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2. Dataset of 143 metagenome-assembled genomes from the Arctic and Atlantic Oceans, including 21 for eukaryotic organisms

Author

Duncan, Anthony, Barry, Kerrie, Daum, Chris, Eloe-Fadrosh, Emiley, Roux, Simon, Schmidt, Katrin, Tringe, Susannah G, Valentin, Klaus U, Varghese, Neha, Salamov, Asaf, Grigoriev, Igor V, Leggett, Richard M, Moulton, Vincent, and Mock, Thomas

Subjects
Genetics, Biotechnology, Generic health relevance, Life Below Water, Genome resolved metagenomics, Phycology, Marine algae, MAGs, Phytoplankton, Polar microbiomes
Abstract

This article presents metagenome-assembled genomes (MAGs) for both eukaryotic and prokaryotic organisms originating from the Arctic and Atlantic oceans, along with gene prediction and functional annotation for MAGs from both domains. Eleven samples from the chlorophyll-a maximum layer of the surface ocean were collected during two cruises in 2012; six from the Arctic in June-July on ARK-XXVII/1 (PS80), and five from the Atlantic in November on ANT-XXIX/1 (PS81). Sequencing and assembly was carried out by the Joint Genome Institute (JGI), who provide annotation of the assembled sequences, and 122 MAGs for prokaryotic organisms. A subsequent binning process identified 21 MAGs for eukaryotic organisms, mostly identified as Mamiellophyceae or Bacillariophyceae. The data for each MAG includes sequences in FASTA format, and tables of functional annotation of genes. For eukaryotic MAGs, transcript and protein sequences for predicted genes are available. A spreadsheet is provided summarising quality measures and taxonomic classifications for each MAG. These data provide draft genomes for uncultured marine microbes, including some of the first MAGs for polar eukaryotes, and can provide reference genetic data for these environments, or used in genomics-based comparison between environments.

Published
2023

6. Monitoring and modelling marine zooplankton in a changing climate

Author

Ratnarajah, Lavenia, Abu-Alhaija, Rana, Atkinson, Angus, Batten, Sonia, Bax, Nicholas J., Bernard, Kim S., Canonico, Gabrielle, Cornils, Astrid, Everett, Jason D., Grigoratou, Maria, Ishak, Nurul Huda Ahmad, Johns, David, Lombard, Fabien, Muxagata, Erik, Ostle, Clare, Pitois, Sophie, Richardson, Anthony J., Schmidt, Katrin, Stemmann, Lars, Swadling, Kerrie M., Yang, Guang, and Yebra, Lidia

Published
2023
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8. Metagenome-assembled genomes of phytoplankton microbiomes from the Arctic and Atlantic Oceans

Author

Duncan, Anthony, Barry, Kerrie, Daum, Chris, Eloe-Fadrosh, Emiley, Roux, Simon, Schmidt, Katrin, Tringe, Susannah G, Valentin, Klaus U, Varghese, Neha, Salamov, Asaf, Grigoriev, Igor V, Leggett, Richard M, Moulton, Vincent, and Mock, Thomas

Subjects
Genetics, Human Genome, Life Below Water, Atlantic Ocean, Chlorophyll A, Eukaryota, Metagenome, Microbiota, Phylogeny, Phytoplankton, Ecology, Microbiology, Medical Microbiology
Abstract

BackgroundPhytoplankton communities significantly contribute to global biogeochemical cycles of elements and underpin marine food webs. Although their uncultured genomic diversity has been estimated by planetary-scale metagenome sequencing and subsequent reconstruction of metagenome-assembled genomes (MAGs), this approach has yet to be applied for complex phytoplankton microbiomes from polar and non-polar oceans consisting of microbial eukaryotes and their associated prokaryotes.ResultsHere, we have assembled MAGs from chlorophyll a maximum layers in the surface of the Arctic and Atlantic Oceans enriched for species associations (microbiomes) with a focus on pico- and nanophytoplankton and their associated heterotrophic prokaryotes. From 679 Gbp and estimated 50 million genes in total, we recovered 143 MAGs of medium to high quality. Although there was a strict demarcation between Arctic and Atlantic MAGs, adjacent sampling stations in each ocean had 51-88% MAGs in common with most species associations between Prasinophytes and Proteobacteria. Phylogenetic placement revealed eukaryotic MAGs to be more diverse in the Arctic whereas prokaryotic MAGs were more diverse in the Atlantic Ocean. Approximately 70% of protein families were shared between Arctic and Atlantic MAGs for both prokaryotes and eukaryotes. However, eukaryotic MAGs had more protein families unique to the Arctic whereas prokaryotic MAGs had more families unique to the Atlantic.ConclusionOur study provides a genomic context to complex phytoplankton microbiomes to reveal that their community structure was likely driven by significant differences in environmental conditions between the polar Arctic and warm surface waters of the tropical and subtropical Atlantic Ocean. Video Abstract.

Published
2022

9. The biogeographic differentiation of algal microbiomes in the upper ocean from pole to pole.

Author

Martin, Kara, Schmidt, Katrin, Toseland, Andrew, Boulton, Chris A, Barry, Kerrie, Beszteri, Bánk, Brussaard, Corina PD, Clum, Alicia, Daum, Chris G, Eloe-Fadrosh, Emiley, Fong, Allison, Foster, Brian, Foster, Bryce, Ginzburg, Michael, Huntemann, Marcel, Ivanova, Natalia N, Kyrpides, Nikos C, Lindquist, Erika, Mukherjee, Supratim, Palaniappan, Krishnaveni, Reddy, TBK, Rizkallah, Mariam R, Roux, Simon, Timmermans, Klaas, Tringe, Susannah G, van de Poll, Willem H, Varghese, Neha, Valentin, Klaus U, Lenton, Timothy M, Grigoriev, Igor V, Leggett, Richard M, Moulton, Vincent, and Mock, Thomas

Subjects
Antarctic Regions, Arctic Regions, Biodiversity, Carbon Cycle, Climate Change, Gene Ontology, Genetic Variation, Geography, Global Warming, Microalgae, Microbiota, Oceans and Seas, Phytoplankton, RNA, Ribosomal, 16S, RNA, Ribosomal, 18S, Sequence Analysis, DNA, Species Specificity, Temperature, Transcriptome
Abstract

Eukaryotic phytoplankton are responsible for at least 20% of annual global carbon fixation. Their diversity and activity are shaped by interactions with prokaryotes as part of complex microbiomes. Although differences in their local species diversity have been estimated, we still have a limited understanding of environmental conditions responsible for compositional differences between local species communities on a large scale from pole to pole. Here, we show, based on pole-to-pole phytoplankton metatranscriptomes and microbial rDNA sequencing, that environmental differences between polar and non-polar upper oceans most strongly impact the large-scale spatial pattern of biodiversity and gene activity in algal microbiomes. The geographic differentiation of co-occurring microbes in algal microbiomes can be well explained by the latitudinal temperature gradient and associated break points in their beta diversity, with an average breakpoint at 14 °C ± 4.3, separating cold and warm upper oceans. As global warming impacts upper ocean temperatures, we project that break points of beta diversity move markedly pole-wards. Hence, abrupt regime shifts in algal microbiomes could be caused by anthropogenic climate change.

Published
2021

13. Insights into the diet and feeding behavior of immature polar cod (Boreogadus saida) from the under‐ice habitat of the central Arctic Ocean.

Author

Schaafsma, Fokje L., Flores, Hauke, David, Carmen L., Castellani, Giulia, Sakinan, Serdar, Meijboom, André, Niehoff, Barbara, Cornils, Astrid, Hildebrandt, Nicole, Schmidt, Katrin, Snoeijs‐Leijonmalm, Pauline, Ehrlich, Julia, and Ashjian, Carin J.

Subjects
DIETARY patterns, GASTROINTESTINAL contents, FORAGE fishes, ARCTIC climate, SPECIFIC gravity
Abstract

Polar cod (Boreogadus saida) is an endemic key species of the Arctic Ocean ecosystem. The ecology of this forage fish is well studied in Arctic shelf habitats where a large part of its population lives. However, knowledge about its ecology in the central Arctic Ocean (CAO), including its use of the sea‐ice habitat, is hitherto very limited. To increase this knowledge, samples were collected at the under‐ice surface during several expeditions to the CAO between 2012 and 2020, including the Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC) expedition. The diet of immature B. saida and the taxonomic composition of their potential prey were analysed, showing that both sympagic and pelagic species were important prey items. Stomach contents included expected prey such as copepods and amphipods. Surprisingly, more rarely observed prey such as appendicularians, chaetognaths, and euphausiids were also found to be important. Comparisons of the fish stomach contents with prey distribution data suggests opportunistic feeding. However, relative prey density and catchability are important factors that determine which type of prey is ingested. Prey that ensures limited energy expenditure on hunting and feeding is often found in the stomach contents even though it is not the dominant species present in the environment. To investigate the importance of prey quality and quantity for the growth of B. saida in this area, we measured energy content of dominant prey species and used a bioenergetic model to quantify the effect of variations in diet on growth rate potential. The modeling results suggest that diet variability was largely explained by stomach fullness and, to a lesser degree, the energetic content of the prey. Our results suggest that under climate change, immature B. saida may be at least equally sensitive to a loss in the number of efficiently hunted prey than to a reduction in the prey's energy content. Consequences for the growth and survival of B. saida will not depend on prey presence alone, but also on prey catchability, digestibility, and energy content. [ABSTRACT FROM AUTHOR]

Published
2024
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16. Efficacy and safety of suvratoxumab for prevention of Staphylococcus aureus ventilator-associated pneumonia (SAATELLITE): a multicentre, randomised, double-blind, placebo-controlled, parallel-group, phase 2 pilot trial

Author

Chochrad, Didier, Dive, Alain, Foret, Frédéric, Simon, Marc, Spapen, Herbert, Creteur, Jacques, Bouckaert, Yves, Biston, Patrick, Bourgeois, Marc, Novacek, Martin, Vymazal, Tomas, Svoboda, Petr, Pachl, Jan, Sramek, Vladimir, Hanauer, Michal, Hruby, Tomas, Balik, Martin, Suchy, Tomas, Lepape, Alain, Argaud, Laurent, Dailler, Frédéric, Desachy, Arnaud, Guitton, Christophe, Mercat, Alain, Meziani, Ferhat, Navellou, Jean-Christophe, Robert, Rene, Souweine, Bertrand, Tadie, Jean-Marc, Maamar, Adel, Annane, Djillali, Tamion, Fabienne, Gros, Antoine, Nseir, Saad, Schwebel, Carole, Francony, Gilles, Lefrant, Jean-Yves, Schneider, Francis, Gründling, Matthias, Motsch, Johann, Reill, Lorenz, Rolfes, Caroline, Welte, Tobias, Cornely, Oliver, Bloos, Frank, Deja, Maria, Schmidt, Katrin, Wappler, Frank, Meier-Hellmann, Andreas, Komnos, Apostolos, Bekos, Vasileios, Koulouras, Vasilios, Soultati, Ioanna, Baltopoulos, Georgios, Filntisis, Georgios, Zakynthinos, Epaminondas, Zakynthinos, Spyros, Pnevmatikos, Ioannis, Krémer, Ildikó, Szentkereszty, Zoltán, Sarkany, Agnes, Marjanek, Zsuzsa, Moura, Pedro, Pintado Delgado, Maria Consuelo, Montejo González, Juan Carlos, Ramirez, Paula, Torres Marti, Antonio, Valia, Juan Carlos, Lorente, Jose, Loza Vazquez, Ana, De Pablo Sanchez, Raúl, Escudero, Dolores, Ferrer Roca, Ricard, Pagani, Jean-Luc, Maggiorini, Marco, François, Bruno, Jafri, Hasan S, Chastre, Jean, Sánchez-García, Miguel, Eggimann, Philippe, Dequin, Pierre-François, Huberlant, Vincent, Viña Soria, Lucia, Boulain, Thierry, Bretonnière, Cédric, Pugin, Jérôme, Trenado, Josep, Hernandez Padilla, Ana Catalina, Ali, Omar, Shoemaker, Kathryn, Ren, Pin, Coenjaerts, Frank E, Ruzin, Alexey, Barraud, Olivier, Timbermont, Leen, Lammens, Christine, Pierre, Vadryn, Wu, Yuling, Vignaud, Julie, Colbert, Susan, Bellamy, Terramika, Esser, Mark T, Dubovsky, Filip, Bonten, Marc J, Goossens, Herman, and Laterre, Pierre-François

Published
2021
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17. Thermal adaptation of Thalassiosira pseudonana using experimental evolution approaches

Author

Schmidt, Katrin

Subjects
579.8
Abstract

Diatoms contribute about 50% of global primary production and are on of the most diverse phytoplankton groups. Additionally, they form the basis of most marine food webs and play an important role in elemental cycles such as carbon and silica. Global warming impacts the diversity and productivity of marine ecosystems as temperature is considered a strong selecting agent underpinning global diversity patterns of marine phytoplankton. In order to gain insights into diatom distribution and diversity in the Atlantic Ocean, we analysed 18S rDNA ribotypes over a broad spatial scale from the Fram Strait to the South Atlantic. Diversity patterns were related to environmental metadata in order to identify main drivers. Our results indicate that salinity had a negative effect on diatom diversity in the Fram Strait transect with stations showing low diversity at high salinities. In contrast, diatom diversity in the Atlantic Ocean was negatively correlated to temperature with high temperature showing low diatom diversity. The order of Coscinodiscales showed a, formerly unknown, cosmopolitan distribution and was the overall most abundant species. With this study we provided an updated estimate of diatom distribution and diversity in the Atlantic Ocean. Phytoplankton physiology is highly temperature dependent and despite the importance of temperature as a major driver of marine phytoplankton evolution, the molecular mechanisms of adaptive evolution under temperature selection are largely unknown but instrumental for predicting how marine phytoplankton will respond to a changing ocean. Here we provide evidence, based on experimental evolution experiments with the marine model diatom Thalassisoria pseudonana that thermal tolerance can rapidly evolve within 300 generations. Our results indicate that upper and lower temperature limits were fixed, however temperature optima for growth shifted towards the selection temperature. Furthermore, temperature had a significant impact on average cell diameter, bSi content and cellular stoichiometry (C:N:P). Physiological adaptation to high temperature was underpinned by differential expression of genes related to protein metabolism (protein binding and folding), and down-regulation of mismatch repair mechanisms potentially causing a high number of SNPs in the genome. Furthermore, several transposable elements showed strong, temperature specific up-regulation suggesting epigenetic enabled genome plasticity. Our results highlight the relation of adaptive pheno- and genotypes driven by temperature selection. This knowledge is key to our understanding of how the environment shapes the evolution of microbes and the biogeochemical processes they drive.

Published
2017

18. Essential omega‐3 fatty acids are depleted in sea ice and pelagic algae of the Central Arctic Ocean

Author

Schmidt, Katrin, Graeve, Martin, Hoppe, Clara JM, Torres‐Valdes, Sinhué, Welteke, Nahid, Whitmore, Laura M, Anhaus, Philipp, Atkinson, Angus, Belt, Simon T, Brenneis, Tina, Campbell, Robert G, Castellani, Giulia, Copeman, Louise A, Flores, Hauke, Fong, Allison A, Hildebrandt, Nicole, Kohlbach, Doreen, Nielsen, Jens M, Parrish, Christopher C, Rad‐Menéndez, Cecilia, Rokitta, Sebastian D, Tippenhauer, Sandra, Zhuang, Yanpei, Schmidt, Katrin, Graeve, Martin, Hoppe, Clara JM, Torres‐Valdes, Sinhué, Welteke, Nahid, Whitmore, Laura M, Anhaus, Philipp, Atkinson, Angus, Belt, Simon T, Brenneis, Tina, Campbell, Robert G, Castellani, Giulia, Copeman, Louise A, Flores, Hauke, Fong, Allison A, Hildebrandt, Nicole, Kohlbach, Doreen, Nielsen, Jens M, Parrish, Christopher C, Rad‐Menéndez, Cecilia, Rokitta, Sebastian D, Tippenhauer, Sandra, and Zhuang, Yanpei

Abstract

Microalgae are the main source of the omega-3 fatty acids eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA), essential for the healthy development of most marine and terrestrial fauna including humans. Inverse correlations of algal EPA and DHA proportions (% of total fatty acids) with temperature have led to suggestions of a warming-induced decline in the global production of these biomolecules and an enhanced importance of high latitude organisms for their provision. The cold Arctic Ocean is a potential hotspot of EPA and DHA production, but consequences of global warming are unknown. Here, we combine a full-seasonal EPA and DHA dataset from the Central Arctic Ocean (CAO), with results from 13 previous field studies and 32 cultured algal strains to examine five potential climate change effects; ice algae loss, community shifts, increase in light, nutrients, and temperature. The algal EPA and DHA proportions were lower in the ice-covered CAO than in warmer peripheral shelf seas, which indicates that the paradigm of an inverse correlation of EPA and DHA proportions with temperature may not hold in the Arctic. We found no systematic differences in the summed EPA and DHA proportions of sea ice versus pelagic algae, and in diatoms versus non-diatoms. Overall, the algal EPA and DHA proportions varied up to four-fold seasonally and 10-fold regionally, pointing to strong light and nutrient limitations in the CAO. Where these limitations ease in a warming Arctic, EPA and DHA proportions are likely to increase alongside increasing primary production, with nutritional benefits for a non-ice-associated food web.

Published
2024

19. Overview of the MOSAiC expedition: Ecosystem

Author

Fong, Allison A., Hoppe, Clara J. M., Aberle, Nicole, Ashjian, Carin J., Assmy, Philipp, Bai, Youcheng, Bakker, Dorothee C. E., Balmonte, John P., Barry, Kevin R., Bertilsson, Stefan, Boulton, William, Bowman, Jeff, Bozzato, Deborah, Bratbak, Gunnar, Buck, Moritz, Campbell, Robert G., Castellani, Giulia, Chamberlain, Emelia J., Chen, Jianfang, Chierici, Melissa, Cornils, Astrid, Creamean, Jessie M., Damm, Ellen, Dethloff, Klaus, Droste, Elise S., Ebenhöh, Oliver, Eggers, Sarah L., Engel, Anja, Flores, Hauke, Fransson, Agneta, Frickenhaus, Stephan, Gardner, Jessie, Gelfman, Cecilia E., Granskog, Mats A., Graeve, Martin, Havermans, Charlotte, Heuzé, Céline, Hildebrandt, Nicole, Hill, Thomas C. J., Hoppema, Mario, Immerz, Antonia, Jin, Haiyan, Koch, Boris P., Kong, Xianyu, Kraberg, Alexandra, Lan, Musheng, Lange, Benjamin A., Larsen, Aud, Lebreton, Benoit, Leu, Eva, Loose, Brice, Maslowski, Wieslaw, Mavis, Camille, Metfies, Katja, Mock, Thomas, Müller, Oliver, Nicolaus, Marcel, Niehoff, Barbara, Nomura, Daiki, Nöthig, Eva-Maria, Oggier, Marc, Oldenburg, Ellen, Olsen, Lasse Mork, Peeken, Ilka, Perovich, Donald K., Popa, Ovidiu, Rabe, Benjamin, Ren, Jian, Rex, Markus, Rinke, Annette, Rokitta, Sebastian, Rost, Björn, Sakinan, Serdar, Salganik, Evgenii, Schaafsma, Fokje L., Schäfer, Hendrik, Schmidt, Katrin, Shoemaker, Katyanne M., Shupe, Matthew D., Snoeijs-Leijonmalm, Pauline, Stefels, Jacqueline, Svenson, Anders, Tao, Ran, Torres-Valdés, Sinhué, Torstensson, Anders, Toseland, Andrew, Ulfsbo, Adam, Van Leeuwe, Maria A., Vortkamp, Martina, Webb, Alison L., Zhuang, Yanpei, Gradinger, Rolf R., Fong, Allison A., Hoppe, Clara J. M., Aberle, Nicole, Ashjian, Carin J., Assmy, Philipp, Bai, Youcheng, Bakker, Dorothee C. E., Balmonte, John P., Barry, Kevin R., Bertilsson, Stefan, Boulton, William, Bowman, Jeff, Bozzato, Deborah, Bratbak, Gunnar, Buck, Moritz, Campbell, Robert G., Castellani, Giulia, Chamberlain, Emelia J., Chen, Jianfang, Chierici, Melissa, Cornils, Astrid, Creamean, Jessie M., Damm, Ellen, Dethloff, Klaus, Droste, Elise S., Ebenhöh, Oliver, Eggers, Sarah L., Engel, Anja, Flores, Hauke, Fransson, Agneta, Frickenhaus, Stephan, Gardner, Jessie, Gelfman, Cecilia E., Granskog, Mats A., Graeve, Martin, Havermans, Charlotte, Heuzé, Céline, Hildebrandt, Nicole, Hill, Thomas C. J., Hoppema, Mario, Immerz, Antonia, Jin, Haiyan, Koch, Boris P., Kong, Xianyu, Kraberg, Alexandra, Lan, Musheng, Lange, Benjamin A., Larsen, Aud, Lebreton, Benoit, Leu, Eva, Loose, Brice, Maslowski, Wieslaw, Mavis, Camille, Metfies, Katja, Mock, Thomas, Müller, Oliver, Nicolaus, Marcel, Niehoff, Barbara, Nomura, Daiki, Nöthig, Eva-Maria, Oggier, Marc, Oldenburg, Ellen, Olsen, Lasse Mork, Peeken, Ilka, Perovich, Donald K., Popa, Ovidiu, Rabe, Benjamin, Ren, Jian, Rex, Markus, Rinke, Annette, Rokitta, Sebastian, Rost, Björn, Sakinan, Serdar, Salganik, Evgenii, Schaafsma, Fokje L., Schäfer, Hendrik, Schmidt, Katrin, Shoemaker, Katyanne M., Shupe, Matthew D., Snoeijs-Leijonmalm, Pauline, Stefels, Jacqueline, Svenson, Anders, Tao, Ran, Torres-Valdés, Sinhué, Torstensson, Anders, Toseland, Andrew, Ulfsbo, Adam, Van Leeuwe, Maria A., Vortkamp, Martina, Webb, Alison L., Zhuang, Yanpei, and Gradinger, Rolf R.

Abstract

The international and interdisciplinary sea-ice drift expedition “The Multidisciplinary drifting Observatory for the Study of Arctic Climate” (MOSAiC) was conducted from October 2019 to September 2020. The aim of MOSAiC was to study the interconnected physical, chemical, and biological characteristics and processes from the atmosphere to the deep sea of the central Arctic system. The ecosystem team addressed current knowledge gaps and explored unknown biological properties over a complete seasonal cycle focusing on three major research areas: biodiversity, biogeochemical cycles, and linkages to the environment. In addition to the measurements of core properties along a complete seasonal cycle, dedicated projects covered specific processes and habitats, or organisms on higher taxonomic or temporal resolution in specific time windows. A wide range of sampling instruments and approaches, including sea-ice coring, lead sampling with pumps, rosette-based water sampling, plankton nets, remotely operated vehicles, and acoustic buoys, was applied to address the science objectives. Further, a broad range of process-related measurements to address, for example, productivity patterns, seasonal migrations, and diversity shifts, were made both in situ and onboard RV Polarstern. This article provides a detailed overview of the sampling approaches used to address the three main science objectives. It highlights the core sampling program and provides examples of habitat- or process-specific sampling. The initial results presented include high biological activities in wintertime and the discovery of biological hotspots in underexplored habitats. The unique interconnectivity of the coordinated sampling efforts also revealed insights into cross-disciplinary interactions like the impact of biota on Arctic cloud formation. This overview further presents both lessons learned from conducting such a demanding field campaign and an outlook on spin-off projects to be conducted over the next

Published
2024
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20. Observing change in pelagic animals as sampling methods shift: the case of Antarctic krill

Author

Hill, Simeon L, Atkinson, Angus, Arata, Javier, Belcher, Anna, Bengtson-Nash, Susan, Bernard, Kim S., Cleary, Alison, Conroy, John, Driscoll, Ryan, Fielding, Sophie, Flores, Hauke, Forcada, Jaume, Halfter, Svenja, Hinke, Jefferson, Hückstädt, Luis, Johnston, Nadine M., Kane, Mary, Kawaguchi, So, Krafft, Bjørn A., Krüger, Lucas, La, Hyoung Sul, Liszka, Cecilia, Meyer, Bettina, Murphy, Eugene, Pakhomov, Evgeny, Perry, Frances, Piñones, Andrea, Polito, Michael J., Reid, Keith, Reiss, Christian, Rombola, Emilce, Saunders, Ryan A., Schmidt, Katrin, Sylvester, Zephryr, Takahashi, Akinori, Tarling, Geraint A., Trathan, Philip N., Veytia, Devi, Watters, George, Xavier, José C., Yang, Guang, Hill, Simeon L, Atkinson, Angus, Arata, Javier, Belcher, Anna, Bengtson-Nash, Susan, Bernard, Kim S., Cleary, Alison, Conroy, John, Driscoll, Ryan, Fielding, Sophie, Flores, Hauke, Forcada, Jaume, Halfter, Svenja, Hinke, Jefferson, Hückstädt, Luis, Johnston, Nadine M., Kane, Mary, Kawaguchi, So, Krafft, Bjørn A., Krüger, Lucas, La, Hyoung Sul, Liszka, Cecilia, Meyer, Bettina, Murphy, Eugene, Pakhomov, Evgeny, Perry, Frances, Piñones, Andrea, Polito, Michael J., Reid, Keith, Reiss, Christian, Rombola, Emilce, Saunders, Ryan A., Schmidt, Katrin, Sylvester, Zephryr, Takahashi, Akinori, Tarling, Geraint A., Trathan, Philip N., Veytia, Devi, Watters, George, Xavier, José C., and Yang, Guang

Abstract

Understanding and managing the response of marine ecosystems to human pressures including climate change requires reliable large-scale and multi-decadal information on the state of key populations. These populations include the pelagic animals that support ecosystem services including carbon export and fisheries. The use of research vessels to collect information using scientific nets and acoustics is being replaced with technologies such as autonomous moorings, gliders, and meta-genetics. Paradoxically, these newer methods sample pelagic populations at ever-smaller spatial scales, and ecological change might go undetected in the time needed to build up large-scale, long time series. These global-scale issues are epitomised by Antarctic krill (Euphausia superba), which is concentrated in rapidly warming areas, exports substantial quantities of carbon and supports an expanding fishery, but opinion is divided on how resilient their stocks are to climatic change. Based on a workshop of 137 krill experts we identify the challenges of observing climate change impacts with shifting sampling methods and suggest three tractable solutions. These are to: improve overlap and calibration of new with traditional methods; improve communication to harmonise, link and scale up the capacity of new but localised sampling programs; and expand opportunities from other research platforms and data sources, including the fishing industry. Contrasting evidence for both change and stability in krill stocks illustrates how the risks of false negative and false positive diagnoses of change are related to the temporal and spatial scale of sampling. Given the uncertainty about how krill are responding to rapid warming we recommend a shift towards a fishery management approach that prioritises monitoring of stock status and can adapt to variability and change.

Published
2024

21. Observing change in pelagic animals as sampling methods shift: the case of Antarctic krill

Author

World Wildlife Fund, Natural Environment Research Council (UK), National Science Foundation (US), European Commission, Instituto Antártico Chileno, Instituto Milenio de Oceanografía (Chile), Korea Polar Research Institute, Ministry of Oceans and Fisheries (South Korea), Helmholtz Association, Natural Sciences and Engineering Research Council of Canada, Agencia Nacional de Investigación y Desarrollo (Chile), Fondo Nacional de Desarrollo Científico y Tecnológico (Chile), Japan Society for the Promotion of Science, University of Tasmania, Fundação para a Ciência e a Tecnologia (Portugal), Hill, Simeon L., Atkinson, Angus, Arata, Javier A., Belcher, Anna, Bengtson Nash, Susan, Bernard, Kim S., Cleary, Alison, Conroy, John A., Driscoll, Ryan, Fielding, Sophie, Flores, Hauke, Forcada, Jaume, Halfter, Svenja, Hinke, Jefferson T., Hückstädt, Luis, Johnston, Nadine M., Kane, Mary, Kawaguchi, So, Krafft, Bjørn A., Krüger, Lucas, La, Hyoung Sul, Liszka, Cecilia M., Meyer, Bettina, Murphy, Eugene J., Pakhomov, Evgeny A., Perry, Frances, Piñones, Andrea, Polito, Michael J., Reid, Keith, Reiss, Christian, Rombola, Emilce, Saunders, Ryan A., Schmidt, Katrin, Sylvester, Zephyr T., Takahashi, Akinori, Tarling, Geraint A., Trathan, Phil N., Veytia, Devi, Watters, George M., Xavier, José C., Yang, Guang, World Wildlife Fund, Natural Environment Research Council (UK), National Science Foundation (US), European Commission, Instituto Antártico Chileno, Instituto Milenio de Oceanografía (Chile), Korea Polar Research Institute, Ministry of Oceans and Fisheries (South Korea), Helmholtz Association, Natural Sciences and Engineering Research Council of Canada, Agencia Nacional de Investigación y Desarrollo (Chile), Fondo Nacional de Desarrollo Científico y Tecnológico (Chile), Japan Society for the Promotion of Science, University of Tasmania, Fundação para a Ciência e a Tecnologia (Portugal), Hill, Simeon L., Atkinson, Angus, Arata, Javier A., Belcher, Anna, Bengtson Nash, Susan, Bernard, Kim S., Cleary, Alison, Conroy, John A., Driscoll, Ryan, Fielding, Sophie, Flores, Hauke, Forcada, Jaume, Halfter, Svenja, Hinke, Jefferson T., Hückstädt, Luis, Johnston, Nadine M., Kane, Mary, Kawaguchi, So, Krafft, Bjørn A., Krüger, Lucas, La, Hyoung Sul, Liszka, Cecilia M., Meyer, Bettina, Murphy, Eugene J., Pakhomov, Evgeny A., Perry, Frances, Piñones, Andrea, Polito, Michael J., Reid, Keith, Reiss, Christian, Rombola, Emilce, Saunders, Ryan A., Schmidt, Katrin, Sylvester, Zephyr T., Takahashi, Akinori, Tarling, Geraint A., Trathan, Phil N., Veytia, Devi, Watters, George M., Xavier, José C., and Yang, Guang

Abstract

Understanding and managing the response of marine ecosystems to human pressures including climate change requires reliable large-scale and multi-decadal information on the state of key populations. These populations include the pelagic animals that support ecosystem services including carbon export and fisheries. The use of research vessels to collect information using scientific nets and acoustics is being replaced with technologies such as autonomous moorings, gliders, and meta-genetics. Paradoxically, these newer methods sample pelagic populations at ever-smaller spatial scales, and ecological change might go undetected in the time needed to build up large-scale, long time series. These global-scale issues are epitomised by Antarctic krill (Euphausia superba), which is concentrated in rapidly warming areas, exports substantial quantities of carbon and supports an expanding fishery, but opinion is divided on how resilient their stocks are to climatic change. Based on a workshop of 137 krill experts we identify the challenges of observing climate change impacts with shifting sampling methods and suggest three tractable solutions. These are to: improve overlap and calibration of new with traditional methods; improve communication to harmonise, link and scale up the capacity of new but localised sampling programs; and expand opportunities from other research platforms and data sources, including the fishing industry. Contrasting evidence for both change and stability in krill stocks illustrates how the risks of false negative and false positive diagnoses of change are related to the temporal and spatial scale of sampling. Given the uncertainty about how krill are responding to rapid warming we recommend a shift towards a fishery management approach that prioritises monitoring of stock status and can adapt to variability and change.

Published
2024

22. Essential omega‐3 fatty acids are depleted in sea ice and pelagic algae of the Central Arctic Ocean

Author

Schmidt, Katrin, primary, Graeve, Martin, additional, Hoppe, Clara J. M., additional, Torres‐Valdes, Sinhué, additional, Welteke, Nahid, additional, Whitmore, Laura M., additional, Anhaus, Philipp, additional, Atkinson, Angus, additional, Belt, Simon T., additional, Brenneis, Tina, additional, Campbell, Robert G., additional, Castellani, Giulia, additional, Copeman, Louise A., additional, Flores, Hauke, additional, Fong, Allison A., additional, Hildebrandt, Nicole, additional, Kohlbach, Doreen, additional, Nielsen, Jens M., additional, Parrish, Christopher C., additional, Rad‐Menéndez, Cecilia, additional, Rokitta, Sebastian D., additional, Tippenhauer, Sandra, additional, and Zhuang, Yanpei, additional

Published
2023
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24. Contributors

Author

Arobaya, Agustina Y.S., primary, Beehler, Bruce M., additional, Blair Brooks, W., additional, Blessington, Jacque, additional, Burchill, Simon, additional, Byers, Jonathan, additional, Byers, Onnie, additional, Castro, Joan, additional, Cianelli, Margit, additional, Dabek, Lisa, additional, Dierenfeld, Ellen, additional, Esson, Carol, additional, Ford, Claire, additional, Gillanders, Alan, additional, Heise-Pavlov, Sigrid, additional, Highland, Margaret, additional, Holbrook, Trevor, additional, Huettmann, Falk, additional, Jaffar, Razak, additional, Kanowski, John, additional, Kemp, Neville, additional, Koibur, Johan F., additional, Kozlowski, Corinne, additional, Kuna, Karau, additional, Legge, Alana, additional, Liddell, Marti H., additional, Liddell, Robert M., additional, Males, Gayl, additional, McGreevy, Thomas J., additional, Miller, Philip, additional, Montgomery, Sy, additional, Nane, Danny, additional, van Nimwegen, Paul, additional, Nolan, Mikal Eversole, additional, Norsworthy, Davi Ann, additional, Okena, Daniel Solomon, additional, Pattiselanno, Freddy, additional, Philips, Nancy, additional, Phillips, Terry M., additional, Pontio, Modi, additional, Porolak, Gabriel, additional, Procter-Gray, Elizabeth, additional, Rabinowitz, Peter M., additional, Richardson, Megan, additional, Samandingke, Danny, additional, Schmidt, Katrin, additional, Schürer, Ulrich, additional, Schwartz, Karin R., additional, Sharpe, Deanna, additional, Shearman, Phil L., additional, Smith, Brett, additional, Sowang, Timmy, additional, Stabach, Jared, additional, Steenberg, Judie, additional, Transue, Emily R., additional, Crook, Erika (Travis), additional, Valentine, Peter, additional, Watson, Patricia, additional, Wells, Zachary, additional, and Wilson, Clevo, additional

Published
2021
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37. Dataset of 143 metagenome-assembled genomes from the Arctic and Atlantic Oceans, including 21 for eukaryotic organisms

Author

Duncan, Anthony, primary, Barry, Kerrie, additional, Daum, Chris, additional, Eloe-Fadrosh, Emiley, additional, Roux, Simon, additional, Schmidt, Katrin, additional, Tringe, Susannah G., additional, Valentin, Klaus U., additional, Varghese, Neha, additional, Salamov, Asaf, additional, Grigoriev, Igor V., additional, Leggett, Richard M., additional, Moulton, Vincent, additional, and Mock, Thomas, additional

Published
2023
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38. Correction to: Incidence of severe sepsis and septic shock in German intensive care units: the prospective, multicentre INSEP study

Author

Marx, Gernot, Litmathe, Jens, Schulz, Jörg B., Dafotakis, Manuel, Möllhoff, Thomas, Stalljohann, Carolin, Engels, Jonas, Sauerzapfe, Barbara, Stolzenberg, Barbara, Jonas, Engels, Möllhoff, Thomas, Carolin, Stalljohann, Thorben, Beeker, Gernot, Marx, Melanie, Schäfer, Tobias, Schürholz, Ertunc, Altiok, Marx, Nikolaus, Alexander, Kersten, Hannah, Dückers, Alexander, Koch, Trautwein, Christian, Scharf, Alexander, Kreuzer, Ilse, Jaschinski, Ulrich, Kreuzer, Ilse, Jaschinski, Ulrich, Niklas, Markus, Kulzer, Michael, Schlott, Martin, Iberer, Thomas, Stella, Oelert, Thorsten, Löhr, Vandana, Pillai, Praeger, Damaris, Knebel, Fabian, Baumann, Gert, Rosseau, Simone, Schlenk, Florian, Hoffmeister, Bodo, Compton, Friederike, Hoffmann, Clemens, Rademacher, Sibylle, Vietzke, Michael, Jörres, Achim, Meisel, Andreas, Hotter, Benjamin, Mengel, Annerose, Goldmann, Anton, Nöther, Frank, Keh, Didier, Schmidt, Katrin, Angermair, Stefan, Kaffarnik, Magnus, Bubser, Florian, Gummelt, Immo, Vedder, Ina, Bach, Friedhelm, Winter, Markus, Weißer, Frank, Roederer, Marc, Martini, Stefan, Bergmann, Lars, Adamzik, Michael, Baumann, Andreas, Wolf, Britta, Zahn, Peter K., Lehnhardt, Marcus, Daigeler, Adrien, Andreas, Andreas Hohn, Reinhold, Katrin, Adolf, Michael, Altenbeck, Nicole, Gussone, Christoph, Dietrich, Johannes Wolfgang, Köditz, Roland, Putensen, Christian, Schewe, Jens-Christian, Muders, Thomas, Soukup, Jens, Skitek, Kornel, Geisser, Wolfgang, Alber, Andreas, Düthorn, Ludwig, Demund, Josef, Düthorn, Ludwig, Criegern, Isabel v., Nowak, Andreas, Morgenstern, Toralf, Gliniorz, Christoph, Meisner, Michael, Dexel, Melanie, Schütte, Jan Karl, Huppertz-Thyssen, Markus H., Schröder, Stefan, Kowalzik, Ralf, Guel, Cansu, Terhorst, Rainer, Nießen, Peter, Hauschild, Rolf, Mutzek, Elisabeth-Maria, Kogelmann, Klaus, Drüner, Matthias, Jarczak, Dominik, Forster, Christian, Willam, Carsten, Eckardt, K. U., Clemenz, Rüdiger, Siemonsen, Sven, Pauschinger, Matthias, Baumgärtel, Matthias, Muschner, Dorothea, Christ, Michael, Wenzl, Martin, Höhl, Rainer, Junger, Axel, Wöhrle, Armin, Kanthak, Henry, Leschke, Matthias, Kanthak, Henry, Wöhrle, Armin, Leschke, Matthias, Kessler, Paul, Souquet, Jochen, Holfeld, Andreas, Habler, Oliver, Thörner, Markus, Vogt, Oliver, Meybohm, Patrick, Zacharowski, Kai, Lindau, Simone, Lenk, Marcus, Weis, Florian, Schubert, Hermann, Kemnitz, Jürgen, Reckort, Sven, Weikert, Martina, Sudhues, Ulrich, Möller, Stefan, Stefan, Pinger, Domke, Andrea, Wiesenack, Christoph, Schmidt, Florian, Döbel, Kai-Uwe, Moerer, Onnen, Schäper, Jörn, Kernchen, Andrea, Gründling, Matthias, Bollmann, Jan, Kuhn, Sven-Olaf, Kemming, Gregor, Einfeld, Carsten, Sommerer, Thomas, Kemming, Gregor, Einfeld, Carsten, Sommerer, Thomas, Köntges, Philipp, Hinz, Burkhard, Jauch, Lars-Oliver, Selonke, Lutz, Kluge, Stefan, Nierhaus, Axel, de Heer, Geraldine, Gruß, Marco, Köhler, Katja, Brinkmann, Alexander, Fuchs, Thomas, Köberer, Andreas, Geuting, Markus, Weigt, Henry, Baltus, Thomas, Scheltz, Claudia, Bloos, Frank, Reinhart, Konrad, Jegen, Rudolf, Flucht, Marcus, Jürgen, Gburek, Flucht, Marcus, Jegen, Rudolf, Stumm, Anne, Rossenbach, Jannik, Stumm, Anne, Haller, Mathias, Stumm, Anne, Rossenbach, Jannik, Lynch, John, Kempkens, Martin, Buechner, Volkmar, Molitor, Dieter, Klasen, Gerda, Rahmen, Bruno, Muhr, Petra, Canaviri, Patricia, Fiedler, Fritz, Lutz, Jürgen, Kaiser, Marc, Klünter, Simon, Krep, Henning, Anders, Helge, Aduckathil, Sanjay, Sakka, Samir, Reessing, Jan Hinnerk, Aabaid, Sabrina, Löbe, Mathias, Bogatsch, Holger, Löffler, Marcus, Engels, Christoph, Molter, Gerd Peter, Stunz, Michael, Mitrenga, Anja, Geldner, Götz, Bürle, Monica, Klasen, Robert, Werner, Steffanie, Wilhelm, Wolfram, Silke, Frenzel, Juliane, Illert, Jana, Schuttpelz, Briegel, Josef, Möhnle, Patrick, Knorr, Adrian, Hartl, Wolfgang, Ney, Ludwig, Stemmler, Hans-Joachim, Pfister, Hans-Walter, Angstwurm, Matthias, Frey, Lorenz, Irlbeck, Michael, Huge, Volker, Weis, Marion, Kilger, Erich, Hofmann-Kiefer, Klaus, Felbinger, Thomas, Kaufmann, Ines, Goeschl, Julia, Brettner, Franz, Hamm, Heiner, Eife, Claudia, Peckelsen, Claus, Findeisen, Michael, Schmidt-Schridde, Patrick, Kuner, Andreas, Walz, Thomas, Kuner, Barbara, Schrauzer, Thomas, Nentwich, Jens, John, Stefan, Byhahn, Christian, Kretschmer, Thomas, Bergold, Martin N., Weyland, Andreas, Jelschen, Florian, Diers, Anja, Knebel, Frieder G., Kupfer, Thomas, Oppert, Michael, Rohde, Steffen, Möllemann, Angela, Oehmichen, Uwe, Renner, Theresa, Bone, Hans-Georg, Freyhoff, Jörg, Holst, Dana, Birken, Thomas, Henschel, Jörg, Gloger, Martin, Brock, Peter, Klösel, Stephan, Albuszies, Gerd, Schumacher, Detlef, Meierhenrich, Rainer, Schöpp, Alexej, Kuhn, Harald, Riessen, Reimer, Haap, Michael, Ziegler, Silvia, Fastnacht-Böttcher, Jana, Schröder, Rolf Jürgen, Weiss, Manfred, Frank, Katrin, Georgieff, Michael, Weiss, Manfred, Barth, Eberhard, Bracht, Henrik, Ehmcke, Heidrun, Francke, Astrid, Ott, Stefan, Köpcke, Jens, Meyer, Andreas, Jokiel, Gunnar, Freund, Thomas, Schick, Guido, Karassimos, Evagelos, and SepNet Critical Care Trials Group

Published
2017
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39. Thin and transient meltwater layers and false bottoms in the Arctic sea ice pack—Recent insights on these historically overlooked features

Author

Smith, Madison M, Angot, Hélène, Chamberlain, Emelia J, Droste, Elise S, Karam, Salar, Muilwijk, Morven, Webb, Alison L, Archer, Stephen D, Beck, Ivo, Blomquist, Byron W, Bowman, Jeff, Boyer, Matthew, Bozzato, Deborah, Chierici, Melissa, Creamean, Jessie, D’Angelo, Alessandra, Delille, Bruno, Fer, Ilker, Fong, Allison A, Fransson, Agneta, Fuchs, Niels, Gardner, Jessie, Granskog, Mats A, Hoppe, Clara JM, Hoppema, Mario, Hoppmann, Mario, Mock, Thomas, Muller, Sofia, Müller, Oliver, Nicolaus, Marcel, Nomura, Daiki, Petäjä, Tuukka, Salganik, Evgenii, Schmale, Julia, Schmidt, Katrin, Schulz, Kirstin M, Shupe, Matthew D, Stefels, Jacqueline, Thielke, Linda, Tippenhauer, Sandra, Ulfsbo, Adam, van Leeuwe, Maria, Webster, Melinda, Yoshimura, Masaki, Zhan, Liyang, Smith, Madison M, Angot, Hélène, Chamberlain, Emelia J, Droste, Elise S, Karam, Salar, Muilwijk, Morven, Webb, Alison L, Archer, Stephen D, Beck, Ivo, Blomquist, Byron W, Bowman, Jeff, Boyer, Matthew, Bozzato, Deborah, Chierici, Melissa, Creamean, Jessie, D’Angelo, Alessandra, Delille, Bruno, Fer, Ilker, Fong, Allison A, Fransson, Agneta, Fuchs, Niels, Gardner, Jessie, Granskog, Mats A, Hoppe, Clara JM, Hoppema, Mario, Hoppmann, Mario, Mock, Thomas, Muller, Sofia, Müller, Oliver, Nicolaus, Marcel, Nomura, Daiki, Petäjä, Tuukka, Salganik, Evgenii, Schmale, Julia, Schmidt, Katrin, Schulz, Kirstin M, Shupe, Matthew D, Stefels, Jacqueline, Thielke, Linda, Tippenhauer, Sandra, Ulfsbo, Adam, van Leeuwe, Maria, Webster, Melinda, Yoshimura, Masaki, and Zhan, Liyang

Abstract

The rapid melt of snow and sea ice during the Arctic summer provides a significant source of low-salinity meltwater to the surface ocean on the local scale. The accumulation of this meltwater on, under, and around sea ice floes can result in relatively thin meltwater layers in the upper ocean. Due to the small-scale nature of these upper-ocean features, typically on the order of 1 m thick or less, they are rarely detected by standard methods, but are nevertheless pervasive and critically important in Arctic summer. Observations during the Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC) expedition in summer 2020 focused on the evolution of such layers and made significant advancements in understanding their role in the coupled Arctic system. Here we provide a review of thin meltwater layers in the Arctic, with emphasis on the new findings from MOSAiC. Both prior and recent observational datasets indicate an intermittent yet longlasting (weeks to months) meltwater layer in the upper ocean on the order of 0.1 m to 1.0 m in thickness, with a large spatial range. The presence of meltwater layers impacts the physical system by reducing bottom ice melt and allowing new ice formation via false bottom growth. Collectively, the meltwater layer and false bottoms reduce atmosphere-ocean exchanges of momentum, energy, and material.The impacts on the coupled Arctic system are far-reaching, including acting as a barrier for nutrient and gas exchange and impacting ecosystem diversity and productivity.

Published
2023

40. Meltwater layer dynamics in a central Arctic lead: Effects of lead width, re-freezing, and mixing during late summer

Author

Nomura, Daiki, Kawaguchi, Yusuke, Webb, Alison L., Li, Yuhong, Dall’osto, Manuel, Schmidt, Katrin, Droste, Elise S., Chamberlain, Emelia J., Kolabutin, Nikolai, Shimanchuk, Egor, Hoppmann, Mario, Gallagher, Michael R., Meyer, Hanno, Mellat, Moein, Bauch, Dorothea, Gabarró, Carolina, Smith, Madison M., Inoue, Jun, Damm, Ellen, Delille, Bruno, Nomura, Daiki, Kawaguchi, Yusuke, Webb, Alison L., Li, Yuhong, Dall’osto, Manuel, Schmidt, Katrin, Droste, Elise S., Chamberlain, Emelia J., Kolabutin, Nikolai, Shimanchuk, Egor, Hoppmann, Mario, Gallagher, Michael R., Meyer, Hanno, Mellat, Moein, Bauch, Dorothea, Gabarró, Carolina, Smith, Madison M., Inoue, Jun, Damm, Ellen, and Delille, Bruno

Abstract

Leads play an important role in the exchange of heat, gases, vapour, and particles between seawater and the atmosphere in ice-covered polar oceans. In summer, these processes can be modified significantly by the formation of a meltwater layer at the surface, yet we know little about the dynamics of meltwater layer formation and persistence. During the drift campaign of the Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC), we examined how variation in lead width, re-freezing, and mixing events affected the vertical structure of lead waters during late summer in the central Arctic. At the beginning of the 4-week survey period, a meltwater layer occupied the surface 0.8 m of the lead, and temperature and salinity showed strong vertical gradients. Stable oxygen isotopes indicate that the meltwater consisted mainly of sea ice meltwater rather than snow meltwater. During the first half of the survey period (before freezing), the meltwater layer thickness decreased rapidly as lead width increased and stretched the layer horizontally. During the latter half of the survey period (after freezing of the lead surface), stratification weakened and the meltwater layer became thinner before disappearing completely due to surface ice formation and mixing processes. Removal of meltwater during surface ice formation explained about 43% of the reduction in thickness of the meltwater layer. The remaining approximate 57% could be explained by mixing within the water column initiated by disturbance of the lower boundary of the meltwater layer through wind-induced ice floe drift. These results indicate that rapid, dynamic changes to lead water structure can have potentially significant effects on the exchange of physical and biogeochemical components throughout the atmosphere–lead–underlying seawater system.

Published
2023
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41. Meltwater layer dynamics in a central Arctic lead: Effects of lead width, re-freezing, and mixing during late summer

Author

Japan Society for the Promotion of Science, Bundesministerium für Bildung und Forschung, Natural Environment Research Council (UK), National Science Foundation (US), Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), Deutsche Forschungsgemeinschaft, Nomura, Daiki, Kawaguchi, Yusuke, Webb, Alison L., Li, Yuhong, Dall'Osto, Manuel, Schmidt, Katrin, Droste, Elise, Chamberlain, Emelia J., Kolabutin, Nikolai, Shimanchuk, Egor, Hoppmann, Mario, Gallagher, Michael R., Meyer, Hanno, Mellat, Moein, Bauch, Dorothea, Gabarró, Carolina, Smith, Madison, Inoue, Jun, Damm, Ellen, Delille, Bruno, Japan Society for the Promotion of Science, Bundesministerium für Bildung und Forschung, Natural Environment Research Council (UK), National Science Foundation (US), Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), Deutsche Forschungsgemeinschaft, Nomura, Daiki, Kawaguchi, Yusuke, Webb, Alison L., Li, Yuhong, Dall'Osto, Manuel, Schmidt, Katrin, Droste, Elise, Chamberlain, Emelia J., Kolabutin, Nikolai, Shimanchuk, Egor, Hoppmann, Mario, Gallagher, Michael R., Meyer, Hanno, Mellat, Moein, Bauch, Dorothea, Gabarró, Carolina, Smith, Madison, Inoue, Jun, Damm, Ellen, and Delille, Bruno

Abstract

Leads play an important role in the exchange of heat, gases, vapour, and particles between seawater and the atmosphere in ice-covered polar oceans. In summer, these processes can be modified significantly by the formation of a meltwater layer at the surface, yet we know little about the dynamics of meltwater layer formation and persistence. During the drift campaign of the Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC), we examined how variation in lead width, re-freezing, and mixing events affected the vertical structure of lead waters during late summer in the central Arctic. At the beginning of the 4-week survey period, a meltwater layer occupied the surface 0.8 m of the lead, and temperature and salinity showed strong vertical gradients. Stable oxygen isotopes indicate that the meltwater consisted mainly of sea ice meltwater rather than snow meltwater. During the first half of the survey period (before freezing), the meltwater layer thickness decreased rapidly as lead width increased and stretched the layer horizontally. During the latter half of the survey period (after freezing of the lead surface), stratification weakened and the meltwater layer became thinner before disappearing completely due to surface ice formation and mixing processes. Removal of meltwater during surface ice formation explained about 43% of the reduction in thickness of the meltwater layer. The remaining approximate 57% could be explained by mixing within the water column initiated by disturbance of the lower boundary of the meltwater layer through wind-induced ice floe drift. These results indicate that rapid, dynamic changes to lead water structure can have potentially significant effects on the exchange of physical and biogeochemical components throughout the atmosphere–lead–underlying seawater system

Published
2023

42. Long-term monitoring on Percent cover of vascular plants in Doñana shrublands 2008-2022

Author

Organismo Autónomo Parques Nacionales (España), Ministerio de Ciencia e Innovación (España), Junta de Andalucía, CSIC - Estación Biológica de Doñana (EBD), Díaz-Delgado, Ricardo [0000-0002-0460-4616], Aragonés, David [0000-0003-4989-9005], Torrijo-Salesa, Mizar [0000-0003-4881-2836], Bustamante Díaz, Javier [0000-0001-7515-0677], Torrijo-Salesa, Mizar [mizar.torrijo@ebd.csic.es], Díaz-Delgado, Ricardo [rdiaz@ebd.csic.es], Díaz-Delgado, Ricardo, Ramírez González, Luis Alfonso, Alcaide, Antonio, Paz Sánchez, David Antonio, Aragonés, David, López, Diego, Ceballos, Olga, Román, Isidro, Rojas, Alejandría, Tenorio, Juan, Schmidt, Katrin, Torrijo-Salesa, Mizar, Bustamante Díaz, Javier, Bustamante, Javier, Organismo Autónomo Parques Nacionales (España), Ministerio de Ciencia e Innovación (España), Junta de Andalucía, CSIC - Estación Biológica de Doñana (EBD), Díaz-Delgado, Ricardo [0000-0002-0460-4616], Aragonés, David [0000-0003-4989-9005], Torrijo-Salesa, Mizar [0000-0003-4881-2836], Bustamante Díaz, Javier [0000-0001-7515-0677], Torrijo-Salesa, Mizar [mizar.torrijo@ebd.csic.es], Díaz-Delgado, Ricardo [rdiaz@ebd.csic.es], Díaz-Delgado, Ricardo, Ramírez González, Luis Alfonso, Alcaide, Antonio, Paz Sánchez, David Antonio, Aragonés, David, López, Diego, Ceballos, Olga, Román, Isidro, Rojas, Alejandría, Tenorio, Juan, Schmidt, Katrin, Torrijo-Salesa, Mizar, Bustamante Díaz, Javier, and Bustamante, Javier

Abstract

The long-term monitoring on plant cover of Doñana shrublands is part of a harmonised protocol for the Long-term Ecological Monitoring Program of Natural Resources and Processes targeting Terrestrial Vegetation. The general aim of this protocol is to monitor and assess the dynamics of the main dominant terrestrial and aquatic vegetation types of Doñana. For shrublands, percent cover is recorded annually starting from 2008 to the present (2022) by staff of the Monitoring Team by one sampling campaign per year during the flowering season (between March and May) in 21 permanent square plots (15x15m). Cover is measured using the line intercept method in 3 transects of 15 m length oriented from East to West and located at fixed points of 2.5, 7.5 and 12.5 metres at both sides of the plot. Using the line-intercept method, the coverage of each species is measured with a measuring tape, including the class age (adult or seedling) and the canopy status (green or dead). This method enables to calculate the percent cover for each species across the transect and for the whole plot, including data on class age and percent of dry and green canopy, additionally to the percent of bare soil, plant density, species richness and vascular plant diversity for every plot.

Published
2023

43. Long-term monitoring on percent cover of vascular plants in shrublands of Doñana 2008-2022

Author

Bustamante Díaz, Javier, Schmidt, Katrin, Tenorio, Juan, Rojas, Alejandria, Román Maudo, Isidro, Ceballos, Olga, López, Diego, Aragonés, David, Paz Sánchez, David Antonio, Alcaide, Antonio, Ramírez González, Luis Alfonso, Torrijo-Salesa, Mizar, Díaz-Delgado, Ricardo, Bustamante Díaz, Javier, Schmidt, Katrin, Tenorio, Juan, Rojas, Alejandria, Román Maudo, Isidro, Ceballos, Olga, López, Diego, Aragonés, David, Paz Sánchez, David Antonio, Alcaide, Antonio, Ramírez González, Luis Alfonso, Torrijo-Salesa, Mizar, and Díaz-Delgado, Ricardo

Abstract

The long-term monitoring on plant cover of Doñana shrublands is part of a harmonised protocol for the Long-term Ecological Monitoring Program of Natural Resources and Processes targeting Terrestrial Vegetation. The general aim of this protocol is to monitor and assess the dynamics of the main dominant terrestrial and aquatic vegetation types of Doñana. For shrublands, percent cover is recorded annually starting from 2008 to the present (2022) by staff of the Monitoring Team by one sampling campaign per year during the flowering season (between March and May) in 21 permanent square plots (15x15m). Cover is measured using the line intercept method in 3 transects of 15 m length oriented from East to West and located at fixed points of 2.5, 7.5 and 12.5 metres at both sides of the plot. Using the line-intercept method, the coverage of each species is measured with a measuring tape, including the class age (adult or seedling) and the canopy status (green or dead). This method enables to calculate the percent cover for each species across the transect and for the whole plot, including data on class age and percent of dry and green canopy, additionally to the percent of bare soil, plant density, species richness and vascular plant diversity for every plot., The aim of this project is to provide information about the evolution of the conservation status of Doñana. To do that, it has been designed a monitoring program of the dynamic of natural processes and the distribution and abundance of species and communities. This monitoring is generating time series of data which is being used to analyse long-term trends.

Published
2023

46. Sea-ice decline makes zooplankton stay deeper for longer

Author

Flores, Hauke, primary, Veyssiere, Gaelle, additional, Castellani, Giulia, additional, Wilkinson, Jeremy, additional, Hoppmann, Mario, additional, Karcher, Michael, additional, Valcic, Lovro, additional, Cornils, Astrid, additional, Geoffroy, Maxime, additional, Nicolaus, Marcel, additional, Niehoff, Barbara, additional, Priou, Pierre, additional, Schmidt, Katrin, additional, and Stroeve, Julienne, additional

Published
2023
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47. Thin and transient meltwater layers and false bottoms in the Arctic sea ice pack—Recent insights on these historically overlooked features

Author

Smith, Madison M., primary, Angot, Hélène, additional, Chamberlain, Emelia J., additional, Droste, Elise S., additional, Karam, Salar, additional, Muilwijk, Morven, additional, Webb, Alison L., additional, Archer, Stephen D., additional, Beck, Ivo, additional, Blomquist, Byron W., additional, Bowman, Jeff, additional, Boyer, Matthew, additional, Bozzato, Deborah, additional, Chierici, Melissa, additional, Creamean, Jessie, additional, D’Angelo, Alessandra, additional, Delille, Bruno, additional, Fer, Ilker, additional, Fong, Allison A., additional, Fransson, Agneta, additional, Fuchs, Niels, additional, Gardner, Jessie, additional, Granskog, Mats A., additional, Hoppe, Clara J. M., additional, Hoppema, Mario, additional, Hoppmann, Mario, additional, Mock, Thomas, additional, Muller, Sofia, additional, Müller, Oliver, additional, Nicolaus, Marcel, additional, Nomura, Daiki, additional, Petäjä, Tuukka, additional, Salganik, Evgenii, additional, Schmale, Julia, additional, Schmidt, Katrin, additional, Schulz, Kirstin M., additional, Shupe, Matthew D., additional, Stefels, Jacqueline, additional, Thielke, Linda, additional, Tippenhauer, Sandra, additional, Ulfsbo, Adam, additional, van Leeuwe, Maria, additional, Webster, Melinda, additional, Yoshimura, Masaki, additional, and Zhan, Liyang, additional

Published
2023
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48. Meltwater layer dynamics in a central Arctic lead: Effects of lead width, re-freezing, and mixing during late summer

Author

Nomura, Daiki, primary, Kawaguchi, Yusuke, additional, Webb, Alison L., additional, Li, Yuhong, additional, Dall’osto, Manuel, additional, Schmidt, Katrin, additional, Droste, Elise S., additional, Chamberlain, Emelia J., additional, Kolabutin, Nikolai, additional, Shimanchuk, Egor, additional, Hoppmann, Mario, additional, Gallagher, Michael R., additional, Meyer, Hanno, additional, Mellat, Moein, additional, Bauch, Dorothea, additional, Gabarró, Carolina, additional, Smith, Madison M., additional, Inoue, Jun, additional, Damm, Ellen, additional, and Delille, Bruno, additional

Published
2023
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