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4. Is one annotation enough? A data-centric image classification benchmark for noisy and ambiguous label estimation

Author

Schmarje, Lars, Grossmann, Vasco, Zelenka, Claudius, Dippel, Sabine, Kiko, Rainer, Oszust, Mariusz, Pastell, Matti, Stracke, Jenny, Valros, Anna, Volkmann, Nina, and Koch, Reinhard

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

High-quality data is necessary for modern machine learning. However, the acquisition of such data is difficult due to noisy and ambiguous annotations of humans. The aggregation of such annotations to determine the label of an image leads to a lower data quality. We propose a data-centric image classification benchmark with ten real-world datasets and multiple annotations per image to allow researchers to investigate and quantify the impact of such data quality issues. With the benchmark we can study the impact of annotation costs and (semi-)supervised methods on the data quality for image classification by applying a novel methodology to a range of different algorithms and diverse datasets. Our benchmark uses a two-phase approach via a data label improvement method in the first phase and a fixed evaluation model in the second phase. Thereby, we give a measure for the relation between the input labeling effort and the performance of (semi-)supervised algorithms to enable a deeper insight into how labels should be created for effective model training. Across thousands of experiments, we show that one annotation is not enough and that the inclusion of multiple annotations allows for a better approximation of the real underlying class distribution. We identify that hard labels can not capture the ambiguity of the data and this might lead to the common issue of overconfident models. Based on the presented datasets, benchmarked methods, and analysis, we create multiple research opportunities for the future directed at the improvement of label noise estimation approaches, data annotation schemes, realistic (semi-)supervised learning, or more reliable image collection., Comment: Accepted at NeurIPS 2022, Benchmark and Dataset Track, Code and Link to data available at https://github.com/Emprime/dcic

Published
2022

9. A Data-Centric Approach for Improving Ambiguous Labels with Combined Semi-supervised Classification and Clustering

Author

Schmarje, Lars, Santarossa, Monty, Schröder, Simon-Martin, Zelenka, Claudius, Kiko, Rainer, Stracke, Jenny, Volkmann, Nina, Koch, Reinhard, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Avidan, Shai, editor, Brostow, Gabriel, editor, Cissé, Moustapha, editor, Farinella, Giovanni Maria, editor, and Hassner, Tal, editor

Published
2022
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11. Publisher Correction: Making marine image data FAIR

Author

Schoening, Timm, Durden, Jennifer M., Faber, Claas, Felden, Janine, Heger, Karl, Hoving, Henk-Jan T., Kiko, Rainer, Köser, Kevin, Krämmer, Christopher, Kwasnitschka, Tom, Möller, Klas Ove, Nakath, David, Naß, Andrea, Nattkemper, Tim W., Purser, Autun, and Zurowietz, Martin

Published
2022
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12. Making marine image data FAIR

Author

Schoening, Timm, Durden, Jennifer M., Faber, Claas, Felden, Janine, Heger, Karl, Hoving, Henk-Jan T., Kiko, Rainer, Köser, Kevin, Krämmer, Christopher, Kwasnitschka, Tom, Möller, Klas Ove, Nakath, David, Naß, Andrea, Nattkemper, Tim W., Purser, Autun, and Zurowietz, Martin

Published
2022
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13. Estimating the copepod biomass in the North West African upwelling system using a bi-frequency acoustic approach.

Author

DIOGOUL, Ndague, BREHMER, Patrice, KIKO, Rainer, PERROT, Yannick, Lebourges-Dhaussy, Anne, RODRIGUES, Elizandro, THIAM, Abou, MOUGET, Anne, EL AYOUBI, Salaheddine, and SARRÉ, Abdoulaye

Subjects
MARINE ecology, CONTINENTAL shelf, OCEAN currents, BIOMASS, COPEPODA
Abstract

The Canary Current Large Marine Ecosystem (CCLME) is one of the most productive Large Marine Ecosystems worldwide. Assessing the abundance, biomass and distribution of zooplankton in the southern part of this system, off the coast of West Africa, remains challenging due to limited sampling efforts and data availability. However, zooplankton is of primary importance for pelagic ecosystem functioning. We applied an inversion method with combined analysis of acoustic and biological data for copepod discrimination using a bi-frequency (38 and 120 kHz) approach. Large copepods with equivalent spherical radii > 0.5 mm were identified using differences in the mean volume backscattering strength (MVBS). Regarding abundance measured by net sampling, copepods strongly dominated the zooplankton community and the large fraction account for 18%. This estimate correlated significantly with MVBS values that were obtained using an inverse algorithm. We confirmed the utility of using 38 kHz for large copepod detection. An epipelagic biomass of large copepod was estimated at 120–850 mg m-2 in March during upwelling season. It is worth noting that this estimation likely underestimates the true biomass due to inherent uncertainties associated with the measurement method. We recommend future investigations in the interest of using only nighttime data to improve the sampling pattern, particularly on the upper part of the water column (< 10 m) as well as on the shallow part of the continental shelf (< 20 m depth) not covered by fisheries vessel. Nevertheless, such high copepod biomass supports high fish production underlining the key role of copepod in the CCLME. Our results open the way to the analysis of the fluctuation and trend of copepod biomass, along with three decades of fisheries acoustics data available in the region. This helps to determine ecosystem changes, particularly under climate change, and to investigate the role of copepods in the southern CCLME carbon pump at the fine scale. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Combining in situ and ex situ plankton image data to reconstruct zooplankton (>1 mm) volume and mass distribution in the global ocean.

Author

Soviadan, Yawouvi Dodji, Dugenne, Mathilde, Drago, Laetitia, Biard, Tristan, Trudnowska, Emilia, Lombard, Fabien, Romagnan, Jean-Baptiste, Jamet, Jean-Louis, Kiko, Rainer, Gorsky, Gabriel, and Stemmann, Lars

Subjects
ZOOPLANKTON, SAMPLING methods, BIOMASS, PLANKTON, LATITUDE
Abstract

Plankton size spectra are important indicators of the ecosystem state, yet such measurements are typically biased by the available sampling methods. Here, we combined individual size measurement from two zooplankton imaging approaches— in situ observation by the Underwater Vision Profiler5 and Multinet-collection supplemented by ex situ imaging via Zooscan—obtained in the global ocean, to calculate zooplankton normalized biovolume size spectra (NBSS) for all organisms larger than 1 mm. The reconstructed NBSS combining both datasets resulted in increased biomass estimates by adding organisms poorly sampled by either of the methods. The optimal values measured by both methods are used to reconstruct the zooplankton biovolume and biomass distributions. The reconstructed slopes appeared steeper and closer to those measured only by the UVP5 (+7.6%) and flatter than those obtained only from the Multinet (−20%), particularly in tropical and temperate latitudes. The main difference in tropical and temperate NBSS from the two devices is due to the fragile rhizarians that were not accounted for when using net data. When possible, we suggest using in situ and ex situ technologies together, and we provide potential indications on how to correct for missing components of the community when only one method is available. [ABSTRACT FROM AUTHOR]

Published
2024
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15. Phosphate Influx and Dust Deposition Create Zonal and Meridional Biogeochemical Gradients in Trichodesmium Abundance.

Author

Mehta, Shreya, Kiko, Rainer, Hauss, Helena, Ojha, Narendra, and Singh, Arvind

Subjects
CARBON cycle, OCEAN temperature, TRICHODESMIUM, CARBON sequestration, HIGH temperatures
Abstract

Trichodesmium plays a key role in the biogeochemical cycling of carbon, nitrogen and phosphorus in the Tropical Atlantic Ocean. A complex interplay of physicochemical factors control the growth of Trichodesmium. However, owing to the large spatial and temporal variability, the relative influence of these factors in controlling Trichodesmium distribution and abundance remains unclear. In this study, we examined the basin‐scale distribution pattern of Trichodesmium in the upper 200 m water column of the Atlantic Ocean (25°N–30°S and 70°W–20°E) using a large data set (n = 33,235) and tried to constrain the distribution based on various physicochemical parameters. We suggest that the combined effect of warm temperatures and phosphate (PO43−) availability determines the zonal spatial extent and the abundance of Trichodesmium in the Tropical North Atlantic Ocean. However, the availability of dissolved iron, along with high sea surface temperatures and meteorological parameters such as the wind direction and precipitation, likely govern the meridional distribution of Trichodesmium across the Atlantic Ocean. Excess PO43− at the surface rules out the possibility of PO43− limitation in regulating the meridional distribution of the Trichodesmium. Depth‐integrated nitrogen fixation rates, based on a multiple linear regression, vary from 0.07 to 306 μmol N m−2 d−1. The presence of Trichodesmium colonies down to a depth of 200 m and the depth‐integrated nitrogen fixation rates reflect the pivotal role of Trichodesmium in the nitrogen budget of this region. Plain Language Summary: Microbial nitrogen fixation is the key to carbon sequestration in the ocean. Trichodesmium, being the ubiquitous nitrogen fixing microbe in the Tropical Atlantic Ocean, contributes significantly to nitrogen inputs. Limited availability of data, however, restricts our understanding of environmental parameters in controlling the distribution and abundance of Trichodesmium. To address this, we conducted a comprehensive analysis using large‐scale field‐based data of Trichodesmium abundance to investigate the role of various physical, chemical, and meteorological parameters on the distribution and abundance of Trichodesmium along the zonal and meridional transects of the Tropical Atlantic Ocean. We conclude that Trichodesmium distribution is governed by a complex interplay of environmental factors. Along the zonal transect, Trichodesmium abundance is primarily governed by the availability of PO43− and high sea surface temperatures. Conversely, the inter‐hemispheric variability seems to be influenced by dust deposition (a proxy for iron inputs) and high sea surface temperatures. Furthermore, our estimation of high modeled depth‐integrated nitrogen fixation rates based on Trichodesmium underscores its crucial role in the nitrogen budget. These findings provide valuable insight into the role of environmental factors driving Trichodesmium abundance and its significance toward the global nitrogen budget. Key Points: Trichodesmium distribution across the east‐west continuum in the Tropical North Atlantic Ocean is governed by the availability of phosphate and elevated sea surface temperaturesThe interhemispheric variability in Trichodesmium distribution in the Atlantic Ocean is regulated by the cumulative effect of high temperature and dust depositionTrichodesmium niche may have been overlooked in the past, potentially leading to underestimation of associated N2 fixation rates [ABSTRACT FROM AUTHOR]

Published
2024
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17. Dynamics of Aggregates and Sinking Carbon Fluxes in a Turbulent Ocean

Author

Siegel, David, Burd, Adrian, Estapa, Margaret, Fields, Erik, Johnson, Leah, Romanelli, Elisa, Brzezinski, Mark, Buesseler, Ken, Clevenger, Samantha, Cetinic, Ivona, Drago, Laetitia, Durkin, Colleen, Kiko, Rainer, Kramer, Sasha, Maas, Amy, Omand, Melissa, Passow, Uta, Steinberg, Deborah, Siegel, David, Burd, Adrian, Estapa, Margaret, Fields, Erik, Johnson, Leah, Romanelli, Elisa, Brzezinski, Mark, Buesseler, Ken, Clevenger, Samantha, Cetinic, Ivona, Drago, Laetitia, Durkin, Colleen, Kiko, Rainer, Kramer, Sasha, Maas, Amy, Omand, Melissa, Passow, Uta, and Steinberg, Deborah

Abstract

The sinking of particulate matter from the upper ocean dominates the export and sequestration of organic carbon by the biological pump, a critical component of the Earth's carbon cycle. Controls on carbon export are thought to be driven by ecological processes that produce and repackage sinking biogenic particles. Here, we present observations during the demise of the Northeast Atlantic Ocean spring bloom illustrating the importance of storm-induced turbulence on the dynamics of sinking particles. A sequence of four large storms caused upper layer mean turbulence levels to vary by more than three orders of magnitude. Large particle (>0.1 to 10 mm) abundance and size changed accordingly: increasing via shear coagulation when turbulence was moderate and decreasing rapidly when turbulence was intense due to shear disaggregation. Particle export was also tied to storm forcing as large particles were mixed to depth during mixed layer deepening. After the mixed layer shoaled, these particles, now isolated from intense surface mixing, grew larger and subsequently sank. This sequence of events matched the timing of sinking particle flux observations. Particle export was influenced by increases in aggregate abundance and porosity, which appeared to be enhanced by the repeated creation and destruction of aggregates. Last, particle transit efficiency through the mesopelagic zone was reduced by presumably biotic processes that created small particles (<0.5 mm) from larger ones. Our results demonstrate that ocean turbulence significantly impacts the nature and dynamics of sinking particles, strongly influencing particle export and the efficiency of the biological pump.

Published
2024
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18. Massive and localized export of selected marine snow types at eddy edges in the South Atlantic Ocean

Author

Accardo, Alexandre, Laxenaire, Rémi, Baudena, Alberto, Speich, Sabrina, Kiko, Rainer, Stemmann, Lars, Accardo, Alexandre, Laxenaire, Rémi, Baudena, Alberto, Speich, Sabrina, Kiko, Rainer, and Stemmann, Lars

Abstract

The open ocean plays a critical role in mitigating climate change by sequestering carbon dioxide (CO2) from the atmosphere for long periods of time. This carbon storage occurs over decades to millennia and relies on the physical pump that transports cold, dense, and DIC-rich waters to the deep ocean, as part of the ocean’s overturning circulation, and the biological carbon pump (BCP). The BCP encompasses a wide range of processes, from the fixation of atmospheric CO2 by phytoplankton activity to carbon sequestration in the deep ocean. Atmospheric CO2 concentrations would be about 200 ppm higher than in a world without biology, and the global climate would be much warmer by default. This study highlights the idea that BCP efficiency is enhanced by the ocean dynamics at mesoscale and submesoscale. In fact, our results suggest that frontal regions, such as those between mesoscale eddies, could lead to an important accumulation and transport of particulate organic matter (POM) from the mixed layer depth (MLD) down to depths of about 600 meters. To reach these conclusions, a multifaceted approach was applied. It included in-situ measurements and marine snow images from a BGC Argo float equipped with an Underwater Vision Profiler (UVP6), satellite altimetry data, and Lagrangian physics diagnostics. We focused our study on three intense features in marine snow distribution observed during the 17-month long float mission in the Cape Basin, southwest of Africa. These features were located in the frontal region between mesoscale eddies. Our study suggests that a particle injection pump induced by a frontogenesis-driven mechanism has the potential to enhance the effectiveness of the biological pump by increasing the depth at which carbon is injected into the water column. This work also emphasizes the importance of establishing repeated sampling campaigns targeting the interface zones between eddies. This could improve our understanding of the mechanisms involved in the deep a

Published
2024
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19. First release of the Pelagic Size Structure database: global datasets of marine size spectra obtained from plankton imaging devices

Author

Dugenne, Mathilde, Corrales-Ugalde, Marco, Luo, Jessica Y., Kiko, Rainer, O'Brien, Todd D., Irisson, Jean-Olivier, Lombard, Fabien, Stemmann, Lars, Stock, Charles, Anderson, Clarissa R., Babin, Marcel, Bhairy, Nagib, Bonnet, Sophie, Carlotti, Francois, Cornils, Astrid, Crockford, E. Taylor, Daniel, Patrick, Desnos, Corinne, Drago, Laetitia, Elineau, Amanda, Fischer, Alexis, Grandrémy, Nina, Grondin, Pierre-Luc, Guidi, Lionel, Guieu, Cecile, Hauss, Helena, Hayashi, Kendra, Huggett, Jenny A., Jalabert, Laetitia, Karp-Boss, Lee, Kenitz, Kasia M., Kudela, Raphael M., Lescot, Magali, Marec, Claudie, McDonnell, Andrew, Mériguet, Zoe, Niehoff, Barbara, Noyon, Margaux, Panaïotis, Thelma, Peacock, Emily, Picheral, Marc, Riquier, Emilie, Roesler, Collin, Romagnan, Jean-Baptiste, Sosik, Heidi M., Spencer, Gretchen, Taucher, Jan, Tilliette, Chloé, Vilain, Marion, Dugenne, Mathilde, Corrales-Ugalde, Marco, Luo, Jessica Y., Kiko, Rainer, O'Brien, Todd D., Irisson, Jean-Olivier, Lombard, Fabien, Stemmann, Lars, Stock, Charles, Anderson, Clarissa R., Babin, Marcel, Bhairy, Nagib, Bonnet, Sophie, Carlotti, Francois, Cornils, Astrid, Crockford, E. Taylor, Daniel, Patrick, Desnos, Corinne, Drago, Laetitia, Elineau, Amanda, Fischer, Alexis, Grandrémy, Nina, Grondin, Pierre-Luc, Guidi, Lionel, Guieu, Cecile, Hauss, Helena, Hayashi, Kendra, Huggett, Jenny A., Jalabert, Laetitia, Karp-Boss, Lee, Kenitz, Kasia M., Kudela, Raphael M., Lescot, Magali, Marec, Claudie, McDonnell, Andrew, Mériguet, Zoe, Niehoff, Barbara, Noyon, Margaux, Panaïotis, Thelma, Peacock, Emily, Picheral, Marc, Riquier, Emilie, Roesler, Collin, Romagnan, Jean-Baptiste, Sosik, Heidi M., Spencer, Gretchen, Taucher, Jan, Tilliette, Chloé, and Vilain, Marion

Abstract

In marine ecosystems, most physiological, ecological, or physical processes are size dependent. These include metabolic rates, the uptake of carbon and other nutrients, swimming and sinking velocities, and trophic interactions, which eventually determine the stocks of commercial species, as well as biogeochemical cycles and carbon sequestration. As such, broad-scale observations of plankton size distribution are important indicators of the general functioning and state of pelagic ecosystems under anthropogenic pressures. Here, we present the first global datasets of the Pelagic Size Structure database (PSSdb), generated from plankton imaging devices. This release includes the bulk particle normalized biovolume size spectrum (NBSS) and the bulk particle size distribution (PSD), along with their related parameters (slope, intercept, and R2) measured within the epipelagic layer (0–200 m) by three imaging sensors: the Imaging FlowCytobot (IFCB), the Underwater Vision Profiler (UVP), and benchtop scanners. Collectively, these instruments effectively image organisms and detrital material in the 7–10 000 µm size range. A total of 92 472 IFCB samples, 3068 UVP profiles, and 2411 scans passed our quality control and were standardized to produce consistent instrument-specific size spectra averaged to 1° × 1° latitude and longitude and by year and month. Our instrument-specific datasets span most major ocean basins, except for the IFCB datasets we have ingested, which were exclusively collected in northern latitudes, and cover decadal time periods (2013–2022 for IFCB, 2008–2021 for UVP, and 1996–2022 for scanners), allowing for a further assessment of the pelagic size spectrum in space and time. The datasets that constitute PSSdb's first release are available at https://doi.org/10.5281/zenodo.11050013 (Dugenne et al., 2024b). In addition, future updates to these data products can be accessed at https://doi.org/10.5281/zenodo.7998799.

Published
2024
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20. First release of the Pelagic Size Structure database: Global datasets of marine size spectra obtained from plankton imaging devices

Author

Dugenne, Mathilde, primary, Corrales-Ugalde, Marco, additional, Luo, Jessica, additional, Kiko, Rainer, additional, O'Brien, Todd, additional, Irisson, Jean-Olivier, additional, Lombard, Fabien, additional, Stemmann, Lars, additional, Stock, Charles, additional, Anderson, Clarissa R., additional, Babin, Marcel, additional, Bhairy, Nagib, additional, Bonnet, Sophie, additional, Carlotti, Francois, additional, Cornils, Astrid, additional, Crockford, E. Taylor, additional, Daniel, Patrick, additional, Desnos, Corinne, additional, Drago, Laetitia, additional, Elineau, Amanda, additional, Fischer, Alexis, additional, Grandrémy, Nina, additional, Grondin, Pierre-Luc, additional, Guidi, Lionel, additional, Guieu, Cecile, additional, Hauss, Helena, additional, Hayashi, Kendra, additional, Huggett, Jenny A., additional, Jalabert, Laetitia, additional, Karp-Boss, Lee, additional, Kenitz, Kasia M., additional, Kudela, Raphael M., additional, Lescot, Magali, additional, Marec, Claudie, additional, McDonnell, Andrew, additional, Mériguet, Zoe, additional, Niehoff, Barbara, additional, Noyon, Margaux, additional, Panaïotis, Thelma, additional, Peacock, Emily, additional, Picheral, Marc, additional, Riquier, Emilie, additional, Roesler, Collin, additional, Romagnan, Jean-Baptiste, additional, Sosik, Heidi M., additional, Spencer, Gretchen, additional, Taucher, Jan, additional, Tilliette, Chloé, additional, and Vilain, Marion, additional

Published
2023
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24. Rethinking sinking: Imaging flow fields of natural marine aggregates to infer porosity-dependent changes in sinking velocity and carbon flux

Author

Flintrop, Clara M., primary, Ahmerkamp, Soeren, additional, Moradi, Nasrollah, additional, Klawonn, Isabell, additional, März, Jöran, additional, Hörstmann, Cora, additional, Kiko, Rainer, additional, Khalili, Arzhang, additional, Grossart, Hans-Peter, additional, Álvarez-Salgado, Xosé A., additional, Arístegui, Javier, additional, and Iversen, Morten H., additional

Published
2023
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25. Three major mesoplanktonic communities resolved by in situ imaging in the upper 500 m of the global ocean

Author

Panaïotis, Thelma, primary, Babin, Marcel, additional, Biard, Tristan, additional, Carlotti, François, additional, Coppola, Laurent, additional, Guidi, Lionel, additional, Hauss, Helena, additional, Karp‐Boss, Lee, additional, Kiko, Rainer, additional, Lombard, Fabien, additional, McDonnell, Andrew M. P., additional, Picheral, Marc, additional, Rogge, Andreas, additional, Waite, Anya M., additional, Stemmann, Lars, additional, and Irisson, Jean‐Olivier, additional

Published
2023
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26. Machine learning in marine ecology: an overview of techniques and applications

Author

Rubbens, Peter, primary, Brodie, Stephanie, additional, Cordier, Tristan, additional, Destro Barcellos, Diogo, additional, Devos, Paul, additional, Fernandes-Salvador, Jose A, additional, Fincham, Jennifer I, additional, Gomes, Alessandra, additional, Handegard, Nils Olav, additional, Howell, Kerry, additional, Jamet, Cédric, additional, Kartveit, Kyrre Heldal, additional, Moustahfid, Hassan, additional, Parcerisas, Clea, additional, Politikos, Dimitris, additional, Sauzède, Raphaëlle, additional, Sokolova, Maria, additional, Uusitalo, Laura, additional, Van den Bulcke, Laure, additional, van Helmond, Aloysius T M, additional, Watson, Jordan T, additional, Welch, Heather, additional, Beltran-Perez, Oscar, additional, Chaffron, Samuel, additional, Greenberg, David S, additional, Kühn, Bernhard, additional, Kiko, Rainer, additional, Lo, Madiop, additional, Lopes, Rubens M, additional, Möller, Klas Ove, additional, Michaels, William, additional, Pala, Ahmet, additional, Romagnan, Jean-Baptiste, additional, Schuchert, Pia, additional, Seydi, Vahid, additional, Villasante, Sebastian, additional, Malde, Ketil, additional, and Irisson, Jean-Olivier, additional

Published
2023
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27. Complete zooplankton size spectra re-constructed from « in situ » imaging and Multinet data in the global ocean

Author

Soviadan, Yawouvi Dodji, primary, Dugenne, Mathilde, additional, Drago, Laetitia, additional, Biard, Tristan, additional, Trudnowska, Emilia, additional, Lombard, Fabien, additional, Romagnan, Jean-Baptiste, additional, Jamet, Jean-Louis, additional, Kiko, Rainer, additional, Gorsky, Gabriel, additional, and Stemmann, Lars, additional

Published
2023
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29. Three major mesoplanktonic communities resolved by in situ imaging in the upper 500 m of the global ocean

Author

Panaïotis, Thelma, Babin, Marcel, Biard, Tristan, Carlotti, François, Coppola, Laurent, Guidi, Lionel, Hauss, Helena, Karp-Boss, Lee, Kiko, Rainer, Lombard, Fabien, Mcdonnell, Andrew, Picheral, Marc, Rogge, Andreas, Waite, Anya, Stemmann, Lars, Irisson, Jean-Olivier, Laboratoire d'océanographie de Villefranche (LOV), Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut de la Mer de Villefranche (IMEV), Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Takuvik International Research Laboratory, Université Laval [Québec] (ULaval)-Centre National de la Recherche Scientifique (CNRS), Laboratoire d’Océanologie et de Géosciences (LOG) - UMR 8187 (LOG), Institut national des sciences de l'Univers (INSU - CNRS)-Université du Littoral Côte d'Opale (ULCO)-Université de Lille-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Nord]), Institut méditerranéen d'océanologie (MIO), Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Toulon (UTLN)-Centre National de la Recherche Scientifique (CNRS), Helmholtz Centre for Ocean Research [Kiel] (GEOMAR), School of Marine Sciences, University of Maine, Orono, ME, Oceanography Department, University of Alaska Fairbanks, Fairbanks, AK, Alfred Wegener Institute Helmholtz Center for Polar and Marine Re- search, D-27570 Bremerhaven (AWI), and Ocean Frontier Institute and Department of Oceanography, Dalhousie University, Halifax

Subjects
global ocean, Copepoda, Trichodesmium, Rhizaria, spatial distribution, plankton communities, [SDE]Environmental Sciences, in situ imagery, biogeography
Abstract

Aim The distribution of mesoplankton communities have been poorly studied at global scale, especially from in situ instruments. This study aims to (1) describe the global distribution of mesoplankton communities in relation with their environment and (2) assess the ability of various environmental-based ocean regionalisations to explain the distribution of these communities. Location Global ocean, 0-500 m depth.Time period 2008 - 2019Major taxa studied 28 groups of large mesoplanktonic and macroplanktonic organ- isms, covering Metazoa, Rhizaria and Cyanobacteria.Methods From a global data set of 2500 vertical profiles making use of the Underwater Vision Profiler 5 (UVP5), an in situ imaging instrument, we studied the global distribu- tion of large (> 600 μm) mesoplanktonic organisms. Among the 6.8 million imaged ob- jects, 330,000 were large zooplanktonic organisms and phytoplankton colonies, the rest consisting of marine snow particles. Multivariate ordination (PCA) and clustering were used to describe patterns in community composition, while comparison with existing regionalisations was performed with regression methods (RDA).Results Within the observed size range, epipelagic plankton communities were Trichodesmium-enriched in the intertropical Atlantic, Copepoda-enriched at high latitudes and in upwelling areas, and Rhizaria-enriched in oligotrophic areas. In the mesopelagic layer, Copepoda-enriched communities were also found at high latitudes and in the At- lantic Ocean, while Rhizaria-enriched communities prevailed in the Peruvian upwelling system and a few mixed communities were found elsewhere. The comparison between the distribution of these communities and a set of existing regionalisations of the ocean suggested that the structure of plankton communities described above is mostly driven by basin-level environmental conditions.Main conclusions n both layers, three types of plankton communities emerged and seemed to be mostly driven by regional environmental conditions. This work sheds light on the role not only of metazoans, but also of unexpected large protists and cyanobacteria in structuring large mesoplankton communities.

Published
2023

30. Towards a distributed and operational pelagic imaging network

Author

Kiko, Rainer, Lopes, Rubens M., Soviadan, Y. Dodji, Stemmann, Lars, Kiko, Rainer, Lopes, Rubens M., Soviadan, Y. Dodji, and Stemmann, Lars

Abstract

Dimensions of particulate matter found in the water column of marine and freshwater environments (the pelagic realm) range from nanometers to tens of meters. Included in this enormous size range are miniature bacteria, phytoplankton (photosynthetic microalgae), mixoplankton (mixotrophic microorganisms), micro- to meter sized drifting animals (zooplankton), plastic particles, detrital aggregates and fecal pellets, fish, whales and many others. These particles and organisms are involved in many different processes and perform a multitude of services, such as in oceanic biogeochemistry (carbon fixation, oxygen production, carbon export and others) or human nourishment (fisheries). Digital optical tools used in pelagic imaging approaches now allow to bridge this enormous size span and to image micro- to meter-sized objects in situ or on discrete samples. Monitoring plankton, nekton, and particle dynamics at spatial and temporal scales that enable effective management of marine and freshwater environments poses a collective challenge for society. We here argue that a global, distributed and operational network for pelagic imaging is needed and within reach, and we provide recommendations how it can be attained via the voluntary activities of the pelagic imaging community and strategic support from funding agencies and other stakeholders.

Published
2023
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31. Zooplankton community succession and trophic links during a mesocosm experiment in the coastal upwelling off Callao Bay (Peru)

Author

Ayon Dejo, Patricia, Pinedo Arteaga, Elda L., Schukat, Anna, Taucher, Jan, Kiko, Rainer, Hauss, Helena, Dorschner, Sabrina, Hagen, Wilhelm, Segura-Noguera, Mariona, Lischka, Silke, Ayon Dejo, Patricia, Pinedo Arteaga, Elda L., Schukat, Anna, Taucher, Jan, Kiko, Rainer, Hauss, Helena, Dorschner, Sabrina, Hagen, Wilhelm, Segura-Noguera, Mariona, and Lischka, Silke

Published
2023
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32. Biological responses to change in Antarctic sea ice habitats

Author

Swadling, Kerrie M., Constable, Andrew J., Fraser, Alexander D., Massom, Robert A., Borup, Melanie D., Ghiglioitti, Laura, Granata, Antonia, Guglielmo, Letterio, Kawaguchi, So, Kennedy, Fraser, Kiko, Rainer, Koubbi, Philippe, Makabe, Ryosuke, Martin, Andrew, Mcminn, Andrew, Moteki, Masato, Pakhomov, Evgeny A., Peeken, Ilka, Reimer, Jody R., Reid, Phillip, Ryan, Ken G., Vacchi, Marino, Virtue, Patti, Weldrick, Christine K., Wongpan, Pat, Wotherspoon, Simon, Swadling, Kerrie M., Constable, Andrew J., Fraser, Alexander D., Massom, Robert A., Borup, Melanie D., Ghiglioitti, Laura, Granata, Antonia, Guglielmo, Letterio, Kawaguchi, So, Kennedy, Fraser, Kiko, Rainer, Koubbi, Philippe, Makabe, Ryosuke, Martin, Andrew, Mcminn, Andrew, Moteki, Masato, Pakhomov, Evgeny A., Peeken, Ilka, Reimer, Jody R., Reid, Phillip, Ryan, Ken G., Vacchi, Marino, Virtue, Patti, Weldrick, Christine K., Wongpan, Pat, and Wotherspoon, Simon

Published
2023
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33. Machine learning in marine ecology: an overview of techniques and applications

Author

Rubbens, Peter, Brodie, Stephanie, Cordier, Tristan, Destro Barcellos, Diogo, Devos, Paul, Fernandes-Salvador, Jose A, Fincham, Jennifer I, Gomes, Alessandra, Handegard, Nils Olav, Howell, Kerry, Jamet, Cédric, Kartveit, Kyrre Heldal, Moustahfid, Hassan, Parcerisas, Clea, Politikos, Dimitris, Sauzède, Raphaëlle, Sokolova, Maria, Uusitalo, Laura, Van den Bulcke, Laure, van Helmond, Aloysius T M, Watson, Jordan T, Welch, Heather, Beltran-Perez, Oscar, Chaffron, Samuel, Greenberg, David S, Kühn, Bernhard, Kiko, Rainer, Lo, Madiop, Lopes, Rubens M, Möller, Klas Ove, Michaels, William, Pala, Ahmet, Romagnan, Jean-Baptiste, Schuchert, Pia, Seydi, Vahid, Villasante, Sebastian, Malde, Ketil, Irisson, Jean-Olivier, Whidden, Christopher, Rubbens, Peter, Brodie, Stephanie, Cordier, Tristan, Destro Barcellos, Diogo, Devos, Paul, Fernandes-Salvador, Jose A, Fincham, Jennifer I, Gomes, Alessandra, Handegard, Nils Olav, Howell, Kerry, Jamet, Cédric, Kartveit, Kyrre Heldal, Moustahfid, Hassan, Parcerisas, Clea, Politikos, Dimitris, Sauzède, Raphaëlle, Sokolova, Maria, Uusitalo, Laura, Van den Bulcke, Laure, van Helmond, Aloysius T M, Watson, Jordan T, Welch, Heather, Beltran-Perez, Oscar, Chaffron, Samuel, Greenberg, David S, Kühn, Bernhard, Kiko, Rainer, Lo, Madiop, Lopes, Rubens M, Möller, Klas Ove, Michaels, William, Pala, Ahmet, Romagnan, Jean-Baptiste, Schuchert, Pia, Seydi, Vahid, Villasante, Sebastian, Malde, Ketil, Irisson, Jean-Olivier, and Whidden, Christopher

Abstract

Machine learning covers a large set of algorithms that can be trained to identify patterns in data. Thanks to the increase in the amount of data and computing power available, it has become pervasive across scientific disciplines. We first highlight why machine learning is needed in marine ecology. Then we provide a quick primer on machine learning techniques and vocabulary. We built a database of & SIM;1000 publications that implement such techniques to analyse marine ecology data. For various data types (images, optical spectra, acoustics, omics, geolocations, biogeochemical profiles, and satellite imagery), we present a historical perspective on applications that proved influential, can serve as templates for new work, or represent the diversity of approaches. Then, we illustrate how machine learning can be used to better understand ecological systems, by combining various sources of marine data. Through this coverage of the literature, we demonstrate an increase in the proportion of marine ecology studies that use machine learning, the pervasiveness of images as a data source, the dominance of machine learning for classification-type problems, and a shift towards deep learning for all data types. This overview is meant to guide researchers who wish to apply machine learning methods to their marine datasets.

Published
2023
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34. Testing the reconstruction of modelled particulate organic carbon from surface ecosystem components using PlankTOM12 and machine learning

Author

Denvil-Sommer, Anna, Buitenhuis, Erik T., Kiko, Rainer, Lombard, Fabien, Guidi, Lionel, Le Quéré, Corinne, Denvil-Sommer, Anna, Buitenhuis, Erik T., Kiko, Rainer, Lombard, Fabien, Guidi, Lionel, and Le Quéré, Corinne

Abstract

Understanding the relationship between surface marine ecosystems and the export of carbon to depth by sinking organic particles is key to representing the effect of ecosystem dynamics and diversity, and their evolution under multiple stressors, on the carbon cycle and climate in models. Recent observational technologies have greatly increased the amount of data available, both for the abundance of diverse plankton groups and for the concentration and properties of particulate organic carbon in the ocean interior. Here we use synthetic model data to test the potential of using machine learning (ML) to reproduce concentrations of particulate organic carbon within the ocean interior based on surface ecosystem and environmental data. We test two machine learning methods that differ in their approaches to data-fitting, the random forest and XGBoost methods. The synthetic data are sampled from the PlankTOM12 global biogeochemical model using the time and coordinates of existing observations. We test 27 different combinations of possible drivers to reconstruct small (POCS) and large (POCL) particulate organic carbon concentrations. We show that ML can successfully be used to reproduce modelled particulate organic carbon over most of the ocean based on ecosystem and modelled environmental drivers. XGBoost showed better results compared to random forest thanks to its gradient boosting trees' architecture. The inclusion of plankton functional types (PFTs) in driver sets improved the accuracy of the model reconstruction by 58 % on average for POCS and by 22 % for POCL. Results were less robust over the equatorial Pacific and some parts of the high latitudes. For POCS reconstruction, the most important drivers were the depth level, temperature, microzooplankton and PO4, while for POCL it was the depth level, temperature, mixed-layer depth, microzooplankton, phaeocystis, PO4 and chlorophyll a averaged over the mixed-layer depth. These results suggest that it will be possible to

Published
2023
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35. Low-Density Plastic Debris Dispersion beneath the Mediterranean Sea Surface

Author

Baudena, Alberto, Kiko, Rainer, Jalón-Rojas, Isabel, Pedrotti, Maria Luiza, Baudena, Alberto, Kiko, Rainer, Jalón-Rojas, Isabel, and Pedrotti, Maria Luiza

Abstract

Plastic is a widespread marine pollutant, with most studies focusing on the distribution of floating plastic debris at the sea surface. Recent evidence, however, indicates a significant presence of such low density plastic in the water column and at the seafloor, but information on its origin and dispersion is lacking. Here, we studied the pathways and fate of sinking plastic debris in the Mediterranean Sea, one of the most polluted world seas. We used a recent Lagrangian plastic-tracking model, forced with realistic parameters, including a maximum estimated sinking speed of 7.8 m/d. Our simulations showed that the locations where particles left the surface differed significantly from those where they reached the seafloor, with lateral transport distances between 119 and 282 km. Furthermore, 60% of particles deposited on the bottom coastal strip (20 km wide) were released from vessels, 20% from the facing country, and 20% from other countries. Theoretical considerations furthermore suggested that biological activities potentially responsible for the sinking of low density plastic occur throughout the water column. Our findings indicate that the responsibility for seafloor plastic pollution is shared among Mediterranean countries, with potential impact on pelagic and benthic biota.

Published
2023
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36. Total Mass Flux in the Northern Humboldt Current System: Rates and Contribution Sources from Central Peru (12° S)

Author

Leigh, Bobby, Aramayo, Víctor, Mendoza, Ursula, Velazco, Federico, Kiko, Rainer, Ayón, Patricia, Fernández, Ernesto, Graco, Michelle, Leigh, Bobby, Aramayo, Víctor, Mendoza, Ursula, Velazco, Federico, Kiko, Rainer, Ayón, Patricia, Fernández, Ernesto, and Graco, Michelle

Abstract

The total mass flux (TMF) of particulate organic matter (POM) is key for understanding the energetic transfer within the “biological pump” (i.e., involving the carbon cycle), reflecting a critical connection between the surface and the bottom. A fixed multi-sediment trap was installed at 30 m depth in Callao Bay, central Peru from March to December 2020. After recovery, samples were dried and weighed to calculate the TMF and pellet flux. The average TMF was 601.9 mg·m−2·day−1, with 70.2 and 860 mg·m−2·day−1 as the lowest and highest values during “normal conditions”. Zooplankton fecal pellets (ZFP) were found in ovoid (e.g., larvae) and cylindrical (e.g., adult copepods) shapes and their flux contribution to TMF was low, ranging from 0.17 to 85.59 mg·m−2·day−1. In contrast with ZFP, fish fecal pellets (FFP) were found in fragments with a cylindrical shape, and their contribution to the TMF was higher than ZFP, ranging from 1 to 92.56 mg·m−2·day−1. Mean sinking velocities were 4.63 ± 3.47 m·day−1 (ZFP) and 432.27 ± 294.26 m·day−1 (FFP). There is a considerable difference between the ZFP and FFP contributions to TMFs. We discuss the implications of these results regarding a still poorly understood process controlling the POM flux off the Peruvian coast.

Published
2023
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37. Editorial: Zooplankton and nekton: gatekeepers of the biological pump, volume II

Author

Kiko, Rainer, Bianchi, Daniele, Hauss, Helena, Iversen, Morten H., Maas, Amy, Kiko, Rainer, Bianchi, Daniele, Hauss, Helena, Iversen, Morten H., and Maas, Amy

Abstract

Zooplankton and nekton organisms play multifaceted roles in marine ecosystems and are integral components of the ocean’s food web. By consuming a wide range of planktonic organisms and detrital matter, they directly impact the size-distribution of particles in the ocean by breaking large aggregates down to smaller fragments and by repackaging single phytoplankton cells into dense fecal pellets. Many zooplankton and nekton organisms also conduct diel vertical migrations (DVM). They ascend to the surface layer of the ocean at dusk to feed during the dark hours and return to midwater depths at dawn to hide from visual predation. As they metabolize and excrete organic material in deeper waters, they contribute to an “active flux” of carbon and nutrients. This active flux can have a substantial impact on the functioning of the biological pump — the process responsible for the downward export of carbon and nutrients into the ocean’s interior. In essence, zooplankton and nekton are gatekeepers of the biological pump via their diverse roles in particle dynamics, from consumption and fragmentation to the active transport of organic matter. Understanding these roles is critical for unraveling the complex mechanisms that govern the health and functioning of marine ecosystems, as well as for improving our models of global biogeochemical processes in the world’s oceans.

Published
2023
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38. First release of the Pelagic Size Structure database: Global datasets of marine size spectra obtained from plankton imaging devices.

Author

Dugenne, Mathilde, Corrales-Ugalde, Marco, Luo, Jessica Y., Kiko, Rainer, O’Brien, Todd D., Irisson, Jean-Olivier, Lombard, Fabien, Stemmann, Lars, Stock, Charles, Anderson, Clarissa R., Babin, Marcel, Bhairy, Nagib, Bonnet, Sophie, Carlotti, Francois, Cornils, Astrid, Crockford, E. Taylor, Daniel, Patrick, Desnos, Corinne, Drago, Laetitia, and Elineau, Amanda

Subjects
CARBON cycle, DATABASES, PARTICLE size distribution, IMAGE sensors, CARBON sequestration
Abstract

In marine ecosystems, most physiological, ecological, or physical processes are size-dependent. These include metabolic rates, uptake of carbon and other nutrients, swimming and sinking velocities, and trophic interactions, which eventually determine the stocks of commercial species, as well as biogeochemical cycles and carbon sequestration. As such, broad scale observations of plankton size distribution are important indicators of the general functioning and state of pelagic ecosystems under anthropogenic pressures. Here, we present the first global datasets of the Pelagic Size Structure database (PSSdb), generated from plankton imaging devices. This release includes the bulk particle Normalized Biovolume Size Spectrum (NBSS) and bulk Particle Size Distribution (PSD), along with their related parameters (slope, intercept, and R2) measured within the epipelagic layer (0-200 m) by three imaging sensors: the Imaging FlowCytobot (IFCB), the Underwater Vision Profiler (UVP) and benchtop scanners. Collectively, these instruments effectively image organisms and detrital material in the 7-10,000 µm size range. A total of 92,472 IFCB samples, 3,068 UVP profiles, and 2,411 scans passed our quality control and were standardized to produce consistent instrument-specific size spectra averaged in 1x1° latitude/longitude, and by year and month. Our instrument-specific datasets span all major ocean basins, except for the IFCB which was exclusively deployed in northern latitudes, and cover decadal time periods (2013-2022 for IFCB, 2008-2021 for UVP, and 1996-2022 for scanners), allowing for a further assessment of the pelagic size spectrum in space and time. [ABSTRACT FROM AUTHOR]

Published
2023
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40. Seasonal cycle of mixing and upward nutrient supply in the equatorial Atlantic cold tongue

Author

Brandt, Peter, Körner, Mareike, Moum, James N., Subramaniam, Ajit, Czeschel, Rena, Krahmann, Gerd, Dengler, Marcus, Roch, Marisa, and Kiko, Rainer

Abstract

The eastern equatorial Atlantic hosts a productive marine ecosystem that depends on the upward supply of nutrients. The main process that transports nutrients into the surface mixed layer is turbulent mixing induced in the shear zone between the surface mixed layer and the core of the Equatorial Undercurrent (EUC). Here we present experimental data from two trans-Atlantic cruises along the equator as well as moored observations allowing to characterize the seasonal cycle of velocity shear and turbulence. These data in combination with hydrographic data allow the analysis of the seasonal cycle of equatorial mixing and upward nitrate flux. The core of the EUC migrates vertically following an annual cycle. It reaches its shallowest position in boreal spring and its deepest position in boreal fall. The seasonal cycle of the maximum nitrate gradient instead shows a primary upward movement during boreal summer and a secondary upward movement in boreal winter bringing the nitrate gradient into the region of enhanced shear and turbulent mixing. During boreal spring, the nitrate gradient is located below the EUC core that is characterized by a minimum of turbulence. It prevents an upward supply of nitrate into the surface mixed layer and results in low productivity. The dynamic behavior of the shear zone is driven by a resonant equatorial basin mode associated with the east- and westward propagation of equatorial Kelvin and Rossby waves making the seasonal cycle of upward nutrient supply and productivity in the equatorial Atlantic distinct from that in the Pacific Ocean., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published
2023

41. Biological responses to change in Antarctic sea ice habitats

Author

Swadling, Kerrie M., primary, Constable, Andrew J., additional, Fraser, Alexander D., additional, Massom, Robert A., additional, Borup, Melanie D., additional, Ghigliotti, Laura, additional, Granata, Antonia, additional, Guglielmo, Letterio, additional, Johnston, Nadine M., additional, Kawaguchi, So, additional, Kennedy, Fraser, additional, Kiko, Rainer, additional, Koubbi, Philippe, additional, Makabe, Ryosuke, additional, Martin, Andrew, additional, McMinn, Andrew, additional, Moteki, Masato, additional, Pakhomov, Evgeny A., additional, Peeken, Ilka, additional, Reimer, Jody, additional, Reid, Phillip, additional, Ryan, Ken G., additional, Vacchi, Marino, additional, Virtue, Patti, additional, Weldrick, Christine K., additional, Wongpan, Pat, additional, and Wotherspoon, Simon J., additional

Published
2023
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43. Cold‐water coral ecosystems under future ocean change: Live coral performance vs. framework dissolution and bioerosion

Author

Büscher, Janina Vanessa, Form, Armin Uwe, Wisshak, Max, Kiko, Rainer, Riebesell, Ulf, 1 GEOMAR Helmholtz Centre for Ocean Research Kiel Research Division 2: Marine Biogeochemistry—Biological Oceanography Kiel Germany, 2 SENCKENBERG am Meer Marine Research Department Wilhelmshaven Germany, and 3 GEOMAR Helmholtz Centre for Ocean Research Kiel Research Division 3: Marine Ecology Kiel Germany

Subjects
laboratory experiments, bioerosion, ddc:577.7, cold-water corals, framwork dissolution, ocean change, Aquatic Science, Oceanography
Abstract

Physiological sensitivity of cold‐water corals to ocean change is far less understood than of tropical corals and very little is known about the impacts of ocean acidification and warming on degradative processes of dead coral framework. In a 13‐month laboratory experiment, we examined the interactive effects of gradually increasing temperature and pCO2 levels on survival, growth, and respiration of two prominent color morphotypes (colormorphs) of the framework‐forming cold‐water coral Lophelia pertusa, as well as bioerosion and dissolution of dead framework. Calcification rates tended to increase with warming, showing temperature optima at ~ 14°C (white colormorph) and 10–12°C (orange colormorph) and decreased with increasing pCO2. Net dissolution occurred at aragonite undersaturation (ΩAr, Bundesministerium für Bildung und Forschung http://dx.doi.org/10.13039/501100002347, Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659, Marine Research in Ireland, French National Research Agency http://dx.doi.org/10.13039/501100001665

Published
2022
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48. A global marine particle size distribution dataset obtained with the Underwater Vision Profiler 5

Author

Kiko, Rainer, primary, Picheral, Marc, additional, Antoine, David, additional, Babin, Marcel, additional, Berline, Léo, additional, Biard, Tristan, additional, Boss, Emmanuel, additional, Brandt, Peter, additional, Carlotti, Francois, additional, Christiansen, Svenja, additional, Coppola, Laurent, additional, de la Cruz, Leandro, additional, Diamond-Riquier, Emilie, additional, Durrieu de Madron, Xavier, additional, Elineau, Amanda, additional, Gorsky, Gabriel, additional, Guidi, Lionel, additional, Hauss, Helena, additional, Irisson, Jean-Olivier, additional, Karp-Boss, Lee, additional, Karstensen, Johannes, additional, Kim, Dong-gyun, additional, Lekanoff, Rachel M., additional, Lombard, Fabien, additional, Lopes, Rubens M., additional, Marec, Claudie, additional, McDonnell, Andrew M. P., additional, Niemeyer, Daniela, additional, Noyon, Margaux, additional, O'Daly, Stephanie H., additional, Ohman, Mark D., additional, Pretty, Jessica L., additional, Rogge, Andreas, additional, Searson, Sarah, additional, Shibata, Masashi, additional, Tanaka, Yuji, additional, Tanhua, Toste, additional, Taucher, Jan, additional, Trudnowska, Emilia, additional, Turner, Jessica S., additional, Waite, Anya, additional, and Stemmann, Lars, additional

Published
2022
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50. Global Distribution of Zooplankton Biomass Estimated by In Situ Imaging and Machine Learning

Author

Drago, Laetitia, primary, Panaïotis, Thelma, additional, Irisson, Jean-Olivier, additional, Babin, Marcel, additional, Biard, Tristan, additional, Carlotti, François, additional, Coppola, Laurent, additional, Guidi, Lionel, additional, Hauss, Helena, additional, Karp-Boss, Lee, additional, Lombard, Fabien, additional, McDonnell, Andrew M. P., additional, Picheral, Marc, additional, Rogge, Andreas, additional, Waite, Anya M., additional, Stemmann, Lars, additional, and Kiko, Rainer, additional

Published
2022
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