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3. Isotopic signatures of snow, sea ice, and surface seawater in the central Arctic Ocean during the MOSAiC expedition

Author

Mellat, Moein, Brunello, Camilla F., Werner, Martin, Bauch, Dorothea, Damm, Ellen, Angelopoulos, Michael, Nomura, Daiki, Welker, Jeffrey M., Schneebeli, Martin, Granskog, Mats A., Hoerhold, Maria, Macfarlane, Amy R., Arndt, Stefanie, Meyer, Hanno, Mellat, Moein, Brunello, Camilla F., Werner, Martin, Bauch, Dorothea, Damm, Ellen, Angelopoulos, Michael, Nomura, Daiki, Welker, Jeffrey M., Schneebeli, Martin, Granskog, Mats A., Hoerhold, Maria, Macfarlane, Amy R., Arndt, Stefanie, and Meyer, Hanno

Published
2024
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4. The Eurasian Arctic Ocean along the MOSAiC drift in 2019–2020: An interdisciplinary perspective on physical properties and processes

Author

Schulz, Kirstin, Koenig, Zoe, Muilwijk, Morven, Bauch, Dorothea, Hoppe, Clara J. M., Droste, Elise S., Hoppmann, Mario, Chamberlain, Emelia J., Laukert, Georgi, Stanton, Tim, Quintanilla-Zurita, Alejandra, Fer, Ilker, Heuzé, Céline, Karam, Salar, Mieruch-Schnülle, Sebastian, Baumann, Till M., Vredenborg, Myriel, Tippenhauer, Sandra, Granskog, Mats A., Schulz, Kirstin, Koenig, Zoe, Muilwijk, Morven, Bauch, Dorothea, Hoppe, Clara J. M., Droste, Elise S., Hoppmann, Mario, Chamberlain, Emelia J., Laukert, Georgi, Stanton, Tim, Quintanilla-Zurita, Alejandra, Fer, Ilker, Heuzé, Céline, Karam, Salar, Mieruch-Schnülle, Sebastian, Baumann, Till M., Vredenborg, Myriel, Tippenhauer, Sandra, and Granskog, Mats A.

Abstract

The Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC, 2019–2020), a year-long drift with the Arctic sea ice, has provided the scientific community with an unprecedented, multidisciplinary dataset from the Eurasian Arctic Ocean, covering high atmosphere to deep ocean across all seasons. However, the heterogeneity of data and the superposition of spatial and temporal variability, intrinsic to a drift campaign, complicate the interpretation of observations. In this study, we have compiled a quality-controlled physical hydrographic dataset with best spatio-temporal coverage and derived core parameters, including the mixed layer depth, heat fluxes over key layers, and friction velocity. We provide a comprehensive and accessible overview of the ocean conditions encountered along the MOSAiC drift, discuss their interdisciplinary implications, and compare common ocean climatologies to these new data. Our results indicate that, for the most part, ocean variability was dominated by regional rather than seasonal signals, carrying potentially strong implications for ocean biogeochemistry, ecology, sea ice, and even atmospheric conditions. Near-surface ocean properties were strongly influenced by the relative position of sampling, within or outside the river-water influenced Transpolar Drift, and seasonal warming and meltwater input. Ventilation down to the Atlantic Water layer in the Nansen Basin allowed for a stronger connectivity between subsurface heat and the sea ice and surface ocean via elevated upward heat fluxes. The Yermak Plateau and Fram Strait regions were characterized by heterogeneous water mass distributions, energetic ocean currents, and stronger lateral gradients in surface water properties in frontal regions. Together with the presented results and core parameters, we offer context for interdisciplinary research, fostering an improved understanding of the complex, coupled Arctic System.

Published
2024
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7. The GEOTRACES Intermediate Data Product 2017

Author

Schlitzer, Reiner, Anderson, Robert F., Dodas, Elena Masferrer, Lohan, Maeve, Geibert, Walter, Tagliabue, Alessandro, Bowie, Andrew, Jeandel, Catherine, Maldonado, Maria T., Landing, William M., Cockwell, Donna, Abadie, Cyril, Abouchami, Wafa, Achterberg, Eric P., Agather, Alison, Aguliar-Islas, Ana, van Aken, Hendrik M., Andersen, Morten, Archer, Corey, Auro, Maureen, de Baar, Hein J., Baars, Oliver, Baker, Alex R., Bakker, Karel, Basak, Chandranath, Baskaran, Mark, Bates, Nicholas R., Bauch, Dorothea, van Beek, Pieter, Behrens, Melanie K., Black, Erin, Bluhm, Katrin, Bopp, Laurent, Bouman, Heather, Bowman, Katlin, Bown, Johann, Boyd, Philip, Boye, Marie, Boyle, Edward A., Branellec, Pierre, Bridgestock, Luke, Brissebrat, Guillaume, Browning, Thomas, Bruland, Kenneth W., Brumsack, Hans-Jürgen, Brzezinski, Mark, Buck, Clifton S., Buck, Kristen N., Buesseler, Ken, Bull, Abby, Butler, Edward, Cai, Pinghe, Mor, Patricia Cámara, Cardinal, Damien, Carlson, Craig, Carrasco, Gonzalo, Casacuberta, Núria, Casciotti, Karen L., Castrillejo, Maxi, Chamizo, Elena, Chance, Rosie, Charette, Matthew A., Chaves, Joaquin E., Cheng, Hai, Chever, Fanny, Christl, Marcus, Church, Thomas M., Closset, Ivia, Colman, Albert, Conway, Tim M., Cossa, Daniel, Croot, Peter, Cullen, Jay T., Cutter, Gregory A., Daniels, Chris, Dehairs, Frank, Deng, Feifei, Dieu, Huong Thi, Duggan, Brian, Dulaquais, Gabriel, Dumousseaud, Cynthia, Echegoyen-Sanz, Yolanda, Edwards, R. Lawrence, Ellwood, Michael, Fahrbach, Eberhard, Fitzsimmons, Jessica N., Russell Flegal, A., Fleisher, Martin Q., van de Flierdt, Tina, Frank, Martin, Friedrich, Jana, Fripiat, Francois, Fröllje, Henning, Galer, Stephen J.G., Gamo, Toshitaka, Ganeshram, Raja S., Garcia-Orellana, Jordi, Garcia-Solsona, Ester, Gault-Ringold, Melanie, George, Ejin, Gerringa, Loes J.A., Gilbert, Melissa, Godoy, Jose M., Goldstein, Steven L., Gonzalez, Santiago R., Grissom, Karen, Hammerschmidt, Chad, Hartman, Alison, Hassler, Christel S., Hathorne, Ed C., Hatta, Mariko, Hawco, Nicholas, Hayes, Christopher T., Heimbürger, Lars-Eric, Helgoe, Josh, Heller, Maija, Henderson, Gideon M., Henderson, Paul B., van Heuven, Steven, Ho, Peng, Horner, Tristan J., Hsieh, Yu-Te, Huang, Kuo-Fang, Humphreys, Matthew P., Isshiki, Kenji, Jacquot, Jeremy E., Janssen, David J., Jenkins, William J., John, Seth, Jones, Elizabeth M., Jones, Janice L., Kadko, David C., Kayser, Rick, Kenna, Timothy C., Khondoker, Roulin, Kim, Taejin, Kipp, Lauren, Klar, Jessica K., Klunder, Maarten, Kretschmer, Sven, Kumamoto, Yuichiro, Laan, Patrick, Labatut, Marie, Lacan, Francois, Lam, Phoebe J., Lambelet, Myriam, Lamborg, Carl H., Le Moigne, Frédéric A.C., Le Roy, Emilie, Lechtenfeld, Oliver J., Lee, Jong-Mi, Lherminier, Pascale, Little, Susan, López-Lora, Mercedes, Lu, Yanbin, Masque, Pere, Mawji, Edward, Mcclain, Charles R., Measures, Christopher, Mehic, Sanjin, Barraqueta, Jan-Lukas Menzel, van der Merwe, Pier, Middag, Rob, Mieruch, Sebastian, Milne, Angela, Minami, Tomoharu, Moffett, James W., Moncoiffe, Gwenaelle, Moore, Willard S., Morris, Paul J., Morton, Peter L., Nakaguchi, Yuzuru, Nakayama, Noriko, Niedermiller, John, Nishioka, Jun, Nishiuchi, Akira, Noble, Abigail, Obata, Hajime, Ober, Sven, Ohnemus, Daniel C., van Ooijen, Jan, O'Sullivan, Jeanette, Owens, Stephanie, Pahnke, Katharina, Paul, Maxence, Pavia, Frank, Pena, Leopoldo D., Peters, Brian, Planchon, Frederic, Planquette, Helene, Pradoux, Catherine, Puigcorbé, Viena, Quay, Paul, Queroue, Fabien, Radic, Amandine, Rauschenberg, S., Rehkämper, Mark, Rember, Robert, Remenyi, Tomas, Resing, Joseph A., Rickli, Joerg, Rigaud, Sylvain, Rijkenberg, Micha J.A., Rintoul, Stephen, Robinson, Laura F., Roca-Martí, Montserrat, Rodellas, Valenti, Roeske, Tobias, Rolison, John M., Rosenberg, Mark, Roshan, Saeed, Rutgers van der Loeff, Michiel M., Ryabenko, Evgenia, Saito, Mak A., Salt, Lesley A., Sanial, Virginie, Sarthou, Geraldine, Schallenberg, Christina, Schauer, Ursula, Scher, Howie, Schlosser, Christian, Schnetger, Bernhard, Scott, Peter, Sedwick, Peter N., Semiletov, Igor, Shelley, Rachel, Sherrell, Robert M., Shiller, Alan M., Sigman, Daniel M., Singh, Sunil Kumar, Slagter, Hans A., Slater, Emma, Smethie, William M., Snaith, Helen, Sohrin, Yoshiki, Sohst, Bettina, Sonke, Jeroen E., Speich, Sabrina, Steinfeldt, Reiner, Stewart, Gillian, Stichel, Torben, Stirling, Claudine H., Stutsman, Johnny, Swarr, Gretchen J., Swift, James H., Thomas, Alexander, Thorne, Kay, Till, Claire P., Till, Ralph, Townsend, Ashley T., Townsend, Emily, Tuerena, Robyn, Twining, Benjamin S., Vance, Derek, Velazquez, Sue, Venchiarutti, Celia, Villa-Alfageme, Maria, Vivancos, Sebastian M., Voelker, Antje H.L., Wake, Bronwyn, Warner, Mark J., Watson, Ros, van Weerlee, Evaline, Alexandra Weigand, M., Weinstein, Yishai, Weiss, Dominik, Wisotzki, Andreas, Woodward, E. Malcolm S., Wu, Jingfeng, Wu, Yingzhe, Wuttig, Kathrin, Wyatt, Neil, Xiang, Yang, Xie, Ruifang C., Xue, Zichen, Yoshikawa, Hisayuki, Zhang, Jing, Zhang, Pu, Zhao, Ye, Zheng, Linjie, Zheng, Xin-Yuan, Zieringer, Moritz, Zimmer, Louise A., Ziveri, Patrizia, Zunino, Patricia, and Zurbrick, Cheryl

Published
2018
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9. The Eurasian Arctic Ocean along the MOSAiC drift (2019-2020): An interdisciplinary perspective on properties and processes

Author

Schulz, Kirstin, primary, Koenig, Zoe, additional, Muilwijk, Morven, additional, Bauch, Dorothea, additional, Hoppe, Clara J. M., additional, Droste, Elise, additional, Hoppmann, Mario, additional, Chamberlain, Emelia J., additional, Laukert, Georgi, additional, Stanton, Tim, additional, Quintanilla Zurita, Alejandra, additional, Fer, Ilker, additional, Heuzé, Céline, additional, Karam, Salar, additional, Mieruch-Schnuelle, Sebastian, additional, Baumann, Till, additional, Vredenborg, Myriel, additional, Tippenhauer, Sandra, additional, and Granskog, Mats A., additional

Published
2023
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11. 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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12. 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

13. Stable oxygen isotopes from the MOSAIC expedition show vertical and horizontal variability of sea-ice and river water signals in the upper Arctic Ocean during winter 

Author

Bauch, Dorothea, primary, Andersen, Nils, additional, Damm, Ellen, additional, D'Angelo, Alessandra, additional, Fang, Ying-chih, additional, Kuznetsov, Ivan, additional, Laukert, Georgi, additional, Mellat, Moein, additional, Meyer, Hanno, additional, Rabe, Benjamin, additional, Schaffer, Janin, additional, Schulz, Kirstin, additional, Tippenhauer, Sandra, additional, and Vredenborg, Myriel, additional

Published
2023
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14. 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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15. Spatial Complexity in Dissolved Organic Matter and Trace Elements Driven by Hydrography and Freshwater Input Across the Arctic Ocean During 2015 Arctic GEOTRACES Expeditions

Author

Williford, Tatiana, primary, Amon, Rainer M. W., additional, Kaiser, Karl, additional, Benner, Ronald, additional, Stedmon, Colin, additional, Bauch, Dorothea, additional, Fitzsimmons, Jessica N., additional, Gerringa, Loes J. A., additional, Newton, Robert, additional, Hansell, Dennis A., additional, Granskog, Mats A., additional, Jensen, Laramie, additional, Laglera, Luis M., additional, Pasqualini, Angelica, additional, Rabe, Benjamin, additional, Reader, Heather, additional, Rutgers van der Loeff, Michiel, additional, and Yan, Ge, additional

Published
2022
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16. Deciphering the Properties of Different Arctic Ice Types During the Growth Phase of MOSAiC: Implications for Future Studies on Gas Pathways

Author

Angelopoulos, Michael, primary, Damm, Ellen, additional, Simões Pereira, Patric, additional, Abrahamsson, Katarina, additional, Bauch, Dorothea, additional, Bowman, Jeff, additional, Castellani, Giulia, additional, Creamean, Jessie, additional, Divine, Dmitry V., additional, Dumitrascu, Adela, additional, Fons, Steven W., additional, Granskog, Mats A., additional, Kolabutin, Nikolai, additional, Krumpen, Thomas, additional, Marsay, Chris, additional, Nicolaus, Marcel, additional, Oggier, Marc, additional, Rinke, Annette, additional, Sachs, Torsten, additional, Shimanchuk, Egor, additional, Stefels, Jacqueline, additional, Stephens, Mark, additional, Ulfsbo, Adam, additional, Verdugo, Josefa, additional, Wang, Lei, additional, Zhan, Liyang, additional, and Haas, Christian, additional

Published
2022
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17. Neodymium isotopes trace marine provenance of Arctic sea ice

Author

Laukert, Georgi, Peeken, I., Bauch, Dorothea, Krumpen, T., Hathorne, Ed C., Werner, K., Gutjahr, Marcus, and Frank, Martin

Subjects
Geochemistry and Petrology, Environmental Chemistry, Geology
Abstract

Radiogenic neodymium (Nd) isotopes (ɛNd) have the potential to serve as a geochemical tracer of the marine origin of Arctic sea ice. This capability results from pronounced ɛNd differences between the distinct marine and riverine sources, which feed the surface waters from which the ice forms. The first dissolved Nd isotope and rare earth element (REE) concentration data obtained from Arctic sea ice collected across the Fram Strait during RV Polarstern cruise PS85 in 2014 confirm the incorporation and preservation of the parental surface seawater ɛNd signatures despite efficient REE rejection. The large ɛNd variability between ice floes and within sea ice cores (−32 to −10) reflects changes in water mass distribution during ice growth and drift from the central Arctic Ocean to Fram Strait. In addition to the parental seawater composition, our new approach facilitates the reconstruction of the transfer of matter between the atmosphere, the sea ice and the ocean. In conjunction with satellite-derived drift trajectories, we enable a more accurate assessment of sea ice origin and spatiotemporal evolution, benefiting studies of sea ice biology, biodiversity, and biogeochemistry.

Published
2022

18. Strong Margin Influence on the Arctic Ocean Barium Cycle Revealed by Pan‐Arctic Synthesis

Author

Whitmore, Laura M., Shiller, Alan M., Horner, Tristan J., Xiang, Yang, Auro, Maureen E., Bauch, Dorothea, Dehairs, Frank, Lam, Phoebe J., Li, Jingxuan, Maldonado, Maria T., Mears, Chantal, Newton, Robert, Pasqualini, Angelica, Planquette, Hélène, Rember, Robert, Thomas, Helmuth, Whitmore, Laura M., Shiller, Alan M., Horner, Tristan J., Xiang, Yang, Auro, Maureen E., Bauch, Dorothea, Dehairs, Frank, Lam, Phoebe J., Li, Jingxuan, Maldonado, Maria T., Mears, Chantal, Newton, Robert, Pasqualini, Angelica, Planquette, Hélène, Rember, Robert, and Thomas, Helmuth

Published
2022
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20. Overview of the MOSAiC expedition: Physical oceanography

Author

Rabe, Benjamin, Heuzé, Céline, Regnery, Julia, Aksenov, Yevgeny, Allerholt, Jacob, Athanase, Marylou, Bai, Youcheng, Basque, Chris, Bauch, Dorothea, Baumann, Till M., Chen, Dake, Cole, Sylvia T., Craw, Lisa, Davies, Andrew, Damm, Ellen, Dethloff, Klaus, Divine, Dmitry V., Doglioni, Francesca, Ebert, Falk, Fang, Ying-Chih, Fer, Ilker, Fong, Allison A., Gradinger, Rolf, Granskog, Mats A., Graupner, Rainer, Haas, Christian, He, Hailun, He, Yan, Hoppmann, Mario, Janout, Markus, Kadko, David, Kanzow, Torsten, Karam, Salar, Kawaguchi, Yusuke, Koenig, Zoe, Kong, Bin, Krishfield, Richard A., Krumpen, Thomas, Kuhlmey, David, Kuznetsov, Ivan, Lan, Musheng, Laukert, Georgi, Lei, Ruibo, Li, Tao, Torres-Valdés, Sinhué, Lin, Lina, Lin, Long, Liu, Hailong, Liu, Na, Loose, Brice, Ma, Xiaobing, McKay, Rosalie, Mallet, Maria, Mallett, Robbie D. C., Maslowski, Wieslaw, Mertens, Christian, Mohrholz, Volker, Muilwijk, Morven, Nicolaus, Marcel, O’Brien, Jeffrey K., Perovich, Donald, Ren, Jian, Rex, Markus, Ribeiro, Natalia, Rinke, Annette, Schaffer, Janin, Schuffenhauer, Ingo, Schulz, Kirstin, Shupe, Matthew D., Shaw, William, Sokolov, Vladimir, Sommerfeld, Anja, Spreen, Gunnar, Stanton, Timothy, Stephens, Mark, Su, Jie, Sukhikh, Natalia, Sundfjord, Arild, Thomisch, Karolin, Tippenhauer, Sandra, Toole, John M., Vredenborg, Myriel, Walter, Maren, Wang, Hangzhou, Wang, Lei, Wang, Yuntao, Wendisch, Manfred, Zhao, Jinping, Zhou, Meng, Zhu, Jialiang, Rabe, Benjamin, Heuzé, Céline, Regnery, Julia, Aksenov, Yevgeny, Allerholt, Jacob, Athanase, Marylou, Bai, Youcheng, Basque, Chris, Bauch, Dorothea, Baumann, Till M., Chen, Dake, Cole, Sylvia T., Craw, Lisa, Davies, Andrew, Damm, Ellen, Dethloff, Klaus, Divine, Dmitry V., Doglioni, Francesca, Ebert, Falk, Fang, Ying-Chih, Fer, Ilker, Fong, Allison A., Gradinger, Rolf, Granskog, Mats A., Graupner, Rainer, Haas, Christian, He, Hailun, He, Yan, Hoppmann, Mario, Janout, Markus, Kadko, David, Kanzow, Torsten, Karam, Salar, Kawaguchi, Yusuke, Koenig, Zoe, Kong, Bin, Krishfield, Richard A., Krumpen, Thomas, Kuhlmey, David, Kuznetsov, Ivan, Lan, Musheng, Laukert, Georgi, Lei, Ruibo, Li, Tao, Torres-Valdés, Sinhué, Lin, Lina, Lin, Long, Liu, Hailong, Liu, Na, Loose, Brice, Ma, Xiaobing, McKay, Rosalie, Mallet, Maria, Mallett, Robbie D. C., Maslowski, Wieslaw, Mertens, Christian, Mohrholz, Volker, Muilwijk, Morven, Nicolaus, Marcel, O’Brien, Jeffrey K., Perovich, Donald, Ren, Jian, Rex, Markus, Ribeiro, Natalia, Rinke, Annette, Schaffer, Janin, Schuffenhauer, Ingo, Schulz, Kirstin, Shupe, Matthew D., Shaw, William, Sokolov, Vladimir, Sommerfeld, Anja, Spreen, Gunnar, Stanton, Timothy, Stephens, Mark, Su, Jie, Sukhikh, Natalia, Sundfjord, Arild, Thomisch, Karolin, Tippenhauer, Sandra, Toole, John M., Vredenborg, Myriel, Walter, Maren, Wang, Hangzhou, Wang, Lei, Wang, Yuntao, Wendisch, Manfred, Zhao, Jinping, Zhou, Meng, and Zhu, Jialiang

Abstract

Arctic Ocean properties and processes are highly relevant to the regional and global coupled climate system, yet still scarcely observed, especially in winter. Team OCEAN conducted a full year of physical oceanography observations as part of the Multidisciplinary drifting Observatory for the Study of the Arctic Climate (MOSAiC), a drift with the Arctic sea ice from October 2019 to September 2020. An international team designed and implemented the program to characterize the Arctic Ocean system in unprecedented detail, from the seafloor to the air-sea ice-ocean interface, from sub-mesoscales to pan-Arctic. The oceanographic measurements were coordinated with the other teams to explore the ocean physics and linkages to the climate and ecosystem. This paper introduces the major components of the physical oceanography program and complements the other team overviews of the MOSAiC observational program. Team OCEAN’s sampling strategy was designed around hydrographic ship-, ice- and autonomous platform-based measurements to improve the understanding of regional circulation and mixing processes. Measurements were carried out both routinely, with a regular schedule, and in response to storms or opening leads. Here we present alongdrift time series of hydrographic properties, allowing insights into the seasonal and regional evolution of the water column from winter in the Laptev Sea to early summer in Fram Strait: freshening of the surface, deepening of the mixed layer, increase in temperature and salinity of the Atlantic Water. We also highlight the presence of Canada Basin deep water intrusions and a surface meltwater layer in leads. MOSAiC most likely was the most comprehensive program ever conducted over the ice-covered Arctic Ocean. While data analysis and interpretation are ongoing, the acquired datasets will support a wide range of physical oceanography and multi-disciplinary research. They will provide a significant foundation for assessing and advancing modeling cap

Published
2022

21. Deciphering the Properties of Different Arctic Ice Types During the Growth Phase of MOSAiC: Implications for Future Studies on Gas Pathways

Author

Angelopoulos, Michael, Damm, Ellen, Simões Pereira, Patric, Abrahamsson, Katarina, Bauch, Dorothea, Bowman, Jeff, Castellani, Giulia, Creamean, Jessie, Divine, Dmitry V., Dumitrascu, Adela, Fons, Steven W., Granskog, Mats A., Kolabutin, Nikolai, Krumpen, Thomas, Marsay, Chris, Nicolaus, Marcel, Oggier, Marc, Rinke, Annette, Sachs, Torsten, Shimanchuk, Egor, Stefels, Jacqueline, Stephens, Mark, Ulfsbo, Adam, Verdugo, Josefa, Wang, Lei, Zhan, Liyang, Haas, Christian, Angelopoulos, Michael, Damm, Ellen, Simões Pereira, Patric, Abrahamsson, Katarina, Bauch, Dorothea, Bowman, Jeff, Castellani, Giulia, Creamean, Jessie, Divine, Dmitry V., Dumitrascu, Adela, Fons, Steven W., Granskog, Mats A., Kolabutin, Nikolai, Krumpen, Thomas, Marsay, Chris, Nicolaus, Marcel, Oggier, Marc, Rinke, Annette, Sachs, Torsten, Shimanchuk, Egor, Stefels, Jacqueline, Stephens, Mark, Ulfsbo, Adam, Verdugo, Josefa, Wang, Lei, Zhan, Liyang, and Haas, Christian

Abstract

The increased fraction of first year ice (FYI) at the expense of old ice (second-year ice (SYI) and multi-year ice (MYI)) likely affects the permeability of the Arctic ice cover. This in turn influences the pathways of gases circulating therein and the exchange at interfaces with the atmosphere and ocean. We present sea ice temperature and salinity time series from different ice types relevant to temporal development of sea ice permeability and brine drainage efficiency from freeze-up in October to the onset of spring warming in May. Our study is based on a dataset collected during the Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC) Expedition in 2019 and 2020. These physical properties were used to derive sea ice permeability and Rayleigh numbers. The main sites included FYI and SYI. The latter was composed of an upper layer of residual ice that had desalinated but survived the previous summer melt and became SYI. Below this ice a layer of new first-year ice formed. As the layer of new first-year ice has no direct contact with the atmosphere, we call it insulated first-year ice (IFYI). The residual/SYI-layer also contained refrozen melt ponds in some areas. During the freezing season, the residual/SYI-layer was consistently impermeable, acting as barrier for gas exchange between the atmosphere and ocean. While both FYI and SYI temperatures responded similarly to atmospheric warming events, SYI was more resilient to brine volume fraction changes because of its low salinity (< 2). Furthermore, later bottom ice growth during spring warming was observed for SYI in comparison to FYI. The projected increase in the fraction of more permeable FYI in autumn and spring in the coming decades may favor gas exchange at the atmosphere-ice interface when sea ice acts as a source relative to the atmosphere. While the areal extent of old ice is decreasing, so is its thickness at the onset of freeze-up. Our study sets the foundation for studies on gas

Published
2022
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22. Spatial complexity in dissolved organic matter and trace elements driven by hydrography and freshwater input across the Arctic Ocean during 2015 Arctic GEOTRACES expeditions

Author

Williford, Tatiana, Amon, Rainer M.W., Kaiser, Karl, Benner, Ronald, Stedmon, Colin, Bauch, Dorothea, Fitzsimmons, Jessica N., Gerringa, Loes J.A., Newton, Robert, Hansell, Dennis A., Granskog, Mats A., Jensen, Laramie, Laglera, Luis M., Pasqualini, Angelica, Rabe, Benjamin, Reader, Heather, van der Rutgers Loeff, Michiel, Yan, Ge, Williford, Tatiana, Amon, Rainer M.W., Kaiser, Karl, Benner, Ronald, Stedmon, Colin, Bauch, Dorothea, Fitzsimmons, Jessica N., Gerringa, Loes J.A., Newton, Robert, Hansell, Dennis A., Granskog, Mats A., Jensen, Laramie, Laglera, Luis M., Pasqualini, Angelica, Rabe, Benjamin, Reader, Heather, van der Rutgers Loeff, Michiel, and Yan, Ge

Abstract

This study traces dissolved organic matter (DOM) in different water masses of the Arctic Ocean and its effect on the distributions of trace elements (TEs; Fe, Cu, Mn, Ni, Zn, Cd) using fluorescent properties of DOM and the terrigenous biomarker lignin. The Nansen, Amundsen, and Makarov Basins were characterized by the influence of Atlantic water and the fluvial discharge of the Siberian rivers with high concentrations of terrigenous DOM (tDOM). The Canada Basin and the Chukchi Sea were characterized by Pacific water, modified through contact with productive shelf sediments with elevated levels of marine DOM. Within the surface layer of the Beaufort Gyre, meteoric water (river water and precipitation) was characterized by low concentrations of lignin and terrigenous DOM fluorescence proxies as DOM is removed during freezing. High-resolution in situ fluorescence profiles revealed that DOM distribution closely followed isopycnals, indicating the strong influence of sea-ice formation and melt, which was also reflected in strong correlations between DOM fluorescence and brine contributions. The relationship of DOM and hydrography to TEs showed that terrigenous and marine DOM were likely carriers of dissolved Fe, Ni, Cu from the Eurasian shelves into the central Arctic Ocean. Chukchi shelf sediments were important sources of dCd, dZn, and dNi, as well as marine ligands that bind and carry these TEs offshore within the upper halocline (UHC) in the Canada Basin. Our data suggest that tDOM components represent stronger ligands relative to marine DOM components, potentially facilitating the long-range transport of TE to the North Atlantic. Key Points Dissolved Organic Matter (DOM) distribution in the Arctic Ocean is largely controlled by sea ice formation and melt processes DOM distribution in the Arctic Ocean reveals its potential as a tracer for halocline formation and freshwater source assignments Terrigenous and marine DOM are carriers of trace elements from shelves to th

Published
2022
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23. A Refinement of the Processes Controlling Dissolved Copper and Nickel Biogeochemistry: Insights From the Pan‐Arctic

Author

Jensen, Laramie T., Cullen, Jay T., Jackson, Sarah L., Gerringa, Loes J. A., Bauch, Dorothea, Middag, Rob, Sherrell, Robert M., Fitzsimmons, Jessica N., Jensen, Laramie T., Cullen, Jay T., Jackson, Sarah L., Gerringa, Loes J. A., Bauch, Dorothea, Middag, Rob, Sherrell, Robert M., and Fitzsimmons, Jessica N.

Abstract

Recent studies, including many from the GEOTRACES program, have expanded our knowledge of trace metals in the Arctic Ocean, an isolated ocean dominated by continental shelf and riverine inputs. Here, we report a unique, pan-Arctic linear relationship between dissolved copper (Cu) and nickel (Ni) present north of 60°N that is absent in other oceans. The correlation is driven primarily by high Cu and Ni concentrations in the low salinity, river-influenced surface Arctic and low, homogeneous concentrations in Arctic deep waters, opposing their typical global distributions. Rivers are a major source of both metals, which is most evident within the central Arctic's Transpolar Drift. Local decoupling of the linear Cu-Ni relationship along the Chukchi Shelf and within the Canada Basin upper halocline reveals that Ni is additionally modified by biological cycling and shelf sediment processes, while Cu is mostly sourced from riverine inputs and influenced by mixing. This observation highlights differences in their chemistries: Cu is more prone to complexation with organic ligands, stabilizing its riverine source fluxes into the Arctic, while Ni is more labile and is dominated by biological processes. Within the Canadian Arctic Archipelago, an important source of Arctic water to the Atlantic Ocean, contributions of Cu and Ni from meteoric waters and the halocline are attenuated during transit to the Atlantic. Additionally, Cu and Ni in deep waters diminish with age due to isolation from surface sources, with higher concentrations in the younger Eastern Arctic basins and lower concentrations in the older Western Arctic basins.

Published
2022
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24. The Transpolar Drift as a Source of Riverine and Shelf‐Derived Trace Elements to the Central Arctic Ocean

Author

Massachusetts Institute of Technology. Center for Global Change Science, Charette, Matthew A., Kipp, Lauren E., Jensen, Laramie T., Dabrowski, Jessica S., Whitmore, Laura M., Fitzsimmons, Jessica N., Williford, Tatiana, Ulfsbo, Adam, Jones, Elizabeth, Bundy, Randelle M., Vivancos, Sebastian M., Pahnke, Katharina, John, Seth G., Xiang, Yang, Hatta, Mariko, Petrova, Mariia V., Heimbürger‐Boavida, Lars‐Eric, Bauch, Dorothea, Newton, Robert, Pasqualini, Angelica, Agather, Alison M., Amon, Rainer M. W., Anderson, Robert F., Andersson, Per S., Benner, Ronald, Bowman, Katlin L., Edwards, R. Lawrence, Gdaniec, Sandra, Gerringa, Loes J. A., González, Aridane G., Granskog, Mats, Haley, Brian, Hammerschmidt, Chad R., Hansell, Dennis A., Henderson, Paul B., Kadko, David C., Kaiser, Karl, Laan, Patrick, Lam, Phoebe J., Lamborg, Carl H., Levier, Martin, Li, Xianglei, Margolin, Andrew R., Measures, Chris, Middag, Rob, Millero, Frank J., Moore, Willard S., Paffrath, Ronja, Planquette, Hélène, Rabe, Benjamin, Reader, Heather, Rember, Robert, Rijkenberg, Micha J. A., Roy‐Barman, Matthieu, Rutgers van der Loeff, Michiel, Saito, Mak, Schauer, Ursula, Schlosser, Peter, Sherrell, Robert M., Shiller, Alan M., Slagter, Hans, Sonke, Jeroen E., Stedmon, Colin, Woosley, Ryan J., Valk, Ole, Ooijen, Jan, Zhang, Ruifeng, Massachusetts Institute of Technology. Center for Global Change Science, Charette, Matthew A., Kipp, Lauren E., Jensen, Laramie T., Dabrowski, Jessica S., Whitmore, Laura M., Fitzsimmons, Jessica N., Williford, Tatiana, Ulfsbo, Adam, Jones, Elizabeth, Bundy, Randelle M., Vivancos, Sebastian M., Pahnke, Katharina, John, Seth G., Xiang, Yang, Hatta, Mariko, Petrova, Mariia V., Heimbürger‐Boavida, Lars‐Eric, Bauch, Dorothea, Newton, Robert, Pasqualini, Angelica, Agather, Alison M., Amon, Rainer M. W., Anderson, Robert F., Andersson, Per S., Benner, Ronald, Bowman, Katlin L., Edwards, R. Lawrence, Gdaniec, Sandra, Gerringa, Loes J. A., González, Aridane G., Granskog, Mats, Haley, Brian, Hammerschmidt, Chad R., Hansell, Dennis A., Henderson, Paul B., Kadko, David C., Kaiser, Karl, Laan, Patrick, Lam, Phoebe J., Lamborg, Carl H., Levier, Martin, Li, Xianglei, Margolin, Andrew R., Measures, Chris, Middag, Rob, Millero, Frank J., Moore, Willard S., Paffrath, Ronja, Planquette, Hélène, Rabe, Benjamin, Reader, Heather, Rember, Robert, Rijkenberg, Micha J. A., Roy‐Barman, Matthieu, Rutgers van der Loeff, Michiel, Saito, Mak, Schauer, Ursula, Schlosser, Peter, Sherrell, Robert M., Shiller, Alan M., Slagter, Hans, Sonke, Jeroen E., Stedmon, Colin, Woosley, Ryan J., Valk, Ole, Ooijen, Jan, and Zhang, Ruifeng

Published
2022

29. Isotopic traits of the Arctic water cycle

Author

Mellat, Moein, Werner, Martin, Brunello, Camilla F., Bauch, Dorothea, Damm, Ellen, Angelopoulos, Michael, Nomura, Daiki, Welker, Jeffrey, Schneebeli, Martin, Granskog, Mats A., D'Angelo, Alessandra, Hoerhold, Maria, Arndt, Stefanie, and Meyer, Hanno

Abstract

The Arctic hydrological cycle undergoes rapid and pronounced changes, including alterations in oceanic and atmospheric circulations, and precipitation patterns. Stable water isotopes (δ18O, δ2H, d-excess) can be used to trace these processes including their potential to feedback into the global climate system. The MOSAiC expedition provided a unique opportunity to collect, analyze, and synthesize discrete samples of the different hydrological compartments in the central Arctic, comprising sea ice, seawater, snow, and melt ponds. Here, we present spatio-temporal variations in the isotopic signatures of more than 1,000 water samples. We found that (i) average seawater δ18O of -1.7‰ conforms to observed and modelled isotopic traits of the Arctic Ocean; (ii) second year ice is relatively depleted compared to first year ice with average δ18O values of -3.1‰ and -0.7‰, respectively. This might be due to post-depositional exchange processes with snow, which has the most depleted isotopic signature among all compartments (mean δ18O=-15.1‰). Our dataset provides an unprecedented description of the present-day isotopic composition of the Arctic water covering a complete seasonal cycle. This will ultimately contribute to resolve the linkages between sea ice, ocean, and atmosphere during critical transitions from frozen ocean to open water conditions.

Published
2022

30. AUTOBIOGRAPHICAL SKETCHES OF WOMEN IN OCEANOGRAPHY

Author

Delaney, Peggy, Abrantes, Fatima, Alexander, Vera, Alldredge, Alice L., Almogi-Labin, Ahuva, Alonso, Belén, Anand, Pallavi, Ates, Sibel Bargu, Bauch, Dorothea, Bell, Robin E., Benitez-Nelson, Claudia, Benoit-Bird, Kelly, Bergamaschi, Dorothy Eden, Bernhard, Joan M., Billups, Katharina, Bronk, Deborah A., Campbell, Lisa, Canuel, Elizabeth A., Carbotte, Suzanne, Cessi, Paola, Chang, Grace C., Chase, Zanna, Chereskin, Teresa, Chiba, Sanae, Chisholm, Penny, Christeson, Gail, Cita, Maria Bianca, Class, Cornelia, Coble, Paula, Conte, Maureen, Cooke, Penelope, Cormier, Marie-Helene, Crane, Kathleen, Daly, Kendra L., Darling, Kate, de Angelis, Marie, De La Rocha, Christina, Demopoulos, Amanda W.J., Dierssen, Heidi, Druffel, Ellen R.M., Edmonds, Henrietta N., Edwards, Margo, Erba, Elisabetta, Ercilla, Gemma, Escutia, Carlota, Estrada, Marta, Falkner, Kelly Kenison, Fine, Rana A., Frank, Tracy D., Gardner, Joan M., Gargett, Ann, Garzoli, Silvia L., Gibson, Deidre M., Gillis, Kathryn, Gilbert, Patricia M., Goffredi, Shana K., Greengrove, Cheryl, Hall, Julie, Muller, Pamela Hallock, Hamme, Roberta C., Harada, Naomi, Harwood, Lois, Haymon, Rachel M., Heywood, Karen J., Hickey, Barbara M., Hill, Tessa M., Hooft, Emilie, Hummon, Julia M., Humphris, Susan E., Hutchinson, Deborah R., Ingalls, Anitra E., Isern, Alexandra R., Johns, Elizabeth, Joseph, Leah H., Joye, Samantha (Mandy), Kappel, Ellen S., Karp-Boss, Lee, Karsten, Jill, Kastner, Miriam, Kelley, Deborah S., Kim, Stacy, Klein, Emily M., Kominz, Michelle, Lange, Carina B., Lavín, Alicia M., Lavoie, Dawn, Leinen, Margaret S., Levin, Lisa A., Liepert, Beate, Lightsom, Frances, Lozier, M. Susan, Lynch-Stieglitz, Jean, Manley, Patricia Lee, Marcus, Nancy, Martin, Ellen E., Martini, Marinna, Matrai, Patricia A., McAndrew, Patricia, McClean, Julie, McGregor, Bonnie A., McHugh, Cecilia, McLaughlin, Fiona, McNutt, Marcia, McPhee-Shaw, Erika E., Mills, Rachel A., Moran, Kathryn, Mulholland, Margaret R., Muller-Parker, Gisèle, Mullineaux, Lauren, Neil, Helen, Noble, Marlene, O'Connell, Suzanne, Oppo, Delia, Orellana, Mónica V., Özkan-Haller, Tuba, Pascual, Mercedes, Passow, Uta, Paytan, Adina, Pilskaln, Cindy, Pyrtle, Ashanti J., Raffi, Isabella, Ravelo, Christina, Raymo, Maureen, Reguera, Beatriz, Reimers, Clare E., Reysenbach, Anna-Louise, Richardson, Mary Jo, Rickaby, Rosalind E.M., Rii, Shimi, Malanotte-Rizzoli, Paola, Robertson, Robin, Robinson, Rebecca, Rosenfeld, Leslie, Ross, Robin M., Ruppel, Carolyn, Russell, Ann D., Sabatés, Ana, Schwager, Katherine B., Scranton, Mary, Sherr, Evelyn B., Silver, Mary, Sloyan, Bernadette M., Smith, Deborah K., Sosik, Heidi M., Spitz, Yvette H., Stakes, Debra S., Stathoplos, Linda, Steinberg, Deborah K., Szmant, Alina M., Tachikawa, Kazuyo, Talaue-McManus, Liana, Talley, Lynne D., Tauxe, Lisa, Tester, Patricia A., Thomas, Debbie, Thomas, Ellen, Tolstoy, Maya, Torres, Marta E., Tréhu, Anne, Van Dover, Cindy Lee, Vlahos, Penny, Von Damm, Karen L., Wade, Bridget, Ward, Bess B., Wheeler, Patricia A., Whelan, Jean, White, Lisa D., Whitman, Jill M., Winckler, Gisela, Wishner, Karen F., Wright, Dawn, Wright, Elizabeth, Yalçin-Özdilek, Şükran, Yen, Jeannette, Yuan, Xiaojun, Zingone, Adriana, and Ziveri, Patrizia

Published
2005

31. Strong Margin Influence on the Arctic Ocean Barium Cycle Revealed by Pan‐Arctic Synthesis

Author

Whitmore, Laura M., primary, Shiller, Alan M., additional, Horner, Tristan J., additional, Xiang, Yang, additional, Auro, Maureen E., additional, Bauch, Dorothea, additional, Dehairs, Frank, additional, Lam, Phoebe J., additional, Li, Jingxuan, additional, Maldonado, Maria T., additional, Mears, Chantal, additional, Newton, Robert, additional, Pasqualini, Angelica, additional, Planquette, Hélène, additional, Rember, Robert, additional, and Thomas, Helmuth, additional

Published
2022
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33. Overview of the MOSAiC expedition: Physical oceanography

Author

Rabe, Benjamin, primary, Heuzé, Céline, additional, Regnery, Julia, additional, Aksenov, Yevgeny, additional, Allerholt, Jacob, additional, Athanase, Marylou, additional, Bai, Youcheng, additional, Basque, Chris, additional, Bauch, Dorothea, additional, Baumann, Till M., additional, Chen, Dake, additional, Cole, Sylvia T., additional, Craw, Lisa, additional, Davies, Andrew, additional, Damm, Ellen, additional, Dethloff, Klaus, additional, Divine, Dmitry V., additional, Doglioni, Francesca, additional, Ebert, Falk, additional, Fang, Ying-Chih, additional, Fer, Ilker, additional, Fong, Allison A., additional, Gradinger, Rolf, additional, Granskog, Mats A., additional, Graupner, Rainer, additional, Haas, Christian, additional, He, Hailun, additional, He, Yan, additional, Hoppmann, Mario, additional, Janout, Markus, additional, Kadko, David, additional, Kanzow, Torsten, additional, Karam, Salar, additional, Kawaguchi, Yusuke, additional, Koenig, Zoe, additional, Kong, Bin, additional, Krishfield, Richard A., additional, Krumpen, Thomas, additional, Kuhlmey, David, additional, Kuznetsov, Ivan, additional, Lan, Musheng, additional, Laukert, Georgi, additional, Lei, Ruibo, additional, Li, Tao, additional, Torres-Valdés, Sinhué, additional, Lin, Lina, additional, Lin, Long, additional, Liu, Hailong, additional, Liu, Na, additional, Loose, Brice, additional, Ma, Xiaobing, additional, McKay, Rosalie, additional, Mallet, Maria, additional, Mallett, Robbie D. C., additional, Maslowski, Wieslaw, additional, Mertens, Christian, additional, Mohrholz, Volker, additional, Muilwijk, Morven, additional, Nicolaus, Marcel, additional, O’Brien, Jeffrey K., additional, Perovich, Donald, additional, Ren, Jian, additional, Rex, Markus, additional, Ribeiro, Natalia, additional, Rinke, Annette, additional, Schaffer, Janin, additional, Schuffenhauer, Ingo, additional, Schulz, Kirstin, additional, Shupe, Matthew D., additional, Shaw, William, additional, Sokolov, Vladimir, additional, Sommerfeld, Anja, additional, Spreen, Gunnar, additional, Stanton, Timothy, additional, Stephens, Mark, additional, Su, Jie, additional, Sukhikh, Natalia, additional, Sundfjord, Arild, additional, Thomisch, Karolin, additional, Tippenhauer, Sandra, additional, Toole, John M., additional, Vredenborg, Myriel, additional, Walter, Maren, additional, Wang, Hangzhou, additional, Wang, Lei, additional, Wang, Yuntao, additional, Wendisch, Manfred, additional, Zhao, Jinping, additional, Zhou, Meng, additional, and Zhu, Jialiang, additional

Published
2022
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36. Changes of water isotopes in Arctic Sea ice, Ocean and atMosphere (CiASOM)

Author

Mellat, Moein, Brunello, Camilla F., Werner, Martin, Bauch, Dorothea, Damm, Ellen, Nomura, Daiki, D'Angelo, Alessandra, and Meyer, Hanno

Abstract

The Arctic water cycle is changing dramatically as evidenced by marked shifts in Arctic sea ice conditions, atmospheric processes, and hydrological regimes. Evaporation from the increasingly ice-free Arctic ocean causes moistening of the atmosphere and serves as an unprecedented water source for the Northern Hemisphere. Stable water isotopes (δ18O, δ2H, d-excess) can be used to trace exchange processes between ocean and atmosphere including their potential to feedback into the global climate system. The MOSAiC expedition provided a unique opportunity to collect, analyze, and synthesize discrete samples of the different hydrological compartments in the central Arctic, comprising sea ice, seawater, snow, and melt ponds. Moreover, we present observations of atmospheric humidity, δ18O, δ2H, and d-excess, obtained from a cavity-ring-down spectrometer installed on RV Polarstern and operated continuously during the MOSAiC expedition. By analyzing discrete samples, we found that average seawater δ18O of -1.7±1.95‰ (n=126) conforms to observed and modelled isotopic traits of the Arctic Ocean. Second year ice is relatively depleted compared to first year ice with average δ18O values of -3.1±2.81‰ (n=397) and -0.7±2.28‰ (n=409), respectively. Snow on top of the sea ice (n=303) has the most depleted isotopic signature among all compartments shaping the Arctic water cycle (mean δ18O=-15.3±7.12‰) The atmospheric water vapour dataset reveals a clear seasonal cycle; significant positive correlations are found both with local specific humidity and air temperature. The comparison of synoptic events, characterized by abrupt isotopic fluctuations, with simultaneous observations from land-based Arctic stations indicates a strong influence of sea ice coverage on the isotopic signal. For an in-depth understanding of the isotopic changes, the observations are compared to an isotope-enhanced ECHAM6 atmosphere simulation. The model-data comparison assesses the capability of this state-of-the-art AGCM to capture the first-order evaporation/condensation processes and their seasonal evolution. Our dataset provides a comprehensive description of the present-day isotopic composition of the Arctic water covering a complete seasonal cycle. This will ultimately contribute to resolve the linkages between sea ice, ocean, and atmosphere during critical transitions from frozen ocean to open water conditions.

Published
2021

37. Insights into Water Mass Origins in the Central Arctic Ocean from in-situ Dissolved Organic Matter Fluorescence.

Author

Stedmon, Colin A, primary, Amon, Rainer M. W., additional, Bauch, Dorothea, additional, Bracher, Astrid, additional, Gonçalves-Araujo, Rafael, additional, Hoppmann, Mario, additional, Krishfield, Richard A., additional, Laney, Samuel, additional, Rabe, Benjamin, additional, Reader, Heather E, additional, and Granskog, Mats Anders, additional

Published
2021
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38. Insights Into Water Mass Origins in the Central Arctic Ocean From In‐Situ Dissolved Organic Matter Fluorescence

Author

Stedmon, Colin A., primary, Amon, Rainer M. W., additional, Bauch, Dorothea, additional, Bracher, Astrid, additional, Gonçalves‐Araujo, Rafael, additional, Hoppmann, Mario, additional, Krishfield, Richard, additional, Laney, Samuel, additional, Rabe, Benjamin, additional, Reader, Heather, additional, and Granskog, Mats A., additional

Published
2021
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39. Dissolved Cd, Co, Cu, Fe, Mn, Ni and Zn in the Arctic Ocean

Author

Gerringa, L. J. A., Rijkenberg, M. J. A., Slagter, H. A., Laan, P., Paffrath, R., Bauch, Dorothea, Rutgers van der Loeff, M., Middag, R., Gerringa, L. J. A., Rijkenberg, M. J. A., Slagter, H. A., Laan, P., Paffrath, R., Bauch, Dorothea, Rutgers van der Loeff, M., and Middag, R.

Published
2021
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40. The impact of land-fast ice on the distribution of terrestrial dissolved organic matter in the Siberian Arctic shelf seas

Author

Hölemann, Jens A., Juhls, Bennet, Bauch, Dorothea, Janout, Markus, Koch, Boris P., Heim, Birgit, Hölemann, Jens A., Juhls, Bennet, Bauch, Dorothea, Janout, Markus, Koch, Boris P., and Heim, Birgit

Abstract

Remobilization of soil carbon as a result of permafrost degradation in the drainage basin of the major Siberian rivers combined with higher precipitation in a warming climate potentially increase the flux of terrestrial derived dissolved organic matter (tDOM) into the Arctic Ocean. The Laptev (LS) and East Siberian Seas (ESS) receive enormous amounts of tDOM-rich river water, which undergoes at least one freeze-melt cycle in the Siberian Arctic shelf seas. To better understand how freezing and melting affect the tDOM dynamics in the LS and ESS, we sampled sea ice, river and seawater for their dissolved organic carbon (DOC) concentration and the colored fraction of dissolved organic matter. The sampling took place in different seasons over a period of 9 years (2010–2019). Our results suggest that the main factor regulating the tDOM distribution in the LS and ESS is the mixing of marine waters with freshwater sources carrying different tDOM concentrations. Of particular importance in this context are the 211 km3 of meltwater from land-fast ice from the LS, containing ~ 0.3 Tg DOC, which in spring mixes with 245 km3 of river water from the peak spring discharge of the Lena River, carrying ~ 2.4 Tg DOC into the LS. During the ice-free season, tDOM transport on the shelves takes place in the surface mixed layer, with the direction of transport depending on the prevailing wind direction. In winter, about 1.2 Tg of brine-related DOC, which was expelled from the growing land-fast ice in the LS, is transported in the near-surface water layer into the Transpolar Drift Stream that flows from the Siberian Shelf toward Greenland. The actual water depth in which the tDOM-rich brines are transported, depends mainly on the density stratification of the LS and ESS in the preceding summer and the amount of ice produced in winter. We suspect that climate change in the Arctic will fundamentally alter the dynamics of tDOM transport in the Arctic marginal seas, which will also have conse

Published
2021

41. Insights into Water Mass Origins in the Central Arctic Ocean from in‐situ Dissolved Organic Matter Fluorescence

Author

Stedmon, Colin A., Amon, Rainer M.W., Bauch, Dorothea, Bracher, Astrid, Gonçalves‐Araujo, Rafael, Hoppmann, Mario, Krishfield, Richard, Laney, Samuel, Rabe, Benjamin, Reader, Heather, Granskog, Mats A., Stedmon, Colin A., Amon, Rainer M.W., Bauch, Dorothea, Bracher, Astrid, Gonçalves‐Araujo, Rafael, Hoppmann, Mario, Krishfield, Richard, Laney, Samuel, Rabe, Benjamin, Reader, Heather, and Granskog, Mats A.

Abstract

The Arctic Ocean receives a large supply of dissolved organic matter (DOM) from its catchment and shelf sediments, which can be traced across much of the basin’s upper waters. This signature can potentially be used as a tracer. On the shelf, the combination of river discharge and sea-ice formation, modifies water densities and mixing considerably. These waters are a source of the halocline layer that covers much of the Arctic Ocean, but also contain elevated levels of DOM. Here we demonstrate how this can be used as a supplementary tracer and contribute to evaluating ocean circulation in the Arctic. A fraction of the organic compounds that DOM consists of fluoresce and can be measured using in-situ fluorometers. When deployed on autonomous platforms these provide high temporal and spatial resolution measurements over long periods. The results of an analysis of data derived from several Ice Tethered Profilers (ITPs) offer a unique spatial coverage of the distribution of DOM in the surface 800m below Arctic sea-ice. Water mass analysis using temperature, salinity and DOM fluorescence, can clearly distinguish between the contribution of Siberian terrestrial DOM and marine DOM from the Chukchi shelf to the waters of the halocline. The findings offer a new approach to trace the distribution of Pacific waters and its export from the Arctic Ocean. Our results indicate the potential to extend the approach to separate freshwater contributions from, sea-ice melt, riverine discharge and the Pacific Ocean. Key Points: Arctic surface waters with comparable temperature and salinity have contrasting in situ dissolved organic matter fluorescence. Organic matter fluorescence can tracklow salinity waters feeding into the Transpolar Drift and haloclinelayers. Siberian and Chukchishelf waters can be separated based on their fluorescence to salinity relationship

Published
2021
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42. Evolution of physical properties of sea ice for multiple ice types at the MOSAiC central floe and the distributed network

Author

Angelopoulos, Michael, Damm, Ellen, Simoes Pereira, Patric, Abrahamsson, Katarina, Bauch, Dorothea, Bowman, Jeff, Dumitrascu, Adela, Krumpen, Thomas, Marsay, Chris, Nomura, Daiki, Rinke, Annette, Stefels, Jacqueline, Sachs, Torsten, Stephens, Mark, Verdugo, Maria Josefa, Wang, Lei, Zhan, Liyang, Angelopoulos, Michael, Damm, Ellen, Simoes Pereira, Patric, Abrahamsson, Katarina, Bauch, Dorothea, Bowman, Jeff, Dumitrascu, Adela, Krumpen, Thomas, Marsay, Chris, Nomura, Daiki, Rinke, Annette, Stefels, Jacqueline, Sachs, Torsten, Stephens, Mark, Verdugo, Maria Josefa, Wang, Lei, and Zhan, Liyang

Published
2021

43. Sea ice permeability evolution on Arctic first and second-year ice on the drifting MOSAiC floe from autumn to spring

Author

Angelopoulos, Michael, Damm, Ellen, Simoes Pereira, Patric, Abrahamsson, Katarina, Bauch, Dorothea, Bowman, Jeff, Dumitrascu, Adela, Krumpen, Thomas, Marsay, Chris, Rinke, Annette, Stefels, Jacqueline, Sachs, Torsten, Stephens, Mark, Verdugo, Maria Josefa, Wang, Lei, Zhan, Liyang, Angelopoulos, Michael, Damm, Ellen, Simoes Pereira, Patric, Abrahamsson, Katarina, Bauch, Dorothea, Bowman, Jeff, Dumitrascu, Adela, Krumpen, Thomas, Marsay, Chris, Rinke, Annette, Stefels, Jacqueline, Sachs, Torsten, Stephens, Mark, Verdugo, Maria Josefa, Wang, Lei, and Zhan, Liyang

Published
2021

44. Spatial variability and evolution of sea ice permeability on the MOSAiC central floe from autumn to spring: Biogeochemistry research sites

Author

Angelopoulos, Michael, Damm, Ellen, Simoes Pereira, Patric, Abrahamsson, Katarina, Bauch, Dorothea, Bowman, Jeff, Dumitrascu, Adela, Krumpen, Thomas, Marsay, Chris, Oggier, Marc, Rinke, Annette, Stefels, Jacqueline, Sachs, Torsten, Stephens, Mark, Verdugo, Maria Josefa, Wang, Lei, Zhan, Liyang, Haas, Christian, Angelopoulos, Michael, Damm, Ellen, Simoes Pereira, Patric, Abrahamsson, Katarina, Bauch, Dorothea, Bowman, Jeff, Dumitrascu, Adela, Krumpen, Thomas, Marsay, Chris, Oggier, Marc, Rinke, Annette, Stefels, Jacqueline, Sachs, Torsten, Stephens, Mark, Verdugo, Maria Josefa, Wang, Lei, Zhan, Liyang, and Haas, Christian

Published
2021

46. Insights into water mass origins in the central Arctic Ocean from in-situ dissolved organic matter fluorescence

Author

Stedmon, Colin, Amon, Rainer M. W., Bauch, Dorothea, Bracher, Astrid, Gonçalves-Araujo, Rafael, Hoppmann, Mario, Krishfield, Richard A., Laney, Samuel R., Rabe, Benjamin, Reader, Heather, Granskog, Mats A., Stedmon, Colin, Amon, Rainer M. W., Bauch, Dorothea, Bracher, Astrid, Gonçalves-Araujo, Rafael, Hoppmann, Mario, Krishfield, Richard A., Laney, Samuel R., Rabe, Benjamin, Reader, Heather, and Granskog, Mats A.

Abstract

Author Posting. © American Geophysical Union, 2021. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research: Oceans 126(7), (2021): e2021JC017407, https://doi.org/10.1029/2021JC017407., The Arctic Ocean receives a large supply of dissolved organic matter (DOM) from its catchment and shelf sediments, which can be traced across much of the basin's upper waters. This signature can potentially be used as a tracer. On the shelf, the combination of river discharge and sea-ice formation, modifies water densities and mixing considerably. These waters are a source of the halocline layer that covers much of the Arctic Ocean, but also contain elevated levels of DOM. Here we demonstrate how this can be used as a supplementary tracer and contribute to evaluating ocean circulation in the Arctic. A fraction of the organic compounds that DOM consists of fluoresce and can be measured using in-situ fluorometers. When deployed on autonomous platforms these provide high temporal and spatial resolution measurements over long periods. The results of an analysis of data derived from several Ice Tethered Profilers (ITPs) offer a unique spatial coverage of the distribution of DOM in the surface 800 m below Arctic sea-ice. Water mass analysis using temperature, salinity and DOM fluorescence, can clearly distinguish between the contribution of Siberian terrestrial DOM and marine DOM from the Chukchi shelf to the waters of the halocline. The findings offer a new approach to trace the distribution of Pacific waters and its export from the Arctic Ocean. Our results indicate the potential to extend the approach to separate freshwater contributions from, sea-ice melt, riverine discharge and the Pacific Ocean., Danish Strategic Research Council for the NAACOS project (grant no. 10-093903), the Danish Center for Marine Research (grant no. 2012-01). C. A. S. has received funding from the Independent Research Fund Denmark Grant No. 9040-00266B. Funding for R.M.W.A. came from the US NSF, Arctic Natural Science program grant 1504469. RG-A has received funding from the European Union's Horizon 2020 research and innovation program under the Marie Skłodowska-Curie Grant Agreement No. 839311. ITP93 and part of the work by MH and BR were a contribution to the Helmholtz society strategic investment Frontiers in Arctic Marine monitoring (FRAM). The work of BR is a contribution to the cooperative projects Regional Atlantic Circulation and global Change (RACE) grant #03F0824E funded by the German Ministry of Science and Education (BBMF) and Advective Pathways of nutrients and key Ecological substances in the Arctic (APEAR) grants NE/R012865/1, NE/R012865/2 and #03V01461, part of the Changing Arctic Ocean program, jointly funded by the UKRI Natural Environment Research Council (NERC) and the BMBF. Support for Krishfield was made possible by grants from the NSF Arctic Observing Network program (PLR-1303644 and OPP-1756100)., 2021-12-27

Published
2021

48. Nutrient inputs, utilization and cycling in the Laptev Sea constrained by macronutrient concentrations and stable silicon isotopes

Author

Laukert, Georgi, Grasse, Patricia, Novikhin, A., Povazhny, V., Doering, Kristin, Hölemann, Jens, Janout, M., Bauch, Dorothea, Kassens, Heidemarie, Frank, Martin, Laukert, Georgi, Grasse, Patricia, Novikhin, A., Povazhny, V., Doering, Kristin, Hölemann, Jens, Janout, M., Bauch, Dorothea, Kassens, Heidemarie, and Frank, Martin

Published
2021
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50. Insights into Water Mass Circulation and Origins in the Central Arctic Ocean from in-situ Dissolved Organic Matter Fluorescence.

Author

Stedmon, Colin A, primary, Amon, Rainer M. W., additional, Bauch, Dorothea, additional, Bracher, Astrid, additional, Gonçalves-Araujo, Rafael, additional, Hoppmann, Mario, additional, Krishfield, Richard A., additional, Laney, Samuel, additional, Rabe, Benjamin, additional, Reader, Heather E, additional, and Granskog, Mats Anders, additional

Published
2021
Full Text
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