Cross‐Shore Flow and Implications for Carbon Export in the California Current Ecosystem: A Lagrangian Analysis
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F. d’Ovidio | M. Ohman | V. Echevin | M. Stukel | P. Chabert
[1] J. McWilliams,et al. Submesoscale Currents Modulate the Seasonal Cycle of Nutrients and Productivity in the California Current System , 2020, Global Biogeochemical Cycles.
[2] F. d’Ovidio,et al. Interaction of the Antarctic Circumpolar Current With Seamounts Fuels Moderate Blooms but Vast Foraging Grounds for Multiple Marine Predators , 2020, Frontiers in Marine Science.
[3] M. Stukel,et al. Investigating the Nutrient Landscape in a Coastal Upwelling Region and Its Relationship to the Biological Carbon Pump , 2020, Geophysical Research Letters.
[4] R. Goericke,et al. Lagrangian Studies of Marine Production: A Multimethod Assessment of Productivity Relationships in the California Current Ecosystem Upwelling Region , 2020 .
[5] R. Castelao,et al. Offshore transport of particulate organic carbon in the California Current System by mesoscale eddies , 2019, Nature Communications.
[6] A. Allen,et al. Euphotic zone nitrification in the California Current Ecosystem , 2019, Limnology and Oceanography.
[7] Marina Lévy,et al. Effects of Eddy‐Driven Subduction on Ocean Biological Carbon Pump , 2019, Global Biogeochemical Cycles.
[8] M. Ohman,et al. The Carbon:234Thorium ratios of sinking particles in the California current ecosystem 1: relationships with plankton ecosystem dynamics , 2019, Marine Chemistry.
[9] H. Claustre,et al. Multi-faceted particle pumps drive carbon sequestration in the ocean , 2019, Nature.
[10] Kenneth L. Smith,et al. Episodic organic carbon fluxes from surface ocean to abyssal depths during long-term monitoring in NE Pacific , 2018, Proceedings of the National Academy of Sciences.
[11] N. Gruber,et al. Origin, Transformation, and Fate: The Three‐Dimensional Biological Pump in the California Current System , 2018, Journal of Geophysical Research: Oceans.
[12] C. Edwards,et al. Coastal Upwelling Revisited: Ekman, Bakun, and Improved Upwelling Indices for the U.S. West Coast , 2018, Journal of Geophysical Research: Oceans.
[13] M. Ohman,et al. CCE V: Primary production, mesozooplankton grazing, and the biological pump in the California Current Ecosystem: Variability and response to El Niño , 2018, Deep Sea Research Part I: Oceanographic Research Papers.
[14] M. Ohman,et al. CCE IV: El Niño-related zooplankton variability in the southern California Current System , 2018, Deep Sea Research Part I: Oceanographic Research Papers.
[15] M. Kahru,et al. CCE II: Spatial and interannual variability in export efficiency and the biological pump in an eastern boundary current upwelling system with substantial lateral advection , 2018, Deep Sea Research Part I: Oceanographic Research Papers.
[16] L. G. Shelton. Ecological Transitions , 2018, The Bronfenbrenner Primer.
[17] Ilan Koren,et al. A Satellite-Based Lagrangian View on Phytoplankton Dynamics. , 2018, Annual review of marine science.
[18] F. Chavez,et al. Nutrient supply, surface currents, and plankton dynamics predict zooplankton hotspots in coastal upwelling systems , 2017 .
[19] N. Gruber,et al. On the long-range offshore transport of organic carbon from the Canary Upwelling System to the open North Atlantic , 2017 .
[20] Alexander M. Chekalyuk,et al. Mesoscale ocean fronts enhance carbon export due to gravitational sinking and subduction , 2017, Proceedings of the National Academy of Sciences.
[21] Emanuele Di Lorenzo,et al. Multi-year persistence of the 2014/15 North Pacific marine heatwave , 2016 .
[22] M. Gehlen,et al. Coastal-ocean uptake of anthropogenic carbon , 2016 .
[23] P. Franks,et al. Biogeochemical properties of eddies in the California Current System , 2016 .
[24] C. Benitez‐Nelson,et al. The biological pump in the Costa Rica Dome: an open-ocean upwelling system with high new production and low export. , 2016, Journal of plankton research.
[25] W. Large,et al. The Benguela upwelling system: Quantifying the sensitivity to resolution and coastal wind representation in a global climate model , 2015 .
[26] M. Kahru,et al. Using Lagrangian‐based process studies to test satellite algorithms of vertical carbon flux in the eastern North Pacific Ocean , 2015 .
[27] M. Pujol,et al. The biogeochemical structuring role of horizontal stirring: Lagrangian perspectives on iron delivery downstream of the Kerguelen Plateau , 2015 .
[28] Mati Kahru,et al. Optimized Merger of Ocean Chlorophyll Algorithms of MODIS-Aqua and VIIRS , 2015, IEEE Geoscience and Remote Sensing Letters.
[29] G. Plattner,et al. Dominant role of eddies and filaments in the offshore transport of carbon and nutrients in the California Current System , 2015 .
[30] M. Lomas,et al. Decoupling of net community and export production on submesoscales in the Sargasso Sea , 2015 .
[31] M. Brzezinski,et al. Enhanced silica ballasting from iron stress sustains carbon export in a frontal zone within the California Current , 2015 .
[32] I. Richter. Climate model biases in the eastern tropical oceans: causes, impacts and ways forward , 2015 .
[33] F. Chavez,et al. Seasonal regulation of primary production in eastern boundary upwelling systems , 2015 .
[34] Mary Jane Perry,et al. Eddy-driven subduction exports particulate organic carbon from the spring bloom , 2015, Science.
[35] M. Ohman,et al. Introduction to CCE-LTER: Responses of the California Current Ecosystem to climate forcing , 2015 .
[36] Francesco d’Ovidio,et al. Use of Ra isotopes to deduce rapid transfer of sediment-derived inputs off Kerguelen , 2014 .
[37] L. Bopp,et al. Physical pathways for carbon transfers between the surface mixed layer and the ocean interior , 2013 .
[38] R. Goericke,et al. Ecological transitions in a coastal upwelling ecosystem , 2013 .
[39] R. Kudela,et al. Trends in the surface chlorophyll of the California Current: Merging data from multiple ocean color satellites , 2012 .
[40] Adrian P. Martin,et al. How does dynamical spatial variability impact 234Th-derived estimates of organic export? , 2012 .
[41] James C. McWilliams,et al. Eddy-induced reduction of biological production in eastern boundary upwelling systems , 2011 .
[42] F. d’Ovidio,et al. Surface coastal circulation patterns by in‐situ detection of Lagrangian coherent structures , 2011 .
[43] R. Goericke,et al. Trophic cycling and carbon export relationships in the California Current Ecosystem , 2011 .
[44] A. King,et al. Dissolved iron and macronutrient distributions in the southern California Current System , 2011 .
[45] Bertrand Chapron,et al. Global Observations of Fine-Scale Ocean Surface Topography With the Surface Water and Ocean Topography (SWOT) Mission , 2010, Front. Mar. Sci..
[46] Qian P. Li,et al. Modeling phytoplankton growth rates and chlorophyll to carbon ratios in California coastal and pelagic ecosystems , 2010 .
[47] M. Ohman,et al. Lagrangian studies of phytoplankton growth and grazing relationships in a coastal upwelling ecosystem off Southern California , 2009 .
[48] R. Kudela,et al. Trends in primary production in the California Current detected with satellite data , 2009 .
[49] Xuemei Qiu,et al. Phenology of coastal upwelling in the California Current , 2009 .
[50] L. Centurioni,et al. Permanent Meanders in the California Current System , 2008 .
[51] James C. McWilliams,et al. North Pacific Gyre Oscillation links ocean climate and ecosystem change , 2008 .
[52] R. Rykaczewski,et al. Influence of ocean winds on the pelagic ecosystem in upwelling regions , 2008, Proceedings of the National Academy of Sciences.
[53] A. King,et al. Evidence for phytoplankton iron limitation in the southern California Current System , 2007 .
[54] E. Di Lorenzo,et al. Decadal variations in the California Current upwelling cells , 2007 .
[55] Adrian P. Martin,et al. The significance of nitrification for oceanic new production , 2007, Nature.
[56] Yasuhiro Yamanaka,et al. NEMURO—a lower trophic level model for the North Pacific marine ecosystem , 2007 .
[57] G. Plattner,et al. Decoupling marine export production from new production , 2005 .
[58] James C. McWilliams,et al. Upwelling response to coastal wind profiles , 2004 .
[59] Mark H. Pickett,et al. Ekman transport and pumping in the California Current based on the U.S. Navy's high‐resolution atmospheric model (COAMPS) , 2003 .
[60] Emanuele Di Lorenzo,et al. Seasonal dynamics of the surface circulation in the Southern California Current System , 2003 .
[61] James C. McWilliams,et al. Equilibrium structure and dynamics of the California Current System , 2003 .
[62] Francisco P. Chavez,et al. A model of plankton dynamics for the coastal upwelling system of Monterey Bay , 2000 .
[63] D. Hutchins,et al. Iron-limited diatom growth and Si:N uptake ratios in a coastal upwelling regime , 1998, Nature.
[64] F. Chavez,et al. Horizontal transport and the distribution of nutrients in the coastal transition zone off Northern California: effects on primary production, phytoplankton biomass and species composition , 1991 .
[65] J. Goering,et al. UPTAKE OF NEW AND REGENERATED FORMS OF NITROGEN IN PRIMARY PRODUCTIVITY1 , 1967 .
[66] J. McWilliams,et al. Orographic shaping of US West Coast wind profiles during the upwelling season , 2015, Climate Dynamics.
[67] Janusz Pempkowiak,et al. The Baltic Sea : a global synthesis , 2010 .
[68] Larry P. Atkinson,et al. Carbon and nutrient fluxes in continental margins : a global synthesis , 2010 .
[69] John A. Barth,et al. Mesoscale structure and its seasonal evolution in the northern California Current System , 2005 .
[70] Deborah K. Steinberg,et al. Upper Ocean Carbon Export and the Biological Pump , 2001 .
[71] T. Platt,et al. f-Ratio and its relationship to ambient nitrate concentration in coastal waters , 1987 .
[72] D. Chelton. LARGE-SCALE RESPONSE OF THE CALIFORNIA CURRENT TO FORCING BY THE WIND STRESS CURL , 1982 .
[73] Kenneth W. Bruland,et al. Fluxes of particulate carbon, nitrogen, and phosphorus in the upper water column of the northeast Pacific , 1979 .