Search

Your search keyword '"Salmon, Verity"' showing total 152 results
Start Over Author "Salmon, Verity"
152 results on '"Salmon, Verity"'

1. Large Divergence of Projected High Latitude Vegetation Composition and Productivity Due To Functional Trait Uncertainty

Author

Liu, Yanlan, Holm, Jennifer A, Koven, Charles D, Salmon, Verity G, Rogers, Alistair, and Torn, Margaret S

Subjects
Hydrology, Climate Change Science, Earth Sciences, Climate Action, dynamic vegetation modeling, Arctic vegetation change, plant trait, vegetation demography, uncertainty analysis, Atmospheric Sciences, Physical Geography and Environmental Geoscience, Environmental Science and Management, Climate change science
Abstract

Vegetation distribution and composition are expected to change in northern high latitudes under rapid warming, which regulates ecosystem functions but remains challenging to predict. Vegetation change arises from the interplay of chronic climate trends such as warming and transient demographic processes of recruitment, growth, competition, and mortality. Most predictive models overlooked the role of demographic dynamics controlled by plant traits. Here, we simulate vegetation dynamics at the Kougarok Hillslope site in Alaska under historical and future climates using the E3SM Land Model coupled to the Functionally Assembled Terrestrial Simulator (ELM-FATES). To evaluate the roles of plant traits, we parameterize the model with 5,265 trait configurations representing diverse physiological and demographic strategies. Results show current modeled biomass, composition, and productivity are most sensitive to traits controlling photosynthetic capacity, carbon allocation, allometry, and phenology. Among all trait configurations, ∼5% reproduce in situ biomass and plant functional type (PFT) composition measured in 2016, that are indistinguishable from these two observed ecosystem states. Notably, these same trait configurations produce diverging biomass, composition, and productivity under future climate, where the uncertainty attributable to traits is twice the change attributable to climate change. The variation of projected productivity arises from emerging PFT composition under novel climate regimes, primarily explained by traits controlling cold-induced mortality, recruitment, and allometry. Our findings highlight the importance and uncertainty of demographic dynamics and its interaction with climate change in shaping Arctic vegetation change. Improved model predictions will likely benefit from explicit consideration of vegetation demography and better constraints of critical traits.

Published
2024

2. Abrupt permafrost thaw drives spatially heterogeneous soil moisture and carbon dioxide fluxes in upland tundra

Author

Rodenhizer, Heidi, Natali, Susan M, Mauritz, Marguerite, Taylor, Meghan A, Celis, Gerardo, Kadej, Stephanie, Kelley, Allison K, Lathrop, Emma R, Ledman, Justin, Pegoraro, Elaine F, Salmon, Verity G, Schädel, Christina, See, Craig, Webb, Elizabeth E, and Schuur, Edward AG

Subjects
Biological Sciences, Ecology, Climate Action, abrupt thaw, Arctic, carbon dioxide, carbon flux, permafrost, soil moisture, thermokarst, Environmental Sciences, Biological sciences, Earth sciences, Environmental sciences
Abstract

Permafrost thaw causes the seasonally thawed active layer to deepen, causing the Arctic to shift toward carbon release as soil organic matter becomes susceptible to decomposition. Ground subsidence initiated by ice loss can cause these soils to collapse abruptly, rapidly shifting soil moisture as microtopography changes and also accelerating carbon and nutrient mobilization. The uncertainty of soil moisture trajectories during thaw makes it difficult to predict the role of abrupt thaw in suppressing or exacerbating carbon losses. In this study, we investigated the role of shifting soil moisture conditions on carbon dioxide fluxes during a 13-year permafrost warming experiment that exhibited abrupt thaw. Warming deepened the active layer differentially across treatments, leading to variable rates of subsidence and formation of thermokarst depressions. In turn, differential subsidence caused a gradient of moisture conditions, with some plots becoming consistently inundated with water within thermokarst depressions and others exhibiting generally dry, but more variable soil moisture conditions outside of thermokarst depressions. Experimentally induced permafrost thaw initially drove increasing rates of growing season gross primary productivity (GPP), ecosystem respiration (Reco ), and net ecosystem exchange (NEE) (higher carbon uptake), but the formation of thermokarst depressions began to reverse this trend with a high level of spatial heterogeneity. Plots that subsided at the slowest rate stayed relatively dry and supported higher CO2 fluxes throughout the 13-year experiment, while plots that subsided very rapidly into the center of a thermokarst feature became consistently wet and experienced a rapid decline in growing season GPP, Reco , and NEE (lower carbon uptake or carbon release). These findings indicate that Earth system models, which do not simulate subsidence and often predict drier active layer conditions, likely overestimate net growing season carbon uptake in abruptly thawing landscapes.

Published
2023

3. The Arctic Plant Aboveground Biomass Synthesis Dataset

Author

Berner, Logan T., Orndahl, Kathleen M., Rose, Melissa, Tamstorf, Mikkel, Arndal, Marie F., Alexander, Heather D., Humphreys, Elyn R., Loranty, Michael M., Ludwig, Sarah M., Nyman, Johanna, Juutinen, Sari, Aurela, Mika, Happonen, Konsta, Mikola, Juha, Mack, Michelle C., Vankoughnett, Mathew R., Iversen, Colleen M., Salmon, Verity G., Yang, Dedi, Kumar, Jitendra, Grogan, Paul, Danby, Ryan K., Scott, Neal A., Olofsson, Johan, Siewert, Matthias B., Deschamps, Lucas, Lévesque, Esther, Maire, Vincent, Morneault, Amélie, Gauthier, Gilles, Gignac, Charles, Boudreau, Stéphane, Gaspard, Anna, Kholodov, Alexander, Bret-Harte, M. Syndonia, Greaves, Heather E., Walker, Donald, Gregory, Fiona M., Michelsen, Anders, Kumpula, Timo, Villoslada, Miguel, Ylänne, Henni, Luoto, Miska, Virtanen, Tarmo, Forbes, Bruce C., Hölzel, Norbert, Epstein, Howard, Heim, Ramona J., Bunn, Andrew, Holmes, Robert M., Hung, Jacqueline K. Y., Natali, Susan M., Virkkala, Anna-Maria, and Goetz, Scott J.

Published
2024
Full Text
View/download PDF

9. Direct observation of permafrost degradation and rapid soil carbon loss in tundra

Author

Plaza, César, Pegoraro, Elaine, Bracho, Rosvel, Celis, Gerardo, Crummer, Kathryn G, Hutchings, Jack A, Hicks Pries, Caitlin E, Mauritz, Marguerite, Natali, Susan M, Salmon, Verity G, Schädel, Christina, Webb, Elizabeth E, and Schuur, Edward AG

Subjects
Climate Action, Meteorology & Atmospheric Sciences
Published
2019

10. Biotic responses buffer warming‐induced soil organic carbon loss in Arctic tundra

Author

Liang, Junyi, Xia, Jiangyang, Shi, Zheng, Jiang, Lifen, Ma, Shuang, Lu, Xingjie, Mauritz, Marguerite, Natali, Susan M, Pegoraro, Elaine, Penton, Christopher Ryan, Plaza, César, Salmon, Verity G, Celis, Gerardo, Cole, James R, Konstantinidis, Konstantinos T, Tiedje, James M, Zhou, Jizhong, Schuur, Edward AG, and Luo, Yiqi

Subjects
Biological Sciences, Climate Action, Alaska, Carbon, Climate Change, Models, Theoretical, Permafrost, Photosynthesis, Plants, Soil, Soil Microbiology, Tundra, acclimation, biotic responses, carbon modeling, climate warming, data assimilation, permafrost, soil carbon, Environmental Sciences, Ecology, Biological sciences, Earth sciences, Environmental sciences
Abstract

Climate warming can result in both abiotic (e.g., permafrost thaw) and biotic (e.g., microbial functional genes) changes in Arctic tundra. Recent research has incorporated dynamic permafrost thaw in Earth system models (ESMs) and indicates that Arctic tundra could be a significant future carbon (C) source due to the enhanced decomposition of thawed deep soil C. However, warming-induced biotic changes may influence biologically related parameters and the consequent projections in ESMs. How model parameters associated with biotic responses will change under warming and to what extent these changes affect projected C budgets have not been carefully examined. In this study, we synthesized six data sets over 5 years from a soil warming experiment at the Eight Mile Lake, Alaska, into the Terrestrial ECOsystem (TECO) model with a probabilistic inversion approach. The TECO model used multiple soil layers to track dynamics of thawed soil under different treatments. Our results show that warming increased light use efficiency of vegetation photosynthesis but decreased baseline (i.e., environment-corrected) turnover rates of SOC in both the fast and slow pools in comparison with those under control. Moreover, the parameter changes generally amplified over time, suggesting processes of gradual physiological acclimation and functional gene shifts of both plants and microbes. The TECO model predicted that field warming from 2009 to 2013 resulted in cumulative C losses of 224 or 87 g/m2 , respectively, without or with changes in those parameters. Thus, warming-induced parameter changes reduced predicted soil C loss by 61%. Our study suggests that it is critical to incorporate biotic changes in ESMs to improve the model performance in predicting C dynamics in permafrost regions.

Published
2018

12. Divergent patterns of experimental and model-derived permafrost ecosystem carbon dynamics in response to Arctic warming

Author

Schädel, Christina, Koven, Charles D, Lawrence, David M, Celis, Gerardo, Garnello, Anthony J, Hutchings, Jack, Mauritz, Marguerite, Natali, Susan M, Pegoraro, Elaine, Rodenhizer, Heidi, Salmon, Verity G, Taylor, Meghan A, Webb, Elizabeth E, Wieder, William R, and Schuur, Edward AG

Subjects
Agricultural, Veterinary and Food Sciences, Biological Sciences, Ecology, Environmental Sciences, Forestry Sciences, Climate Action, gross primary productivity, net ecosystem exchange, ecosystem respiration, tundra, thaw, CLM, Meteorology & Atmospheric Sciences
Abstract

In the last few decades, temperatures in the Arctic have increased twice as much as the rest of the globe. As permafrost thaws in response to this warming, large amounts of soil organic matter may become vulnerable to decomposition. Microbial decomposition will release carbon (C) from permafrost soils, however, warmer conditions could also lead to enhanced plant growth and C uptake. Field and modeling studies show high uncertainty in soil and plant responses to climate change but there have been few studies that reconcile field and model data to understand differences and reduce uncertainty. Here, we evaluate gross primary productivity (GPP), ecosystem respiration (Reco), and net ecosystem C exchange (NEE) from eight years of experimental soil warming in moist acidic tundra against equivalent fluxes from the Community Land Model during simulations parameterized to reflect the field conditions associated with this manipulative field experiment. Over the eight-year experimental period, soil temperatures and thaw depths increased with warming in field observations and model simulations. However, the field and model results do not agree on warming effects on water table depth; warming created wetter soils in the field and drier soils in the models. In the field, initial increases in growing season GPP, Reco, and NEE to experimentally-induced permafrost thaw created a higher C sink capacity in the first years followed by a stronger C source in years six through eight. In contrast, both models predicted linear increases in GPP, Reco, and NEE with warming. The divergence of model results from field experiments reveals the role subsidence, hydrology, and nutrient cycling play in influencing the C flux responses to permafrost thaw, a complexity that the models are not structurally able to predict, and highlight challenges associated with projecting C cycle dynamics across the Arctic.

Published
2018

13. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change

Author

Salmon, Verity G., Brice, Deanne J., Bridgham, Scott, Childs, Joanne, Graham, Jake, Griffiths, Natalie A., Hofmockel, Kirsten, Iversen, Colleen M., Jicha, Terri M., Kolka, Randy K., Kostka, Joel E., Malhotra, Avni, Norby, Richard J., Phillips, Jana R., Ricciuto, Daniel, Schadt, Christopher W., Sebestyen, Stephen D., Shi, Xiaoying, Walker, Anthony P., Warren, Jeffrey M., Weston, David J., Yang, Xiaojuan, and Hanson, Paul J.

Published
2021
Full Text
View/download PDF

15. Nonlinear CO2 flux response to 7 years of experimentally induced permafrost thaw.

Author

Mauritz, Marguerite, Bracho, Rosvel, Celis, Gerardo, Hutchings, Jack, Natali, Susan M, Pegoraro, Elaine, Salmon, Verity G, Schädel, Christina, Webb, Elizabeth E, and Schuur, Edward AG

Subjects
Carbon Dioxide, Soil, Arctic Regions, Carbon Cycle, Tundra, Permafrost, Arctic, carbon, ecosystem respiration, experimental warming, gross primary productivity, net ecosystem exchange, permafrost, thaw, tundra, Ecology, Environmental Sciences, Biological Sciences
Abstract

Rapid Arctic warming is expected to increase global greenhouse gas concentrations as permafrost thaw exposes immense stores of frozen carbon (C) to microbial decomposition. Permafrost thaw also stimulates plant growth, which could offset C loss. Using data from 7 years of experimental Air and Soil warming in moist acidic tundra, we show that Soil warming had a much stronger effect on CO2 flux than Air warming. Soil warming caused rapid permafrost thaw and increased ecosystem respiration (Reco ), gross primary productivity (GPP), and net summer CO2 storage (NEE). Over 7 years Reco , GPP, and NEE also increased in Control (i.e., ambient plots), but this change could be explained by slow thaw in Control areas. In the initial stages of thaw, Reco , GPP, and NEE increased linearly with thaw across all treatments, despite different rates of thaw. As thaw in Soil warming continued to increase linearly, ground surface subsidence created saturated microsites and suppressed Reco , GPP, and NEE. However Reco and GPP remained high in areas with large Eriophorum vaginatum biomass. In general NEE increased with thaw, but was more strongly correlated with plant biomass than thaw, indicating that higher Reco in deeply thawed areas during summer months was balanced by GPP. Summer CO2 flux across treatments fit a single quadratic relationship that captured the functional response of CO2 flux to thaw, water table depth, and plant biomass. These results demonstrate the importance of indirect thaw effects on CO2 flux: plant growth and water table dynamics. Nonsummer Reco models estimated that the area was an annual CO2 source during all years of observation. Nonsummer CO2 loss in warmer, more deeply thawed soils exceeded the increases in summer GPP, and thawed tundra was a net annual CO2 source.

Published
2017

16. Environmental controls on observed spatial variability of soil pore water geochemistry in small headwater catchments underlain with permafrost

Author

Conroy, Nathan Alec, primary, Heikoop, Jeffrey M., additional, Lathrop, Emma, additional, Musa, Dea, additional, Newman, Brent D., additional, Xu, Chonggang, additional, McCaully, Rachael E., additional, Arendt, Carli A., additional, Salmon, Verity G., additional, Breen, Amy, additional, Romanovsky, Vladimir, additional, Bennett, Katrina E., additional, Wilson, Cathy J., additional, and Wullschleger, Stan D., additional

Published
2023
Full Text
View/download PDF

18. Contributors

Author

Abney, Rebecca, primary, Anderson, Jill T., additional, Andriuzzi, Walter, additional, Barnes, Morgan, additional, Benavides, Katherine, additional, Berhe, Asmeret Asefaw, additional, Bogie, Nathaniel, additional, Bradford, Mark A., additional, Callaham, Mac A., additional, Campbell, John L., additional, Carey, Joanna, additional, Carrell, Alyssa A., additional, Cavaleri, Molly A., additional, Cowden, Charles C., additional, Crowther, Thomas W., additional, DeAngelis, Kristen M., additional, Frankson, Paul T., additional, Frey, Serita, additional, Ghezzehei, Teamrat A., additional, Giardina, Christian P., additional, Groffman, Peter M., additional, Hannifin, Robert, additional, Harte, John, additional, Jabis, Meredith D., additional, Jiang, Lifen, additional, Jin, Lixia, additional, Khan, Shafkat, additional, Kivlin, Stephanie N., additional, Kueppers, Lara M., additional, Lubetkin, Kaitlin C., additional, Ludwig, Sarah, additional, Luo, Yiqi, additional, Machmuller, Megan B., additional, MacTavish, Rachel, additional, Melillo, Jerry M., additional, Mohan, Jacqueline E., additional, Moore, John C., additional, Moreland, Kimber, additional, Natali, Sue, additional, Nottingham, Andrew T., additional, Pold, Grace, additional, Pressler, Yamina, additional, Reed, Sasha C., additional, Romero-Olivares, Adriana, additional, Roy Chowdhury, Priyanka, additional, Rudgers, Jennifer A., additional, Rustad, Lindsey E., additional, Salmon, Verity, additional, Sanders-DeMott, Rebecca, additional, Santos, Fernanda, additional, Schuur, Ted, additional, Shao, Junjiong, additional, Shefferson, Richard P., additional, Shi, Zheng, additional, Simpson, Rodney, additional, Slot, Martijn, additional, Snyder, Bruce A., additional, Chapin, F. Stuart, additional, Sulman, Benjamin N., additional, Suseela, Vidya, additional, Tang, Jianwu, additional, Templer, Pamela H., additional, Todd-Brown, Katherine, additional, van Gestel, Natasja, additional, Wadgymar, Susana M., additional, Wall, Diana H., additional, Winkler, Daniel E., additional, Wood, Tana E., additional, Yang, Yan, additional, Zhou, Xuhui, additional, and Zhou, Zhenghu, additional

Published
2019
Full Text
View/download PDF

20. Permafrost and Climate Change: Carbon Cycle Feedbacks From the Warming Arctic

Author

Schuur, Edward A.G., primary, Abbott, Benjamin W., additional, Commane, Roisin, additional, Ernakovich, Jessica, additional, Euskirchen, Eugenie, additional, Hugelius, Gustaf, additional, Grosse, Guido, additional, Jones, Miriam, additional, Koven, Charlie, additional, Leshyk, Victor, additional, Lawrence, David, additional, Loranty, Michael M., additional, Mauritz, Marguerite, additional, Olefeldt, David, additional, Natali, Susan, additional, Rodenhizer, Heidi, additional, Salmon, Verity, additional, Schädel, Christina, additional, Strauss, Jens, additional, Treat, Claire, additional, and Turetsky, Merritt, additional

Published
2022
Full Text
View/download PDF

21. We Must Stop Fossil Fuel Emissions to Protect Permafrost Ecosystems

Author

Abbott, Benjamin W., primary, Brown, Michael, additional, Carey, Joanna C., additional, Ernakovich, Jessica, additional, Frederick, Jennifer M., additional, Guo, Laodong, additional, Hugelius, Gustaf, additional, Lee, Raymond M., additional, Loranty, Michael M., additional, Macdonald, Robie, additional, Mann, Paul J., additional, Natali, Susan M., additional, Olefeldt, David, additional, Pearson, Pam, additional, Rec, Abigail, additional, Robards, Martin, additional, Salmon, Verity G., additional, Sayedi, Sayedeh Sara, additional, Schädel, Christina, additional, Schuur, Edward A. G., additional, Shakil, Sarah, additional, Shogren, Arial J., additional, Strauss, Jens, additional, Tank, Suzanne E., additional, Thornton, Brett F., additional, Treharne, Rachael, additional, Turetsky, Merritt, additional, Voigt, Carolina, additional, Wright, Nancy, additional, Yang, Yuanhe, additional, Zarnetske, Jay P., additional, Zhang, Qiwen, additional, and Zolkos, Scott, additional

Published
2022
Full Text
View/download PDF

23. We Must Stop Fossil Fuel Emissions to Protect Permafrost Ecosystems

Author

Abbott, Benjamin W., Brown, Michael, Carey, Joanna C., Ernakovich, Jessica, Frederick, Jennifer, Guo, Laodong, Hugelius, Gustaf, Lee, Raymond M., Loranty, Michael M., Macdonald, Robie W, Mann, Paul James, Natali, Sue M., Olefeldt, David, Pearson, Pam, Rec, Abigail, Robards, Martin, Salmon, Verity G., Sayedi, Sayedeh Sara, Schädel, Christina, Schuur, Edward. A. G., Shakil, Sarah, Shogren, Arial J., Strauss, Jens, Tank, Suzanne E, Thornton, Brett F., Treharne, Rachael, Turetsky, Merritt, Voigt, Carolina, Wright, Nancy, Yang, Yuanhe, Zarnetske, Jay P., Zhang, Qiwen, Zolkos, Scott, Abbott, Benjamin W., Brown, Michael, Carey, Joanna C., Ernakovich, Jessica, Frederick, Jennifer, Guo, Laodong, Hugelius, Gustaf, Lee, Raymond M., Loranty, Michael M., Macdonald, Robie W, Mann, Paul James, Natali, Sue M., Olefeldt, David, Pearson, Pam, Rec, Abigail, Robards, Martin, Salmon, Verity G., Sayedi, Sayedeh Sara, Schädel, Christina, Schuur, Edward. A. G., Shakil, Sarah, Shogren, Arial J., Strauss, Jens, Tank, Suzanne E, Thornton, Brett F., Treharne, Rachael, Turetsky, Merritt, Voigt, Carolina, Wright, Nancy, Yang, Yuanhe, Zarnetske, Jay P., Zhang, Qiwen, and Zolkos, Scott

Abstract

Climate change is an existential threat to the vast global permafrost domain. The diverse human cultures, ecological communities, and biogeochemical cycles of this tenth of the planet depend on the persistence of frozen conditions. The complexity, immensity, and remoteness of permafrost ecosystems make it difficult to grasp how quickly things are changing and what can be done about it. Here, we summarize terrestrial and marine changes in the permafrost domain with an eye toward global policy. While many questions remain, we know that continued fossil fuel burning is incompatible with the continued existence of the permafrost domain as we know it. If we fail to protect permafrost ecosystems, the consequences for human rights, biosphere integrity, and global climate will be severe. The policy implications are clear: the faster we reduce human emissions and draw down atmospheric CO2, the more of the permafrost domain we can save. Emissions reduction targets must be strengthened and accompanied by support for local peoples to protect intact ecological communities and natural carbon sinks within the permafrost domain. Some proposed geoengineering interventions such as solar shading, surface albedo modification, and vegetation manipulations are unproven and may exacerbate environmental injustice without providing lasting protection. Conversely, astounding advances in renewable energy have reopened viable pathways to halve human greenhouse gas emissions by 2030 and effectively stop them well before 2050. We call on leaders, corporations, researchers, and citizens everywhere to acknowledge the global importance of the permafrost domain and work towards climate restoration and empowerment of Indigenous and immigrant communities in these regions.

Published
2022

24. Permafrost and Climate Change : Carbon Cycle Feedbacks From the Warming Arctic

Author

Schuur, Edward A. G., Abbott, Benjamin W., Commane, Roisin, Ernakovich, Jessica, Euskirchen, Eugenie, Hugelius, Gustaf, Grosse, Guido, Jones, Miriam, Koven, Charlie, Leshyk, Victor, Lawrence, David, Loranty, Michael M., Mauritz, Marguerite, Olefeldt, David, Natali, Susan, Rodenhizer, Heidi, Salmon, Verity, Schädel, Christina, Strauss, Jens, Treat, Claire, Turetsky, Merritt, Schuur, Edward A. G., Abbott, Benjamin W., Commane, Roisin, Ernakovich, Jessica, Euskirchen, Eugenie, Hugelius, Gustaf, Grosse, Guido, Jones, Miriam, Koven, Charlie, Leshyk, Victor, Lawrence, David, Loranty, Michael M., Mauritz, Marguerite, Olefeldt, David, Natali, Susan, Rodenhizer, Heidi, Salmon, Verity, Schädel, Christina, Strauss, Jens, Treat, Claire, and Turetsky, Merritt

Abstract

Rapid Arctic environmental change affects the entire Earth system as thawing permafrost ecosystems release greenhouse gases to the atmosphere. Understanding how much permafrost carbon will be released, over what time frame, and what the relative emissions of carbon dioxide and methane will be is key for understanding the impact on global climate. In addition, the response of vegetation in a warming climate has the potential to offset at least some of the accelerating feedback to the climate from permafrost carbon. Temperature, organic carbon, and ground ice are key regulators for determining the impact of permafrost ecosystems on the global carbon cycle. Together, these encompass services of permafrost relevant to global society as well as to the people living in the region and help to determine the landscape-level response of this region to a changing climate.

Published
2022
Full Text
View/download PDF

25. Permafrost and Climate Change: Carbon Cycle Feedbacks From the Warming Arctic

Author

Schuur, Edward AG, Abbott, Benjamin W, Commane, Roisin, Ernakovich, Jessica, Euskirchen, Eugenie S, Hugelius, Gustaf, Grosse, Guido, Jones, Miriam C, Koven, Charles, Leshyk, Victor, Lawrence, David M, Loranty, Michael M, Mauritz, Marguerite, Olefeldt, David, Natali, Susan M, Rodenhizer, Heidi, Salmon, Verity G, Schädel, Christina, Strauss, Jens, Treat, Claire, Turetsky, Merritt R, Schuur, Edward AG, Abbott, Benjamin W, Commane, Roisin, Ernakovich, Jessica, Euskirchen, Eugenie S, Hugelius, Gustaf, Grosse, Guido, Jones, Miriam C, Koven, Charles, Leshyk, Victor, Lawrence, David M, Loranty, Michael M, Mauritz, Marguerite, Olefeldt, David, Natali, Susan M, Rodenhizer, Heidi, Salmon, Verity G, Schädel, Christina, Strauss, Jens, Treat, Claire, and Turetsky, Merritt R

Abstract

Rapid Arctic environmental change affects the entire Earth system as thawing permafrost ecosystems release greenhouse gases to the atmosphere. Understanding how much permafrost carbon will be released, over what time frame, and what the relative emissions of carbon dioxide and methane will be is key for understanding the impact on global climate. In addition, the response of vegetation in a warming climate has the potential to offset at least some of the accelerating feedback to the climate from permafrost carbon. Temperature, organic carbon, and ground ice are key regulators for determining the impact of permafrost ecosystems on the global carbon cycle. Together, these encompass services of permafrost relevant to global society as well as to the people living in the region and help to determine the landscape-level response of this region to a changing climate.

Published
2022

26. We Must Stop Fossil Fuel Emissions to Protect Permafrost Ecosystems

Author

Abbott, Benjamin W, Brown, Michael, Carey, Joanna C, Ernakovich, Jessica, Frederick, Jennifer, Guo, Laodong, Hugelius, Gustaf, Lee, Raymond M, Loranty, Michael M, Macdonald, Robie W, Mann, Paul James, Natali, Sue M, Olefeldt, David, Pearson, Pam, Rec, Abigail, Robards, Martin, Salmon, Verity G, Sayedi, Sayedeh Sara, Schädel, Christina, Schuur, Edward AG, Shakil, Sarah, Shogren, Arial J, Strauss, Jens, Tank, Suzanne E, Thornton, Brett F, Treharne, Rachael, Turetsky, Merritt, Voigt, Carolina, Wright, Nancy, Yang, Yuanhe, Zarnetske, Jay P, Zhang, Qiwen, Zolkos, Scott, Abbott, Benjamin W, Brown, Michael, Carey, Joanna C, Ernakovich, Jessica, Frederick, Jennifer, Guo, Laodong, Hugelius, Gustaf, Lee, Raymond M, Loranty, Michael M, Macdonald, Robie W, Mann, Paul James, Natali, Sue M, Olefeldt, David, Pearson, Pam, Rec, Abigail, Robards, Martin, Salmon, Verity G, Sayedi, Sayedeh Sara, Schädel, Christina, Schuur, Edward AG, Shakil, Sarah, Shogren, Arial J, Strauss, Jens, Tank, Suzanne E, Thornton, Brett F, Treharne, Rachael, Turetsky, Merritt, Voigt, Carolina, Wright, Nancy, Yang, Yuanhe, Zarnetske, Jay P, Zhang, Qiwen, and Zolkos, Scott

Abstract

Climate change is an existential threat to the vast global permafrost domain. The diverse human cultures, ecological communities, and biogeochemical cycles of this tenth of the planet depend on the persistence of frozen conditions. The complexity, immensity, and remoteness of permafrost ecosystems make it difficult to grasp how quickly things are changing and what can be done about it. Here, we summarize terrestrial and marine changes in the permafrost domain with an eye toward global policy. While many questions remain, we know that continued fossil fuel burning is incompatible with the continued existence of the permafrost domain as we know it. If we fail to protect permafrost ecosystems, the consequences for human rights, biosphere integrity, and global climate will be severe. The policy implications are clear: the faster we reduce human emissions and draw down atmospheric CO2, the more of the permafrost domain we can save. Emissions reduction targets must be strengthened and accompanied by support for local peoples to protect intact ecological communities and natural carbon sinks within the permafrost domain. Some proposed geoengineering interventions such as solar shading, surface albedo modification, and vegetation manipulations are unproven and may exacerbate environmental injustice without providing lasting protection. Conversely, astounding advances in renewable energy have reopened viable pathways to halve human greenhouse gas emissions by 2030 and effectively stop them well before 2050. We call on leaders, corporations, researchers, and citizens everywhere to acknowledge the global importance of the permafrost domain and work towards climate restoration and empowerment of Indigenous and immigrant communities in these regions.

Published
2022

28. Supplementary material to "Environmental Controls on Observed Spatial Variability of Soil Pore Water Geochemistry in Small Headwater Catchments Underlain with Permafrost"

Author

Conroy, Nathan Alec, primary, Heikoop, Jeffrey, additional, Lathrop, Emma, additional, Musa, Dea, additional, Newman, Brent, additional, Xu, Chonggang, additional, McCaully, Rachael, additional, Arendt, Carli, additional, Salmon, Verity, additional, Breen, Amy, additional, Romanovsky, Vladimir, additional, Bennett, Katrina, additional, Wilson, Cathy, additional, and Wullschleger, Stan, additional

Published
2022
Full Text
View/download PDF

29. Environmental Controls on Observed Spatial Variability of Soil Pore Water Geochemistry in Small Headwater Catchments Underlain with Permafrost

Author

Conroy, Nathan Alec, primary, Heikoop, Jeffrey, additional, Lathrop, Emma, additional, Musa, Dea, additional, Newman, Brent, additional, Xu, Chonggang, additional, McCaully, Rachael, additional, Arendt, Carli, additional, Salmon, Verity, additional, Breen, Amy, additional, Romanovsky, Vladimir, additional, Bennett, Katrina, additional, Wilson, Cathy, additional, and Wullschleger, Stan, additional

Published
2022
Full Text
View/download PDF

30. Corrigendum

Author

Bengough, A. Glyn, primary, Blancaflor, Elison B., additional, Brunner, Ivano, additional, Comas, Louise H., additional, Freschet, Grégoire T., additional, Gessler, Arthur, additional, Iversen, Colleen M., additional, Janěcek, Štěpán, additional, Kliměsová, Jitka, additional, Lambers, Hans, additional, McCormack, M. Luke, additional, Meier, Ina C., additional, Mommer, Liesje, additional, Pagès, Loïc, additional, Poorter, Hendrik, additional, Postma, Johannes A., additional, Rewald, Boris, additional, Rose, Laura, additional, Roumet, Catherine, additional, Ryser, Peter, additional, Salmon, Verity, additional, Scherer‐Lorenzen, Michael, additional, Soudzilovskaia, Nadejda A., additional, Tharayil, Nishanth, additional, Valverde‐Barrantes, Oscar J., additional, Weemstra, Monique, additional, Weigelt, Alexandra, additional, Wurzburger, Nina, additional, York, Larry M., additional, and Zadworny, Marcin, additional

Published
2022
Full Text
View/download PDF

31. Whole-Ecosystem Warming Increases Plant-Available Nitrogen and Phosphorus in an Ombrotrophic Bog

Author

Iversen, Colleen M., primary, Latimer, John, additional, Brice, Deanne J., additional, Childs, Joanne, additional, Vander Stel, Holly M., additional, Defrenne, Camille E., additional, Graham, Jake, additional, Griffiths, Natalie A., additional, Malhotra, Avni, additional, Norby, Richard J., additional, Oleheiser, Keith C., additional, Phillips, Jana R., additional, Salmon, Verity G., additional, Sebestyen, Stephen D., additional, Yang, Xiaojuan, additional, and Hanson, Paul J., additional

Published
2022
Full Text
View/download PDF

33. A starting guide to root ecology: strengthening ecological concepts and standardising root classification, sampling, processing and trait measurements

Author

Freschet, Grégoire T., primary, Pagès, Loïc, additional, Iversen, Colleen M., additional, Comas, Louise H., additional, Rewald, Boris, additional, Roumet, Catherine, additional, Klimešová, Jitka, additional, Zadworny, Marcin, additional, Poorter, Hendrik, additional, Postma, Johannes A., additional, Adams, Thomas S., additional, Bagniewska‐Zadworna, Agnieszka, additional, Bengough, A. Glyn, additional, Blancaflor, Elison B., additional, Brunner, Ivano, additional, Cornelissen, Johannes H. C., additional, Garnier, Eric, additional, Gessler, Arthur, additional, Hobbie, Sarah E., additional, Meier, Ina C., additional, Mommer, Liesje, additional, Picon‐Cochard, Catherine, additional, Rose, Laura, additional, Ryser, Peter, additional, Scherer‐Lorenzen, Michael, additional, Soudzilovskaia, Nadejda A., additional, Stokes, Alexia, additional, Sun, Tao, additional, Valverde‐Barrantes, Oscar J., additional, Weemstra, Monique, additional, Weigelt, Alexandra, additional, Wurzburger, Nina, additional, York, Larry M., additional, Batterman, Sarah A., additional, Gomes de Moraes, Moemy, additional, Janeček, Štěpán, additional, Lambers, Hans, additional, Salmon, Verity, additional, Tharayil, Nishanth, additional, and McCormack, M. Luke, additional

Published
2021
Full Text
View/download PDF

36. Supplementary material to "High Temporal and Spatial Nitrate Variability on an Alaskan Hillslope Dominated by Alder Shrubs"

Author

McCaully, Rachael E., primary, Arendt, Carli A., additional, Newman, Brent D., additional, Salmon, Verity G., additional, Heikoop, Jeffrey M., additional, Wilson, Cathy J., additional, Sevanto, Sanna, additional, Wales, Nathan A., additional, Perkins, George B., additional, Marina, Oana C., additional, and Wullschleger, Stan D., additional

Published
2021
Full Text
View/download PDF

37. Shallow soils are warmer under trees and tall shrubs across arctic and boreal ecosystems

Author

Kropp, Heather, Loranty, Michael M., Natali, Susan M., Kholodov, Alexander L., Rocha, Adrian V., Myers-Smith, Isla H., Abbott, Benjamin W., Abermann, Jakob, Blanc-Betes, Elena, Blok, Daan, Blume-Werry, Gesche, Boike, Julia, Breen, Amy L., Cahoon, Sean M. P., Christiansen, Casper T., Douglas, Thomas A., Epstein, Howard E., Frost, Gerald V., Goeckede, Mathias, Høye, Toke T., Mamet, Steven D., O’Donnell, Jonathan A., Olefeldt, David, Phoenix, Gareth K., Salmon, Verity G., Sannel, A. Britta K., Smith, Sharon L., Sonnentag, Oliver, Smith Vaughn, Lydia, Williams, Mathew, Elberling, Bo, Gough, Laura, Hjort, Jan, Lafleur, Peter M., Euskirchen, Eugenie, Heijmans, Monique M. P. D., Humphreys, Elyn, Iwata, Hiroki, Jones, Benjamin M., Jorgenson, M. Torre, Grünberg, Inge, Kim, Yongwon, Laundre, James A., Mauritz, Marguerite, Michelsen, Anders, Schaepman-Strub, Gabriela, Tape, Ken D., Ueyama, Masahito, Lee, Bang-Yong, Langley, Kirsty, Lund, Magnus, Kropp, Heather, Loranty, Michael M., Natali, Susan M., Kholodov, Alexander L., Rocha, Adrian V., Myers-Smith, Isla H., Abbott, Benjamin W., Abermann, Jakob, Blanc-Betes, Elena, Blok, Daan, Blume-Werry, Gesche, Boike, Julia, Breen, Amy L., Cahoon, Sean M. P., Christiansen, Casper T., Douglas, Thomas A., Epstein, Howard E., Frost, Gerald V., Goeckede, Mathias, Høye, Toke T., Mamet, Steven D., O’Donnell, Jonathan A., Olefeldt, David, Phoenix, Gareth K., Salmon, Verity G., Sannel, A. Britta K., Smith, Sharon L., Sonnentag, Oliver, Smith Vaughn, Lydia, Williams, Mathew, Elberling, Bo, Gough, Laura, Hjort, Jan, Lafleur, Peter M., Euskirchen, Eugenie, Heijmans, Monique M. P. D., Humphreys, Elyn, Iwata, Hiroki, Jones, Benjamin M., Jorgenson, M. Torre, Grünberg, Inge, Kim, Yongwon, Laundre, James A., Mauritz, Marguerite, Michelsen, Anders, Schaepman-Strub, Gabriela, Tape, Ken D., Ueyama, Masahito, Lee, Bang-Yong, Langley, Kirsty, and Lund, Magnus

Abstract

© The Author(s), 2021. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Kropp, H., Loranty, M. M., Natali, S. M., Kholodov, A. L., Rocha, A., V., Myers-Smith, I., Abbot, B. W., Abermann, J., Blanc-Betes, E., Blok, D., Blume-Werry, G., Boike, J., Breen, A. L., Cahoon, S. M. P., Christiansen, C. T., Douglas, T. A., Epstein, H. E., Frost, G., V., Goeckede, M., Hoye, T. T., Mamet, S. D., O'Donnell, J. A., Olefeldt, D., Phoenix, G. K., Salmon, V. G., Sannel, A. B. K., Smith, S. L., Sonnentag, O., Vaughn, L. S., Williams, M., Elberling, B., Gough, L., Hjort, J., Lafleur, P. M., Euskirchen, E. S., Heijmans, M. M. P. D., Humphreys, E. R., Iwata, H., Jones, B. M., Jorgenson, M. T., Gruenberg, I., Kim, Y., Laundre, J., Mauritz, M., Michelsen, A., Schaepman-Strub, G., Tape, K. D., Ueyama, M., Lee, B., Langley, K., & Lund, M. Shallow soils are warmer under trees and tall shrubs across arctic and boreal ecosystems. Environmental Research Letters, 16(1), (2021): 015001. doi:10.1088/1748-9326/abc994., Soils are warming as air temperatures rise across the Arctic and Boreal region concurrent with the expansion of tall-statured shrubs and trees in the tundra. Changes in vegetation structure and function are expected to alter soil thermal regimes, thereby modifying climate feedbacks related to permafrost thaw and carbon cycling. However, current understanding of vegetation impacts on soil temperature is limited to local or regional scales and lacks the generality necessary to predict soil warming and permafrost stability on a pan-Arctic scale. Here we synthesize shallow soil and air temperature observations with broad spatial and temporal coverage collected across 106 sites representing nine different vegetation types in the permafrost region. We showed ecosystems with tall-statured shrubs and trees (>40 cm) have warmer shallow soils than those with short-statured tundra vegetation when normalized to a constant air temperature. In tree and tall shrub vegetation types, cooler temperatures in the warm season do not lead to cooler mean annual soil temperature indicating that ground thermal regimes in the cold-season rather than the warm-season are most critical for predicting soil warming in ecosystems underlain by permafrost. Our results suggest that the expansion of tall shrubs and trees into tundra regions can amplify shallow soil warming, and could increase the potential for increased seasonal thaw depth and increase soil carbon cycling rates and lead to increased carbon dioxide loss and further permafrost thaw., We thank G Peter Kershaw, LeeAnn Fishback, Cathy Wilson, and Coleen Iversen for assistance in collection of data. We thank the Permafrost Carbon Network for support and organization of the data synthesis. We thank Vladimir Romanovsky for his feedback and contribution of publicly available data. This project was supported by the National Science Foundation (Grant No. 1417745 to M L, Grant No. 1417700 to S M N, Grant No. 1417908 to A K, Grant No. 1556772 to A R, Grant No. 1637459 to L G, Grant No. 1636476 and Grant No. 1503912 to E S E, Grant No. 1806213 to B M J, Grant No. 1833056 to K D T), UK Natural Environment Research Council (Grant No. NE/M016323/1 to I H M S, Grant No. NE/K00025X/1 to G K P, Grant No. NE/K000292/1 to M W), Natural Sciences and Engineering Research (to P L, I H M S, Grant No. RGPIN-2016-04688 to D O), Council of Canada, Canadian Graduate Scholarship to (I H M -S), Greenland Ecosystem Monitoring Programme: ClimateBasis (to J A and K A), The Next-Generation Ecosystem Experiments (NGEE Arctic) project is supported by the Office of Biological and Environmental Research in the DOE Office of Science (to A L B), Engineer Research and Development Center Army Direct (6.1) Research Program and the Strategic Environmental Research and Development Program (projects RC-2110 and 18-1170 to T A D), United States Geological Survey (to E E S), Arctic Challenge for Sustainability (ArCS; Grant No. JPMXD1300000000) and ArCS II (Grant No. JPMXD1420318865) (to M U and H I), the Danish National Research Foundation (Grant No. CENPERM DNRF100 to B E), the Academy of Finland (Grant No. 315519), the National Research Foundation of Korea (Grant Nos. NRF-2016M1A5A1901769; KOPRI-PN20081 to K Y and B Y L), Research Network for Geosciences in Berlin and Potsdam (to I G), the Swiss National Science Foundation (Grant No. 140631 to G S S), the URPP Global Change and Biodiversity, University of Zurich (to G S S), the University of Alberta Northern Research Awards (to D O), and th

Published
2021

38. A starting guide to root ecology : strengthening ecological concepts and standardising root classification, sampling, processing and trait measurements

Author

Freschet, Grégoire T., Pagès, Loïc, Iversen, Colleen M., Comas, Louise H., Rewald, Boris, Roumet, Catherine, Klimešová, Jitka, Zadworny, Marcin, Poorter, Hendrik, Postma, Johannes A., Adams, Thomas S., Bagniewska-Zadworna, Agnieszka, Bengough, A.G., Blancaflor, Elison B., Brunner, Ivano, Cornelissen, Johannes H.C., Garnier, Eric, Gessler, Arthur, Hobbie, Sarah E., Meier, Ina C., Mommer, Liesje, Picon-Cochard, Catherine, Rose, Laura, Ryser, Peter, Scherer-Lorenzen, Michael, Soudzilovskaia, Nadejda A., Stokes, Alexia, Sun, Tao, Valverde-Barrantes, Oscar J., Weemstra, Monique, Weigelt, Alexandra, Wurzburger, Nina, York, Larry M., Batterman, Sarah A., Gomes de Moraes, Moemy, Janeček, Štěpán, Lambers, Hans, Salmon, Verity, Tharayil, Nishanth, McCormack, M.L., Freschet, Grégoire T., Pagès, Loïc, Iversen, Colleen M., Comas, Louise H., Rewald, Boris, Roumet, Catherine, Klimešová, Jitka, Zadworny, Marcin, Poorter, Hendrik, Postma, Johannes A., Adams, Thomas S., Bagniewska-Zadworna, Agnieszka, Bengough, A.G., Blancaflor, Elison B., Brunner, Ivano, Cornelissen, Johannes H.C., Garnier, Eric, Gessler, Arthur, Hobbie, Sarah E., Meier, Ina C., Mommer, Liesje, Picon-Cochard, Catherine, Rose, Laura, Ryser, Peter, Scherer-Lorenzen, Michael, Soudzilovskaia, Nadejda A., Stokes, Alexia, Sun, Tao, Valverde-Barrantes, Oscar J., Weemstra, Monique, Weigelt, Alexandra, Wurzburger, Nina, York, Larry M., Batterman, Sarah A., Gomes de Moraes, Moemy, Janeček, Štěpán, Lambers, Hans, Salmon, Verity, Tharayil, Nishanth, and McCormack, M.L.

Abstract

In the context of a recent massive increase in research on plant root functions and their impact on the environment, root ecologists currently face many important challenges to keep on generating cutting-edge, meaningful and integrated knowledge. Consideration of the below-ground components in plant and ecosystem studies has been consistently called for in recent decades, but methodology is disparate and sometimes inappropriate. This handbook, based on the collective effort of a large team of experts, will improve trait comparisons across studies and integration of information across databases by providing standardised methods and controlled vocabularies. It is meant to be used not only as starting point by students and scientists who desire working on below-ground ecosystems, but also by experts for consolidating and broadening their views on multiple aspects of root ecology. Beyond the classical compilation of measurement protocols, we have synthesised recommendations from the literature to provide key background knowledge useful for: (1) defining below-ground plant entities and giving keys for their meaningful dissection, classification and naming beyond the classical fine-root vs coarse-root approach; (2) considering the specificity of root research to produce sound laboratory and field data; (3) describing typical, but overlooked steps for studying roots (e.g. root handling, cleaning and storage); and (4) gathering metadata necessary for the interpretation of results and their reuse. Most importantly, all root traits have been introduced with some degree of ecological context that will be a foundation for understanding their ecological meaning, their typical use and uncertainties, and some methodological and conceptual perspectives for future research. Considering all of this, we urge readers not to solely extract protocol recommendations for trait measurements from this work, but to take a moment to read and reflect on the extensive information contained in th

Published
2021

40. Shallow soils are warmer under trees and tall shrubs across Arctic and Boreal ecosystems

Author

Kropp, Heather, Loranty, Michael M., Natali, Susan M, Kholodov, Alexander L, Rocha, Adrian V, Myers-Smith, Isla H., Abbott, Benjamin W, Abermann, Jakob, Blanc-Betes, Elena, Blok, Daan, Blume-Werry, Gesche, Boike, Julia, Breen, Amy L., Cahoon, Sean M.P., Christiansen, Casper T., Douglas, Thomas A., Epstein, Howard E., Frost, Gerald V, Goeckede, Mathias, Høye, Toke T., Mamet, Steven Douglas, O'Donnell, Jonathan A., Olefeldt, David, Phoenix, Gareth K., Salmon, Verity G., Sannel, Anna Britta Kristina, Smith, Sharon L., Sonnentag, Oliver, Vaughn, Lydia, Williams, Mathew, Elberling, Bo, Gough, Laura, Hjort, Jan, Lafleur, Peter M., Euskirchen, Eugenie S, Heijmans, Monique, Humphreys, Elyn R, Iwata, Hiroki, Jones, Benjamin M., Jorgenson, Torre, Grünberg, Inge, Kim, Yongwon, Laundre, James, Mauritz, Marguerite, Michelsen, Anders, Schaepman-Strub, Gabriela, Tape, Ken D, Ueyama, Masahito, Lee, Bang-Yong, Langley, Kirsty, Lund, Magnus, Kropp, Heather, Loranty, Michael M., Natali, Susan M, Kholodov, Alexander L, Rocha, Adrian V, Myers-Smith, Isla H., Abbott, Benjamin W, Abermann, Jakob, Blanc-Betes, Elena, Blok, Daan, Blume-Werry, Gesche, Boike, Julia, Breen, Amy L., Cahoon, Sean M.P., Christiansen, Casper T., Douglas, Thomas A., Epstein, Howard E., Frost, Gerald V, Goeckede, Mathias, Høye, Toke T., Mamet, Steven Douglas, O'Donnell, Jonathan A., Olefeldt, David, Phoenix, Gareth K., Salmon, Verity G., Sannel, Anna Britta Kristina, Smith, Sharon L., Sonnentag, Oliver, Vaughn, Lydia, Williams, Mathew, Elberling, Bo, Gough, Laura, Hjort, Jan, Lafleur, Peter M., Euskirchen, Eugenie S, Heijmans, Monique, Humphreys, Elyn R, Iwata, Hiroki, Jones, Benjamin M., Jorgenson, Torre, Grünberg, Inge, Kim, Yongwon, Laundre, James, Mauritz, Marguerite, Michelsen, Anders, Schaepman-Strub, Gabriela, Tape, Ken D, Ueyama, Masahito, Lee, Bang-Yong, Langley, Kirsty, and Lund, Magnus

Abstract

Soils are warming as air temperatures rise across the Arctic and Boreal region concurrent with the expansion of tall-statured shrubs and trees in the tundra. Changes in vegetation structure and function are expected to alter soil thermal regimes, thereby modifying climate feedbacks related to permafrost thaw and carbon cycling. However, current understanding of vegetation impacts on soil temperature is limited to local or regional scales and lacks the generality necessary to predict soil warming and permafrost stability on a pan-Arctic scale. Here we synthesize shallow soil and air temperature observations with broad spatial and temporal coverage collected across 106 sites representing nine different vegetation types in the permafrost region. We showed ecosystems with tall-statured shrubs and trees (> 40 cm) have warmer shallow soils than those with short-statured tundra vegetation when normalized to a constant air temperature. In tree and tall shrub vegetation types, cooler temperatures in the warm season do not lead to cooler mean annual soil temperature indicating that ground thermal regimes in the cold-season rather than the warm-season are most critical for predicting soil warming in ecosystems underlain by permafrost. Our results suggest that the expansion of tall shrubs and trees into tundra regions can amplify shallow soil warming, and could increase the potential for increased seasonal thaw depth and increase soil carbon cycling rates and lead to increased carbon dioxide loss and further permafrost thaw.

Published
2020

42. Shallow soils are warmer under trees and tall shrubs across Arctic and Boreal ecosystems

Author

Kropp, Heather, primary, Loranty, Michael M, additional, Natali, Susan M, additional, Kholodov, Alexander L, additional, Rocha, Adrian V, additional, Myers-Smith, Isla, additional, Abbot, Benjamin W, additional, Abermann, Jakob, additional, Blanc-Betes, Elena, additional, Blok, Daan, additional, Blume-Werry, Gesche, additional, Boike, Julia, additional, Breen, Amy L, additional, Cahoon, Sean M P, additional, Christiansen, Casper T, additional, Douglas, Thomas A, additional, Epstein, Howard E, additional, Frost, Gerald V, additional, Goeckede, Mathias, additional, Høye, Toke T, additional, Mamet, Steven D, additional, O’Donnell, Jonathan A, additional, Olefeldt, David, additional, Phoenix, Gareth K, additional, Salmon, Verity G, additional, Sannel, A Britta K, additional, Smith, Sharon L, additional, Sonnentag, Oliver, additional, Vaughn, Lydia Smith, additional, Williams, Mathew, additional, Elberling, Bo, additional, Gough, Laura, additional, Hjort, Jan, additional, Lafleur, Peter M, additional, Euskirchen, Eugenie S, additional, Heijmans, Monique MPD, additional, Humphreys, Elyn R, additional, Iwata, Hiroki, additional, Jones, Benjamin M, additional, Jorgenson, M Torre, additional, Grünberg, Inge, additional, Kim, Yongwon, additional, Laundre, James, additional, Mauritz, Marguerite, additional, Michelsen, Anders, additional, Schaepman-Strub, Gabriela, additional, Tape, Ken D, additional, Ueyama, Masahito, additional, Lee, Bang-Yong, additional, Langley, Kirsty, additional, and Lund, Magnus, additional

Published
2020
Full Text
View/download PDF

43. Environmental Controls on Observed Spatial Variability of Soil Pore Water Geochemistry in Small Headwater Catchments Underlain with Permafrost.

Author

Conroy, Nathan Alec, Heikoop, Jeffrey M., Lathrop, Emma, Musa, Dea, Newman, Brent D., Chonggang Xu, McCaully, Rachael E., Arendt, Carli A., Salmon, Verity G., Breen, Amy, Romanovsky, Vladimir, Bennett, Katrina E., Wilson, Cathy J., and Wullschleger, Stan D.

Subjects
SPATIAL analysis (Statistics), GEOCHEMISTRY, PERMAFROST, GEOCHEMICAL cycles, WATER chemistry
Abstract

Soil pore water (SPW) chemistry can vary substantially across multiple scales in Arctic permafrost landscapes. The magnitude of these variations and their relationship to scale are critical considerations for understanding current controls on geochemical cycling and for predicting future changes. These aspects are especially important for Arctic change modelling where accurate representation of sub-grid variability may be necessary to predict watershed scale behaviours. Our research goal was to characterize intra- and inter-watershed soil water geochemical variations at two contrasting locations in the Seward Peninsula of Alaska, USA. We then attempt to establish which environmental factors were important for controlling concentrations of important pore water solutes in these systems. The SPW geochemistry of 18 locations spanning two small Arctic catchments were examined for spatial variability and its dominant environmental controls. The primary environmental controls considered were vegetation, soil moisture/redox condition, water/soil interactions and hydrologic transport, and mineral solubility. The sampling locations varied in terms of vegetation type and canopy height, presence or absence of near-surface permafrost, soil moisture, and hillslope position. Vegetation was found to have a significant impact on SPW NO3 concentrations, associated with the localized presence of nitrogen-fixing alders and mineralization and nitrification of leaf litter from tall willow shrubs. The elevated NO3 concentrations were however, frequently equipoised by increased microbial denitrification in regions with sufficient moisture to support it. Vegetation also had an observable impact on soil moisture sensitive constituents, but the effect was less significant. The redox conditions in both catchments were generally limited by Fe reduction, seemingly well-buffered by a cache of amorphous Fe hydroxides, with the most reducing conditions found at sampling locations with the highest soil moisture content. Non-redox-sensitive cations were affected by a wide variety of water-soil interactions that affect mineral solubility and transport. Identification of the dominant controls on current SPW hydrogeochemistry allows for qualitative prediction of future geochemical trends in small Arctic catchments that are likely to experience warming and permafrost thaw. As source areas for geochemical fluxes to the broader Arctic hydrologic system, geochemical processes occurring in these environments are particularly important to understand and predict with regards to such environmental changes. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

44. Assessing dynamic vegetation model parameter uncertainty across Alaskan arctic tundra plant communities.

Author

Euskirchen, Eugénie S., Serbin, Shawn P., Carman, Tobey B., Fraterrigo, Jennifer M., Genet, Hélène, Iversen, Colleen M., Salmon, Verity, and McGuire, A. David

Subjects
TUNDRAS, PLANT communities, HETEROTROPHIC respiration, TEMPERATURE control, DYNAMIC models, COASTAL plains, PRIMARY productivity (Biology)
Abstract

As the Arctic region moves into uncharted territory under a warming climate, it is important to refine the terrestrial biosphere models (TBMs) that help us understand and predict change. One fundamental uncertainty in TBMs relates to model parameters, configuration variables internal to the model whose value can be estimated from data. We incorporate a version of the Terrestrial Ecosystem Model (TEM) developed for arctic ecosystems into the Predictive Ecosystem Analyzer (PEcAn) framework. PEcAn treats model parameters as probability distributions, estimates parameters based on a synthesis of available field data, and then quantifies both model sensitivity and uncertainty to a given parameter or suite of parameters. We examined how variation in 21 parameters in the equation for gross primary production influenced model sensitivity and uncertainty in terms of two carbon fluxes (net primary productivity and heterotrophic respiration) and two carbon (C) pools (vegetation C and soil C). We set up different parameterizations of TEM across a range of tundra types (tussock tundra, heath tundra, wet sedge tundra, and shrub tundra) in northern Alaska, along a latitudinal transect extending from the coastal plain near Utqiaġvik to the southern foothills of the Brooks Range, to the Seward Peninsula. TEM was most sensitive to parameters related to the temperature regulation of photosynthesis. Model uncertainty was mostly due to parameters related to leaf area, temperature regulation of photosynthesis, and the stomatal responses to ambient light conditions. Our analysis also showed that sensitivity and uncertainty to a given parameter varied spatially. At some sites, model sensitivity and uncertainty tended to be connected to a wider range of parameters, underlining the importance of assessing tundra community processes across environmental gradients or geographic locations. Generally, across sites, the flux of net primary productivity (NPP) and pool of vegetation C had about equal uncertainty, while heterotrophic respiration had higher uncertainty than the pool of soil C. Our study illustrates the complexity inherent in evaluating parameter uncertainty across highly heterogeneous arctic tundra plant communities. It also provides a framework for iteratively testing how newly collected field data related to key parameters may result in more effective forecasting of Arctic change. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

47. Direct observation of permafrost degradation and rapid soil carbon loss in tundra

Author

Plaza de Carlos, César, Pegoraro, Elaine, Bracho, Rosvel, Celis, Gerardo, Crummer, Kathryn G., Hutchings, Jack A., Hicks Pries, Caitlin E., Mauritz, Marguerite, Natali, Susan M., Salmon, Verity G., Schädel, Christina, Webb, Elizabeth E., Schuur, Edward A. G., Plaza de Carlos, César, Pegoraro, Elaine, Bracho, Rosvel, Celis, Gerardo, Crummer, Kathryn G., Hutchings, Jack A., Hicks Pries, Caitlin E., Mauritz, Marguerite, Natali, Susan M., Salmon, Verity G., Schädel, Christina, Webb, Elizabeth E., and Schuur, Edward A. G.

Published
2019

49. Tundra is a consistent source of CO2 at a site with progressive permafrost thaw during 6 years of chamber and eddy covariance measurements

Author

Celis, Gerardo, primary, Mauritz, Marguerite, additional, Bracho, Rosvel, additional, Salmon, Verity G., additional, Webb, Elizabeth E., additional, Hutchings, Jack, additional, Natali, Susan M., additional, Schädel, Christina, additional, Crummer, Kathryn G., additional, and Schuur, Edward A. G., additional

Published
2017
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results