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3. A simplified, data-constrained approach to estimate the permafrost carbonclimate feedback

Author

Koven, CD, Schuur, EAG, Schädel, C, Bohn, TJ, Burke, EJ, Chen, G, Chen, X, Ciais, P, Grosse, G, Harden, JW, Hayes, DJ, Hugelius, G, Jafarov, EE, Krinner, G, Kuhry, P, Lawrence, DM, MacDougall, AH, Marchenko, SS, McGuire, AD, Natali, SM, Nicolsky, DJ, Olefeldt, D, Peng, S, Romanovsky, VE, Schaefer, KM, Strauss, J, Treat, CC, and Turetsky, M

Subjects
Agricultural, Veterinary and Food Sciences, Biological Sciences, Forestry Sciences, Climate Action, Carbon, Climate Change, Computer Simulation, Databases, Factual, Ecosystem, Environmental Monitoring, Feedback, Freezing, Models, Chemical, Models, Statistical, Permafrost, permafrost, climate change, carbon-climate feedbacks, methane, carbon–climate feedbacks, General Science & Technology
Abstract

We present an approach to estimate the feedback from large-scale thawing of permafrost soils using a simplified, data-constrained model that combines three elements: soil carbon (C) maps and profiles to identify the distribution and type of C in permafrost soils; incubation experiments to quantify the rates of C lost after thaw; and models of soil thermal dynamics in response to climate warming. We call the approach the Permafrost Carbon Network Incubation-Panarctic Thermal scaling approach (PInc-PanTher). The approach assumes that C stocks do not decompose at all when frozen, but once thawed follow set decomposition trajectories as a function of soil temperature. The trajectories are determined according to a three-pool decomposition model fitted to incubation data using parameters specific to soil horizon types. We calculate litterfall C inputs required to maintain steady-state C balance for the current climate, and hold those inputs constant. Soil temperatures are taken from the soil thermal modules of ecosystem model simulations forced by a common set of future climate change anomalies under two warming scenarios over the period 2010 to 2100. Under a medium warming scenario (RCP4.5), the approach projects permafrost soil C losses of 12.2-33.4 Pg C; under a high warming scenario (RCP8.5), the approach projects C losses of 27.9-112.6 Pg C. Projected C losses are roughly linearly proportional to global temperature changes across the two scenarios. These results indicate a global sensitivity of frozen soil C to climate change (γ sensitivity) of -14 to -19 Pg C °C(-1) on a 100 year time scale. For CH4 emissions, our approach assumes a fixed saturated area and that increases in CH4 emissions are related to increased heterotrophic respiration in anoxic soil, yielding CH4 emission increases of 7% and 35% for the RCP4.5 and RCP8.5 scenarios, respectively, which add an additional greenhouse gas forcing of approximately 10-18%. The simplified approach presented here neglects many important processes that may amplify or mitigate C release from permafrost soils, but serves as a data-constrained estimate on the forced, large-scale permafrost C response to warming.

Published
2015

4. A simplified, data-constrained approach to estimate the permafrost carbon-climate feedback.

Author

Koven, CD, Schuur, EAG, Schädel, C, Bohn, TJ, Burke, EJ, Chen, G, Chen, X, Ciais, P, Grosse, G, Harden, JW, Hayes, DJ, Hugelius, G, Jafarov, EE, Krinner, G, Kuhry, P, Lawrence, DM, MacDougall, AH, Marchenko, SS, McGuire, AD, Natali, SM, Nicolsky, DJ, Olefeldt, D, Peng, S, Romanovsky, VE, Schaefer, KM, Strauss, J, Treat, CC, and Turetsky, M

Subjects
Carbon, Models, Statistical, Ecosystem, Environmental Monitoring, Freezing, Models, Chemical, Feedback, Computer Simulation, Databases, Factual, Climate Change, Permafrost, carbon–climate feedbacks, climate change, methane, permafrost, carbon-climate feedbacks, General Science & Technology
Abstract

We present an approach to estimate the feedback from large-scale thawing of permafrost soils using a simplified, data-constrained model that combines three elements: soil carbon (C) maps and profiles to identify the distribution and type of C in permafrost soils; incubation experiments to quantify the rates of C lost after thaw; and models of soil thermal dynamics in response to climate warming. We call the approach the Permafrost Carbon Network Incubation-Panarctic Thermal scaling approach (PInc-PanTher). The approach assumes that C stocks do not decompose at all when frozen, but once thawed follow set decomposition trajectories as a function of soil temperature. The trajectories are determined according to a three-pool decomposition model fitted to incubation data using parameters specific to soil horizon types. We calculate litterfall C inputs required to maintain steady-state C balance for the current climate, and hold those inputs constant. Soil temperatures are taken from the soil thermal modules of ecosystem model simulations forced by a common set of future climate change anomalies under two warming scenarios over the period 2010 to 2100. Under a medium warming scenario (RCP4.5), the approach projects permafrost soil C losses of 12.2-33.4 Pg C; under a high warming scenario (RCP8.5), the approach projects C losses of 27.9-112.6 Pg C. Projected C losses are roughly linearly proportional to global temperature changes across the two scenarios. These results indicate a global sensitivity of frozen soil C to climate change (γ sensitivity) of -14 to -19 Pg C °C(-1) on a 100 year time scale. For CH4 emissions, our approach assumes a fixed saturated area and that increases in CH4 emissions are related to increased heterotrophic respiration in anoxic soil, yielding CH4 emission increases of 7% and 35% for the RCP4.5 and RCP8.5 scenarios, respectively, which add an additional greenhouse gas forcing of approximately 10-18%. The simplified approach presented here neglects many important processes that may amplify or mitigate C release from permafrost soils, but serves as a data-constrained estimate on the forced, large-scale permafrost C response to warming.

Published
2015

5. The Zero Emissions Commitment and climate stabilization

Author

Palazzo Corner, S., Siegert, M., Ceppi, P., Fox-Kemper, B., Frölicher, T., Gallego-Sala, A., Haigh, J., Hegerl, G., Jones, C., Knutti, R., Koven, C., MacDougall, A., Meinshausen, M., Nicholls, Z., Sallée, J., Sanderson, B., Séférian, R., Turetsky, M., Williams, R., Zaehle, S., Rogelj, J., Palazzo Corner, S., Siegert, M., Ceppi, P., Fox-Kemper, B., Frölicher, T., Gallego-Sala, A., Haigh, J., Hegerl, G., Jones, C., Knutti, R., Koven, C., MacDougall, A., Meinshausen, M., Nicholls, Z., Sallée, J., Sanderson, B., Séférian, R., Turetsky, M., Williams, R., Zaehle, S., and Rogelj, J.

Abstract

How do we halt global warming? Reaching net zero carbon dioxide (CO2) emissions is understood to be a key milestone on the path to a safer planet. But how confident are we that when we stop carbon emissions, we also stop global warming? The Zero Emissions Commitment (ZEC) quantifies how much warming or cooling we can expect following a complete cessation of anthropogenic CO2 emissions. To date, the best estimate by the Intergovernmental Panel on Climate Change (IPCC) Sixth Assessment Report is zero change, though with substantial uncertainty. In this article, we present an overview of the changes expected in major Earth system processes after net zero and their potential impact on global surface temperature, providing an outlook toward building a more confident assessment of ZEC in the decades to come. We propose a structure to guide research into ZEC and associated changes in the climate, separating the impacts expected over decades, centuries, and millennia. As we look ahead at the century billed to mark the end of net anthropogenic CO2 emissions, we ask: what is the prospect of a stable climate in a post-net zero world?

Published
2023
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6. Mapping boreal peatland ecosystem types from multitemporal radar and optical satellite imagery

Author

Bourgeau-Chavez, L.L., Endres, S., Powell, R., Battaglia, M.J., Benscoter, B., Turetsky, M., Kasischke, E.S., and Banda, E.

Subjects
Peat bogs -- Identification and classification, Vegetation mapping -- Methods, Earth sciences
Abstract

The ability to distinguish peatland types at the landscape scale has implications for inventory, conservation, estimation of carbon storage, fuel loading, and postfire carbon emissions, among others. This paper presents a multisensor, multiseason remote sensing approach to delineate boreal peatland types (wooded bog, open fen, shrubby fen, treed fen) using a combination of multiple dates of L-band (24 cm) synthetic aperture radar (SAR) from ALOS PALSAR, C-band (~5.6 cm) from ERS-1 or ERS-2, and Landsat 5 TM optical remote sensing data. Imagery was first evaluated over a small test area of boreal Alberta, Canada, to determine the feasibility of using multisensor SAR and optical data to discriminate peatland types. Then object-based and (or) machine-learning classification algorithms were applied to 3.4 million ha of peatland-rich subregions of Alberta, Canada, and the 4.24 million ha region of Michigan's Upper Peninsula where peatlands are less dominant. Accuracy assessments based on field-sampled sites show high overall map accuracies (93%-94% for Alberta and Michigan), which exceed those of previous mapping efforts. Key words: peatlands, fens, bogs, boreal, synthetic aperture radar, SAR, Landsat, PALSAR, ERS-2, Random Forests, mapping. La capacite de distinguer les types de tourbieres a l'echelle du paysage a des repercussions notamment sur l'inventaire, la conservation, l'estimation de la sequestration du carbone, la charge de combustible et les emissions de carbone apres un feu. Cet article presente une approche de teledetection multi-capteur et multi-saison pour delimiter les differents types de tourbieres boreales (tourbieres ombrotrophes boisees, tourbieres minerotrophes ouvertes, arbustives ou arborees) a l'aide d'une combinaison de donnees de teledetection multi-temporelles du radar a synthese d'ouverture (SAR) en bande L (24 cm) du satellite ALOS PALSAR et en bande C (~5,6 cm) du satellite ERS-1 ou ERS-2 ainsi que de donnees optiques du satellite Landsat 5 TM. L'imagerie a d'abord ete evaluee sur une superficie experimentale limitee dans le nord de l'Alberta, au Canada, pour determiner la faisabilite d'utiliser le SAR multi-capteur et des donnees optiques pour distinguer les types de tourbieres. Ensuite, des algorithmes de classification fondes sur les objets ou l'apprentissage automatique ont ete appliques a 3,4 millions ha de sous-regions de l'Alberta, au Canada, riches en tourbieres et a la region de 4,24 millions ha de la peninsule superieure du Michigan ou les tourbieres sont moins dominantes. Les evaluations de la precision fondees sur les sites echantillonnes au sol montrent des precisions cartographiques globales elevees (93-94 % pour l'Alberta et le Michigan) qui depassent celles des essais anterieurs de cartographies. [Traduit par la Redaction] Mots-cles: tourbieres, tourbieres minerotrophes, tourbieres ombrotrophes, boreal, radar a synthese d'ouverture, (SAR), Landsat, PALSAR, ERS-2, forets aleatoires, cartographie., Introduction Peatlands are defined as having saturated soils, anaerobic conditions, and large accumulations of partially decomposed organic plant material (peat) below the ground. This accumulation is a result of low [...]

Published
2017
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7. A simplified, data-constrained approach to estimate the permafrost carbon–climate feedback

Author

Koven, C. D., Schuur, E. A. G., Schädel, C., Bohn, T. J., Burke, E. J., Chen, G., Chen, X., Ciais, P., Grosse, G., Harden, J. W., Hayes, D. J., Hugelius, G., Jafarov, E. E., Krinner, G., Kuhry, P., Lawrence, D. M., MacDougall, A. H., Marchenko, S. S., McGuire, A. D., Natali, S. M., Nicolsky, D. J., Olefeldt, D., Peng, S., Romanovsky, V. E., Schaefer, K. M., Strauss, J., Treat, C. C., and Turetsky, M.

Published
2015

11. Terrestrial and Freshwater Ecosystems and Their Services

Author

Singh, Bettina, Parmesan, C, Morecroft, MD, Trisurat, Y, Adrian, R, Anshari, GZ, Arneth, A, Gao, Q, Gonzalez, P, Harris, R, Price, J, Stevens, N, Talukdar, GH, Strutz, SE, Ackerly, DD, Anderson, E, Boyd, P, Birkmann, J, Bremerich, V, Brotons, L, Buotte, P, Campbell, D, Castellanos, E, Chen, Y-Y, Cissé, G, Cooley, S, Cowie, A, Dhimal, M, Domisch, S, Donner, S, Douwes, Errol, Escobar, LE, Rivera Ferre, M, Flecker, A, Foden, W, Gallagher, RV, Gaxiola, A, Gemeda, A, Goulding, M, Grey, K-A, López Gunn, E, Harrison, S, Hicke, J, Hilmi, NJM, Barragan-Jason, G, Keith, DA, Bezner Kerr, R, Kraemer, BM, Langhans, S, Lasco, R, Latimer, A, Lempert, R, Lluch-Cota, SE, Loisel, J, Mackey, J, Martinetto, P, Matthews, R, McPhearson, T, Mauritzen, M, Midgley, G, Mordecai, E, Moreira, F, Mukherji, A, Myers-Smith, I, Nabuurs, G-J, Neufeldt, H, Pearce-Higgins, J, Pecl, G, Pedace, R, Townsend Peterson, A, Piepenburg, D, Postigo, JC, Pulhin, J, Racault, M-F, Rocklöv, J, Rogelj, J, Rost, B, Romanello, M, Gallego-Sala, A, Schmidt, D, Schoeman, D, Seddon, N, Semenza, JC, Singer, MC, Singh, PK, Slingsby, J, Smith, P, Sukumar, R, Tirado, MC, Trisos, C, Turetsky, M, Turner, B, van Aalst, M, Young, K, Singh, Bettina, Parmesan, C, Morecroft, MD, Trisurat, Y, Adrian, R, Anshari, GZ, Arneth, A, Gao, Q, Gonzalez, P, Harris, R, Price, J, Stevens, N, Talukdar, GH, Strutz, SE, Ackerly, DD, Anderson, E, Boyd, P, Birkmann, J, Bremerich, V, Brotons, L, Buotte, P, Campbell, D, Castellanos, E, Chen, Y-Y, Cissé, G, Cooley, S, Cowie, A, Dhimal, M, Domisch, S, Donner, S, Douwes, Errol, Escobar, LE, Rivera Ferre, M, Flecker, A, Foden, W, Gallagher, RV, Gaxiola, A, Gemeda, A, Goulding, M, Grey, K-A, López Gunn, E, Harrison, S, Hicke, J, Hilmi, NJM, Barragan-Jason, G, Keith, DA, Bezner Kerr, R, Kraemer, BM, Langhans, S, Lasco, R, Latimer, A, Lempert, R, Lluch-Cota, SE, Loisel, J, Mackey, J, Martinetto, P, Matthews, R, McPhearson, T, Mauritzen, M, Midgley, G, Mordecai, E, Moreira, F, Mukherji, A, Myers-Smith, I, Nabuurs, G-J, Neufeldt, H, Pearce-Higgins, J, Pecl, G, Pedace, R, Townsend Peterson, A, Piepenburg, D, Postigo, JC, Pulhin, J, Racault, M-F, Rocklöv, J, Rogelj, J, Rost, B, Romanello, M, Gallego-Sala, A, Schmidt, D, Schoeman, D, Seddon, N, Semenza, JC, Singer, MC, Singh, PK, Slingsby, J, Smith, P, Sukumar, R, Tirado, MC, Trisos, C, Turetsky, M, Turner, B, van Aalst, M, and Young, K

Published
2022

13. Climate change and the permafrost carbon feedback

Author

Schuur, E. A. G., McGuire, A. D., Schädel, C., Grosse, G., Harden, J. W., Hayes, D. J., Hugelius, G., Koven, C. D., Kuhry, P., Lawrence, D. M., Natali, S. M., Olefeldt, D., Romanovsky, V. E., Schaefer, K., Turetsky, M. R., Treat, C. C., and Vonk, J. E.

Published
2015
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14. Expert assessment of vulnerability of permafrost carbon to climate change

Author

Schuur, E. A. G., Abbott, B. W., Bowden, W. B., Brovkin, V., Camill, P., Canadell, J. G., Chanton, J. P., Chapin, III, F. S., Christensen, T. R., Ciais, P., Crosby, B. T., Czimczik, C. I., Grosse, G., Harden, J., Hayes, D. J., Hugelius, G., Jastrow, J. D., Jones, J. B., Kleinen, T., Koven, C. D., Krinner, G., Kuhry, P., Lawrence, D. M., McGuire, A. D., Natali, S. M., O’Donnell, J. A., Ping, C. L., Riley, W. J., Rinke, A., Romanovsky, V. E., Sannel, A. B. K., Schädel, C., Schaefer, K., Sky, J., Subin, Z. M., Tarnocai, C., Turetsky, M. R., Waldrop, M. P., Walter Anthony, K. M., Wickland, K. P., Wilson, C. J., and Zimov, S. A.

Published
2013
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15. Mapping and understanding the vulnerability of northern peatlands to permafrost thaw at scales relevant to community adaptation planning

Author

Gibson, C., Cottenie, K., Gingras-Hill, T., Kokelj, S. V., Baltzer, J. L., Chasmer, Laura, Turetsky, M. R., Gibson, C., Cottenie, K., Gingras-Hill, T., Kokelj, S. V., Baltzer, J. L., Chasmer, Laura, and Turetsky, M. R.

Abstract

Developing spatially explicit permafrost datasets and climate assessments at scales relevant to northern communities is increasingly important as land users and decision makers incorporate changing permafrost conditions in community and adaptation planning. This need is particularly strong within the discontinuous permafrost zone of the Northwest Territories (NWT) Canada where permafrost peatlands are undergoing rapid thaw due to a warming climate. Current data products for predicting landscapes at risk of thaw are generally built at circumpolar scales and do not lend themselves well to fine-scale regional interpretations. Here, we present a new permafrost vulnerability dataset that assesses the degree of permafrost thaw within peatlands across a 750 km latitudinal gradient in the NWT. This updated dataset provides spatially explicit estimates of where peatland thermokarst potential exists, thus making it much more suitable for local, regional or community usage. Within southern peatland complexes, we show that permafrost thaw affects up to 70% of the peatland area and that thaw is strongly mediated by both latitude and elevation, with widespread thaw occuring particularly at low elevations. At the northern end of our latitudinal gradient, peatland permafrost remains climate-protected with relatively little thaw. Collectively these results demonstrate the importance of scale in permafrost analyses and mapping if research is to support northern communities and decision makers in a changing climate. This study offers a more scale-appropriate approach to support community adaptative planning under scenarios of continued warming and widespread permafrost thaw.

Published
2021

16. Permafrost

Author

Food and Agriculture Organization of the United Nations, (FAO), Intergovernmental Technical Panel on Soils, (ITPS), Strauss, Jens, Abbott, Benjamin, Hugelius, Gustaf, Schuur, Edward. A. G., Treat, Claire, Fuchs, Matthias, Schädel, Christina, Ulrich, Mathias, Turetsky, M. R., Keuschnig, Markus, Biasi, Christina, Yang, Yuanhe, Grosse, Guido, Food and Agriculture Organization of the United Nations, (FAO), Intergovernmental Technical Panel on Soils, (ITPS), Strauss, Jens, Abbott, Benjamin, Hugelius, Gustaf, Schuur, Edward. A. G., Treat, Claire, Fuchs, Matthias, Schädel, Christina, Ulrich, Mathias, Turetsky, M. R., Keuschnig, Markus, Biasi, Christina, Yang, Yuanhe, and Grosse, Guido

Abstract

Permafrost is perennially frozen ground, such as soil, rock, and ice. In permafrost regions, plant and microbial life persists primarily in the near-surface soil that thaws every summer, called the ‘active layer’ (Figure 20). The cold and wet conditions in many permafrost regions limit decomposition of organic matter. In combination with soil mixing processes caused by repeated freezing and thawing, this has led to the accumulation of large stocks of soil organic carbon in the permafrost zone over multi-millennial timescales. As the climate warms, permafrost carbon could be highly vulnerable to climatic warming. Permafrost occurs primarily in high latitudes (e.g. Arctic and Antarctic) and at high elevation (e.g. Tibetan Plateau, Figure 21). The thickness of permafrost varies from less than 1 m (in boreal peatlands) to more than 1 500 m (in Yakutia). The coldest permafrost is found in the Transantarctic Mountains in Antarctica (−36°C) and in northern Canada for the Northern Hemisphere (-15°C; Obu et al., 2019, 2020). In contrast, some of the warmest permafrost occurs in peatlands in areas with mean air temperatures above 0°C. Here permafrost exists because thick peat layers insulate the ground during the summer. Most of the permafrost existing today formed during cold glacials (e.g. before 12 000 years ago) and has persisted through warmer interglacials. Some shallow permafrost (max 30–70m depth) formed during the Holocene (past 5000 years) and some even during the Little Ice Age from 400–150 years ago. There are few extensive regions suitable for row crop agriculture in the permafrost zone. Additionally, in areas where large-scale agriculture has been conducted, ground destabilization has been common. Surface disturbance such as plowing or trampling of vegetation can alter the thermal regime of the soil, potentially triggering surface subsidence or abrupt collapse. This may influence soil hydrology, nutrient cycling, and organic matter storage. These changes often h

Published
2021

17. Carbon Fluxes and Microbial Activities From Boreal Peatlands Experiencing Permafrost Thaw

Author

Waldrop, M. P., McFarland, J., Manies, K. L., Leewis, M. C., Blazewicz, S. J., Jones, M. C., Neumann, R. B., Keller, J. K., Cohen, L., Euskirchen, E. S., Edgar, C., Turetsky, M. R., Cable, W. L., Waldrop, M. P., McFarland, J., Manies, K. L., Leewis, M. C., Blazewicz, S. J., Jones, M. C., Neumann, R. B., Keller, J. K., Cohen, L., Euskirchen, E. S., Edgar, C., Turetsky, M. R., and Cable, W. L.

Abstract

Permafrost thaw in northern ecosystems may cause large quantities of carbon (C) to move from soil to atmospheric pools. Because soil microbial communities play a critical role in regulating C fluxes from soils, we examined microbial activity and greenhouse gas production soon after permafrost thaw and ground collapse (into collapse‐scar bogs), relative to the permafrost plateau or older thaw features. Using multiple field and laboratory‐based assays at a field site in interior Alaska, we show that the youngest collapse‐scar bog had the highest CH4 production potential from soil incubations, and, based upon temporal changes in porewater concentrations and 13C‐CH4 and 13C‐CO2, had greater summer in situ rates of respiration, methanogenesis, and surface CH4 oxidation. These patterns could be explained by greater C and N availability in the young bog, while alternative terminal electron accepting processes did not play a significant role. Field diffusive CH4 fluxes from the young bog were 4.1 times greater in the shoulder season and 1.7–7.2 times greater in winter relative to older bogs, but not during summer. Greater relative CH4 flux rates in the shoulder season and winter could be due to reduced CH4 oxidation relative to summer, magnifying the importance of differences in production. Both the permafrost plateau and collapse‐scar bogs were sources of C to the atmosphere due in large part to winter C fluxes. In collapse scar bogs, winter is a critical period when differences in thermokarst age translates to differences in surface fluxes.

Published
2021

20. Biological and geophysical feedbacks with fire in the Earth system

Author

Australian Research Council, National Aeronautics and Space Administration (US), Archibald, S. [0000-0003-2786-3976], Greve, M. [0000-0002-6229-8506], McGlinn, D. J. [0000-0003-2359-3526], Pausas, J. G. [0000-0003-3533-5786], Turetsky, M. R. [0000-0003-0155-8666], Archibald, S., Lehmann, C. E. R., Belcher, Claire M., Bond, W. J., Bradstock, R. A., Daniau, A. L., Dexter, Kyle G., Forrestel, E. J., Greve, Michelle, He, Tianhua, Higgins, S. I., Hoffmann, W. A., Lamont, Byron B., McGlinn, D. J., Moncrieff, G. R., Osborne, C. P., Pausas, J. G., Price, Owen F., Ripley, B. S., Rogers, B. M., Schwilk, Dylan W., Simon, Marcelo F., Turetsky, M. R., Werf, G. R. Van der, Zanne, A. E., Australian Research Council, National Aeronautics and Space Administration (US), Archibald, S. [0000-0003-2786-3976], Greve, M. [0000-0002-6229-8506], McGlinn, D. J. [0000-0003-2359-3526], Pausas, J. G. [0000-0003-3533-5786], Turetsky, M. R. [0000-0003-0155-8666], Archibald, S., Lehmann, C. E. R., Belcher, Claire M., Bond, W. J., Bradstock, R. A., Daniau, A. L., Dexter, Kyle G., Forrestel, E. J., Greve, Michelle, He, Tianhua, Higgins, S. I., Hoffmann, W. A., Lamont, Byron B., McGlinn, D. J., Moncrieff, G. R., Osborne, C. P., Pausas, J. G., Price, Owen F., Ripley, B. S., Rogers, B. M., Schwilk, Dylan W., Simon, Marcelo F., Turetsky, M. R., Werf, G. R. Van der, and Zanne, A. E.

Abstract

Roughly 3% of the Earth's land surface burns annually, representing a critical exchange of energy and matter between the land and atmosphere via combustion. Fires range from slow smouldering peat fires, to low-intensity surface fires, to intense crown fires, depending on vegetation structure, fuel moisture, prevailing climate, and weather conditions. While the links between biogeochemistry, climate and fire are widely studied within Earth system science, these relationships are also mediated by fuels—namely plants and their litter—that are the product of evolutionary and ecological processes. Fire is a powerful selective force and, over their evolutionary history, plants have evolved traits that both tolerate and promote fire numerous times and across diverse clades. Here we outline a conceptual framework of how plant traits determine the flammability of ecosystems and interact with climate and weather to influence fire regimes. We explore how these evolutionary and ecological processes scale to impact biogeochemical and Earth system processes. Finally, we outline several research challenges that, when resolved, will improve our understanding of the role of plant evolution in mediating the fire feedbacks driving Earth system processes. Understanding current patterns of fire and vegetation, as well as patterns of fire over geological time, requires research that incorporates evolutionary biology, ecology, biogeography, and the biogeosciences.

Published
2018

21. Resilience of Alaska's Boreal Forest to Climatic Change

Author

Chapin, F. S., III, McGuire, A. D, Ruess, R. W, Hollingsworth, T. N, Mack, M. C, Johnstone, J. F, Kasischke, E. S, Euskirchen, E. S, Jones, J. B, Jorgenson, M. T, Kielland, K, Kofinas, G. P, Turetsky, M. R, Yarie, J, Lloyd, A. H, and Taylor, D. L

Subjects
Earth Resources And Remote Sensing
Abstract

This paper assesses the resilience of Alaska s boreal forest system to rapid climatic change. Recent warming is associated with reduced growth of dominant tree species, plant disease and insect outbreaks, warming and thawing of permafrost, drying of lakes, increased wildfire extent, increased postfire recruitment of deciduous trees, and reduced safety of hunters traveling on river ice. These changes have modified key structural features, feedbacks, and interactions in the boreal forest, including reduced effects of upland permafrost on regional hydrology, expansion of boreal forest into tundra, and amplification of climate warming because of reduced albedo (shorter winter season) and carbon release from wildfires. Other temperature-sensitive processes for which no trends have been detected include composition of plant and microbial communities, long-term landscape-scale change in carbon stocks, stream discharge, mammalian population dynamics, and river access and subsistence opportunities for rural indigenous communities. Projections of continued warming suggest that Alaska s boreal forest will undergo significant functional and structural changes within the next few decades that are unprecedented in the last 6000 years. The impact of these social ecological changes will depend in part on the extent of landscape reorganization between uplands and lowlands and on policies regulating subsistence opportunities for rural communities.

Published
2010
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22. Alaska's Changing Fire Regime - Implications for the Vulnerability of Its Boreal Forests

Author

Kasischke, E. S, Hoy, E. E, Verbyla, D. L, Rupp, T. S, Duffy, P. A, McGuire, A. D, Murphy, K. A, Jandt, R, Barnes, J. L, Calef, M, and Turetsky, M. R

Subjects
Earth Resources And Remote Sensing
Abstract

A synthesis was carried out to examine Alaska s boreal forest fire regime. During the 2000s, an average of 767 000 ha/year burned, 50% higher than in any previous decade since the 1940s. Over the past 60 years, there was a decrease in the number of lightning-ignited fires, an increase in extreme lightning-ignited fire events, an increase in human-ignited fires, and a decrease in the number of extreme human-ignited fire events. The fraction of area burned from humanignited fires fell from 26% for the 1950s and 1960s to 5% for the 1990s and 2000s, a result from the change in fire policy that gave the highest suppression priorities to fire events that occurred near human settlements. The amount of area burned during late-season fires increased over the past two decades. Deeper burning of surface organic layers in black spruce (Picea mariana (Mill.) BSP) forests occurred during late-growing-season fires and on more well-drained sites. These trends all point to black spruce forests becoming increasingly vulnerable to the combined changes of key characteristics of Alaska s fire regime, except on poorly drained sites, which are resistant to deep burning. The implications of these fire regime changes to the vulnerability and resilience of Alaska s boreal forests and land and fire management are discussed.

Published
2010
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23. Modeling Fire Severity in Black Spruce Stands in the Alaskan Boreal Forest Using Spectral and Non-Spectral Geospatial Data

Author

Barrett, K, Kasischke, E. S, McGuire, A. D, Turetsky, M. R, and Kane, E. S

Subjects
Earth Resources And Remote Sensing
Abstract

Biomass burning in the Alaskan interior is already a major disturbance and source of carbon emissions, and is likely to increase in response to the warming and drying predicted for the future climate. In addition to quantifying changes to the spatial and temporal patterns of burned areas, observing variations in severity is the key to studying the impact of changes to the fire regime on carbon cycling, energy budgets, and post-fire succession. Remote sensing indices of fire severity have not consistently been well-correlated with in situ observations of important severity characteristics in Alaskan black spruce stands, including depth of burning of the surface organic layer. The incorporation of ancillary data such as in situ observations and GIS layers with spectral data from Landsat TM/ETM+ greatly improved efforts to map the reduction of the organic layer in burned black spruce stands. Using a regression tree approach, the R2 of the organic layer depth reduction models was 0.60 and 0.55 (pb0.01) for relative and absolute depth reduction, respectively. All of the independent variables used by the regression tree to estimate burn depth can be obtained independently of field observations. Implementation of a gradient boosting algorithm improved the R2 to 0.80 and 0.79 (pb0.01) for absolute and relative organic layer depth reduction, respectively. Independent variables used in the regression tree model of burn depth included topographic position, remote sensing indices related to soil and vegetation characteristics, timing of the fire event, and meteorological data. Post-fire organic layer depth characteristics are determined for a large (N200,000 ha) fire to identify areas that are potentially vulnerable to a shift in post-fire succession. This application showed that 12% of this fire event experienced fire severe enough to support a change in post-fire succession. We conclude that non-parametric models and ancillary data are useful in the modeling of the surface organic layer fire depth. Because quantitative differences in post-fire surface characteristics do not directly influence spectral properties, these modeling techniques provide better information than the use of remote sensing data alone.

Published
2010
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24. Ten new insights in climate science 2020- A horizon scan

Author

Pihl, E., Alfredsson, Eva, Bengtsson, M., Bowen, K. J., Cástan Broto, V., Chou, K. T., Cleugh, H., Ebi, K., Edwards, C. M., Fisher, E., Friedlingstein, P., Godoy-Faúndez, A., Gupta, M., Harrington, A. R., Hayes, K., Hayward, B. M., Hebden, S. R., Hickmann, T., Hugelius, G., Ilyina, T., Jackson, R. B., Keenan, T. F., Lambino, R. A., Leuzinger, S., Malmaeus, M., McDonald, R. I., McMichael, C., Miller, C. A., Muratori, M., Nagabhatla, N., Nagendra, H., Passarello, C., Penuelas, J., Pongratz, J., Rockström, J., Romero-Lankao, P., Roy, J., Scaife, A. A., Schlosser, P., Schuur, E., Scobie, M., Sherwood, S. C., Sioen, G. B., Skovgaard, J., Sobenes Obregon, E. A., Sonntag, S., Spangenberg, J. H., Spijkers, O., Srivastava, L., Stammer, D. B., Torres, P. H. C., Turetsky, M. R., Ukkola, A. M., Van Vuuren, D. P., Voigt, C., Wannous, C., Zelinka, M. D., Pihl, E., Alfredsson, Eva, Bengtsson, M., Bowen, K. J., Cástan Broto, V., Chou, K. T., Cleugh, H., Ebi, K., Edwards, C. M., Fisher, E., Friedlingstein, P., Godoy-Faúndez, A., Gupta, M., Harrington, A. R., Hayes, K., Hayward, B. M., Hebden, S. R., Hickmann, T., Hugelius, G., Ilyina, T., Jackson, R. B., Keenan, T. F., Lambino, R. A., Leuzinger, S., Malmaeus, M., McDonald, R. I., McMichael, C., Miller, C. A., Muratori, M., Nagabhatla, N., Nagendra, H., Passarello, C., Penuelas, J., Pongratz, J., Rockström, J., Romero-Lankao, P., Roy, J., Scaife, A. A., Schlosser, P., Schuur, E., Scobie, M., Sherwood, S. C., Sioen, G. B., Skovgaard, J., Sobenes Obregon, E. A., Sonntag, S., Spangenberg, J. H., Spijkers, O., Srivastava, L., Stammer, D. B., Torres, P. H. C., Turetsky, M. R., Ukkola, A. M., Van Vuuren, D. P., Voigt, C., Wannous, C., and Zelinka, M. D.

Abstract

Non-technical summary We summarize some of the past year's most important findings within climate change-related research. New research has improved our understanding of Earth's sensitivity to carbon dioxide, finds that permafrost thaw could release more carbon emissions than expected and that the uptake of carbon in tropical ecosystems is weakening. Adverse impacts on human society include increasing water shortages and impacts on mental health. Options for solutions emerge from rethinking economic models, rights-based litigation, strengthened governance systems and a new social contract. The disruption caused by COVID-19 could be seized as an opportunity for positive change, directing economic stimulus towards sustainable investments. Technical summary A synthesis is made of ten fields within climate science where there have been significant advances since mid-2019, through an expert elicitation process with broad disciplinary scope. Findings include: (1) a better understanding of equilibrium climate sensitivity; (2) abrupt thaw as an accelerator of carbon release from permafrost; (3) changes to global and regional land carbon sinks; (4) impacts of climate change on water crises, including equity perspectives; (5) adverse effects on mental health from climate change; (6) immediate effects on climate of the COVID-19 pandemic and requirements for recovery packages to deliver on the Paris Agreement; (7) suggested long-term changes to governance and a social contract to address climate change, learning from the current pandemic, (8) updated positive cost-benefit ratio and new perspectives on the potential for green growth in the short- A nd long-term perspective; (9) urban electrification as a strategy to move towards low-carbon energy systems and (10) rights-based litigation as an increasingly important method to address climate change, with recent clarifications on the legal standing and representation of future generations. Social media summary Stronger permafrost, QC 20211002

Published
2020
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25. Permafrost Region Greenhouse Gas Budgets Suggest a Weak CO2Sink and CH4and N2O Sources, But Magnitudes Differ Between Top‐Down and Bottom‐Up Methods

Author

Hugelius, G., Ramage, J., Burke, E., Chatterjee, A., Smallman, T. L., Aalto, T., Bastos, A., Biasi, C., Canadell, J. G., Chandra, N., Chevallier, F., Ciais, P., Chang, J., Feng, L., Jones, M. W., Kleinen, T., Kuhn, M., Lauerwald, R., Liu, J., López‐Blanco, E., Luijkx, I. T., Marushchak, M. E., Natali, S. M., Niwa, Y., Olefeldt, D., Palmer, P. I., Patra, P. K., Peters, W., Potter, S., Poulter, B., Rogers, B. M., Riley, W. J., Saunois, M., Schuur, E. A. G., Thompson, R. L., Treat, C., Tsuruta, A., Turetsky, M. R., Virkkala, A.‐M., Voigt, C., Watts, J., Zhu, Q., and Zheng, B.

Abstract

Large stocks of soil carbon (C) and nitrogen (N) in northern permafrost soils are vulnerable to remobilization under climate change. However, there are large uncertainties in present‐day greenhouse gas (GHG) budgets. We compare bottom‐up (data‐driven upscaling and process‐based models) and top‐down (atmospheric inversion models) budgets of carbon dioxide (CO2), methane (CH4) and nitrous oxide (N2O) as well as lateral fluxes of C and N across the region over 2000–2020. Bottom‐up approaches estimate higher land‐to‐atmosphere fluxes for all GHGs. Both bottom‐up and top‐down approaches show a sink of CO2in natural ecosystems (bottom‐up: −29 (−709, 455), top‐down: −587 (−862, −312) Tg CO2‐C yr−1) and sources of CH4(bottom‐up: 38 (22, 53), top‐down: 15 (11, 18) Tg CH4‐C yr−1) and N2O (bottom‐up: 0.7 (0.1, 1.3), top‐down: 0.09 (−0.19, 0.37) Tg N2O‐N yr−1). The combined global warming potential of all three gases (GWP‐100) cannot be distinguished from neutral. Over shorter timescales (GWP‐20), the region is a net GHG source because CH4dominates the total forcing. The net CO2sink in Boreal forests and wetlands is largely offset by fires and inland water CO2emissions as well as CH4emissions from wetlands and inland waters, with a smaller contribution from N2O emissions. Priorities for future research include the representation of inland waters in process‐based models and the compilation of process‐model ensembles for CH4and N2O. Discrepancies between bottom‐up and top‐down methods call for analyses of how prior flux ensembles impact inversion budgets, more and well‐distributed in situ GHG measurements and improved resolution in upscaling techniques. The northern permafrost region covers large areas and stores very large amounts of carbon and nitrogen in soils and sediments. With climate change, there is concern that thawing permafrost will release greenhouse gases into the atmosphere, shifting the region from long‐term cooling of the global climate to a net warming effect. In this study, we used different techniques to assess the greenhouse gas budgets of carbon dioxide, methane and nitrous oxide for the time period 2000‒2020. We find that the region is a net sink of carbon dioxide, mainly in boreal forests and wetlands, while carbon dioxide is emitted from inland waters and fires affecting both forest and tundra. Lakes and wetlands are strong sources of methane, which contributes to warm the climate significantly, especially over shorter timescales. Nitrous oxide is emitted at low rates across the region, with a relatively limited impact on climate. In summary, the climate warming from the northern permafrost region is likely close to neutral when calculated over a 100 years time window, but it warms the climate when calculated over a 20 years time window. The northern terrestrial permafrost region was a weak annual CO2sink and stable source of CH4and N2O during the time period 2000–2020The global warming potential is indistinguishable from neutral over a 100 years time period but a net source of warming over a 20 year periodBottom‐up and top‐down methods yield different magnitudes of estimates that cannot be fully reconciled The northern terrestrial permafrost region was a weak annual CO2sink and stable source of CH4and N2O during the time period 2000–2020 The global warming potential is indistinguishable from neutral over a 100 years time period but a net source of warming over a 20 year period Bottom‐up and top‐down methods yield different magnitudes of estimates that cannot be fully reconciled

Published
2024
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28. Biological and geophysical feedbacks with fire in the Earth system

Author

Archibald, Sally, Lehmann, Caroline E. R, Belcher, C, Bond, William J, Bradstock, Ross A, Daniau, A-L, Dexter, K, Forrestel, E, Greve, M, He, T, Higgins, S I, Hoffmann, W, Lamont, B B, McGlinn, D J, Moncrieff, G, Osborne, C P, Pausas, Juli G, Price, Owen F, Ripley, B, Rogers, B, Schwilk, D, Simon, M, Turetsky, M, Van Der Werf, G R, Zanne, A E, Archibald, Sally, Lehmann, Caroline E. R, Belcher, C, Bond, William J, Bradstock, Ross A, Daniau, A-L, Dexter, K, Forrestel, E, Greve, M, He, T, Higgins, S I, Hoffmann, W, Lamont, B B, McGlinn, D J, Moncrieff, G, Osborne, C P, Pausas, Juli G, Price, Owen F, Ripley, B, Rogers, B, Schwilk, D, Simon, M, Turetsky, M, Van Der Werf, G R, and Zanne, A E

Abstract

Roughly 3% of the Earth's land surface burns annually, representing a critical exchange of energy and matter between the land and atmosphere via combustion. Fires range from slow smouldering peat fires, to low-intensity surface fires, to intense crown fires, depending on vegetation structure, fuel moisture, prevailing climate, and weather conditions. While the links between biogeochemistry, climate and fire are widely studied within Earth system science, these relationships are also mediated by fuels-namely plants and their litter-that are the product of evolutionary and ecological processes. Fire is a powerful selective force and, over their evolutionary history, plants have evolved traits that both tolerate and promote fire numerous times and across diverse clades. Here we outline a conceptual framework of how plant traits determine the flammability of ecosystems and interact with climate and weather to influence fire regimes. We explore how these evolutionary and ecological processes scale to impact biogeochemical and Earth system processes. Finally, we outline several research challenges that, when resolved, will improve our understanding of the role of plant evolution in mediating the fire feedbacks driving Earth system processes. Understanding current patterns of fire and vegetation, as well as patterns of fire over geological time, requires research that incorporates evolutionary biology, ecology, biogeography, and the biogeosciences.

Published
2018

29. Biological and geophysical feedbacks with fire in the Earth system

Author

Archibald, S., Lehmann, C., Belcher, C., Bond, W., Bradstock, R., Daniau, A., Dexter, K., Forrestel, E., Greve, M., He, Tianhua, Higgins, S., Hoffmann, W., Lamont, Byron, McGlinn, D., Moncrieff, G., Osborne, C., Pausas, J., Price, O., Ripley, B., Rogers, B., Schwilk, D., Simon, M., Turetsky, M., Van der Werf, G., Zanne, A., Archibald, S., Lehmann, C., Belcher, C., Bond, W., Bradstock, R., Daniau, A., Dexter, K., Forrestel, E., Greve, M., He, Tianhua, Higgins, S., Hoffmann, W., Lamont, Byron, McGlinn, D., Moncrieff, G., Osborne, C., Pausas, J., Price, O., Ripley, B., Rogers, B., Schwilk, D., Simon, M., Turetsky, M., Van der Werf, G., and Zanne, A.

Abstract

Roughly 3% of the Earth’s land surface burns annually, representing a critical exchange of energy and matter between the land and atmosphere via combustion. Fires range from slow smouldering peat fires, to low-intensity surface fires, to intense crown fires, depending on vegetation structure, fuel moisture, prevailing climate, and weather conditions. While the links between biogeochemistry, climate and fire are widely studied within Earth system science, these relationships are also mediated by fuels—namely plants and their litter—that are the product of evolutionary and ecological processes. Fire is a powerful selective force and, over their evolutionary history, plants have evolved traits that both tolerate and promote fire numerous times and across diverse clades. Here we outline a conceptual framework of how plant traits determine the flammability of ecosystems and interact with climate and weather to influence fire regimes. We explore how these evolutionary and ecological processes scale to impact biogeochemical and Earth system processes. Finally, we outline several research challenges that, when resolved, will improve our understanding of the role of plant evolution in mediating the fire feedbacks driving Earth system processes. Understanding current patterns of fire and vegetation, as well as patterns of fire over geological time, requires research that incorporates evolutionary biology, ecology, biogeography, and the biogeosciences.

Published
2018

30. Biological and geophysical feedbacks with fire in the Earth system

Author

Archibald, S, primary, Lehmann, C E R, additional, Belcher, C M, additional, Bond, W J, additional, Bradstock, R A, additional, Daniau, A-L, additional, Dexter, K G, additional, Forrestel, E J, additional, Greve, M, additional, He, T, additional, Higgins, S I, additional, Hoffmann, W A, additional, Lamont, B B, additional, McGlinn, D J, additional, Moncrieff, G R, additional, Osborne, C P, additional, Pausas, J G, additional, Price, O, additional, Ripley, B S, additional, Rogers, B M, additional, Schwilk, D W, additional, Simon, M F, additional, Turetsky, M R, additional, Van der Werf, G R, additional, and Zanne, A E, additional

Published
2018
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31. Biomass offsets little or none of permafrost carbon release from soils, streams, and wild␣re: an expert assessment

Author

Abbott, B. W., Jones, J. B., Schuur, E. A. G., Chapin, F. S., Bowden, W. B., Bret-Harte, M. S., Epstein, H. E., Flannigan, M. D., Harms, T. K., Hollingsworth, T. N., Mack, M. C., Mcguire, A. D., Natali, S. M., Rocha, A. V., Tank, S. E., Turetsky, M. R., Vonk, J. E., Wickland, K. P., Aiken, G. R., Alexander, H. D., Amon, R. M. W., Benscoter, B. W., Bergeron, Y., Bishop, K., Blarquez, O., Bond-Lamberty, B., Breen, A. L., Buffam, I., Cai, Y. H., Christopher Carcaillet, Carey, S. K., Chen, J. M., Chen, H. Y. H., Christensen, T. R., Cooper, L. W., Cornelissen, J. H. C., Groot, W. J., Deluca, T. H., Dorrepaal, E., Fetcher, N., Finlay, J. C., Forbes, B. C., French, N. H. F., Gauthier, S., Girardin, M. P., Goetz, S. J., Goldammer, J. G., Gough, L., Grogan, P., Guo, L. D., Higuera, P. E., Hinzman, L., Hu, F. S., Hugelius, G., Jafarov, E. E., Jandt, R., Johnstone, J. F., Karlsson, J., Kasischke, E. S., Kattner, G., Kelly, R., Keuper, F., Kling, G. W., Kortelainen, P., Kouki, J., Kuhry, P., Laudon, H., Laurion, I., Macdonald, R. W., Mann, P. J., Martikainen, P. J., Mcclelland, J. W., Molau, U., Oberbauer, S. F., Olefeldt, D., Pare, D., Parisien, M. A., Payette, S., Peng, C. H., Pokrovsky, O. S., Rastetter, E. B., Raymond, P. A., Raynolds, M. K., Rein, G., Reynolds, J. F., Robards, M., Rogers, B. M., Schadel, C., Schaefer, K., Schmidt, I. K., Shvidenko, A., Sky, J., Spencer, R. G. M., Starr, G., Striegl, R. G., Teisserenc, R., Tranvik, L. J., Virtanen, T., Welker, J. M., Zimov, S., Institute of Arctic Biology and Department of Biology & Wildlife, University of Alaska [Fairbanks] (UAF), Ecosystèmes, biodiversité, évolution [Rennes] (ECOBIO), Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)-Institut Ecologie et Environnement (INEE), Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS)-Observatoire des Sciences de l'Univers de Rennes (OSUR)-Centre National de la Recherche Scientifique (CNRS), Laboratoire d'Ecologie des Hydrosystèmes Naturels et Anthropisés (LEHNA), Centre National de la Recherche Scientifique (CNRS)-Institut National de la Recherche Agronomique (INRA)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-École Nationale des Travaux Publics de l'État (ENTPE), McMaster University [Hamilton, Ontario], 955713, National Science Foundation, OPP-0806394, Office of Polar Programs, Future Forest (Mistra), SITES (Swedish Science Foundation), TOMCAR-Permafrost #277059, Marie Curie International Reintegration, Institute of Arctic Biology, Université de Rennes (UR)-Institut Ecologie et Environnement (INEE), Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS)-Observatoire des Sciences de l'Univers de Rennes (OSUR), Université de Rennes (UR)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Rennes 2 (UR2)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Rennes 2 (UR2)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Centre National de la Recherche Scientifique (CNRS), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-École Nationale des Travaux Publics de l'État (ENTPE)-Centre National de la Recherche Scientifique (CNRS), Centre National de la Recherche Scientifique (CNRS)-Observatoire des Sciences de l'Univers de Rennes (OSUR)-Institut Ecologie et Environnement (INEE), Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES), Earth and Climate, Systems Ecology, Amsterdam Global Change Institute, Environmental Sciences, Tarmo Virtanen / Principal Investigator, and Environmental Change Research Unit (ECRU)

Subjects
0106 biological sciences, 010504 meteorology & atmospheric sciences, Biomass, F800, SEQUESTRATION, Permafrost, 01 natural sciences, FIRE, wildfire, Klimatforskning, Arctic, вечная мерзлота, Dissolved organic carbon, ECOSYSTEMS, SDG 13 - Climate Action, boreal, General Environmental Science, Total organic carbon, ARCTIC TUNDRA, CLIMATE-CHANGE, Carbon, Climate change, Miljövetenskap, Permafrost carbon cycle, Earth and Related Environmental Sciences, STORAGE, углеродный баланс, particulate organic carbon, Climate Research, permafrost carbon, Soil science, 010603 evolutionary biology, BOREAL FOREST, биомасса, Ecosystem, SDG 14 - Life Below Water, 1172 Environmental sciences, 0105 earth and related environmental sciences, INTERIOR ALASKA, coastal erosion, Hydrology, VULNERABILITY, NITROGEN DEPOSITION, Renewable Energy, Sustainability and the Environment, coastal erosion Supplementary material for this article is available, Public Health, Environmental and Occupational Health, Geovetenskap och miljövetenskap, 15. Life on land, dissolved organic carbon, Tundra, 13. Climate action, Soil water, Environmental science, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, Environmental Sciences
Abstract

CT3 ; EnjS4; International audience; As the permafrost region warms, its large organic carbon pool will be increasingly vulnerable to decomposition, combustion, and hydrologic export. Models predict that some portion of this release will be offset by increased production of Arctic and boreal biomass; however, the lack of robust estimates of net carbon balance increases the risk of further overshooting international emissions targets. Precise empirical or model-based assessments of the critical factors driving carbon balance are unlikely in the near future, so to address this gap, we present estimates from 98 permafrost-region experts of the response of biomass, wild␣re, and hydrologic carbon ␣ux to climate change. Results suggest that contrary to model projections, total permafrost-region biomass could decrease due to water stress and disturbance, factors that are not adequately incorporated in current models. Assessments indicate that end-of-the-century organic carbon release from Arctic rivers and collapsing coastlines could increase by 75% while carbon loss via burning could increase four-fold. Experts identi␣ed water balance, shifts in vegetation community, and permafrost degradation as the key sources of uncertainty in predicting future system response. In combination with previous ␣ndings, results suggest the permafrost region will become a carbon source to the atmosphere by 2100 regardless of warming scenario but that 65%–85% of permafrost carbon release can still be avoided if human emissions are actively reduced.

Published
2016
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33. A synthesis of thermokarst and thermo-erosion rates in northern permafrost regions

Author

Grosse, Guido, Sannel, Britta, Abbott, Benjamin, Arp, Christopher, Camill, Philip, Farquharson, Louise M., Günther, Frank, Hayes, Daniel J., Jones, Benjamin M., Jorgenson, T., Kokelj, S., Kuhry, P., Lenz, Josefine, Liu, Lin, McGuire, A. D., Morgenstern, Anne, Nitze, Ingmar, O'Donnell, J., Olefeldt, David, Parsekian, Andrew D., Romanovsky, V. E., Schuur, Edward. A. G., Turetsky, M., Walter Anthony, K. M., Wullschlaeger, S., Grosse, Guido, Sannel, Britta, Abbott, Benjamin, Arp, Christopher, Camill, Philip, Farquharson, Louise M., Günther, Frank, Hayes, Daniel J., Jones, Benjamin M., Jorgenson, T., Kokelj, S., Kuhry, P., Lenz, Josefine, Liu, Lin, McGuire, A. D., Morgenstern, Anne, Nitze, Ingmar, O'Donnell, J., Olefeldt, David, Parsekian, Andrew D., Romanovsky, V. E., Schuur, Edward. A. G., Turetsky, M., Walter Anthony, K. M., and Wullschlaeger, S.

Published
2017

34. Climate change and the permafrost carbon feedback

Author

Schuur, E. A G, McGuire, A. D., Schädel, C., Grosse, G., Harden, J. W., Hayes, D. J., Hugelius, G., Koven, C. D., Kuhry, P., Lawrence, D. M., Natali, S. M., Olefeldt, D., Romanovsky, V. E., Schaefer, K., Turetsky, M. R., Treat, C. C., Vonk, J. E., Organic geochemistry, NWO-VENI: Ancient organic matter that matters: The fate of Siberian Yedoma deposits, Organic geochemistry, and NWO-VENI: Ancient organic matter that matters: The fate of Siberian Yedoma deposits

Subjects
010504 meteorology & atmospheric sciences, Climate Change, Yedoma, Climate change, chemistry.chemical_element, Permafrost, 010501 environmental sciences, Atmospheric sciences, 01 natural sciences, Methane, Carbon Cycle, Feedback, chemistry.chemical_compound, Freezing, SDG 13 - Climate Action, Seawater, General, 0105 earth and related environmental sciences, Medicine(all), Multidisciplinary, Arctic Regions, Uncertainty, Carbon Dioxide, chemistry, 13. Climate action, Greenhouse gas, Carbon dioxide, Permafrost carbon cycle, Carbon
Abstract

Large quantities of organic carbon are stored in frozen soils (permafrost) within Arctic and sub-Arctic regions. A warming climate can induce environmental changes that accelerate the microbial breakdown of organic carbon and the release of the greenhouse gases carbon dioxide and methane. This feedback can accelerate climate change, but the magnitude and timing of greenhouse gas emission from these regions and their impact on climate change remain uncertain. Here we find that current evidence suggests a gradual and prolonged release of greenhouse gas emissions in a warming climate and present a research strategy with which to target poorly understood aspects of permafrost carbon dynamics.

Published
2014
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35. Circumpolar distribution and carbon storage of thermokarst landscapes

Author

Olefeldt, D., Goswami, S., Grosse, G., Hayes, D., Hugelius, Gustaf, Kuhry, Peter, McGuire, A. D., Romanovsky, V. E., Sannel, A. Britta K., Schuur, E. A. G., Turetsky, M. R., Olefeldt, D., Goswami, S., Grosse, G., Hayes, D., Hugelius, Gustaf, Kuhry, Peter, McGuire, A. D., Romanovsky, V. E., Sannel, A. Britta K., Schuur, E. A. G., and Turetsky, M. R.

Abstract

Thermokarst is the process whereby the thawing of ice- rich permafrost ground causes land subsidence, resulting in development of distinctive landforms. Accelerated thermokarst due to climate change will damage infrastructure, but also impact hydrology, ecology and biogeochemistry. Here, we present a circumpolar assessment of the distribution of thermokarst landscapes, defined as landscapes comprised of current thermokarst landforms and areas susceptible to future thermokarst development. At 3.6 x 10(6) km(2), thermokarst landscapes are estimated to cover similar to 20% of the northern permafrost region, with approximately equal contributions from three landscape types where characteristic wetland, lake and hillslope thermokarst landforms occur. We estimate that approximately half of the below-ground organic carbon within the study region is stored in thermokarst landscapes. Our results highlight the importance of explicitly considering thermokarst when assessing impacts of climate change, including future landscape greenhouse gas emissions, and provide a means for assessing such impacts at the circumpolar scale.

Published
2016
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37. The Lebyazhinka Burial Ground (Middle Volga Region, Russia): New 14C Dates and the Reservoir Effect.

Author

Shishlina, N I, van der Plicht, J, and Turetsky, M A

Abstract

We report new accelerator mass spectrometry radiocarbon (AMS 14C) dates of bones from humans, animals, and fish from grave 12 of the Lebyazhinka V Eneolithic burial ground in the middle Volga River region, Russia. Earlier conventional dates established a chronology. This has to be adjusted by new insights: the date has to be corrected for reservoir effects. For this purpose we redated bone from a human, and for herbivore and freshwater fauna from the same context, and included measurements of the stable isotopes δ13C and δ15N. The reservoir offset for the human appears to be about 700 14C yr. [ABSTRACT FROM AUTHOR]

Published
2018
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40. Climate change and the permafrost carbon feedback

Author

Schuur, E. A G, McGuire, A. D., Schädel, C., Grosse, G., Harden, J. W., Hayes, D. J., Hugelius, G., Koven, C. D., Kuhry, P., Lawrence, D. M., Natali, S. M., Olefeldt, D., Romanovsky, V. E., Schaefer, K., Turetsky, M. R., Treat, C. C., Vonk, J. E., Schuur, E. A G, McGuire, A. D., Schädel, C., Grosse, G., Harden, J. W., Hayes, D. J., Hugelius, G., Koven, C. D., Kuhry, P., Lawrence, D. M., Natali, S. M., Olefeldt, D., Romanovsky, V. E., Schaefer, K., Turetsky, M. R., Treat, C. C., and Vonk, J. E.

Abstract

Large quantities of organic carbon are stored in frozen soils (permafrost) within Arctic and sub-Arctic regions. A warming climate can induce environmental changes that accelerate the microbial breakdown of organic carbon and the release of the greenhouse gases carbon dioxide and methane. This feedback can accelerate climate change, but the magnitude and timing of greenhouse gas emission from these regions and their impact on climate change remain uncertain. Here we find that current evidence suggests a gradual and prolonged release of greenhouse gas emissions in a warming climate and present a research strategy with which to target poorly understood aspects of permafrost carbon dynamics.

Published
2015

41. Climate change and the permafrost carbon feedback

Author

Organic geochemistry, NWO-VENI: Ancient organic matter that matters: The fate of Siberian Yedoma deposits, Schuur, E. A G, McGuire, A. D., Schädel, C., Grosse, G., Harden, J. W., Hayes, D. J., Hugelius, G., Koven, C. D., Kuhry, P., Lawrence, D. M., Natali, S. M., Olefeldt, D., Romanovsky, V. E., Schaefer, K., Turetsky, M. R., Treat, C. C., Vonk, J. E., Organic geochemistry, NWO-VENI: Ancient organic matter that matters: The fate of Siberian Yedoma deposits, Schuur, E. A G, McGuire, A. D., Schädel, C., Grosse, G., Harden, J. W., Hayes, D. J., Hugelius, G., Koven, C. D., Kuhry, P., Lawrence, D. M., Natali, S. M., Olefeldt, D., Romanovsky, V. E., Schaefer, K., Turetsky, M. R., Treat, C. C., and Vonk, J. E.

Published
2015

44. Mapping thermokarst vulnerability at the pan-arctic scale

Author

Olefeldt, D., Goswami, Santonu, Grosse, Guido, Hayes, D.J., Hugelius, Gustaf, Kuhry, Peter, McGuire, A. D., Sannel, A.B.K., Schuur, Edward. A. G., Turetsky, M., Olefeldt, D., Goswami, Santonu, Grosse, Guido, Hayes, D.J., Hugelius, Gustaf, Kuhry, Peter, McGuire, A. D., Sannel, A.B.K., Schuur, Edward. A. G., and Turetsky, M.

Published
2014

45. Climate Change and the Permafrost Carbon Feedback

Author

Schuur, E. A. G., McGuire, A. D., Grosse, Guido, Harden, Jennifer W., Hayes, D.J., Hugelius, Gustaf, Koven, C. D., Kuhry, P., Lawrence, D. M., Natali, S.M., Olefeldt, D., Romanovskii, V. E., Schädel, C., Schaefer, K., Turetsky, M., Treat, C. C., Vonk, J., Schuur, E. A. G., McGuire, A. D., Grosse, Guido, Harden, Jennifer W., Hayes, D.J., Hugelius, Gustaf, Koven, C. D., Kuhry, P., Lawrence, D. M., Natali, S.M., Olefeldt, D., Romanovskii, V. E., Schädel, C., Schaefer, K., Turetsky, M., Treat, C. C., and Vonk, J.

Abstract

Approximately twice as much soil carbon is stored in the northern circumpolar permafrost zone than is currently contained in the atmosphere. Permafrost thaw, and the microbial decomposition of previously frozen organic carbon, is considered one of the most likely positive feedbacks from terrestrial ecosystems to the atmosphere in a warmer world. Yet, the rate and form of release is highly uncertain but crucial for predicting the strength and timing of this carbon cycle feedback this century and beyond. New insight brought together under a multi-year synthesis effort by the Permafrost Carbon Network helps constrain current understanding of the permafrost carbon feedback to climate, and provides a framework for newly developing research initiatives in this region. A newly enlarged soil carbon database continues to verify the widespread pattern of large quantities of carbon accumulated deep in permafrost soils. The known pool of permafrost carbon is now estimated to be 1330-1580 Pg C, with the potential for ~400 Pg C in deep permafrost sediments that remain largely unquantified. Laboratory incubations of these permafrost soils reveal that a significant fraction of this material can be mineralized by microbes and converted to CO2 and CH4 on time scales of years to decades, with decade-long average losses from aerobic incubations ranging from 6-34% of initial carbon. Variation in loss rates is depended on the carbon to nitrogen ratio, with higher values leading to more proportional loss. Model scenarios show potential C release from the permafrost zone ranging from 37-174 Pg C by 2100 under the current climate warming trajectory (RCP 8.5), with an average across models of 92±17 Pg C. Furthermore, thawing permafrost C is forecasted to impact global climate for centuries, with models, on average, estimating 59% of total C emissions after 2100. Taken together, greenhouse gas emissions from warming permafrost appear likely to occur at a magnitude similar to other historicall

Published
2014

47. The Lebyazhinka Burial Ground (Middle Volga Region, Russia): New 14C Dates and the Reservoir Effect

Author

Shishlina, N I, van der Plicht, J, and Turetsky, M A

Abstract

AbstractWe report new accelerator mass spectrometry radiocarbon (AMS 14C) dates of bones from humans, animals, and fish from grave 12 of the Lebyazhinka V Eneolithic burial ground in the middle Volga River region, Russia. Earlier conventional dates established a chronology. This has to be adjusted by new insights: the date has to be corrected for reservoir effects. For this purpose we redated bone from a human, and for herbivore and freshwater fauna from the same context, and included measurements of the stable isotopes δ13C and δ15N. The reservoir offset for the human appears to be about 700 14C yr.

Published
2018
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48. Climate change: High risk of permafrost thaw

Author

Schuur, Edward A. G., Abbott, Benjamin, Bowden, W.B., Brovkin, V., Camill, P., Canadell, J., Chapin, F. S., Christensen, T., Chanton, J. P., Ciais, P., Crill, P.M., Crosby, T., Czimczik, C.I., Grosse, Guido, Hayes, D.J., Hugelius, Gustaf, Jastrow, J.D., Kleinen, T., Koven, C., Krinner, G., Kuhry, P., Lawrence, D., Natali, S.M., Ping, C. L., Rinke, Annette, Riley, W.J., Romanovsky, V. E., Sannel, A.B.K., Schädel, C., Schaefer, K., Subin, Z.M., Tarnocai, Charles, Turetsky, M., Walter-Anthony, K.M., Wilson, C.J., Zimov, S. A., Schuur, Edward A. G., Abbott, Benjamin, Bowden, W.B., Brovkin, V., Camill, P., Canadell, J., Chapin, F. S., Christensen, T., Chanton, J. P., Ciais, P., Crill, P.M., Crosby, T., Czimczik, C.I., Grosse, Guido, Hayes, D.J., Hugelius, Gustaf, Jastrow, J.D., Kleinen, T., Koven, C., Krinner, G., Kuhry, P., Lawrence, D., Natali, S.M., Ping, C. L., Rinke, Annette, Riley, W.J., Romanovsky, V. E., Sannel, A.B.K., Schädel, C., Schaefer, K., Subin, Z.M., Tarnocai, Charles, Turetsky, M., Walter-Anthony, K.M., Wilson, C.J., and Zimov, S. A.

Published
2011

50. The Outpatient Referral Process: What Is Its Diagnosis and Treatment?

Author

Gandhi, TK, Sittig, DF, Song, J, Franklin, M, Turetsky, M, Teich, JM, Komaroff, AL, and Bates, DW

Subjects
InformationSystems_GENERAL, Posters
Abstract

Optimization of the physician-to-physician referral process is increasingly important with managed care. Based on a physician survey, we found that there is potential to improve the efficiency and appropriateness of the communication process through computerization.

Published
1998

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