LandCarbon Active
Great Plains region of the United States
Baseline and projected future carbon storage and greenhouse-gas fluxes
Ecosystems of the Western United States
Baseline and projected future carbon storage and greenhouse-gas fluxes
Ecosystems of the eastern United States
Baseline and projected future carbon storage and greenhouse-gas fluxes
Ecosystems of Alaska
Baseline and projected future carbon storage and greenhouse-gas fluxes
The biologic carbon sequestration assessment program (LandCarbon) investigates ecosystem carbon cycle problems and develops carbon management science and monitoring methods.
Specifically, LandCarbon is focused on the following research areas:
- Synthesize and assess current and potential carbon balance (stocks and fluxes) in major terrestrial and aquatic ecosystems
- Evaluate the effects of both natural and anthropogenic driving forces on ecosystem carbon balance and greenhouse gas fluxes
- Develop carbon monitoring methods and capabilities
- Conduct research and provide science support for increasing carbon sequestration in land management policies and practices
Since 2010, the USGS has:
- Released a methodology for the national assessment of biologic carbon sequestration (USGS Scientific Investigations Report 5233)
- Completed the assessment for the conterminous United States divided into three regional reports (USGS Professional Papers 1787- Great Plains, 1797- Western US, and 1804- Eastern US), and Alaska and Hawaii separately
- Developed and released a LandCarbon website for data distribution and visualization.
Additionally, a number of research papers have been published in leading journals by USGS and academic scientists supported by the program.
Going forward, the new focus of the program is in two priority areas:
- Synthesis and assessment linking ecosystem carbon balance with natural and anthropogenic processes as well as carbon management
- Carbon sequestration application studies in support of Department of the Interior land management decision making
Activities:
Aquatic Systems
The USGS investigates the amount of carbon burial, emissions, and export taking place in the aquatic ecosystems of the United States. Data analysis and modeling are used to identify the controls on greenhouse gas emissions from lakes and rivers, as well as the magnitude of carbon burial in sediments. Linkages between land use and carbon cycling in nearby aquatic habitats are being characterized in order to understand the effects of human activity such as agriculture and development on aquatic carbon cycling. Carbon export to the coastal ocean is also being quantified, and ecosystem models will describe the movement of continental carbon exports through the coastal food web.
Inland aquatic ecosystems (rivers, lakes, ponds, and reservoirs) play several important roles in the carbon cycle. Carbon that has been fixed via terrestrial primary production and processed in the soil is exported to surface water as both organic and mineral carbon compounds. In the aquatic environment, organic carbon compounds are respired (converted to CO2) by bacteria. This process can lead to a greater concentration of CO2 in the water than in the air (supersaturation), which results in "degassing", or emission of CO2 to the atmosphere. At the same time, plants and algae in aquatic ecosystems take up CO2 for photosynthesis. As it moves through the food web, most of this carbon is ultimately converted back to CO2 by respiration, but some of it can be buried in sediments. Anaerobic decomposition of carbon buried in sediments can create CH4, another greenhouse gas, which can also escape to the atmosphere. River systems transport carbon, originating from both terrestrial and aquatic systems, to the coastal ocean, where it is then further processed (emitted as greenhouse gases, buried in sediments, or transported offshore).
Carbon Sequestration Assessment
According to the newly completed the 2nd State of Carbon Cycle Report (), Terrestrial and aquatic ecosystems in the United States are a significant carbon sinks, taking up approximately a quarter of the nation’s CO2 emissions. The ecosystem carbon sink can be highly variable over space and time due to natural disturbances and land use decisions (Goodale and others, 2002)). Fire, for example, is a disturbance that affects a forest's carbon storage and has effects of both releasing CO2 and CH4 back into the atmosphere and strengthening a forest ecosystem's ability to increase sequestration over the long-term. USGS conducts synthesis and assessment of carbon sequestration processes and long-term balances of major ecosystems including forests, croplands, grasslands, and wetlands in relation to both natural and anthropogenic driving forces.
Ecosystem Disturbances – Wildland Fire
Ecosystem disturbance modeling and emission estimation produces spatially-explicit forecasts of fire patterns, and the resulting greenhouse gas emissions for U.S biomes. At the heart of the approach is a series of statistical and process-based models, coded in C++, that simulate processes of fire ignition, spread, and emissions. Patterns of historic ignitions are characterized using logistic regressions that relate ignition location to daily fuel moisture conditions, as well as, vegetation type and urban extent. These ignition models are used to determine when and where ignitions are located under stable or changing climate scenarios. Once ignitions are located, the area burned is determined by allowing each ignition to spread using the minimum travel time algorithm. After fire spread is complete, emissions are calculated using the FOFEM and CONSUME models.
Vegetation, fuels, daily weather, and fuel moisture data are critical to disturbance simulations. Vegetation and fuels data are provided by the LANDFIRE project. The daily weather data we use have 12 km spatial resolution and span from 1950 to 2010. For future climate-change scenarios, we randomly resample annual sequences of historic daily weather and rescale them to match the monthly means provided by downscaled climate-change forecasts. Fuel moistures and fire behavior indices are calculated for both historic and forecast daily weather using the National Fire Danger Rating System and then used as predictor variables for ignition locations, fire spread, and fire emissions.
Future Scenarios and land use modeling
To study potential changes in land use, land cover and land management in the future United States, USGS has incorporated probable scenarios as defined by the Intergovernmental Panel on Climate Change (IPCC) in its fourth and fifth assessment reports (AR4 and AR5), which lists major driving forces of future emissions, including changes in demographic, technological and economic developments. To be able to incorporate these scenario assumptions into ongoing research and to produce nationally and regionally unique future potential land use and land cover scenarios, data on historical land-cover change from USGS and information derived from a global integrated assessment model are used in conjunction with expert analysis to 1) downscale scenario narrative storylines to national and sub-national scales, and 2) develop quantitative regional projections of LULC change for major land-use sectors of the conterminous United States. Results of this process are a set of quantitative future scenarios for specific land use and land cover classes, unique at both national and regional scales.
There are large uncertainties in how land and climate systems will evolve and interact to shape future ecosystem carbon dynamics. To address this uncertainty, we developed the Land-Use and Carbon Scenario Simulator (LUCAS) to track changes in land use, land cover, land management, and disturbance, and their impact on ecosystem carbon storage and flux. The LUCAS model combines a state-and-transition simulation model (STSM) for modeling land-change with a stock and flow model for modeling carbon dynamics, within a scenario-based framework. These two models were developed in conjunction within the ST-SIM modeling environment to provide a complete package for testing a range of future scenarios of land-use change and their impacts on carbon dynamics. Land-use change scenarios developed from the Intergovernmental Panel on Climate Change's (IPCC) Special Report on Emission Scenarios (SRES), and Representative Concentration Pathways (RCPs), as well as scenarios developed from historical land-use change datasets that include a range of mitigation and adaptation policies can be applied in the model.
Below are data releases associated with this project.
Below are publications associated with this project.
Land-use threats and protected areas: a scenario-based, landscape level approach
The impact of climate and reservoirs on longitudinal riverine carbon fluxes from two major watersheds in the Central and Intermontane West
Spatially explicit modeling of 1992-2100 land cover and forest stand age for the conterminous United States
Simulated impacts of mountain pine beetle and wildfire disturbances on forest vegetation composition and carbon stocks in the Southern Rocky Mountains
Inorganic carbon loading as a primary driver of dissolved carbon dioxide concentrations in the lakes and reservoirs of the contiguous United States
Extending airborne electromagnetic surveys for regional active layer and permafrost mapping with remote sensing and ancillary data, Yukon Flats ecoregion, central Alaska
Effect of heterogeneous atmospheric CO2 on simulated global carbon budget
234U/238U and δ87Sr in peat as tracers of paleosalinity in the Sacramento-San Joaquin Delta of California, USA
Mountain pine beetle impacts on vegetation and carbon stocks
Land use and carbon dynamics in the southeastern United States from 1992 to 2050
Baseline and projected future carbon storage and greenhouse-gas fluxes in ecosystems of the Western United States
Scenarios of land use and land cover change in the conterminous United States: Utilizing the special report on emission scenarios at ecoregional scales
- Overview
The biologic carbon sequestration assessment program (LandCarbon) investigates ecosystem carbon cycle problems and develops carbon management science and monitoring methods.
Specifically, LandCarbon is focused on the following research areas:
- Synthesize and assess current and potential carbon balance (stocks and fluxes) in major terrestrial and aquatic ecosystems
- Evaluate the effects of both natural and anthropogenic driving forces on ecosystem carbon balance and greenhouse gas fluxes
- Develop carbon monitoring methods and capabilities
- Conduct research and provide science support for increasing carbon sequestration in land management policies and practices
Since 2010, the USGS has:
- Released a methodology for the national assessment of biologic carbon sequestration (USGS Scientific Investigations Report 5233)
- Completed the assessment for the conterminous United States divided into three regional reports (USGS Professional Papers 1787- Great Plains, 1797- Western US, and 1804- Eastern US), and Alaska and Hawaii separately
- Developed and released a LandCarbon website for data distribution and visualization.
Additionally, a number of research papers have been published in leading journals by USGS and academic scientists supported by the program.
Going forward, the new focus of the program is in two priority areas:
- Synthesis and assessment linking ecosystem carbon balance with natural and anthropogenic processes as well as carbon management
- Carbon sequestration application studies in support of Department of the Interior land management decision making
Activities:
Aquatic Systems
The USGS investigates the amount of carbon burial, emissions, and export taking place in the aquatic ecosystems of the United States. Data analysis and modeling are used to identify the controls on greenhouse gas emissions from lakes and rivers, as well as the magnitude of carbon burial in sediments. Linkages between land use and carbon cycling in nearby aquatic habitats are being characterized in order to understand the effects of human activity such as agriculture and development on aquatic carbon cycling. Carbon export to the coastal ocean is also being quantified, and ecosystem models will describe the movement of continental carbon exports through the coastal food web.
Inland aquatic ecosystems (rivers, lakes, ponds, and reservoirs) play several important roles in the carbon cycle. Carbon that has been fixed via terrestrial primary production and processed in the soil is exported to surface water as both organic and mineral carbon compounds. In the aquatic environment, organic carbon compounds are respired (converted to CO2) by bacteria. This process can lead to a greater concentration of CO2 in the water than in the air (supersaturation), which results in "degassing", or emission of CO2 to the atmosphere. At the same time, plants and algae in aquatic ecosystems take up CO2 for photosynthesis. As it moves through the food web, most of this carbon is ultimately converted back to CO2 by respiration, but some of it can be buried in sediments. Anaerobic decomposition of carbon buried in sediments can create CH4, another greenhouse gas, which can also escape to the atmosphere. River systems transport carbon, originating from both terrestrial and aquatic systems, to the coastal ocean, where it is then further processed (emitted as greenhouse gases, buried in sediments, or transported offshore).
Carbon Sequestration Assessment
According to the newly completed the 2nd State of Carbon Cycle Report (), Terrestrial and aquatic ecosystems in the United States are a significant carbon sinks, taking up approximately a quarter of the nation’s CO2 emissions. The ecosystem carbon sink can be highly variable over space and time due to natural disturbances and land use decisions (Goodale and others, 2002)). Fire, for example, is a disturbance that affects a forest's carbon storage and has effects of both releasing CO2 and CH4 back into the atmosphere and strengthening a forest ecosystem's ability to increase sequestration over the long-term. USGS conducts synthesis and assessment of carbon sequestration processes and long-term balances of major ecosystems including forests, croplands, grasslands, and wetlands in relation to both natural and anthropogenic driving forces.
Ecosystem Disturbances – Wildland Fire
Ecosystem disturbance modeling and emission estimation produces spatially-explicit forecasts of fire patterns, and the resulting greenhouse gas emissions for U.S biomes. At the heart of the approach is a series of statistical and process-based models, coded in C++, that simulate processes of fire ignition, spread, and emissions. Patterns of historic ignitions are characterized using logistic regressions that relate ignition location to daily fuel moisture conditions, as well as, vegetation type and urban extent. These ignition models are used to determine when and where ignitions are located under stable or changing climate scenarios. Once ignitions are located, the area burned is determined by allowing each ignition to spread using the minimum travel time algorithm. After fire spread is complete, emissions are calculated using the FOFEM and CONSUME models.Vegetation, fuels, daily weather, and fuel moisture data are critical to disturbance simulations. Vegetation and fuels data are provided by the LANDFIRE project. The daily weather data we use have 12 km spatial resolution and span from 1950 to 2010. For future climate-change scenarios, we randomly resample annual sequences of historic daily weather and rescale them to match the monthly means provided by downscaled climate-change forecasts. Fuel moistures and fire behavior indices are calculated for both historic and forecast daily weather using the National Fire Danger Rating System and then used as predictor variables for ignition locations, fire spread, and fire emissions.
Future Scenarios and land use modeling
To study potential changes in land use, land cover and land management in the future United States, USGS has incorporated probable scenarios as defined by the Intergovernmental Panel on Climate Change (IPCC) in its fourth and fifth assessment reports (AR4 and AR5), which lists major driving forces of future emissions, including changes in demographic, technological and economic developments. To be able to incorporate these scenario assumptions into ongoing research and to produce nationally and regionally unique future potential land use and land cover scenarios, data on historical land-cover change from USGS and information derived from a global integrated assessment model are used in conjunction with expert analysis to 1) downscale scenario narrative storylines to national and sub-national scales, and 2) develop quantitative regional projections of LULC change for major land-use sectors of the conterminous United States. Results of this process are a set of quantitative future scenarios for specific land use and land cover classes, unique at both national and regional scales.There are large uncertainties in how land and climate systems will evolve and interact to shape future ecosystem carbon dynamics. To address this uncertainty, we developed the Land-Use and Carbon Scenario Simulator (LUCAS) to track changes in land use, land cover, land management, and disturbance, and their impact on ecosystem carbon storage and flux. The LUCAS model combines a state-and-transition simulation model (STSM) for modeling land-change with a stock and flow model for modeling carbon dynamics, within a scenario-based framework. These two models were developed in conjunction within the ST-SIM modeling environment to provide a complete package for testing a range of future scenarios of land-use change and their impacts on carbon dynamics. Land-use change scenarios developed from the Intergovernmental Panel on Climate Change's (IPCC) Special Report on Emission Scenarios (SRES), and Representative Concentration Pathways (RCPs), as well as scenarios developed from historical land-use change datasets that include a range of mitigation and adaptation policies can be applied in the model.
- Data
Below are data releases associated with this project.
- Publications
Below are publications associated with this project.
Filter Total Items: 145Land-use threats and protected areas: a scenario-based, landscape level approach
Anthropogenic land use will likely present a greater challenge to biodiversity than climate change this century in the Pacific Northwest, USA. Even if species are equipped with the adaptive capacity to migrate in the face of a changing climate, they will likely encounter a human-dominated landscape as a major dispersal obstacle. Our goal was to identify, at the ecoregion-level, protected areas inAuthorsTamara S. Wilson, Benjamin M. Sleeter, Rachel R. Sleeter, Christopher E. SoulardThe impact of climate and reservoirs on longitudinal riverine carbon fluxes from two major watersheds in the Central and Intermontane West
A nested sampling network on the Colorado (CR) and Missouri Rivers (MR) provided data to assess impacts of large-scale reservoir systems and climate on carbon export. The Load Estimator (LOADEST) model was used to estimate both dissolved inorganic and organic carbon (DIC and DOC) fluxes for a total of 22 sites along the main stems of the CR and MR. Both the upper CR and MR DIC and DOC fluxes increAuthorsSarah M. Stackpoole, Edward G. Stets, Robert G. StrieglSpatially explicit modeling of 1992-2100 land cover and forest stand age for the conterminous United States
Information on future land-use and land-cover (LULC) change is needed to analyze the impact of LULC change on ecological processes. The U.S. Geological Survey has produced spatially explicit, thematically detailed LULC projections for the conterminous United States. Four qualitative and quantitative scenarios of LULC change were developed, with characteristics consistent with the IntergovernmentalAuthorsTerry L. Sohl, Kristi Sayler, Michelle Bouchard, Ryan R. Reker, Aaron M. Friesz, Stacie L. Bennett, Benjamin M. Sleeter, Rachel R. Sleeter, Tamara S. Wilson, Christopher E. Soulard, Michelle Knuppe, Travis Van HofwegenSimulated impacts of mountain pine beetle and wildfire disturbances on forest vegetation composition and carbon stocks in the Southern Rocky Mountains
Forests play an important role in sequestering carbon and offsetting anthropogenic greenhouse gas emissions, but changing disturbance regimes may compromise the capability of forests to store carbon. In the Southern Rocky Mountains, a recent outbreak of mountain pine beetle (Dendroctonus ponderosae; MPB) has caused levels of tree mortality that are unprecedented in recorded history. To evaluate thAuthorsMegan K. Caldwell, Todd Hawbaker, Jenny S. Briggs, P.W. Cigan, Susan StittInorganic carbon loading as a primary driver of dissolved carbon dioxide concentrations in the lakes and reservoirs of the contiguous United States
Accurate quantification of CO2 flux across the air-water interface and identification of the mechanisms driving CO2 concentrations in lakes and reservoirs is critical to integrating aquatic systems into large-scale carbon budgets, and to predicting the response of these systems to changes in climate or terrestrial carbon cycling. Large-scale estimates of the role of lakes and reservoirs in the carAuthorsCory P. McDonald, Edward G. Stets, Robert G. Striegl, David ButmanExtending airborne electromagnetic surveys for regional active layer and permafrost mapping with remote sensing and ancillary data, Yukon Flats ecoregion, central Alaska
Machine-learning regression tree models were used to extrapolate airborne electromagnetic resistivity data collected along flight lines in the Yukon Flats Ecoregion, central Alaska, for regional mapping of permafrost. This method of extrapolation (r = 0.86) used subsurface resistivity, Landsat Thematic Mapper (TM) at-sensor reflectance, thermal, TM-derived spectral indices, digital elevation modelAuthorsNeal J. Pastick, M. Torre Jorgenson, Bruce K. Wylie, Burke J. Minsley, Lei Ji, Michelle Ann Walvoord, Bruce D. Smith, Jared D. Abraham, Joshua R. RoseEffect of heterogeneous atmospheric CO2 on simulated global carbon budget
The effects of rising atmospheric carbon dioxide (CO2) on terrestrial carbon (C) sequestration have been a key focus in global change studies. As anthropological CO2 emissions substantially increase, the spatial variability of atmospheric CO2 should be considered to reduce the potential bias on C source and sink estimations. In this study, the global spatial–temporal patterns of near surface CO2 cAuthorsZhen Zhang, Hong Jiang, Jinxun Liu, Weimin Ju, Xiuying Zhang234U/238U and δ87Sr in peat as tracers of paleosalinity in the Sacramento-San Joaquin Delta of California, USA
The purpose of this study was to determine the history of paleosalinity over the past 6000+ years in the Sacramento-San Joaquin Delta (the Delta), which is the innermost part of the San Francisco Estuary. We used a combination of Sr and U concentrations, d87Sr values, and 234U/238U activity ratios (AR) in peat as proxies for tracking paleosalinity. Peat cores were collected in marshes on Browns IsAuthorsJudith Z. Drexler, James B. Paces, Charles N. Alpers, Lisamarie Windham-Myers, Leonid A. Neymark, Thomas D. Bullen, Howard E. TaylorMountain pine beetle impacts on vegetation and carbon stocks
In the Southern Rocky Mountains, an epidemic outbreak of mountain pine beetle (Dendroctonus ponderosae; MPB) has caused levels of tree mortality unprecedented in recorded history. The impacts of this mortality on vegetation composition, forest structure, and carbon stocks have only recently received attention, although the impacts of other disturbances such as fires and land-use/land-cover changeAuthorsTodd Hawbaker, Jennifer S. Briggs, Megan K. Caldwell, Susan StittLand use and carbon dynamics in the southeastern United States from 1992 to 2050
Land use and land cover change (LUCC) plays an important role in determining the spatial distribution, magnitude, and temporal change of terrestrial carbon sources and sinks. However, the impacts of LUCC are not well understood and quantified over large areas. The goal of this study was to quantify the spatial and temporal patterns of carbon dynamics in various terrestrial ecosystems in the southeAuthorsShuqing Zhao, Shuguang Liu, Terry L. Sohl, Claudia Young, Jeremy M. WernerBaseline and projected future carbon storage and greenhouse-gas fluxes in ecosystems of the Western United States
This assessment was conducted to fulfill the requirements of section 712 of the Energy Independence and Security Act (EISA) of 2007 and to improve understanding of carbon and greenhouse gas (GHG) fluxes in ecosystems of the Western United States. The assessment examined carbon storage, carbon fluxes, and other GHG fluxes (methane and nitrous oxide) in all major terrestrial ecosystems (forests, graAuthorsZhi-Liang Zhu, Bradley C. ReedScenarios of land use and land cover change in the conterminous United States: Utilizing the special report on emission scenarios at ecoregional scales
Global environmental change scenarios have typically provided projections of land use and land cover for a relatively small number of regions or using a relatively coarse resolution spatial grid, and for only a few major sectors. The coarseness of global projections, in both spatial and thematic dimensions, often limits their direct utility at scales useful for environmental management. This paperAuthorsBenjamin M. Sleeter, Terry L. Sohl, Michelle A. Bouchard, Ryan R. Reker, Christopher E. Soulard, William Acevedo, Glenn E. Griffith, Rachel R. Sleeter, Roger F. Auch, Kristi Sayler, Stephen Prisley, Zhi-Liang Zhu