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Poster Sessions
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| |Home| | |Background| | |Programme| |
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|Registration| |
|
|Logistics| | |Contacts| |
|
Poster Sessions
|
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TOPIC 1:
Trace elements in ecological
and biogeochemical processes Click here to download PDF of abstracts for topic 1 (159 KB) |
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| Authors | Title | |
| PS1: 1.1 | Achilles et al. | Importance of Iron for Trichodesmium in the North Atlantic. |
| PS1: 1.2 | Amouroux & Church | The cycle of volatile metals between waters and atmosphere |
| PS1: 1.3 | Assmy, Henjes, Klaas & Smetacek | Biological response to iron fertilization in the Polar Frontal Zone of the Southern Ocean (EisenEx) |
| PS1: 1.4 | Blain, Jeandel, Pondaven & Queguiner | KEOPS (Kerguelen, compared study of Open and in Surface water) |
| PS1: 1.5 | Bucciarelli, Sedwick, Blain & Tréguer | Physical-chemical control of the vertical distributions of iron in the Southern Ocean |
| PS1: 1.6 | Claustre | BIOSOPE (BIOgeochemistry and Optic SOuth Pacific Experiment) : investigation of an undersampled oceanic area |
| PS1: 1.7 | Cochlan, Herndon, Roberts & Kudela | New and Regenerated Production During the Southern Ocean Iron Enrichment Experiments (SOFeX) |
| PS1: 1.8 | de Baar and La Roche | Trace Metals in the Oceans: Evolution, Biology and Global Change |
| PS1: 1.9 | Dickson & Bintz | Chemical Reference Materials: Setting the Standards for Ocean Science |
| PS1: 1.10 | Fones & Moffett | In-situ measurement of biologically important trace metal species using DGT |
| PS1: 1.11 | Franck & Brzezinski | Effect of Fe addition on cell-specific silica production in mixed diatom assemblages from the eastern equatorial Pacific |
| PS1: 1.12 | Jeandel & Sternberg | BARium in MEDiterranean (BARMED) project |
| PS1: 1.13 | Kalmykov, Aliev, Sapozhnikov & Lisitsin | Study of ecological and geochemical processes using natural and man-made radionuclides |
| PS1: 1.14 | Kosakowska & Pempkowiak | The effect of natural and anthropogenic organic substances on the uptake of iron by algae under iron deficient conditions |
| PS1: 1.15 | Koukina, Korneeva, Ametistova & Bek | Trace metals and enzymatic activities in sediments of Kandalaksha Bay (White sea, Russian Arctic) |
| PS1: 1.16 | Leynaert et al. | Effect of iron deficiency on silicate uptake kinetics |
| PS1: 1.17 | Moffett et al. | Metal speciation and phytoplankton effects |
| PS1: 1.18 | Saifullah, Sarwat & Khan | Distribution of iron in mangrove habitat of Karachi |
| PS1: 1.19 | Sanathanam, Srinivasan & Ramadhasp | Impact of Heavy Metal Pollution on the Biodiverstiy of Oceanic Phytoplankton of the Gulf of Mannar, India |
| PS1: 1.20 | Sarkar & Bhattacharya | Microcontaminants in sediments and biota of a tropical mangrove estuary, northeast coast of India |
| PS1: 1.21 | Sofikitis, Desboeufs & Colin | Biogeochemical iron cycling |
| PS1: 1.22 | Statham | Cycling of dissolved organic phosphorus in oligotrophic oceanic domains |
| PS1: 1.23 | van den Berg & Ellwood | Cobalt speciation in Southern Ocean waters |
| PS1: 1.24 | Wells, Trick, & Hughes | The Roles of Domoic Acid and Copper in Alleviating Iron Stress of Toxigenic Pseudo-nitzschia Diatoms |
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TOPIC 2:
Physical forcing of
biogeochemical cycling and marine food webs
Click here to download PDF of abstracts for topic 2 (206 KB) |
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| Authors | Title | |
| PS1: 2.1 | Allemand et al. | Massive Corals, revisited Paleoclimate Archives |
| PS1: 2.2 | Barrera-Alba et al. | Biogeochemical Transport Balance, Phytoplankton and Bacterial Coupling in a Sub-tropical Estuary, Brazil |
| PS1: 2.3 | Boutin et al. | Variability of air-sea CO2 fluxes in the Southern Ocean inferred from CARIOCA drifters, ships and remotely sensed measurements |
| PS1: 2.4 | Carlini, Di Maio, Marcelli and Perilli | Chlorophyll patterns in anticyclonic vortex and distribution of DOC and Nutrients in Sardinia Sea : preliminary results |
| PS1: 2.5 | Chernyshkov, Sirota, Andrianov and Glez | Comparison of the pelagic ecosystems interannual variability in the Canary and Benguela upwelling systems |
| PS1: 2.6 | Conte, Dickey, Weber, Johnson and Knap | Mesoscale physical forcing of pulsed export of labile biogenic material to the deep Sargasso Sea |
| PS1: 2.7 | Crise et al. | Ten years of numerical studies on the pelagic Mediterranean ecosystem |
| PS1: 2.8 | Dandonneau et al. | Sea surface ecosystem and oceanic waves |
| PS1: 2.9 | Ediger, Tuğrul and Yılmaz | Distribution of nutrients, chl-a, POM and primary production in relation to the prevailing hydrographic features of the NE Mediterranean |
| PS1: 2.10 | Escribano et al. | The 1997/98 El Niño in the Humboldt Current System: a synthesis |
| PS1: 2.11 | Greve | The key role of thermal speciation in marine organisms |
| PS1: 2.12 | Knap, Bates, Lomas and Johnson | The Bermuda Atlantic Time-series Study (BATS): A time-series Window on Climate forcing of ocean variability |
| PS1: 2.13 | Kontar, Shapiro and Lobkovsky | Estimation of the impact of submarine groundwater discharge on the bio-geochemical parameters of coastal waters |
| PS1: 2.14 | Le Quere and Gruber | Gaining insight into the interannual variability of air-sea CO2 fluxes using satellite observations |
| PS1: 2.15 | Letelier, Karl, Abbott, Bidigare and White | The role micro-phytoplankton in bio-elemental cycling in stratified oligotrophic waters of the North Pacific Subtropical Gyre |
| PS1: 2.16 | Llido, Machu, Dadou and Garcon | Interannual variability in the Agulhas Current System : a comparative study between a coupled physical-biological model and multi-remote sensing data sets |
| PS1: 2.17 | Mahanta and Goswami | C-N-P flux from Brahmaputra-Ganges system to the Bay of Bengal: Potential Impact on the Biogeochemistry of the Indian Ocean |
| PS1: 2.18 | Marrase et al. | Links between trophic interactions and biogeochemical fluxes mediated through small-scale hydrodynamics: First efforts of the NTAP project |
| PS1: 2.19 | Mata, Ponsard, Jiménez; Morales and Mangin | Validation of Ocean Color Sensors in Case 2 waters: The biogeochemical processes in the Gulf of Cadiz (SW, Spain) |
| PS1: 2.20 | Menkes et al. | Tropical Instability vortices: a major control of the ecosystem in the tropical Pacific and Atlantic oceans |
| PS1: 2.21 | Moore, Holdsworth and Alverson | Climate change in the North Pacific region over the last three centuries |
| PS1: 2.22 | Moser et al. | Primary productivity and instantaneous transport of salt, chlorophyll-a, seston and dissolved nutrients in a polluted tropical estuarine system. |
| PS1: 2.23 | Nejstgaard, Frischer, Gruebel and Verity | May prey genes be used to determine zooplankton feeding in situ? |
| PS1: 2.24 | Orr, Aumont, Bopp and the OCMIP group | Evaluation of seasonal air-sea co2 fluxes in global ocean carbon-cycle models |
| PS1: 2.25 | Penven and Roy | Building the link between the basin scale signal and eastern boundary |
| PS1: 2.26 | Proctor et al. | Effects of simple climate change on primary production on the NW European Shelf |
| PS1: 2.27 | Sanchez-Vidal et al. | Particle fluxes and organic carbon budget in the Almeria-Oran front in the eastern Alboran Sea |
| PS1: 2.28 | Schmitt, Seuront and Souissi | Introducing microscale patterns and processes into global scales |
| PS1: 2.29 | Skreslet | Interference of hydro-electric power production with a marine food web |
| PS1: 2.30 | Spitz, Abbott and Richman | On the role of remineralization from a modeling perspective |
| PS1: 2.31 | Valencia, Franco, Borja, Belzunce and Solaun | Systems and Processes in the Basque Coast (SE Bay of Biscay) |
| PS1: 2.32 | Varela et al. | Latitudinal patterns of nitrogen uptake and dissolved organic nitrogen release in the Central Atlantic Ocean: the role of phytoplankton size-structure |
| PS1: 2.33 | Yin and Harrison | Monsoonal Influence on Seasonal Variations in Nutrients and Phytoplankton Biomass in the Pearl River Estuary and Adjacent Coastal Waters of Hong Kong |
| PS1: 2.34 | Yunev | Long-term variability of vertical chlorophyll profiles in the open Black Sea during warm months: consequence of cultural eutrophication or climatic changes? |
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TOPIC 3:
Climatic modulation of organic matter
fluxes Click here to download PDF of abstracts for topic 3 (124 KB) |
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| Authors | Title | |
| PS1: 3.1 | Andersen and Goutx | Production and Exportation of Carbon : control by HEterotrophic organisms at small time scales (PECHE) |
| PS1: 3.2 | Dugdale, Wilkerson, Chai, Barber and Peng | Diatoms in control and at risk: climate feedbacks and anthropogenic forcing |
| PS1: 3.3 | Goes, do R. Gomes, Limsakul and Saino | Climate Modulated Carbon Export In The North Pacific Ocean The Role Of El-Nino Events |
| PS1: 3.4 | Harlay et al. | Assessment of the importance of the carbonate pump |
| PS1: 3.5 | Iriarte and Gonzalez | Primary productivity and biomass of size-fractionated phytoplankton in a coastal upwelling area (Bahía Mejillones, 23S, Chile), during and after the 1997-1998 El Niño |
| PS1: 3.6 | Ivanova, Murdmaa and Vetrov | Organic carbon fluxes and paleoproductivity in the Eastern Barents Sea: responses to climatic changes during the Holocene and the last Millenium |
| PS1: 3.7 | Kohfeld, Le Quéré and Bopp | Limited Role of Export Production in Glacial-Interglacial CO2 Cycles? |
| PS1: 3.8 | Ménot-Combes, Sessions, Hayes and Altabet | Rapid Analysis of Carbon Isotopic Compositions of Sedimentary Algal Sterols |
| PS1: 3.9 | Niang et al. | Seasonal and spatial Variability of the phytoplankton composition infered from photosynthetic pigments inventories: preliminary results from the GeP&CO experiment |
| PS1: 3.10 | Oguz, Cokacar and Malanotte-Rizzoli | Decadal Warming and Change in Annual Cycle of Phytoplankton Blooms in the Black Sea |
| PS1: 3.11 | Ragueneau et al. | Quantification Si and C decoupling in the world ocean |
| PS1: 3.12 | Ribi | Climate Change, Sea Level Rise and Impact on Marine Wetlands |
| PS1: 3.13 | Saino | A Profiling Buoy System for real time monitoring of the Ocean Primary Productivity |
| PS1: 3.14 | Seritti, Santinelli and Nannicini | Vertical distribution of the Dissolved Organic Carbon (DOC) in different areas of the Mediterranean Sea |
| PS1: 3.15 | van Beek et al. | 228Ra/226Ra activity ratio in suspended matter to track barite formation and transport in the water column |
| PS1: 3.16 | Zhang | Nutrient entrainment by storms in oligotrophic ocean |
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TOPIC 4:
Direct
effects of anthropogenic CO2 on
biogeochemical cycles and ecosystems Click here to download PDF of abstracts for topic 4 (152 KB) |
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| Authors | Title | |
| PS1: 4.1 | Aerts, Godoi, Harlay, Chou, Van Grieken | Characterization of marine CaCO3 particles in the context of Global Change |
| PS1: 4.2 | Álvarez, Ríos, Pérez, Bryden and Rosón | Transports and Budgets of Toal Inorganic Carbon in the Subpolar and Temperate North Atlantic. |
| PS1: 4.3 | Delille et al. | Calcification and organic production of coccolithophorids Emiliania huxleyi under different atmospheric pCO2 in a mesocosm experiment |
| PS1: 4.4 | Engel and Heemann | Influence of CO2 on the production of transparent exopolymer particles (TEP) by marine phytoplankton |
| PS1: 4.5 | Feely et al. | In-situ Calcium Carbonate Dissolution in the Pacific Ocean |
| PS1: 4.6 | Friis | Researching anthropogenic CO2 in the ocean |
| PS1: 4.7 | Gattuso and Frankignoulle | Response of marine organisms and ecosystems to elevated carbon dioxide |
| PS1: 4.8 | Gehlen, Bassinot and McCorkle | The dissolution of marine carbonates: Shedding a new light on reaction kinetics and solubility |
| PS1: 4.9 | Goyet et al. | ACTION “Anthropogenic Carbon: Temporal Increase, Obervations and Numerization” : A contribution to the French National program PROOF “PROcessus biogéochimiques dans l’Océan et Flux” |
| PS1: 4.10 | Harada | Biogeochemical Approach to Environmental Assessment for Direct CO2 Sequestration into Deep Water |
| PS1: 4.11 | Held | Towards a Scheme for Risk Analysis of Carbon Sequestration Options |
| PS1: 4.12 | Joos, Plattner and Stocker | Changes in the Oxygen Content of the Ocean: Implications for the Carbon Budget and Ocean Circulation |
| PS1: 4.13 | Lee et al. | An Updated Estimate of Anthropogenic CO2 Inventory in the Atlantic Ocean |
| PS1: 4.14 | Makkaveev | The estimation of the role of the physical and biochemical processes of the seasonal variability of the carbon system in the upper waters of the World Ocean |
| PS1: 4.15 | Pierce | Future Changes in Biological Activity in the North Pacific Ocean due to Anthropogenic Forcing |
| PS1: 4.16 | Sabine, Key, Feely and Greeley | Inorganic carbon in the Indian Ocean |
| PS1: 4.17 | Sarma, Ono and Saino | Increase of Total Alkalinity due to shoaling of aragonite saturation horizon in the Pacific and Indian Oceans: Influence of anthropogenic carbon inputs |
| PS1: 4.18 | Sundarvel | Human impact on carbon biogeochemical cycle and oceanic ecosystem |
| PS1: 4.19 | Touratier and Goyet | Hydrological properties and distribution of the tracer 'CAO' |
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TOPIC 5:
Integrating food web dynamics from end
to end Click here to download PDF of abstracts for topic 4 (128 KB) |
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| Authors | Title | |
| PS1: 5.1 | Besiktepe, Simo and Tang | DMS and DMSP in the Black Sea, Marmara Sea, Aegean Sea and the Mediterranean Sea during October 2000 |
| PS1: 5.2 | Bucklin, Wiebe, Frost and Fogarty | ZooGene: a molecular database for rapid and accurate species identification of calanoid copepods and euphausiids |
| PS1: 5.3 | Carroll | Arctic Marine Ecosystems On Thin Ice: Climatic Influence on Energy Flow and Trophic Structure in the Norwegian Arctic |
| PS1: 5.4 | Gauns | Role of microzooplankton in the food web dynamics of the Arabian Sea |
| PS1: 5.5 | Incze and Richert | Biodiversity and Process Studies in Support of Ecosystem-Based Management: the Gulf of Maine Program of the Census of Marine Life |
| PS1: 5.6 | Laws | Maximum resiliency as a food web organizing construct |
| PS1: 5.7 | Pakhomov | Feeding dynamics of the pelagic tunicate Salpa thompsoni in the Southern Ocean: low to high latitude comparison |
| PS1: 5.8 | Mayzaud | Importance of adaptive strategies in the biological response of the pelagic organisms and ecosystem to global changes |
| PS1: 5.9 | Vaulot, Scanlan, Medlin, Pedrós-Alió, Throndsen and the PICODIV participants | The unsuspected diversity of marine eukaryotic picoplankton: results from the european PICODIV program |
| PS1: 5.10 | Zitzmann and Berninger | The importance and function of the microbial pelagic food web in the Greenland Sea |
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TOPIC 6:
Continental margins Click here to download PDF of abstracts for topic 6 (164 KB) |
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| Authors | Title | |
| PS2: 6.1 | Bode et al. | Spring phytoplankton blooms and hydrographic variability in shelf waters of northern Spain |
| PS2: 6.2 | Bonnin (Jerome) and van Raaphorst | Dissolved silica enrichment in the deep water |
| PS2: 6.3 | Chauvaud et al. | High resolution records on scallop shells : a new tool to investigate seasonal changes in coastal environments ? |
| PS2: 6.4 | Chen, Wong, Xu, Dong and Zhang | Impact of Margin Water Exchange on the Biogeochemistry over the Continental Shelf - Examples from East China Sea and South China Sea |
| PS2: 6.5 | Chou, Wollast and Roevros | Trace Element Composition of Suspended Matter along the Biscay Margin in the Northeast Atlantic |
| PS2: 6.6 | Dai, Cai, Zhai and Hu | Carbon Biogeochemistry In China Marginal Seas - Progress And Perspectives |
| PS2: 6.7 | Dellwig, Brumsack, Kölsch, Reuter and Terjung | Biogeochemical water column signatures of the Wadden Sea of NW Germany: Budgets and system states |
| PS2: 6.8 | Elkalay, Thomas, Bozec, Ruardij and deBaar | The continental shelf pump: a case study in the North Sea |
| PS2: 6.9 | Giraud and Le Quéré | Considering a coastal ocean model for global simulations |
| PS2: 6.10 | González et al. | Physical and Biological Features Associated with the Continental Margin in the Humboldt Current System off Chile |
| PS2: 6.11 | Hoepffner, Garcia-Gorriz and Melin | Biogeochemical properties and carbon cycle in the Adriatic Sea resulting from SeaWiFS imagery and modeling |
| PS2: 6.12 | Hung, Chen, Lin, Chung and Sheu | Exports of Dissolved and Particulate Organic Carbon from the East China Sea Shelf |
| PS2: 6.13 | Huret, Garcon, Dadou and Dumas | Modeling the biogeochemical activity on the Southeastern South American continental shelf |
| PS2: 6.14 | Hydes | The role of ships of opportunity in the OCEANS |
| PS2: 6.15 | Jordi et al. | Shelf open ocean exchanges through submarine canyons |
| PS2: 6.16 | Lizon and Gentilhomme | Microalgae dynamic in a coastal zone impacted by human activities and climate perturbations |
| PS2: 6.17 | Louanchi et al. | Interannual variability of nutrient distributions along the algerian coastal shelf |
| PS2: 6.18 | Naik and Naqvi | Benthic Denitrification in the Eastern Arabian Sea |
| PS2: 6.19 | Pempkowiak and Kosakowska | Carbon budget and fluxes in the Baltic sea |
| PS2: 6.20 | Ragueneau et al. | Si-WEBS, a European network for the study of Si fluxes on continental margins |
| PS2: 6.21 | Seitzinger et al. | Global Patterns of Human Activities on Land and Nutrient Enrichment of Coastal Marine Ecosystems: Current Conditions and Future Projections |
| PS2: 6.22 | Song | Ocean Modeling in Generalized Vertical Coordinate and Its Applications to the Asian Marginal Seas |
| PS2: 6.23 | Soto, Norambuena and Leal | Fate of N, P and C supplied by Salmon Farming: the Challenge of Predicting Ecosystem Effects |
| PS2: 6.24 | Sugimoto and Takeuchi | Variations in plankton biomass and fish catch in the continental margin south of Japan |
| PS2: 6.25 | Tambiev and Lisitsyn | Biogeochemical processes impact on differentiation of the sedimentary material in Arctic region |
| PS2: 6.26 | Zang, Wu and Liu | Response and Feed-back of Shelf Biogeochemistry to the Input of Land-source materials: Examples from Changjiang - East China Sea System |
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TOPIC 7:
The
mesopelagic layer Click here to download PDF of abstracts for topic 7 (104 KB) |
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| Authors | Title | |
| PS2: 7.1 | Glover and Conte | A Coupled Epipelagic-Meso/Bathypelagic Particle Flux Model for the Bermuda Atlantic Time-series Station (BATS)/Oceanic Flux Program (OFP) Site |
| PS2: 7.2 | Jackson | Particle dynamics and carbon flux in the mesopelagic |
| PS2: 7.3 | Kasatkina, Shnar and Chernyshkov | Spatial distribution variability of the pelagic community around South Sandwich Islands in relation to oceanographic conditions |
| PS2: 7.4 | Koppelmann and Weikert | The influence of mesozooplankton on the remineralisation of organic carbon in the deep-sea |
| PS2: 7.5 | Madhupratap | Twilight zone in the Arabian Sea |
| PS2: 7.6 | Rivkin and Legendre | Biogenic Carbon Cycling and Remineralization in the Mesopelagic |
| PS2: 7.7 | Roman, Spear, Zhang, Greenlaw, Van Holliday | Mesopelagic Mesozooplankton Aggregations: Potential Hot Spots for Particle Transformation and Transport |
| PS2: 7.8 | Tanaka, Rochelle-Newall, Rassoulzadegan and Gattuso | Bacterial production and plankton respiration in the mesopelagic layer of the NW Mediterranean Sea |
| PS2: 7.9 | Zimin, Kasatkina, Sushin, Chernyshkov and Shnar | Influence of oceanographic and meteorological processes on the distribution of zooplankton (euphausia superba) in the Antarctic Sector of Atlantic (AsA) |
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TOPIC 8:
Biogeochemical hotspots, choke points,
triggers, switches and non-linear
responses Click here to download PDF of abstracts for topic 8 (105 KB) |
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| Authors | Title | |
| PS2: 8.1 | Leinn | Three main sources of CH4 and H2S - Quantitative estimates of fluxes in the ocean |
| PS2: 8.2 | Anagnostou, Sioulas and Karageorgis | The role of CO2 as driving force for the climate change from the last ice period of Holocene to the recent interglacial conditions. An evidence from the sediment depositions in a semienclosed marine system (Pagassitikos Gulf/Hellas) |
| PS2: 8.3 | Brinis, Momzikoff, Mejanelle, Fillaux, Gondry, Lebaron, Herndl and Saliot | How chemistry of the sea surface microlayer influences biogeochemical processes at the atmosphere/ocean interface |
| PS2: 8.4 | El Boukhary, Ruiz-Pino and Bethoux | Is the oxygen changing in the Mediterranean Sea ? |
| PS2: 8.5 | Hamacher, Wagener, Soares, Anderson and Rodrigues | Material fluxes across mangrove and adjacent coastal areas in Rio de Janeiro, Brazil |
| PS2: 8.6 | Hong, Huang and Li | Biogeochemistry of Taiwan Strait Upwelling Ecosystem: Dynamics and structure |
| PS2: 8.7 | Jorissen et al. | FORAMPROX -- an integrated ecological geochemical effort of proxy amelioration |
| PS2: 8.8 | Kemp | Giant Diatom Dumps as spatial and temporal biogeochemical hotspots |
| PS2: 8.9 | Metzl, Brunet, Jabaud-Jan, Pierre, Poisson and Schauer | Interannual variability and future change of air-sea CO2 fluxes in the Southern Ocean |
| PS2: 8.10 | Paulmier and Ruiz-Pino | Oxygen Minimum Layer (OML) modeling: Organic Matter (OM) recycling or preservation? A possible CO2 and N2O coupling? |
| PS2: 8.11 | Turnewitsch and Graf | Variability of particulate seawater properties related to bottom mixed layer-associated internal waves in shallow water on a time scale of hours |
| PS2: 8.12 | Turnewitsch, Lahajnar, Thomson and Croudace | re Asymmetric Flow Fields Around Kilometer-Scale Topographic Seafloor Elevations Reflected in the Sediment? |
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TOPIC 10:
Coupled
models of biogeochemical cycles and
ecosystems Click here to download PDF of abstracts for topic 10 (154 KB) |
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| Authors | Title | |
| PS2: 10.1 | Aiken, Robinson and members of CASIX team | Centre of observation of Air-Sea Interactions and fluXes (CASIX) |
| PS2: 10.2 | Alverson and Le Grand | Glacial-Interglacial changes in Atmsopheric CO2 |
| PS2: 10.3 | Andre, Menkes, Dubroca, Guinet, Shankar, BenMustapha and Menard | Modelling Predator Environment: Tropical Tuna, and Fin-Whales in the NW Mediterranean |
| PS2: 10.4 | Armstrong | A compact model structure for analysis of food web data and for carbon cycle simulation |
| PS2: 10.5 | Buitenhuis, Le Quéré and Aumont | On the development and evaluation of a Dynamic Green Ocean Model: role of phytoplankton calcifiers for ocean biogeochemistry |
| PS2: 10.6 | Carlotti and Sourisseau | A multi-population size-structured model of zooplankton for studying food-web dynamics and biogeochemical fluxes |
| PS2: 10.7 | Dowell, Runge & Campbell | Characterizing the global distribution and nature of the rate of algal loss in pelagic marine ecosystems |
| PS2: 10.8 | Drevillon, Dadou, Garcon, Charria, De Mey, Greiner and Benkiran | Physical validation of a North Atlantic Ocean model assimilating altimetry data prior to biogeochemical studies |
| PS2: 10.9 | Dunne, Armstrong, Deutsch, Gnanadesikan, Gruber, Sarmiento and Swathi | Empirical and predictive models for the particle export ratio |
| PS2: 10.10 | Fujii, Nojiri, Yamanaka and Kishi | Simulated physical environments and biogeochemical processes at the subarctic North Pacific time-series Station KNOT (44N, 155E) |
| PS2: 10.11 | Grégoire, Beckers, Kostianoy, Nezlin, Stanev and Nihoul | Exchange Processes and Nitrogen Cycling on the Shelf and Slope area of the Black Sea Basin |
| PS2: 10.12 | Hemmings, Srokosz, Challenor and Fasham | Calibration and validation of an ecosystem model using satellite ocean colour data |
| PS2: 10.13 | Hofmann and Maqueda | Modeling the seasonal pCO_2 cycle in the subarctic Pacific ocean |
| PS2: 10.14 | Klaas and Archer | Spatial Patterns of Organic Carbon in Sediment Traps: Application to the LGM Carbon Cycle |
| PS2: 10.15 | Lampitt, Popova, Send and the ANIMATE partnership | Assimilation of real time observations into regional 3D-biogeochemical models: The future is bright |
| PS2: 10.16 | Lancelot et al. | Using the 3D coupled physical-biological model MIRO&CO to assess Phaeocystis blooms and related C, N, P and Si cycling in the Southern Bight of the North Sea and the response to short-term climatic and nutrient changes |
| PS2: 10.17 | Lehodey | Modelling the climate-related fluctuations of tuna populations from coupled ocean-biogeochemical-populations dynamics models |
| PS2: 10.18 | Liu, Sun, Wang, Zhu and Han | Modeling Study on the Ecosystem of the Bohai Sea using a Coupled Three-dimensional Physical-chemical-biological Ocean Model |
| PS2: 10.19 | Nurdjaman (Susanna) | A Model of The Lower Trophic Level Ecosystem |
| PS2: 10.20 | Pahlow, Vezina and Wright | Modeling the relationship between climate and marine dissolved organic matter |
| PS2: 10.21 | Parekh, Dutkiewicz and Follows | Models of the Global Ocean Iron Cycle and Ocean Productivity |
| PS2: 10.22 | Santoleri, Banzon, Marullo, Napolitano, D’Ortenzio and Evans | Year-to-year variability phytoplankton bloom in southern Adriatic Sea (1998-2000): SeaWiFS observation and modelling study |
| PS2: 10.23 | Solidoro, Cossarini, Melaku Canu, Pastres, Mosetti and Tomini | Ecological modeling in coastal area: from nutrient dynamics to marine resources under different scenarios of human activity and physical forcing. Examples from a real case study |
| PS2: 10.24 | Spall, Barciela, Liddicoat and Aiken | Modelling the deep ocean carbon cycle as part of the Centre for observation of Air-Sea Interactions and fluXes (CASIX) |
| PS2: 10.25 | Thoms and Engel | Modeling the aggregation of dissolved polysaccharides during a marine phytoplankton bloom |
| PS2: 10.26 | Uitz, Claustre, More and Hooker | Analysis of HPLC pigment database : Towards a climatology of phytoplankton functional groups |
| PS2: 10.27 | Weber, Völker, Schartau and Wolf-Gladrow | A model of iron cycling in the mixed layer of the ocean |
| PS2: 10.28 | Woods | Predictability of the plankton ecosystem |
| PS2: 10.29 | Yamanaka, Aita and Kishi | Preliminary results from a marine ecosystem model |
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TOPIC 11:
Programmes Click here to download PDF of abstracts for topic 11 (83 KB) |
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| Authors | Title | |
| PS2: 11.1 | Anderson, Francois, Frank, Henderson, Jeandel and Sharma | Planning Activities for GEOSECS-II |
| PS2: 11.2 | Avril and Conkright | JGOFS Data Management: What has been done? What has been learned? |
| PS2: 11.3 | Bathman, Hofmann, Murphy and Nicol | ICCED: Integrated analyses of Circumpolar Climate interactions and Ecosystem Dynamics in the Southern Ocean - A Southern Ocean Initiative for the OCEANS Programme |
| PS2: 11.4 | Beaugrand | The Continuous Plankton Recorder survey: climate change and biogeochemical processes in the North Atlantic Ocean |
| PS2: 11.5 | Civitarese and Gacic | THE SOUTHERN ADRIATIC FIELD LABORATORY: ITS STORY STARTS NOW! |
| PS2: 11.6 | Dittert, Diepenbroek and Grobe | WDC-MARE / PANGAEA: a convenient data- and information management partner with YOU ? |
| PS2: 11.7 | Doney et al. | An ocean research component to the U.S. Carbon Cycle Science Program (CCSP-Oceans) |
| PS2: 11.8 | Gallardo et al. | Center for Oceanographic Research in the Eastern South Pacific (COPAS) |
| PS2: 11.9 | Hebbeln, Fischer, Paul and Schulz | RCOM - Research Center Ocean Margins at the University of Bremen |
| PS2: 11.10 | Hunt, Loeng and Drinkwater | Ecosystem Studies of Sub-arctic Seas |
| PS2: 11.11 | Larocque and Alverson | The IGBP-PAGES program |
| PS2: 11.12 | Lochte et al. - The Members of the Paleo-JGOFS Task Team | Linking Past and Present Ocean Processes |
| PS2: 11.13 | Migon | Presentation of the interdisciplinary project MELISSA (PROOF Programme) |
| PS2: 11.14 | O'Brien | The WORLD OCEAN DATABASE: A global integrated database of physical, chemical, and biological measurements for biogeochemical studies. |
| PS2: 11.15 | Pérez, Cabanas, Rosón, Ríos, Castro and Alvarez | MINAS: A New Site for Observing Climate Change in the Inter-gyre Region of the Eastern North Atlantic |
| PS2: 11.16 | Perry | GLOBEC Retrospective Analyses and Time Series Studies in Marine Ecosystems |
| PS2: 11.17 | Robinson | The Atlantic Meridional Transect Programme |
| PS2: 11.18 | Sicre and Claustre | The French program PROOF : linking biogeochemistry to climate change and environmental perturbations |
| PS2: 11.19 | Williamson and Heath | Physical controls on ecosystem dynamics in UK shelf seas and the northern North Atlantic: an overview of the UK GLOBEC programme |
| PS2: 11.20 | Yarincik and O'Dor | The Census of Marine Life |
| PS2: 11.21 | Zhang and Grassle | The Ocean Biogeographic Information System |
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