Your search keyword '"Wagner, Penelope M."' showing total 10 results

1. A red tide in the pack ice of the Arctic Ocean

Author

Olsen, Lasse M., Duarte, Pedro, Peralta-Ferriz, Cecilia, Kauko, Hanna M., Johansson, Malin, Peeken, Ilka, Różańska-Pluta, Magdalena, Tatarek, Agnieszka, Wiktor, Jozef, Fernández-Méndez, Mar, Wagner, Penelope M., Pavlov, Alexey K., Hop, Haakon, and Assmy, Philipp

Published

2019

2. Improving satellite-based monitoring of the Arctic polar regions: identification of research and capacity gaps

Author

Gabarró, Carolina, Hughes, Nick, Wilkinson, Jeremy, Bertino, Laurent, Bracher, Astrid, Diehl, Thomas, Dierking, Wolfgang, Gonzalez-Gambau, Veronica, Lavergne, Thomas, Madurell, Teresa, Malnes, Eirik, Wagner, Penelope M., Gabarró, Carolina, Hughes, Nick, Wilkinson, Jeremy, Bertino, Laurent, Bracher, Astrid, Diehl, Thomas, Dierking, Wolfgang, Gonzalez-Gambau, Veronica, Lavergne, Thomas, Madurell, Teresa, Malnes, Eirik, and Wagner, Penelope M.

Abstract

We present a comprehensive review of the current status of remotely sensed and in situ sea ice, ocean, and land parameters acquired over the Arctic and Antarctic and identify current data gaps through comparison with the portfolio of products provided by Copernicus services. While we include several land parameters, the focus of our review is on the marine sector. The analysis is facilitated by the outputs of the KEPLER H2020 project. This project developed a road map for Copernicus to deliver an improved European capacity for monitoring and forecasting of the Polar Regions, including recommendations and lessons learnt, and the role citizen science can play in supporting Copernicus’ capabilities and giving users ownership in the system. In addition to summarising this information we also provide an assessment of future satellite missions (in particular the Copernicus Sentinel Expansion Missions), in terms of the potential enhancements they can provide for environmental monitoring and integration/assimilation into modelling/forecast products. We identify possible synergies between parameters obtained from different satellite missions to increase the information content and the robustness of specific data products considering the end-users requirements, in particular maritime safety. We analyse the potential of new variables and new techniques relevant for assimilation into simulations and forecasts of environmental conditions and changes in the Polar Regions at various spatial and temporal scales. This work concludes with several specific recommendations to the EU for improving the satellite-based monitoring of the Polar Regions.

Published

2023

3. A new structure for the Sea Ice Essential Climate variables of the Global Climate Observing System

Author

Lavergne, Thomas, Kern, Stefan, Aaboe, Signe, Derby, Lauren, Dybkjaer, Gorm, Garric, Gilles, Heil, Petra, Hendricks, Stefan, Holfort, Jürgen, Howell, Stephen, Key, Jeffrey, Lieser, Jan, Maksym, Ted, Maslowski, Wieslaw, Meier, Walt, Muñoz-Sabater, Joaquín, Nicolas, Julien, Ozsoy, Burcu, Rabe, Benjamin, Rack, Wolfgang, Raphael, Marilyn, de Rosnay, Patricia, Smolyanitsky, Vasily, Tietsche, Steffen, Ukita, Jinro, Vichi, Marcello, Wagner, Penelope M., Willmes, Sascha, Zhao, Xi, Lavergne, Thomas, Kern, Stefan, Aaboe, Signe, Derby, Lauren, Dybkjaer, Gorm, Garric, Gilles, Heil, Petra, Hendricks, Stefan, Holfort, Jürgen, Howell, Stephen, Key, Jeffrey, Lieser, Jan, Maksym, Ted, Maslowski, Wieslaw, Meier, Walt, Muñoz-Sabater, Joaquín, Nicolas, Julien, Ozsoy, Burcu, Rabe, Benjamin, Rack, Wolfgang, Raphael, Marilyn, de Rosnay, Patricia, Smolyanitsky, Vasily, Tietsche, Steffen, Ukita, Jinro, Vichi, Marcello, Wagner, Penelope M., Willmes, Sascha, and Zhao, Xi

Abstract

Author Posting. © American Meteorological Society, 2022. This article is posted here by permission of American Meteorological Society for personal use, not for redistribution. The definitive version was published in Bulletin of the American Meteorological Society 103(6), (2022): E1502-E1521, https://doi.org/10.1175/bams-d-21-0227.1., Climate observations inform about the past and present state of the climate system. They underpin climate science, feed into policies for adaptation and mitigation, and increase awareness of the impacts of climate change. The Global Climate Observing System (GCOS), a body of the World Meteorological Organization (WMO), assesses the maturity of the required observing system and gives guidance for its development. The Essential Climate Variables (ECVs) are central to GCOS, and the global community must monitor them with the highest standards in the form of Climate Data Records (CDR). Today, a single ECV—the sea ice ECV—encapsulates all aspects of the sea ice environment. In the early 1990s it was a single variable (sea ice concentration) but is today an umbrella for four variables (adding thickness, edge/extent, and drift). In this contribution, we argue that GCOS should from now on consider a set of seven ECVs (sea ice concentration, thickness, snow depth, surface temperature, surface albedo, age, and drift). These seven ECVs are critical and cost effective to monitor with existing satellite Earth observation capability. We advise against placing these new variables under the umbrella of the single sea ice ECV. To start a set of distinct ECVs is indeed critical to avoid adding to the suboptimal situation we experience today and to reconcile the sea ice variables with the practice in other ECV domains., PH’s contribution was funded under the Australian Government’s Antarctic Science Collaboration Initiative program, and contributes to Project 6 of the Australian Antarctic Program Partnership (ASCI000002). PH acknowledges support through the Australian Antarctic Science Projects 4496 and 4506, and the International Space Science Institute (Bern, Switzerland) project #405., 2022-12-01

Published

2022

4. The observed recent surface air temperature development across Svalbard and concurring footprints in local sea ice cover

Author

Dahlke, Sandro, Hughes, Nicholas E., Wagner, Penelope M., Gerland, Sebastian, Wawrzyniak, Tomasz, Ivanov, Boris, Maturilli, Marion, Dahlke, Sandro, Hughes, Nicholas E., Wagner, Penelope M., Gerland, Sebastian, Wawrzyniak, Tomasz, Ivanov, Boris, and Maturilli, Marion

Abstract

The Svalbard archipelago in the Arctic North Atlantic is experiencing rapid changes in the surface climate and sea ice distribution, with impacts for the coupled climate system and the local society. This study utilizes observational data of surface air temperature (SAT) from 1980–2016 across the whole Svalbard archipelago, and sea ice extent (SIE) from operational sea ice charts to conduct a systematic assessment of climatologies, long-term changes and regional differences. The proximity to the warm water mass of the West Spitsbergen Current drives a markedly warmer climate in the western coastal regions compared to northern and eastern Svalbard. This imprints on the SIE climatology in southern and western Svalbard, where the annual maxima of 50–60% area ice coverage are substantially less than 80–90% in the northern and eastern fjords. Owing to winter-amplified warming, the local climate is shifting towards more maritime conditions, and SIE reductions of between 5 and 20% per decade in particular regions are found, such that a number of fjords in the west have been virtually ice-free in recent winters. The strongest decline comes along with SAT forcing and occurs over the most recent 1–2 decades in all regions; while in the 1980s and 1990s, enhanced northerly winds and sea ice drift can explain 30–50% of SIE variability around northern Svalbard, where they had correspondingly lead to a SIE increase. With an ongoing warming it is suggested that both the meteorological and cryospheric conditions in eastern Svalbard will become increasingly similar to what is already observed in the western fjords, namely suppressed typical Arctic climate conditions.

Published

2020

5. The observed recent surface air temperature development across Svalbard and concurring footprints in local sea ice cover

Author

Dahlke, Sandro, primary, Hughes, Nicholas E., additional, Wagner, Penelope M., additional, Gerland, Sebastian, additional, Wawrzyniak, Tomasz, additional, Ivanov, Boris, additional, and Maturilli, Marion, additional

Published

2020

6. Algal Hot Spots in a Changing Arctic Ocean: Sea-Ice Ridges and the Snow-Ice Interface

Author

Fernández-Méndez, Mar, primary, Olsen, Lasse M., additional, Kauko, Hanna M., additional, Meyer, Amelie, additional, Rösel, Anja, additional, Merkouriadi, Ioanna, additional, Mundy, Christopher J., additional, Ehn, Jens K., additional, Johansson, A. Malin, additional, Wagner, Penelope M., additional, Ervik, Åse, additional, Sorrell, Brian K., additional, Duarte, Pedro, additional, Wold, Anette, additional, Hop, Haakon, additional, and Assmy, Philipp, additional

Published

2018

7. Can we extend local sea-ice measurements to satellite scale? An example from the N-ICE2015 expedition

Author

Rösel, Anja, primary, King, Jennifer, additional, Doulgeris, Anthony P., additional, Wagner, Penelope M., additional, Johansson, A. Malin, additional, and Gerland, Sebastian, additional

Published

2017

8. Leads in Arctic pack ice enable early phytoplankton blooms below snow-covered sea ice

Author

Assmy, Philipp, Fernández-Méndez, Mar, Duarte, Pedro, Meyer, Amelie, Randelhoff, Achim, Mundy, Christopher J., Olsen, Lasse M., Kauko, Hanna Maria, Bailey, Allison, Chierici, Melissa, Cohen, Lana, Doulgeris, Anthony P., Ehn, Jens K., Fransson, Agneta, Gerland, Sebastian, Hop, Haakon, Hudson, Stephen R., Hughes, Nick, Itkin, Polona, Johnsen, Geir, King, Jennifer A., Koch, Boris P., Koenig, Zoe, Kwasniewski, Slawomir, Laney, Samuel R., Nicolaus, Marcel, Pavlov, Alexey K., Polashenski, Christopher M., Provost, Christine, Rösel, Anja, Sandbu, Marthe, Spreen, Gunnar, Smedsrud, Lars H., Sundfjord, Arild, Taskjelle, Torbjørn, Tatarek, Agnieszka, Wiktor, Jozef, Wagner, Penelope M., Wold, Anette, Steen, Harald, Granskog, Mats A., Assmy, Philipp, Fernández-Méndez, Mar, Duarte, Pedro, Meyer, Amelie, Randelhoff, Achim, Mundy, Christopher J., Olsen, Lasse M., Kauko, Hanna Maria, Bailey, Allison, Chierici, Melissa, Cohen, Lana, Doulgeris, Anthony P., Ehn, Jens K., Fransson, Agneta, Gerland, Sebastian, Hop, Haakon, Hudson, Stephen R., Hughes, Nick, Itkin, Polona, Johnsen, Geir, King, Jennifer A., Koch, Boris P., Koenig, Zoe, Kwasniewski, Slawomir, Laney, Samuel R., Nicolaus, Marcel, Pavlov, Alexey K., Polashenski, Christopher M., Provost, Christine, Rösel, Anja, Sandbu, Marthe, Spreen, Gunnar, Smedsrud, Lars H., Sundfjord, Arild, Taskjelle, Torbjørn, Tatarek, Agnieszka, Wiktor, Jozef, Wagner, Penelope M., Wold, Anette, Steen, Harald, and Granskog, Mats A.

Abstract

© The Author(s), 2017. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Scientific Reports 7 (2017): 40850, doi:10.1038/srep40850., The Arctic icescape is rapidly transforming from a thicker multiyear ice cover to a thinner and largely seasonal first-year ice cover with significant consequences for Arctic primary production. One critical challenge is to understand how productivity will change within the next decades. Recent studies have reported extensive phytoplankton blooms beneath ponded sea ice during summer, indicating that satellite-based Arctic annual primary production estimates may be significantly underestimated. Here we present a unique time-series of a phytoplankton spring bloom observed beneath snow-covered Arctic pack ice. The bloom, dominated by the haptophyte algae Phaeocystis pouchetii, caused near depletion of the surface nitrate inventory and a decline in dissolved inorganic carbon by 16 ± 6 g C m−2. Ocean circulation characteristics in the area indicated that the bloom developed in situ despite the snow-covered sea ice. Leads in the dynamic ice cover provided added sunlight necessary to initiate and sustain the bloom. Phytoplankton blooms beneath snow-covered ice might become more common and widespread in the future Arctic Ocean with frequent lead formation due to thinner and more dynamic sea ice despite projected increases in high-Arctic snowfall. This could alter productivity, marine food webs and carbon sequestration in the Arctic Ocean., This study was supported by the Centre for Ice, Climate and Ecosystems (ICE) at the Norwegian Polar Institute, the Ministry of Climate and Environment, Norway, the Research Council of Norway (projects Boom or Bust no. 244646, STASIS no. 221961, CORESAT no. 222681, CIRFA no. 237906 and AMOS CeO no. 223254), and the Ministry of Foreign Affairs, Norway (project ID Arctic), the ICE-ARC program of the European Union 7th Framework Program (grant number 603887), the Polish-Norwegian Research Program operated by the National Centre for Research and Development under the Norwegian Financial Mechanism 2009–2014 in the frame of Project Contract Pol-Nor/197511/40/2013, CDOM-HEAT, and the Ocean Acidification Flagship program within the FRAM- High North Research Centre for Climate and the Environment, Norway.

Published

2017

9. Leads in Arctic pack ice enable early phytoplankton blooms below snow-covered sea ice

Author

Assmy, Philipp, primary, Fernández-Méndez, Mar, additional, Duarte, Pedro, additional, Meyer, Amelie, additional, Randelhoff, Achim, additional, Mundy, Christopher J., additional, Olsen, Lasse M., additional, Kauko, Hanna M., additional, Bailey, Allison, additional, Chierici, Melissa, additional, Cohen, Lana, additional, Doulgeris, Anthony P., additional, Ehn, Jens K., additional, Fransson, Agneta, additional, Gerland, Sebastian, additional, Hop, Haakon, additional, Hudson, Stephen R., additional, Hughes, Nick, additional, Itkin, Polona, additional, Johnsen, Geir, additional, King, Jennifer A., additional, Koch, Boris P., additional, Koenig, Zoe, additional, Kwasniewski, Slawomir, additional, Laney, Samuel R., additional, Nicolaus, Marcel, additional, Pavlov, Alexey K., additional, Polashenski, Christopher M., additional, Provost, Christine, additional, Rösel, Anja, additional, Sandbu, Marthe, additional, Spreen, Gunnar, additional, Smedsrud, Lars H., additional, Sundfjord, Arild, additional, Taskjelle, Torbjørn, additional, Tatarek, Agnieszka, additional, Wiktor, Jozef, additional, Wagner, Penelope M., additional, Wold, Anette, additional, Steen, Harald, additional, and Granskog, Mats A., additional

Published

2017

10. The observed recent surface air temperature development across Svalbard and concurring footprints in local sea ice cover

Author

Dahlke, Sandro, Hughes, Nicholas E., Wagner, Penelope M., Gerland, Sebastian, Wawrzyniak, Tomasz, Ivanov, Boris, and Maturilli, Marion

Subjects

13. Climate action

Abstract

The Svalbard archipelago in the Arctic North Atlantic is experiencing rapid changes in the surface climate and sea ice distribution, with impacts for the coupled climate system and the local society. This study utilizes observational data of surface air temperature (SAT) from 1980–2016 across the whole Svalbard archipelago, and sea ice extent (SIE) from operational sea ice charts to conduct a systematic assessment of climatologies, long-term changes and regional differences. The proximity to the warm water mass of the West Spitsbergen Current drives a markedly warmer climate in the western coastal regions compared to northern and eastern Svalbard. This imprints on the SIE climatology in southern and western Svalbard, where the annual maxima of 50–60% area ice coverage are substantially less than 80–90% in the northern and eastern fjords. Owing to winter-amplified warming, the local climate is shifting towards more maritime conditions, and SIE reductions of between 5 and 20% per decade in particular regions are found, such that a number of fjords in the west have been virtually ice-free in recent winters. The strongest decline comes along with SAT forcing and occurs over the most recent 1–2 decades in all regions; while in the 1980s and 1990s, enhanced northerly winds and sea ice drift can explain 30–50% of SIE variability around northern Svalbard, where they had correspondingly lead to a SIE increase. With an ongoing warming it is suggested that both the meteorological and cryospheric conditions in eastern Svalbard will become increasingly similar to what is already observed in the western fjords, namely suppressed typical Arctic climate conditions.