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2. Splendid isolation? Atlantic Canada's 'good' pandemic

Author

Webber, Patrick

Subjects
Epidemics -- Care and treatment -- Nova Scotia -- Canada -- New Brunswick, Influenza -- Care and treatment, Developing countries, Stress (Psychology) -- Care and treatment, Social sciences
Abstract

There is no such thing as a good pandemic. There are merely less bad pandemics. Even with well over three million COVID-19 deaths officially recorded and with numbers in the [...]

Published
2021

5. Albert W. Johnson, 1926–2017

Author

Murray, David F., Brown, Jerry, Chapin, Terry, Johnson, Susan, Mooney, Harold, Murray, Barbara, Shaver, Gus, Swartz, Jerry, Turner-Bogren, Betsy, Walker, Donald (Skip), and Webber, Patrick

Published
2018

7. Liberal resilience in a hyperlocal region

Author

Webber, Patrick

Subjects
Political parties -- New Brunswick -- Canada, Social sciences
Abstract

No one expected the Liberals to repeat their 2015 sweep of all 32 seats in Atlantic Canada, with nearly 59 per cent of the vote. In 2019, the Liberals' goal [...]

Published
2020

8. Jack Ives, 1931–2024.

Author

Miller, Gifford H. and Webber, Patrick J.

Subjects
UNIVERSITY faculty, GLACIOLOGY, MOUNTAIN ecology, WORLD War II, DOCTOR of philosophy degree
Published
2024
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10. Multi-Decadal Changes in Tundra Environments and Ecosystems: Synthesis of the International Polar Year-Back to the Future Project (IPY-BTF)

Author

Callaghan, Terry V., Tweedie, Craig E., Åkerman, Jonas, Andrews, Christopher, Bergstedt, Johan, Butler, Malcolm G., Christensen, Torben R., Cooley, Dorothy, Dahlberg, Ulrika, Danby, Ryan K., Daniëls, Fred J. A., de Molenaar, Johannes G., Dick, Jan, Mortensen, Christian Ebbe, Ebert-May, Diane, Emanuelsson, Urban, Eriksson, Håkan, Hedenås, Henrik, Henry, Greg. H. R., Hik, David S., Hobbie, John E., Jantze, Elin J., Jaspers, Cornelia, Johansson, Cecilia, Johansson, Margareta, Johnson, David R., Johnstone, Jill F., Jonasson, Christer, Kennedy, Catherine, Kenney, Alice J., Keuper, Frida, Koh, Saewan, Krebs, Charles J., Lantuit, Hugues, Lara, Mark J., Lin, David, Lougheed, Vanessa L., Madsen, Jesper, Matveyeva, Nadya, McEwen, Daniel C., Myers-Smith, Isla H., Narozhniy, Yuriy K., Olsson, Håkan, Pohjola, Veijo A., Price, Larry W., Rigét, Frank, Rundqvist, Sara, Sandström, Anneli, Tamstorf, Mikkel, Van Bogaert, Rik, Villarreal, Sandra, Webber, Patrick J., and Zemtsov, Valeriy A.

Published
2011
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14. The politics of the raised drawbridge: the rising tide of parochial populism confounds categories of left and right

Author

Webber, Patrick

Subjects
Populism -- Political aspects, Political parties -- Western Europe -- United Kingdom, Protectionism -- Political aspects, Democracy -- Western Europe -- United Kingdom -- Political aspects, Social sciences, European Union -- Political aspects
Abstract

Populism is growing across the West. Established political parties are atrophying. Political norms are changing, fast. Traditional parties in Europe and the United States are petrified. The future of the [...]

Published
2016

17. Plant Community Responses to Experimental Warming across the Tundra Biome

Author

Walker, Marilyn D., Wahren, C. Henrik, Hollister, Robert D., Henry, Greg H. R., Ahlquist, Lorraine E., Alatalo, Juha M., Bret-Harte, M. Syndonia, Calef, Monika P., Callaghan, Terry V., Carroll, Amy B., Epstein, Howard E., Jónsdóttir, Ingibjörg S., Klein, Julia A., Magnússon, Borgþór, Molau, Ulf, Oberbauer, Steven F., Rewa, Steven P., Robinson, Clare H., Shaver, Gaius R., Suding, Katharine N., Thompson, Catharine C., Tolvanen, Anne, Totland, Ørjan, Turner, P. Lee, Tweedie, Craig E., Webber, Patrick J., and Wookey, Philip A.

Published
2006
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24. Evidence and Implications of Recent Climate Change in Northern Alaska and Other Arctic Regions

Author

Hinzman, Larry D., Bettez, Neil D., Bolton, W. Robert, Chapin, F. Stuart, Dyurgerov, Mark B., Fastie, Chris L., Griffith, Brad, Hollister, Robert D., Hope, Allen, Huntington, Henry P., Jensen, Anne M., Jia, Gensuo J., Jorgenson, Torre, Kane, Douglas L., Klein, David R., Kofinas, Gary, Lynch, Amanda H., Lloyd, Andrea H., McGuire, A. David, Nelson, Frederick E., Oechel, Walter C., Osterkamp, Thomas E., Racine, Charles H., Romanovsky, Vladimir E., Stone, Robert S., Stow, Douglas A., Sturm, Matthew, Tweedie, Craig E., Vourlitis, George L., Walker, Marilyn D., Walker, Donald A., Webber, Patrick J., Welker, Jeffrey M., Winker, Kevin S., and Yoshikawa, Kenji

Published
2005
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25. Circumpolar Arctic Vegetation Classification

Author

Walker, Donald A., primary, Daniëls, Fred J.A., additional, Matveyeva, Nadezhda V., additional, Šibík, Jozef, additional, Walker, Marilyn D., additional, Breen, Amy L., additional, Druckenmiller, Lisa A., additional, Raynolds, Martha K., additional, Bültmann, Helga, additional, Hennekens, Stephan, additional, Buchhorn, Marcel, additional, Epstein, Howard E., additional, Ermokhina, Ksenia, additional, Fosaa, Anna M., additional, Hei∂marsson, Starri, additional, Heim, Birgit, additional, Jónsdóttir, Ingibjörg S., additional, Koroleva, Natalia, additional, Lévesque, Esther, additional, MacKenzie, William H., additional, Henry, Greg H.R., additional, Nilsen, Lennart, additional, Peet, Robert, additional, Razzhivin, Volodya, additional, Talbot, Stephen S., additional, Telyatnikov, Mikhail, additional, Thannheiser, Dietbert, additional, Webber, Patrick J., additional, and Wirth, Lisa M., additional

Published
2018
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27. Circumpolar Arctic Vegetation Classification

Author

Walker, Donald A., Daniëls, Fred J.A., Matveyeva, Nadezhda V., Šibík, Jozef, Walker, Marilyn D., Breen, Amy L., Druckenmiller, Lisa A., Raynolds, Martha K., Bültmann, Helga, Hennekens, Stephan, Buchhorn, Marcel, Epstein, Howard E., Ermokhina, Ksenia, Fosaa, Anna M., Heidmarsson, Starri, Heim, Birgit, Jónsdóttir, Ingibjörg S., Koroleva, Natalia, Lévesque, Esther, MacKenzie, William H., Henry, Greg H.R., Nilsen, Lennart, Peet, Robert, Razzhivin, Volodya, Talbot, Stephen S., Telyatnikov, Mikhail, Thannheiser, Dietbert, Webber, Patrick J., Wirth, Lisa M., Walker, Donald A., Daniëls, Fred J.A., Matveyeva, Nadezhda V., Šibík, Jozef, Walker, Marilyn D., Breen, Amy L., Druckenmiller, Lisa A., Raynolds, Martha K., Bültmann, Helga, Hennekens, Stephan, Buchhorn, Marcel, Epstein, Howard E., Ermokhina, Ksenia, Fosaa, Anna M., Heidmarsson, Starri, Heim, Birgit, Jónsdóttir, Ingibjörg S., Koroleva, Natalia, Lévesque, Esther, MacKenzie, William H., Henry, Greg H.R., Nilsen, Lennart, Peet, Robert, Razzhivin, Volodya, Talbot, Stephen S., Telyatnikov, Mikhail, Thannheiser, Dietbert, Webber, Patrick J., and Wirth, Lisa M.

Abstract

Aims: An Arctic Vegetation Classification (AVC) is needed to address issues related to rapid Arctic-wide changes to climate, land-use, and biodiversity. Location: The 7.1 million km2 Arctic tundra biome. Approach and conclusions: The purpose, scope and conceptual framework for an Arctic Vegetation Archive (AVA) and Classification (AVC) were developed during numerous workshops starting in 1992. The AVA and AVC are modeled after the European vegetation archive (EVA) and classification (EVC). The AVA will use Turboveg for data management. The AVC will use a Braun-Blanquet (Br.-Bl.) classification approach. There are approximately 31,000 Arctic plots that could be included in the AVA. An Alaska AVA (AVA-AK, 24 datasets, 3026 plots) is a prototype for archives in other parts of the Arctic. The plan is to eventually merge data from other regions of the Arctic into a single Turboveg v3 database. We present the pros and cons of using the Br.-Bl. classification approach compared to the EcoVeg (US) and Biogeoclimatic Ecological Classification (Canada) approaches. The main advantages are that the Br.-Bl. approach already has been widely used in all regions of the Arctic, and many described, well-accepted vegetation classes have a pan-Arctic distribution. A crosswalk comparison of Dryas octopetala communities described according to the EcoVeg and the Braun-Blanquet approaches indicates that the non-parallel hierarchies of the two approaches make crosswalks difficult above the plantcommunity level. A preliminary Arctic prodromus contains a list of typical Arctic habitat types with associated described syntaxa from Europe, Greenland, western North America, and Alaska. Numerical clustering methods are used to provide an overview of the variability of habitat types across the range of datasets and to determine their relationship to previously described Braun-Blanquet syntaxa. We emphasize the need for continued maintenance of the Pan-Arctic Species List, and additional plot data to

Published
2018

32. State of the Climate in 2010

Author

Achberger, Christine, Ackerman, Steven A., Ahlstrom, A., Alfaro, Eric J., Allan, Robert J., Alves, Robert J., Amador, Jorge A., Amelie, Vincent, Andrianjafinirina, Solonomenjanahary, Antonov, John, Arndt, Derek S., Ashik, Igor, Atheru, Zachary, Attaher, Samar M., Baez, Julian, Banzon, Viva, Baringer, Molly O., Barreira, Sandra, Barriopedro, David, Barthia, Pawan K., Beal, Lisa M., Becker, Andreas, Behrenfeld, Michael J., Bell, Gerald D., Belward, Alan S., Benedetti, Angela, Berrisford, Paul, Berry, David I., Beszczynska-Moeller, Agnieszka, Bhatt, Uma S., Bidegain, Mario, Bindoff, Nathaniel L., Bissolli, Peter, Blake, Eric S., Blunden, Jessica, Booneeady, Prithiviraj, Bosilovich, Michael G., Boudet, Dagne R., Box, Jason E., Boyer, Timothy P., Bromwich, David H., Brown, Ross, Bryden, Harry L., Bulygina, Olga N., Burrows, John, Butler, J., Cais, Philippe, Calderon, Blanca, Callaghan, T. V., Camargo, Suzana J., Cappelen, John, Carmack, Eddy, Chambers, Don P., Chelliah, Muthuvel, Chidichimo, Maria P., Christiansen, H., Christy, John, Coehlo, Caio A. S., Colwell, Steve, Comiso, Josefino C., Compo, Gilber P., Crouch, Jake, Cunningham, Stuart A., Cutie, Virgen C., Dai, Aiguo, Davydova-Belitskaya, Valentina, Jeu, Richard, Decker, David, Dee, Dick, Demircan, M., Derksen, Chris, Diamond, Howard J., Dlugokencky, Howard, Dohan, Kathleen, Dolman, A. Johannes, Dorigo, Wouter, Drozdov, Dmitry S., Durack, Paul J., Dutton, Geoffrey S., Easterling, David, Ebita, Ayataka, Eischeid, Jon, Elkins, James W., Epstein, Howard E., Euscategui, Christian, Faijka-Williams, Eleanor, Famiglietti, James S., Faniriantsoa, Rija, Feely, Richard A., Fekete, Balazs M., Fenimore, Chris, Fettweis, Xavier, Field, Eric, Fioletov, Vitali E., Fogarty, Vitali E., Fogt, Ryan L., Forbes, B. C., Foster, Michael J., Frajka-Williams, E., Free, Melissa, Frolov, Ivan, Ganesan, A. L., Ganter, Catherine, Gibney, Ethan J., Gill, Stephen, Gill, M., Gitau, Wilson, Gleason, Karin L., Gobron, Nadine, Goldenberg, Stanley B., Goni, Gustavo J., Gonzalez, Idelmis G., Good, Simon A., Gottschalck, Jonathan, Gould, William A., Gouveia, Celia M., Griffiths, Georgina M., Guard, Chip, Guevara, Vladimir V., Haas, C., Hall, Bradley D., Halpert, Michael S., Heidinger, Andrew K., Heil, A., Heim, Richard R., Hennon, Paula A., Henry, Greg H. R., Hidalgo, Hugo G., Hilburn, Kyle, Hirschi, Joel J. M., Ho, Shu-Peng, Hobgood, Jay S., Hoerling, Martin, Holgate, Simon, Hook, Simon J., Hugony, Sebastien, Hurst, D., Ishihara, Hiroshi, Itoh, M., Jaimes, Ena, Jeffries, Martin, Jia, Gensu J., Jin, Xiangze, John, William E., Johnson, Bryan, Johnson, Gregory C., Jones, Philip D., Jumaux, Guillaume, Kabidi, Khadija, Kaiser, Johannes W., Kanzow, Torsten O., Kaplan, Alexey, Kearns, Edward J., Keller, Linda M., Kennedy, John J., Khatiwala, Samar, Kholodov, Alexander, Khoshkam, Mahbobeh, Kikuchi, T., Kimberlain, Todd B., Knaff, John A., Kobayashi, Shinya, Kokelj, Steve V., Korshunova, Natalia N., Kratz, David P., Krishfield, Richard, Kruger, Andries, Kruk, Michael C., Kumar Arun, Lammers, Richard B., Lander, Mark A., Landsea, Chris W., Lantuit, Hugues, Lantz, Trevor C., Lapinel, Braulio P., Lareef, Zubair, Lazzara, Matthew A., Leon, Antonia L., Leon, Gloria, Lauliette, Eric, Levitus, Sydney, Levy, Joel M., L Heureux, Michelle, Lin, I. I., Liu, Hongxing, Liu, Yanju, Liu, Yi, Loeb, Norman G., Long, Craig S., Lorrey, Andrew M., Lumpkin, Rick, Luo, Jing-Jia, Lyman, John M., Macdonald, Alison M., Maddux, Brent C., Maier, Frank, Malkova, Galina, Marchenko, Sergey, Marengo, Jose A., Maritorena, Stephane, Marotzke, Jochem, Martinez Guingla, Rodney, Maslanik, Jochem, Masson, Robert A., Mcbride, Charlotte, Mcgree, Simon, Mclaughlin, Fiona, Mcpeters, Rich, Mcvicar, Tim R., Mears, Carl A., Medany, Mahmoud A., Meier, Walt, Meinen, Christopher S., Merrifield, Mark A., Miller, Laury, Mitchum, Gary T., Montzka, Steve, Morcrette, Jean-Jacques, Mote, Thomas, Muhle, Jens, Mullan, A. Brett, Murray, Don, Nash, Eric R., Nerem, Steven R., Newman, Paul A., Nishino, S., Njau, Leonard, Noetzli, J., Oberbauer, S. F., Oberman, Naum, Obregon, Andre, Ogallo, Laban, Oludhe, Christopher, O Malley, Robert T., Overland, James, Park, Geun-Ha, Parker, David E., Pasch, Richard J., Pegion, Phil, Peltier, Alexandre, Pelto, Mauri S., Penalba, Olga C., Perez, Ramon S., Perlwitz, Judith, Perovich, Donald, Peterson, Thomas C., Pezza, Alexandre B., Phillips, David, Pinzon, Jorge E., Pitts, Michael C., Proshutinsky, A., Quegan, S., Quintana, Juan, Quintero, Alexander, Rabe, B., Rahimzadeh, Fatemeh, Rajeevan, Madhavan, Rayner, Darren, Rayner, Nick A., Raynolds, Martha K., Razuvaev, Vyacheslav N., Reagan, James R., Reid, Phillip, Renwick, James A., Revadekar, Jayashree, Reynolds, Richard W., Richter-Menge, Jacqueline, Rignot, Eric, Robinson, David A., Rodell, Matthew, Rogers, Mark, Romanovsky, Vladimir, Romero-Cruz, Fernando, Ronchail, Josyane, Rosenlof, Karen, Rossi, Shawn, Rutledge, Glenn, Saatchi, Sassan, Sabine, Christopher L., Saha, Suranjana, Sanchez-Lugo, Ahira, Santee, Michelle L., Sato, Hitoshi, Sawaengphokhai, P., Sayouri, Amal, Scambos, Ted A., Schauer, U., Schemm, Jae, Schmid, Claudia, Schneider, Philipp, Schueller, Dominique, Sensoy, Serhat, Sharp, Martin, Shaver, Gus R., Shiklomanov, Alexander, Shiklomanov, N., Shimada, Koji, Siegel, David A., Simmons, Adrian, Skansi, Maria, Smith, Adam, Smith, Cathy, Smith, S., Smith, Thomas M., Sokolov, Vladimir, Spence, Jacqueline M., Srivastava, Arvind Kumar, Stackhouse, Paul W., Stammerjohn, Sharon, Steele, Mike, Steinbrecht, Wolfgang, Stephenson, Tannecia S., Stolarski, Richard S., Tahani, Lloyd, Takahashi, Taro, Taylor, Michael A., Thepaut, Jean-Noel, Thiaw, Wassila M., Thorne, Peter W., Timmermans, M. L., Tobin, Skie, Toole, John, Trewin, Blair C., Trigo, Ricardo M., Tucker, Compton J., Tweedie, Craig E., As, D., Wal, R. S. W., A, Ronald J., Werf, G. R., Vautard, Robert, Vieira, G., Vincent, Lucie A., Vinther, Lucie A., Vinther, B., Vose, Russell, Wagner, Wolfgang, Wahr, John, Walker, David A., Walsh, John, Wang, Chunzai, Wang, Junhong, Wang, Lei, Wang, Muyin, Wang, Sheng-Hung, Wanninkhof, Rik, Weaver, Scott, Webber, Patrick J., Weber, Mark, Weller, Robert A., Weyman, James, Whitewood, Robert, Wijffels, Susan E., Wilber, Anne C., Willett, Katharine M., Williams, W., Willis, Joshua K., Wolken, Gabriel, Wong, Takmeng, Woodgate, Rebecca, Woodworth, Philip, Wovrosh, Alex J., Xue, Yan, Michiyo Yamamoto-Kawai, Yin, Xungang, Yu, Lisan, Zhang, Liangying, Zhang, Peiqun, Zhao, L., Zhou, Xinjia, and Zimmermann, S.

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, 13. Climate action, Earth science, Environmental science, Thermal state, 14. Life underwater, 010502 geochemistry & geophysics, 16. Peace & justice, Permafrost, 01 natural sciences, 0105 earth and related environmental sciences
Abstract

Several large-scale climate patterns influenced climate conditions and weather patterns across the globe during 2010. The transition from a warm El Niño phase at the beginning of the year to a cool La Niña phase by July contributed to many notable events, ranging from record wetness across much of Australia to historically low Eastern Pacific basin and near-record high North Atlantic basin hurricane activity. The remaining five main hurricane basins experienced below- to well-below-normal tropical cyclone activity. The negative phase of the Arctic Oscillation was a major driver of Northern Hemisphere temperature patterns during 2009/10 winter and again in late 2010. It contributed to record snowfall and unusually low temperatures over much of northern Eurasia and parts of the United States, while bringing above-normal temperatures to the high northern latitudes. The February Arctic Oscillation Index value was the most negative since records began in 1950. The 2010 average global land and ocean surface temperature was among the two warmest years on record. The Arctic continued to warm at about twice the rate of lower latitudes. The eastern and tropical Pacific Ocean cooled about 1°C from 2009 to 2010, reflecting the transition from the 2009/10 El Niño to the 2010/11 La Niña. Ocean heat fluxes contributed to warm sea surface temperature anomalies in the North Atlantic and the tropical Indian and western Pacific Oceans. Global integrals of upper ocean heat content for the past several years have reached values consistently higher than for all prior times in the record, demonstrating the dominant role of the ocean in the Earth's energy budget. Deep and abyssal waters of Antarctic origin have also trended warmer on average since the early 1990s. Lower tropospheric temperatures typically lag ENSO surface fluctuations by two to four months, thus the 2010 temperature was dominated by the warm phase El Niño conditions that occurred during the latter half of 2009 and early 2010 and was second warmest on record. The stratosphere continued to be anomalously cool. Annual global precipitation over land areas was about five percent above normal. Precipitation over the ocean was drier than normal after a wet year in 2009. Overall, saltier (higher evaporation) regions of the ocean surface continue to be anomalously salty, and fresher (higher precipitation) regions continue to be anomalously fresh. This salinity pattern, which has held since at least 2004, suggests an increase in the hydrological cycle. Sea ice conditions in the Arctic were significantly different than those in the Antarctic during the year. The annual minimum ice extent in the Arctic—reached in September—was the third lowest on record since 1979. In the Antarctic, zonally averaged sea ice extent reached an all-time record maximum from mid-June through late August and again from mid-November through early December. Corresponding record positive Southern Hemisphere Annular Mode Indices influenced the Antarctic sea ice extents. Greenland glaciers lost more mass than any other year in the decade-long record. The Greenland Ice Sheet lost a record amount of mass, as the melt rate was the highest since at least 1958, and the area and duration of the melting was greater than any year since at least 1978. High summer air temperatures and a longer melt season also caused a continued increase in the rate of ice mass loss from small glaciers and ice caps in the Canadian Arctic. Coastal sites in Alaska show continuous permafrost warming and sites in Alaska, Canada, and Russia indicate more significant warming in relatively cold permafrost than in warm permafrost in the same geographical area. With regional differences, permafrost temperatures are now up to 2°C warmer than they were 20 to 30 years ago. Preliminary data indicate there is a high probability that 2010 will be the 20th consecutive year that alpine glaciers have lost mass. Atmospheric greenhouse gas concentrations continued to rise and ozone depleting substances continued to decrease. Carbon dioxide increased by 2.60 ppm in 2010, a rate above both the 2009 and the 1980–2010 average rates. The global ocean carbon dioxide uptake for the 2009 transition period from La Niña to El Niño conditions, the most recent period for which analyzed data are available, is estimated to be similar to the long-term average. The 2010 Antarctic ozone hole was among the lowest 20% compared with other years since 1990, a result of warmer-than-average temperatures in the Antarctic stratosphere during austral winter between mid-July and early September.

Published
2011
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33. Circumpolar Arctic Vegetation Classification

Author

Walker, D.A., Daniëls, Fred J.A., Matveyeva, Nadezhda V., Šibík, Jozef, Walker, Marilyn D., Breen, Amy L., Druckenmiller, Lisa A., Raynolds, Martha K., Bültmann, Helga, Hennekens, Stephan, Buchhorn, Marcel, Epstein, Howard E., Ermokhina, Ksenia, Fosaa, Anna M., Hei∂marsson, Starri, Heim, Birgit, Jónsdóttir, Ingibjörg S., Koroleva, Natalia, Lévesque, Esther, MacKenzie, William H., Greg, Henry R., Nilsen, Lennart, Peet, Robert, Razzhivin, Volodya, Talbot, Stephen S., Telyatnikov, Mikhail, Thannheiser, Dietbert, Webber, Patrick J., Wirth, Lisa M., Walker, D.A., Daniëls, Fred J.A., Matveyeva, Nadezhda V., Šibík, Jozef, Walker, Marilyn D., Breen, Amy L., Druckenmiller, Lisa A., Raynolds, Martha K., Bültmann, Helga, Hennekens, Stephan, Buchhorn, Marcel, Epstein, Howard E., Ermokhina, Ksenia, Fosaa, Anna M., Hei∂marsson, Starri, Heim, Birgit, Jónsdóttir, Ingibjörg S., Koroleva, Natalia, Lévesque, Esther, MacKenzie, William H., Greg, Henry R., Nilsen, Lennart, Peet, Robert, Razzhivin, Volodya, Talbot, Stephen S., Telyatnikov, Mikhail, Thannheiser, Dietbert, Webber, Patrick J., and Wirth, Lisa M.

Abstract

An Arctic Vegetation Classification (AVC) is needed to address issues related to rapid Arctic-wide changes to climate, land-use, and biodiversity. Location: The 7.1 million km2 Arctic tundra biome. Approach and conclusions: The purpose, scope and conceptual framework for an Arctic Vegetation Archive (AVA) and Classification (AVC) were developed during numerous workshops starting in 1992. The AVA and AVC are modeled after the European vegetation archive (EVA) and classification (EVC). The AVA will use Turboveg for data management. The EVC will use a Braun-Blanquet (Br.-Bl.) classification approach. There are approximately 31,000 Arctic plots that could be included in the AVA. An Alaska AVA (AVA-AK, 24 datasets, 3026 plots) is a prototype for archives in other parts of the Arctic. The plan is to eventually merge data from otherregions of the Arctic into a single Turboveg v3 database. We present the pros and cons of using the Br.-Bl. classification approach compared to the EcoVeg (US) and Biogeoclimatic Ecological Classification (Canada) approaches. The main advantages are that the Br.-Bl. approach already has been widely used in all regions of the Arctic, and many described, well-accepted vegetation classes have a pan-Arctic distribution. A crosswalk comparison of Dryas octopetala communities described according to the EcoVeg and the Braun-Blanquet approaches indicates that the non-parallel hierarchies of the two approaches make crosswalks difficult above the plantcommunity level. A preliminary Arctic prodromus contains a list of typical Arctic habitat types with associated described syntaxa from Europe, Greenland, western North America, and Alaska. Numerical clustering methods are used to provide an overview of the variability of habitat types across the range of datasets and to determine their relationship to previously described Braun-Blanquet syntaxa. We emphasize the need for continued maintenance of the Pan-Arctic Species List, and additional plot data to fully

Published
2017

34. From entry to practice to advanced nurse practitioner – the progression of competencies and how they assist in delivery of eHealth programs for healthy ageing

Author

Murphy, Judy, Gossen, William, Webber, Patrick, Rodger, Daragh, Hussey, Pamela, Murphy, Judy, Gossen, William, Webber, Patrick, Rodger, Daragh, and Hussey, Pamela

Abstract

Most of the health issues encountered in persons of older age are the result of one or more chronic diseases. The evidence base reports that chronic diseases can be prevented or delayed by engaging in healthy behaviors. Education provides a cost effective intervention on both economic grounds in addition to delivery of optimal patient outcomes. Information and Communication Technology (ICT) increasingly is viewed as a critical utility in eHealth delivery, providing scope for expanding online education facilities for older persons. Developing nursing competencies in the delivery of eHealth solutions to deliver user education programs therefore makes sense. This chapter discusses nursing competencies on the development of targeted eHealth programs for healthy ageing. The role of Advanced Nurse Practitioner in Ireland and its associated competency set identifies how a strong action learning model can be designed to deliver eHealth educational programs for effective delivery of healthy ageing in place.

Published
2017
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35. The Alaska Arctic Vegetation Archive (AVA-AK)

Author

Walker, Donald A., Breen, Amy L., Druckenmiller, Lisa A., Wirth, Lisa W., Fisher, Will, Raynolds, Martha K., Šibík, Jozef, Walker, Marilyn D., Hennekens, Stephan, Boggs, Keith, Boucher, Tina, Buchhorn, Marcel, Bültmann, Helga, Cooper, David J., Daniëls, Fred J.A., Davidson, Scott J., Ebersole, James J., Elmendorf, Sara C., Epstein, Howard E., Gould, William A., Hollister, Robert D., Iversen, Colleen M., Jorgenson, M.T., Kade, Anja, Lee, Michael T., MacKenzie, William H., Peet, Robert K., Peirce, Jana L., Schickhoff, Udo, Sloan, Victoria L., Talbot, Stephen S., Tweedie, Craig E., Villarreal, Sandra, Webber, Patrick J., Zona, Donatella, Walker, Donald A., Breen, Amy L., Druckenmiller, Lisa A., Wirth, Lisa W., Fisher, Will, Raynolds, Martha K., Šibík, Jozef, Walker, Marilyn D., Hennekens, Stephan, Boggs, Keith, Boucher, Tina, Buchhorn, Marcel, Bültmann, Helga, Cooper, David J., Daniëls, Fred J.A., Davidson, Scott J., Ebersole, James J., Elmendorf, Sara C., Epstein, Howard E., Gould, William A., Hollister, Robert D., Iversen, Colleen M., Jorgenson, M.T., Kade, Anja, Lee, Michael T., MacKenzie, William H., Peet, Robert K., Peirce, Jana L., Schickhoff, Udo, Sloan, Victoria L., Talbot, Stephen S., Tweedie, Craig E., Villarreal, Sandra, Webber, Patrick J., and Zona, Donatella

Abstract

The Alaska Arctic Vegetation Archive (AVA-AK, GIVD-ID: NA-US-014) is a free, publically available database archive of vegetation-plot data from the Arctic tundra region of northern Alaska. The archive currently contains 24 datasets with 3,026 non-overlapping plots. Of these, 74% have geolocation data with 25-m or better precision. Species cover data and header data are stored in a Turboveg database. A standardized Pan Arctic Species List provides a consistent nomenclature for vascular plants, bryophytes, and lichens in the archive. A web-based online Alaska Arctic Geoecological Atlas (AGA-AK) allows viewing and downloading the species data in a variety of formats, and provides access to a wide variety of ancillary data. We conducted a preliminary cluster analysis of the first 16 datasets (1,613 plots) to examine how the spectrum of derived clusters is related to the suite of datasets, habitat types, and environmental gradients. We present the contents of the archive, assess its strengths and weaknesses, and provide three supplementary files that include the data dictionary, a list of habitat types, an overview of the datasets, and details of the cluster analysis.

Published
2016

37. The Alaska Arctic Vegetation Archive (AVA-AK)

Author

Walker, Donald A., primary, Breen, Amy L., additional, Druckenmiller, Lisa A., additional, Wirth, Lisa W., additional, Fisher, Will, additional, Raynolds, Martha K., additional, Šibík, Jozef, additional, Walker, Marilyn D., additional, Hennekens, Stephan, additional, Boggs, Keith, additional, Boucher, Tina, additional, Buchhorn, Marcel, additional, Bültmann, Helga, additional, Cooper, David J., additional, Daniëls, Fred J.A, additional, Davidson, Scott J., additional, Ebersole, James J., additional, Elmendorf, Sara C., additional, Epstein, Howard E., additional, Gould, William A., additional, Hollister, Robert D., additional, Iversen, Colleen M., additional, Jorgenson, M. Torre, additional, Kade, Anja, additional, Lee, Michael T., additional, MacKenzie, William H., additional, Peet, Robert K., additional, Peirce, Jana L., additional, Schickhoff, Udo, additional, Sloan, Victoria L., additional, Talbot, Stephen S., additional, Tweedie, Craig E., additional, Villarreal, Sandra, additional, Webber, Patrick J., additional, and Zona, Donatella, additional

Published
2016
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40. Global assessment of experimental climate warming on tundra vegetation : heterogeneity over space and time

Author

Elmendorf, Sarah C., Henry, Gregory H. R., Hollister, Robert D., Alatalo, Juha, Bjork, Robert G., Bjorkman, Anne D., Callaghan, Terry V., Collier, Laura Siegwart, Cooper, Elisabeth J., Cornelissen, Johannes H. C., Day, Thomas A., Fosaa, Anna Maria, Gould, William A., Gretarsdottir, Jarngerdur, Harte, John, Hermanutz, Luise, Hik, David S., Hofgaard, Annika, Jarrad, Frith, Jonsdottir, Ingibjorg Svala, Keuper, Frida, Klanderud, Kari, Klein, Julia A., Koh, Saewan, Kudo, Gaku, Lang, Simone I., Loewen, Val, May, Jeremy L., Mercado, Joel, Michelsen, Anders, Molau, Ulf, Myers-Smith, Isla H., Oberbauer, Steven F., Pieper, Sara, Post, Eric, Rixen, Christian, Robinson, Clare H., Schmidt, Niels Martin, Shaver, Gaius R., Stenstrom, Anna, Tolvanen, Anne, Totland, Orjan, Troxler, Tiffany, Wahren, Carl-Henrik, Walker, Marilyn D., Webber, Patrick J., Welker, Jeffery M., Wookey, Philip A., Elmendorf, Sarah C., Henry, Gregory H. R., Hollister, Robert D., Alatalo, Juha, Bjork, Robert G., Bjorkman, Anne D., Callaghan, Terry V., Collier, Laura Siegwart, Cooper, Elisabeth J., Cornelissen, Johannes H. C., Day, Thomas A., Fosaa, Anna Maria, Gould, William A., Gretarsdottir, Jarngerdur, Harte, John, Hermanutz, Luise, Hik, David S., Hofgaard, Annika, Jarrad, Frith, Jonsdottir, Ingibjorg Svala, Keuper, Frida, Klanderud, Kari, Klein, Julia A., Koh, Saewan, Kudo, Gaku, Lang, Simone I., Loewen, Val, May, Jeremy L., Mercado, Joel, Michelsen, Anders, Molau, Ulf, Myers-Smith, Isla H., Oberbauer, Steven F., Pieper, Sara, Post, Eric, Rixen, Christian, Robinson, Clare H., Schmidt, Niels Martin, Shaver, Gaius R., Stenstrom, Anna, Tolvanen, Anne, Totland, Orjan, Troxler, Tiffany, Wahren, Carl-Henrik, Walker, Marilyn D., Webber, Patrick J., Welker, Jeffery M., and Wookey, Philip A.

Abstract

Understanding the sensitivity of tundra vegetation to climate warming is critical to forecasting future biodiversity and vegetation feedbacks to climate. In situ warming experiments accelerate climate change on a small scale to forecast responses of local plant communities. Limitations of this approach include the apparent site-specificity of results and uncertainty about the power of short-term studies to anticipate longer term change. We address these issues with a synthesis of 61 experimental warming studies, of up to 20 years duration, in tundra sites worldwide. The response of plant groups to warming often differed with ambient summer temperature, soil moisture and experimental duration. Shrubs increased with warming only where ambient temperature was high, whereas graminoids increased primarily in the coldest study sites. Linear increases in effect size over time were frequently observed. There was little indication of saturating or accelerating effects, as would be predicted if negative or positive vegetation feedbacks were common. These results indicate that tundra vegetation exhibits strong regional variation in response to warming, and that in vulnerable regions, cumulative effects of long-term warming on tundra vegetation and associated ecosystem consequences have the potential to be much greater than we have observed to date., The following authors were added to this article (see correction below):Alatalo, JuhaWalker, MarilynCorrection in: Ecology Letters, Vol. 17, Issue 2, page 260 (Feb 2014).DOI: 10.1111/ele.12218

Published
2012
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41. Plot-scale evidence of tundra vegetation change and links to recent summer warming

Author

Elmendorf, Sarah C., Henry, Gregory H. R., Hollister, Robert D., Bjork, Robert G., Boulanger-Lapointe, Noemie, Cooper, Elisabeth J., Cornelissen, Johannes H. C., Day, Thomas A., Dorrepaal, Ellen, Elumeeva, Tatiana G., Gill, Mike, Gould, William A., Harte, John, Hik, David S., Hofgaard, Annika, Johnson, David R., Johnstone, Jill F., Jonsdottir, Ingibjorg Svala, Jorgenson, Janet C., Klanderud, Kari, Klein, Julia A., Koh, Saewan, Kudo, Gaku, Lara, Mark, Levesque, Esther, Magnusson, Borgthor, May, Jeremy L., Mercado-Diaz, Joel A., Michelsen, Anders, Molau, Ulf, Myers-Smith, Isla H., Oberbauer, Steven F., Onipchenko, Vladimir G., Rixen, Christian, Schmidt, Niels Martin, Shaver, Gaius R., Spasojevic, Marko J., Porhallsdottir, Pora Ellen, Tolvanen, Anne, Troxler, Tiffany, Tweedie, Craig E., Villareal, Sandra, Wahren, Carl-Henrik, Walker, Xanthe, Webber, Patrick J., Welker, Jeffrey M., Wipf, Sonja, Elmendorf, Sarah C., Henry, Gregory H. R., Hollister, Robert D., Bjork, Robert G., Boulanger-Lapointe, Noemie, Cooper, Elisabeth J., Cornelissen, Johannes H. C., Day, Thomas A., Dorrepaal, Ellen, Elumeeva, Tatiana G., Gill, Mike, Gould, William A., Harte, John, Hik, David S., Hofgaard, Annika, Johnson, David R., Johnstone, Jill F., Jonsdottir, Ingibjorg Svala, Jorgenson, Janet C., Klanderud, Kari, Klein, Julia A., Koh, Saewan, Kudo, Gaku, Lara, Mark, Levesque, Esther, Magnusson, Borgthor, May, Jeremy L., Mercado-Diaz, Joel A., Michelsen, Anders, Molau, Ulf, Myers-Smith, Isla H., Oberbauer, Steven F., Onipchenko, Vladimir G., Rixen, Christian, Schmidt, Niels Martin, Shaver, Gaius R., Spasojevic, Marko J., Porhallsdottir, Pora Ellen, Tolvanen, Anne, Troxler, Tiffany, Tweedie, Craig E., Villareal, Sandra, Wahren, Carl-Henrik, Walker, Xanthe, Webber, Patrick J., Welker, Jeffrey M., and Wipf, Sonja

Abstract

Temperature is increasing at unprecedented rates across most of the tundra biome(1). Remote-sensing data indicate that contemporary climate warming has already resulted in increased productivity over much of the Arctic(2,3), but plot-based evidence for vegetation transformation is not widespread. We analysed change in tundra vegetation surveyed between 1980 and 2010 in 158 plant communities spread across 46 locations. We found biome-wide trends of increased height of the plant canopy and maximum observed plant height for most vascular growth forms; increased abundance of litter; increased abundance of evergreen, low-growing and tall shrubs; and decreased abundance of bare ground. Intersite comparisons indicated an association between the degree of summer warming and change in vascular plant abundance, with shrubs, forbs and rushes increasing with warming. However, the association was dependent on the climate zone, the moisture regime and the presence of permafrost. Our data provide plot-scale evidence linking changes in vascular plant abundance to local summer warming in widely dispersed tundra locations across the globe.

Published
2012
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42. Global assessment of experimental climate warming on tundra vegetation: Heterogeneity over space and time

Author

Elmendorf, Sarah, Henry, Gregory, Hollister, Robert, Bjork, Robert, Bjorkman, Anne, Callaghan, Terry, Siegwart Collier, Laura, Cooper, Elisabeth, Cornelissen, Johannes, Day, Thomas, Fosaa, Anna Maria, Gould, William, Gretarsdottir, Jarngerour, Harte, John, Hermanutz, Luise, Hik, David, Hofgaard, Annika, Jarrad, Frith, Jonsdottir, Ingibjorg Svala, Keuper, Frida, Klanderud, Kari, Klein, Julia, Koh, Saewan, Kudo, Gaku, Lang, Simone, Loewen, Val, May, Jeremy, Mercado, Joel, Michelsen, Anders, Molau, Ulf, Myers-Smith, Isla, Oberbauer, Steven, Pieper, Sara, Post, Eric, Rixen, Christian, Robinson, Clare, Schmidt, Niels Martin, Shaver, Gaius, Stenstrom, Anna, Tolvanen, Anne, Totland, Orjan, Troxler, Tiffany, Wahren, Carl-Henrich, Webber, Patrick, Welker, Jeffery, Wookey, Philip, Elmendorf, Sarah, Henry, Gregory, Hollister, Robert, Bjork, Robert, Bjorkman, Anne, Callaghan, Terry, Siegwart Collier, Laura, Cooper, Elisabeth, Cornelissen, Johannes, Day, Thomas, Fosaa, Anna Maria, Gould, William, Gretarsdottir, Jarngerour, Harte, John, Hermanutz, Luise, Hik, David, Hofgaard, Annika, Jarrad, Frith, Jonsdottir, Ingibjorg Svala, Keuper, Frida, Klanderud, Kari, Klein, Julia, Koh, Saewan, Kudo, Gaku, Lang, Simone, Loewen, Val, May, Jeremy, Mercado, Joel, Michelsen, Anders, Molau, Ulf, Myers-Smith, Isla, Oberbauer, Steven, Pieper, Sara, Post, Eric, Rixen, Christian, Robinson, Clare, Schmidt, Niels Martin, Shaver, Gaius, Stenstrom, Anna, Tolvanen, Anne, Totland, Orjan, Troxler, Tiffany, Wahren, Carl-Henrich, Webber, Patrick, Welker, Jeffery, and Wookey, Philip

Abstract

Understanding the sensitivity of tundra vegetation to climate warming is critical to forecasting future biodiversity and vegetation feedbacks to climate. In situ warming experiments accelerate climate change on a small scale to forecast responses of local plant communities. Limitations of this approach include the apparent site-specificity of results and uncertainty about the power of short-term studies to anticipate longer term change. We address these issues with a synthesis of 61 experimental warming studies, of up to 20 years duration, in tundra sites worldwide. The response of plant groups to warming often differed with ambient summer temperature, soil moisture and experimental duration. Shrubs increased with warming only where ambient temperature was high, whereas graminoids increased primarily in the coldest study sites. Linear increases in effect size over time were frequently observed. There was little indication of saturating or accelerating effects, as would be predicted if negative or positive vegetation feedbacks were common. These results indicate that tundra vegetation exhibits strong regional variation in response to warming, and that in vulnerable regions, cumulative effects of long-term warming on tundra vegetation – and associated ecosystem consequences – have the potential to be much greater than we have observed to date.

Published
2012

43. Global assessment of experimental climate warming on tundra vegetation:heterogeneity over space and time

Author

Elmendorf, Sarah C., Henry, Gregory H.R., Hollister, Robert D., Björk, Robert G., Bjorkman, Anne D., Callaghan, Terry V., Collier, Laura Siegwart, Cooper, Elisabeth J., Cornelissen, Johannes H.C., Day, Thomas A., Fosaa, Anna Maria, Gould, William A., Gretarsdottir, Jarngerdur, Harte, John, Hermanutz, Luise, Hik, David S., Hofgaard, Annika, Jarrad, Frith, Jonsdottir, Ingibjorg Svala, Keuper, Frida, Klanderud, Kari, Klein, Julia A., Koh, Saewan, Kudo, Gaku, Lang, Simone I., Loewen, Val, May, Jeremy L., Mercado, Joel, Michelsen, Anders, Molau, Ulf, Myers-Smith, Isla H., Oberbauer, Steven F., Pieper, Sara, Post, Eric, Rixen, Christian, Robinson, Clare H., Schmidt, Niels Martin, Shaver, Gaius R., Stenstrom, Anna, Tolvanen, Anne, Totland, Orjan, Troxler, Tiffany, Wahren, Carl-Henrik, Webber, Patrick J., Welker, Jeffery M., Wookey, Philip A., Elmendorf, Sarah C., Henry, Gregory H.R., Hollister, Robert D., Björk, Robert G., Bjorkman, Anne D., Callaghan, Terry V., Collier, Laura Siegwart, Cooper, Elisabeth J., Cornelissen, Johannes H.C., Day, Thomas A., Fosaa, Anna Maria, Gould, William A., Gretarsdottir, Jarngerdur, Harte, John, Hermanutz, Luise, Hik, David S., Hofgaard, Annika, Jarrad, Frith, Jonsdottir, Ingibjorg Svala, Keuper, Frida, Klanderud, Kari, Klein, Julia A., Koh, Saewan, Kudo, Gaku, Lang, Simone I., Loewen, Val, May, Jeremy L., Mercado, Joel, Michelsen, Anders, Molau, Ulf, Myers-Smith, Isla H., Oberbauer, Steven F., Pieper, Sara, Post, Eric, Rixen, Christian, Robinson, Clare H., Schmidt, Niels Martin, Shaver, Gaius R., Stenstrom, Anna, Tolvanen, Anne, Totland, Orjan, Troxler, Tiffany, Wahren, Carl-Henrik, Webber, Patrick J., Welker, Jeffery M., and Wookey, Philip A.

Abstract

Understanding the sensitivity of tundra vegetation to climate warming is critical to forecasting future biodiversity and vegetation feedbacks to climate. In situ warming experiments accelerate climate change on a small scale to forecast responses of local plant communities. Limitations of this approach include the apparent site-specificity of results and uncertainty about the power of short-term studies to anticipate longer term change. We address these issues with a synthesis of 61 experimental warming studies, of up to 20 years duration, in tundra sites worldwide. The response of plant groups to warming often differed with ambient summer temperature, soil moisture and experimental duration. Shrubs increased with warming only where ambient temperature was high, whereas graminoids increased primarily in the coldest study sites. Linear increases in effect size over time were frequently observed. There was little indication of saturating or accelerating effects, as would be predicted if negative or positive vegetation feedbacks were common. These results indicate that tundra vegetation exhibits strong regional variation in response to warming, and that in vulnerable regions, cumulative effects of long-term warming on tundra vegetation and associated ecosystem consequences have the potential to be much greater than we have observed to date.

Published
2012

44. Cumulative geoecological effects of 62 years of infrastructure and climate change in ice-rich permafrost landscapes, Prudhoe Bay Oilfield, Alaska

Author

Raynolds, Martha K., primary, Walker, Donald A., additional, Ambrosius, Kenneth J., additional, Brown, Jerry, additional, Everett, Kaye R., additional, Kanevskiy, Mikhail, additional, Kofinas, Gary P., additional, Romanovsky, Vladimir E., additional, Shur, Yuri, additional, and Webber, Patrick J., additional

Published
2014
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47. Plot-scale evidence of tundra vegetation change and links to recent summer warming

Author

Elmendorf, Sarah C., primary, Henry, Gregory H. R., additional, Hollister, Robert D., additional, Björk, Robert G., additional, Boulanger-Lapointe, Noémie, additional, Cooper, Elisabeth J., additional, Cornelissen, Johannes H. C., additional, Day, Thomas A., additional, Dorrepaal, Ellen, additional, Elumeeva, Tatiana G., additional, Gill, Mike, additional, Gould, William A., additional, Harte, John, additional, Hik, David S., additional, Hofgaard, Annika, additional, Johnson, David R., additional, Johnstone, Jill F., additional, Jónsdóttir, Ingibjörg Svala, additional, Jorgenson, Janet C., additional, Klanderud, Kari, additional, Klein, Julia A., additional, Koh, Saewan, additional, Kudo, Gaku, additional, Lara, Mark, additional, Lévesque, Esther, additional, Magnússon, Borgthor, additional, May, Jeremy L., additional, Mercado-Dı´az, Joel A., additional, Michelsen, Anders, additional, Molau, Ulf, additional, Myers-Smith, Isla H., additional, Oberbauer, Steven F., additional, Onipchenko, Vladimir G., additional, Rixen, Christian, additional, Martin Schmidt, Niels, additional, Shaver, Gaius R., additional, Spasojevic, Marko J., additional, Þórhallsdóttir, Þóra Ellen, additional, Tolvanen, Anne, additional, Troxler, Tiffany, additional, Tweedie, Craig E., additional, Villareal, Sandra, additional, Wahren, Carl-Henrik, additional, Walker, Xanthe, additional, Webber, Patrick J., additional, Welker, Jeffrey M., additional, and Wipf, Sonja, additional

Published
2012
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48. Global assessment of experimental climate warming on tundra vegetation: heterogeneity over space and time

Author

Elmendorf, Sarah C., primary, Henry, Gregory H. R., additional, Hollister, Robert D., additional, Björk, Robert G., additional, Bjorkman, Anne D., additional, Callaghan, Terry V., additional, Collier, Laura Siegwart, additional, Cooper, Elisabeth J., additional, Cornelissen, Johannes H. C., additional, Day, Thomas A., additional, Fosaa, Anna Maria, additional, Gould, William A., additional, Grétarsdóttir, Járngerður, additional, Harte, John, additional, Hermanutz, Luise, additional, Hik, David S., additional, Hofgaard, Annika, additional, Jarrad, Frith, additional, Jónsdóttir, Ingibjörg Svala, additional, Keuper, Frida, additional, Klanderud, Kari, additional, Klein, Julia A., additional, Koh, Saewan, additional, Kudo, Gaku, additional, Lang, Simone I., additional, Loewen, Val, additional, May, Jeremy L., additional, Mercado, Joel, additional, Michelsen, Anders, additional, Molau, Ulf, additional, Myers-Smith, Isla H., additional, Oberbauer, Steven F., additional, Pieper, Sara, additional, Post, Eric, additional, Rixen, Christian, additional, Robinson, Clare H., additional, Schmidt, Niels Martin, additional, Shaver, Gaius R., additional, Stenström, Anna, additional, Tolvanen, Anne, additional, Totland, Ørjan, additional, Troxler, Tiffany, additional, Wahren, Carl-Henrik, additional, Webber, Patrick J., additional, Welker, Jeffery M., additional, and Wookey, Philip A., additional

Published
2011
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