> Geophysical Research Letters<\/span>, 44(5)<\/span>, 2407\u20112415. doi:10.1002\/2016GL071348<\/a>.<\/p>\n

2016 (8)<\/span><\/strong><\/h6>\n

Becker,\u00a0M., Andersen,\u00a0N., Erlenkeuser,\u00a0H., Humphreys,\u00a0M. P., Tanhua,\u00a0T. and K\u00f6rtzinger,\u00a0A.(2016). An internally consistent dataset of d13C-DIC in the North Atlantic Ocean \u2013 NAC13v1.<\/span> Earth System Science Data<\/span>, 8(2)<\/span>, 559\u2011570. doi:10.5194\/essd\u20118\u2011559\u20112016<\/a>.<\/p>\n

Fr\u00f6b,\u00a0F., Olsen,\u00a0A., V\u00e5ge,\u00a0K., Moore,\u00a0G. W. K., Yashayaev,\u00a0I., Jeansson,\u00a0E. and Rajasakaren,\u00a0B.(2016). Irminger Sea deep convection injects oxygen and anthropogenic carbon to the ocean interior.<\/span> Nature Communications<\/span>, 7(1)<\/span>. doi:10.1038\/ncomms13244<\/a>.<\/p>\n

Fry,\u00a0C. H., Tyrrell,\u00a0T. and Achterberg,\u00a0E. P.(2016). Analysis of longitudinal variations in North Pacific alkalinity to improve predictive algorithms.<\/span> Global Biogeochemical Cycles<\/span>, 30(10)<\/span>, 1493\u20111508. doi:10.1002\/2016GB005398<\/a>.<\/p>\n

Garc\u00eda-Ib\u00e1\u00f1ez,\u00a0M. I., Zunino,\u00a0P., Fr\u00f6b,\u00a0F., Carracedo,\u00a0L. I., R\u00edos,\u00a0A. F., Mercier,\u00a0H., Olsen,\u00a0A. and P\u00e9rez,\u00a0F. F.(2016). Ocean acidification in the subpolar North Atlantic: rates and mechanisms controlling pH changes.<\/span> Biogeosciences<\/span>, 13(12)<\/span>, 3701\u20113715. doi:10.5194\/bg\u201113\u20113701\u20112016<\/a>.<\/p>\n

McKinley, G. A., Fay, A. R., Lovenduski, N. S. and Pilcher, D. J.(2016). Natural Variability and Anthropogenic Trends in the Ocean Carbon Sink.<\/span> Annual Review of Marine Science<\/span>, 9(1)<\/span>, 125‑150. doi:10.1146\/annurev‑marine‑010816‑060529<\/a>.<\/p>\n

Iudicone,\u00a0D., Rodgers,\u00a0K. B., Plancherel,\u00a0Y., Aumont,\u00a0O., Ito,\u00a0T., Key,\u00a0R. M., Madec,\u00a0G. and Ishii,\u00a0M.(2016). The formation of the ocean\u2019s anthropogenic carbon reservoir.<\/span> Scientific Reports<\/span>, 6(1)<\/span>. doi:10.1038\/srep35473<\/a>.<\/p>\n

Lauvset,\u00a0S. K., Key,\u00a0R. M., Olsen,\u00a0A., van Heuven,\u00a0S., Velo,\u00a0A., Lin,\u00a0X., Schirnick,\u00a0C., Kozyr,\u00a0A., Tanhua,\u00a0T., Hoppema,\u00a0M., Jutterstr\u00f6m,\u00a0S., Steinfeldt,\u00a0R., Jeansson,\u00a0E., Ishii,\u00a0M., Perez,\u00a0F. F., Suzuki,\u00a0T. and Watelet,\u00a0S.(2016). A new global interior ocean mapped climatology: the 1\u00b0?\u00d7??1\u00b0 GLODAP version 2.<\/span> Earth System Science Data<\/span>, 8(2)<\/span>, 325\u2011340. doi:10.5194\/essd\u20118\u2011325\u20112016<\/a>.<\/p>\n

Yasunaka,\u00a0S., Murata,\u00a0A., Watanabe,\u00a0E., Chierici,\u00a0M., Fransson,\u00a0A., van Heuven,\u00a0S., Hoppema,\u00a0M., Ishii,\u00a0M., Johannessen,\u00a0T., Kosugi,\u00a0N., Lauvset,\u00a0S. K., Mathis,\u00a0J. T., Nishino,\u00a0S., Omar,\u00a0A. M., Olsen,\u00a0A., Sasano,\u00a0D., Takahashi,\u00a0T. and Wanninkhof,\u00a0R.(2016). Mapping of the air\u2013sea CO2 flux in the Arctic Ocean and its adjacent seas: Basin-wide distribution and seasonal to interannual variability.<\/span> Polar Science<\/span>, 10(3)<\/span>, 323\u2011334. doi:10.1016\/j.polar.2016.03.006<\/a>.<\/p>\n

Reports, etc.<\/strong><\/h3>\n

Johns, W., Speich, S., Araujo, M., and lead authors (2021), Tropical Atlantic Observing System (TAOS) Review Report. (Accessed<\/a> 21.09.2021)<\/p>\n

Claustre, H., K. S. Johnson, and Y. Takeshita (2020), Observing the Global Ocean with Biogeochemical-Argo, in Annual Review of Marine Science, Vol 12, edited by C. A. Carlson and S. J. Giovannoni, pp. 23-48.<\/p>\n

Talley, L., G. C. Johnson, S. Purkey, R. A. Feely, and R. Wanninkhof (2017), Global Ocean Ship-based Hydrographic Investigations Program (GO-SHIP) provides key climate-relevant deep ocean observations, US CLIVAR Variations, 15. (Accessed<\/a> 09.04.2018)<\/p>\n

Willamson, P., C. Turley, and C. Ostle (2017), MCCIP Science Review 2017: Ocean acidification. 1-14, doi:10.14465\/2017.arc10.001-oac<\/a>.<\/p>\n

Humphreys, M. P., C. Dumousseaud, and E. Achterberg (2016), GA10 Carbonate Chemistry, doi:10.13140\/RG.2.1.1394.3926<\/a>.<\/p>\n

Ostle, C., P. Williamson, Y. Artioli, D. C. E. Bakker, S. Birchenough, C. E. Davis, S. Dye, M. Edwards, H. S. Findlay, N. Greenwood, S. Hartman, M. P. Humphreys, T. Jickells, M. Johnson, P. Landschuetzer, R. Parker, D. Pearce, J. Pinnegar, C. Robinson, U. Schuster, B. Silburn, R. Thomas, S. Wakelin, P. Walsham, and A. J. Watson (2016), Carbon dioxide and ocean acidification observations in UK waters. Synthesis report with a focus on 2010\u20132015, University of East Anglia, UK. doi: 10.13140\/RG.2.1.4819.4164<\/a>.<\/p>\n

Mann<\/span>,\u00a0Z. \u00c1. and <\/span>Stolz, V. (2018), Advances in Service-Oriented and Cloud Computing: Workshops of ESOCC 2017, Oslo, Norway, September 27-29, 2017, Revised Selected Papers. Communications in Computer and Information(824). Springer, 2018. ISBN: 3319790900, 9783319790909 (Accessed<\/a> 02.11.2018).<\/span><\/p>\n

Mazloff, M. R., and A. Verdy (2015), State estimation for determining the properties and sensitivities of the Southern Ocean carbon cycle, US CLIVAR Variations, 13: 20-25. (Accessed<\/a> 09.04.2018).<\/p>\n<\/div>\n

\u00a0<\/span><\/div>\n","protected":false},"excerpt":{"rendered":"

Peer-reviewed journal articles Last updated: 2023-02-07 2025 (91) Adebayo, M. B., Bolton, C. T., Bassinot, F. and de Garidel\u2010Thoron, T.(2025). A Comparison of New and Established Foraminiferal Dissolution Proxies in Tropical Indian Ocean Deep\u2010Sea Sediments. Paleoceanography and Paleoclimatology, 40(6). doi:10.1029\/2024PA005053. \u00c5rthun, M., Dinh, K. V., D\u00f6rr, J., Dupont, N., Fransner, F., Nilsen, I., Renaud, P. E., Skogen, M. D., Assmy, P., Chierici, M., Duarte, P., Fransson, A., Hansen, C., Nascimento, M. C., Pedersen, T., … Continue reading “Publications using GLODAPv2”<\/span><\/a><\/p>\n","protected":false},"author":2,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"class_list":["post-1327","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/glodap.info\/index.php\/wp-json\/wp\/v2\/pages\/1327","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/glodap.info\/index.php\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/glodap.info\/index.php\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/glodap.info\/index.php\/wp-json\/wp\/v2\/users\/2"}],"replies":[{"embeddable":true,"href":"https:\/\/glodap.info\/index.php\/wp-json\/wp\/v2\/comments?post=1327"}],"version-history":[{"count":58,"href":"https:\/\/glodap.info\/index.php\/wp-json\/wp\/v2\/pages\/1327\/revisions"}],"predecessor-version":[{"id":1925,"href":"https:\/\/glodap.info\/index.php\/wp-json\/wp\/v2\/pages\/1327\/revisions\/1925"}],"wp:attachment":[{"href":"https:\/\/glodap.info\/index.php\/wp-json\/wp\/v2\/media?parent=1327"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}