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7 results on '"Neal J. Pastick"'

3. The role of environmental driving factors in historical and projected carbon dynamics of wetland ecosystems in Alaska

Author

Amy L. Breen, Tom Kurkowski, Neal J. Pastick, Bruce K. Wylie, A. David McGuire, Kristofer D. Johnson, Hélène Genet, Yujie He, Qianlai Zhuang, Joy S. Clein, Zhou Lyu, T. Scott Rupp, Zhiliang Zhu, A. Bennett, and Eugénie S. Euskirchen

Subjects
0106 biological sciences, 010504 meteorology & atmospheric sciences, Climate change, Wetland, Carbon sequestration, Atmospheric sciences, Global Warming, 01 natural sciences, Carbon Cycle, Wildfires, Ecosystem, 0105 earth and related environmental sciences, Carbon dioxide in Earth's atmosphere, geography, geography.geographical_feature_category, Ecology, 010604 marine biology & hydrobiology, Global warming, Carbon Dioxide, Models, Theoretical, Wetlands, Greenhouse gas, Environmental science, Climate model, Methane, Alaska, Forecasting
Abstract

Wetlands are critical terrestrial ecosystems in Alaska, covering ~177,000 km2 , an area greater than all the wetlands in the remainder of the United States. To assess the relative influence of changing climate, atmospheric carbon dioxide (CO2 ) concentration, and fire regime on carbon balance in wetland ecosystems of Alaska, a modeling framework that incorporates a fire disturbance model and two biogeochemical models was used. Spatially explicit simulations were conducted at 1-km resolution for the historical period (1950-2009) and future projection period (2010-2099). Simulations estimated that wetland ecosystems of Alaska lost 175 Tg carbon (C) in the historical period. Ecosystem C storage in 2009 was 5,556 Tg, with 89% of the C stored in soils. The estimated loss of C as CO2 and biogenic methane (CH4 ) emissions resulted in wetlands of Alaska increasing the greenhouse gas forcing of climate warming. Simulations for the projection period were conducted for six climate change scenarios constructed from two climate models forced under three CO2 emission scenarios. Ecosystem C storage averaged among climate scenarios increased 3.94 Tg C/yr by 2099, with variability among the simulations ranging from 2.02 to 4.42 Tg C/yr. These increases were driven primarily by increases in net primary production (NPP) that were greater than losses from increased decomposition and fire. The NPP increase was driven by CO2 fertilization (~5% per 100 parts per million by volume increase) and by increases in air temperature (~1% per °C increase). Increases in air temperature were estimated to be the primary cause for a projected 47.7% mean increase in biogenic CH4 emissions among the simulations (~15% per °C increase). Ecosystem CO2 sequestration offset the increase in CH4 emissions during the 21st century to decrease the greenhouse gas forcing of climate warming. However, beyond 2100, we expect that this forcing will ultimately increase as wetland ecosystems transition from being a sink to a source of atmospheric CO2 because of (1) decreasing sensitivity of NPP to increasing atmospheric CO2 , (2) increasing availability of soil C for decomposition as permafrost thaws, and (3) continued positive sensitivity of biogenic CH4 emissions to increases in soil temperature.

Published
2016
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4. Assessing historical and projected carbon balance of Alaska: A synthesis of results and policy/management implications

Author

Richard Birdsey, Zhou Lyu, T. Scott Rupp, Qianlai Zhuang, Bruce K. Wylie, Robert G. Striegl, Zhiliang Zhu, Sarah M. Stackpoole, Hélène Genet, A. David McGuire, Yujie He, Xiaoping Zhou, David V. D'Amore, and Neal J. Pastick

Subjects
0106 biological sciences, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ecology, Aquatic ecosystem, Climate Change, Primary production, Greenhouse gas inventory, Wetland, Permafrost, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, Carbon Cycle, Environmental Policy, Greenhouse gas, Environmental science, Terrestrial ecosystem, Ecosystem, Alaska, 0105 earth and related environmental sciences, Forecasting
Abstract

We summarize the results of a recent interagency assessment of land carbon dynamics in Alaska, in which carbon dynamics were estimated for all major terrestrial and aquatic ecosystems for the historical period (1950-2009) and a projection period (2010-2099). Between 1950 and 2009, upland and wetland (i.e., terrestrial) ecosystems of the state gained 0.4 Tg C/yr (0.1% of net primary production, NPP), resulting in a cumulative greenhouse gas radiative forcing of 1.68 × 10-3 W/m2 . The change in carbon storage is spatially variable with the region of the Northwest Boreal Landscape Conservation Cooperative (LCC) losing carbon because of fire disturbance. The combined carbon transport via various pathways through inland aquatic ecosystems of Alaska was estimated to be 41.3 Tg C/yr (17% of terrestrial NPP). During the projection period (2010-2099), carbon storage of terrestrial ecosystems of Alaska was projected to increase (22.5-70.0 Tg C/yr), primarily because of NPP increases of 10-30% associated with responses to rising atmospheric CO2 , increased nitrogen cycling, and longer growing seasons. Although carbon emissions to the atmosphere from wildfire and wetland CH4 were projected to increase for all of the climate projections, the increases in NPP more than compensated for those losses at the statewide level. Carbon dynamics of terrestrial ecosystems continue to warm the climate for four of the six future projections and cool the climate for only one of the projections. The attribution analyses we conducted indicated that the response of NPP in terrestrial ecosystems to rising atmospheric CO2 (~5% per 100 ppmv CO2 ) saturates as CO2 increases (between approximately +150 and +450 ppmv among projections). This response, along with the expectation that permafrost thaw would be much greater and release large quantities of permafrost carbon after 2100, suggests that projected carbon gains in terrestrial ecosystems of Alaska may not be sustained. From a national perspective, inclusion of all of Alaska in greenhouse gas inventory reports would ensure better accounting of the overall greenhouse gas balance of the nation and provide a foundation for considering mitigation activities in areas that are accessible enough to support substantive deployment.

Published
2018

5. The role of driving factors in historical and projected carbon dynamics of upland ecosystems in Alaska

Author

Y. Zhang, David V. D'Amore, Joy S. Clein, Hélène Genet, Eugénie S. Euskirchen, Bruce K. Wylie, A. David McGuire, Frances E. Biles, Qianlai Zhuang, T. Scott Rupp, Yujie He, Xiaoping Zhou, Svetlana Kushch Schroder, Zhou Lyu, Amy L. Breen, Tom Kurkowski, A. Bennett, Neal J. Pastick, Kristofer D. Johnson, and Zhiliang Zhu

Subjects
0106 biological sciences, Carbon dioxide in Earth's atmosphere, 010504 meteorology & atmospheric sciences, Ecology, Fire regime, Climate Change, Primary production, Climate change, Soil carbon, 010603 evolutionary biology, 01 natural sciences, Models, Biological, Fires, Carbon cycle, Carbon Cycle, Environmental science, Ecosystem, Climate model, Seasons, Alaska, 0105 earth and related environmental sciences
Abstract

It is important to understand how upland ecosystems of Alaska, which are estimated to occupy 84% of the state (i.e., 1,237,774 km2 ), are influencing and will influence state-wide carbon (C) dynamics in the face of ongoing climate change. We coupled fire disturbance and biogeochemical models to assess the relative effects of changing atmospheric carbon dioxide (CO2 ), climate, logging and fire regimes on the historical and future C balance of upland ecosystems for the four main Landscape Conservation Cooperatives (LCCs) of Alaska. At the end of the historical period (1950-2009) of our analysis, we estimate that upland ecosystems of Alaska store ~50 Pg C (with ~90% of the C in soils), and gained 3.26 Tg C/yr. Three of the LCCs had gains in total ecosystem C storage, while the Northwest Boreal LCC lost C (-6.01 Tg C/yr) because of increases in fire activity. Carbon exports from logging affected only the North Pacific LCC and represented less than 1% of the state's net primary production (NPP). The analysis for the future time period (2010-2099) consisted of six simulations driven by climate outputs from two climate models for three emission scenarios. Across the climate scenarios, total ecosystem C storage increased between 19.5 and 66.3 Tg C/yr, which represents 3.4% to 11.7% increase in Alaska upland's storage. We conducted additional simulations to attribute these responses to environmental changes. This analysis showed that atmospheric CO2 fertilization was the main driver of ecosystem C balance. By comparing future simulations with constant and with increasing atmospheric CO2 , we estimated that the sensitivity of NPP was 4.8% per 100 ppmv, but NPP becomes less sensitive to CO2 increase throughout the 21st century. Overall, our analyses suggest that the decreasing CO2 sensitivity of NPP and the increasing sensitivity of heterotrophic respiration to air temperature, in addition to the increase in C loss from wildfires weakens the C sink from upland ecosystems of Alaska and will ultimately lead to a source of CO2 to the atmosphere beyond 2100. Therefore, we conclude that the increasing regional C sink we estimate for the 21st century will most likely be transitional.

Published
2017

6. Historical and projected trends in landscape drivers affecting carbon dynamics in Alaska

Author

T. Scott Rupp, Norman B. Bliss, Bruce K. Wylie, Hélène Genet, Elchin Jafarov, M. Torre Jorgenson, Neal J. Pastick, Joseph F. Knight, Kristofer D. Johnson, Paul A. Duffy, and A. David McGuire

Subjects
0106 biological sciences, Carbon Sequestration, 010504 meteorology & atmospheric sciences, Climate Change, Climate change, Permafrost, Wetland, 010603 evolutionary biology, 01 natural sciences, Carbon Cycle, Taiga, Ecosystem, Tundra, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Ecology, Global warming, Temperature, Arctic, Environmental science, Alaska
Abstract

Modern climate change in Alaska has resulted in widespread thawing of permafrost, increased fire activity, and extensive changes in vegetation characteristics that have significant consequences for socioecological systems. Despite observations of the heightened sensitivity of these systems to change, there has not been a comprehensive assessment of factors that drive ecosystem changes throughout Alaska. Here we present research that improves our understanding of the main drivers of the spatiotemporal patterns of carbon dynamics using in situ observations, remote sensing data, and an array of modeling techniques. In the last 60 yr, Alaska has seen a large increase in mean annual air temperature (1.7°C), with the greatest warming occurring over winter and spring. Warming trends are projected to continue throughout the 21st century and will likely result in landscape-level changes to ecosystem structure and function. Wetlands, mainly bogs and fens, which are currently estimated to cover 12.5% of the landscape, strongly influence exchange of methane between Alaska's ecosystems and the atmosphere and are expected to be affected by thawing permafrost and shifts in hydrology. Simulations suggest the current proportion of near-surface (within 1 m) and deep (within 5 m) permafrost extent will be reduced by 9-74% and 33-55% by the end of the 21st century, respectively. Since 2000, an average of 678 595 ha/yr was burned, more than twice the annual average during 1950-1999. The largest increase in fire activity is projected for the boreal forest, which could result in a reduction in late-successional spruce forest (8-44%) and an increase in early-successional deciduous forest (25-113%) that would mediate future fire activity and weaken permafrost stability in the region. Climate warming will also affect vegetation communities across arctic regions, where the coverage of deciduous forest could increase (223-620%), shrub tundra may increase (4-21%), and graminoid tundra might decrease (10-24%). This study sheds light on the sensitivity of Alaska's ecosystems to change that has the potential to significantly affect local and regional carbon balance, but more research is needed to improve estimates of land-surface and subsurface properties, and to better account for ecosystem dynamics affected by a myriad of biophysical factors and interactions.

Published
2017

7. Spatial variability and landscape controls of near-surface permafrost within the Alaskan Yukon River Basin

Author

Michelle Ann Walvoord, Joshua R. Rose, Bruce K. Wylie, Matthew B. Rigge, M. Torre Jorgenson, and Neal J. Pastick

Subjects
Hydrology, Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Drainage basin, Paleontology, Soil Science, Forestry, Land cover, Aquatic Science, Permafrost, Ecosystem structure, Field (geography), Multivariate interpolation, Thematic Mapper, Spatial variability, Physical geography, Geology, Water Science and Technology
Abstract

The distribution of permafrost is important to understand because of permafrost's influence on high-latitude ecosystem structure and functions. Moreover, near-surface (defined here as within 1 m of the Earth's surface) permafrost is particularly susceptible to a warming climate and is generally poorly mapped at regional scales. Subsequently, our objectives were to (1) develop the first-known binary and probabilistic maps of near-surface permafrost distributions at a 30 m resolution in the Alaskan Yukon River Basin by employing decision tree models, field measurements, and remotely sensed and mapped biophysical data; (2) evaluate the relative contribution of 39 biophysical variables used in the models; and (3) assess the landscape-scale factors controlling spatial variations in permafrost extent. Areas estimated to be present and absent of near-surface permafrost occupy approximately 46% and 45% of the Alaskan Yukon River Basin, respectively; masked areas (e.g., water and developed) account for the remaining 9% of the landscape. Strong predictors of near-surface permafrost include climatic indices, land cover, topography, and Landsat 7 Enhanced Thematic Mapper Plus spectral information. Our quantitative modeling approach enabled us to generate regional near-surface permafrost maps and provide essential information for resource managers and modelers to better understand near-surface permafrost distribution and how it relates to environmental factors and conditions.

Published
2014
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