Skip to main content
U.S. flag

An official website of the United States government

Has the USGS made any Biologic Carbon Sequestration assessments?

The USGS is congressionally mandated (2007 Energy Independence and Security Act) to conduct a comprehensive national assessment of storage and flux (flow) of carbon and the fluxes of other greenhouse gases (including carbon dioxide) in ecosystems.

At this writing, reports have been completed for Alaska, the Eastern U.S., the Great Plains, and the Western U.S.

Learn more: Carbon Emissions and Sequestration

Related

link
Major Carbon Pools

What is carbon sequestration?

Carbon dioxide is the most commonly produced greenhouse gas. Carbon sequestration is the process of capturing and storing atmospheric carbon dioxide. It is one method of reducing the amount of carbon dioxide in the atmosphere with the goal of reducing global climate change. The USGS is conducting assessments on two major types of carbon sequestration: geologic and biologic.
link

What is carbon sequestration?

Carbon dioxide is the most commonly produced greenhouse gas. Carbon sequestration is the process of capturing and storing atmospheric carbon dioxide. It is one method of reducing the amount of carbon dioxide in the atmosphere with the goal of reducing global climate change. The USGS is conducting assessments on two major types of carbon sequestration: geologic and biologic.
Learn More
link
Uncovering the Ecosystem Service Value of Carbon Sequestration in National Parks. Photo by Robert Crootof, NPS.

What’s the difference between geologic and biologic carbon sequestration?

Geologic carbon sequestration is the process of storing carbon dioxide (CO2) in underground geologic formations. The CO2 is usually pressurized until it becomes a liquid, and then it is injected into porous rock formations in geologic basins. This method of carbon storage is also sometimes a part of enhanced oil recovery, otherwise known as tertiary recovery, because it is typically used later in...
link

What’s the difference between geologic and biologic carbon sequestration?

Geologic carbon sequestration is the process of storing carbon dioxide (CO2) in underground geologic formations. The CO2 is usually pressurized until it becomes a liquid, and then it is injected into porous rock formations in geologic basins. This method of carbon storage is also sometimes a part of enhanced oil recovery, otherwise known as tertiary recovery, because it is typically used later in...
Learn More
link
Orthoimage of a four-way interchange, Los Angeles, CA

How does carbon get into the atmosphere?

Atmospheric carbon dioxide comes from two primary sources—natural and human activities. Natural sources of carbon dioxide include most animals, which exhale carbon dioxide as a waste product. Human activities that lead to carbon dioxide emissions come primarily from energy production, including burning coal, oil, or natural gas. Learn more: Sources of Greenhouse Gas Emissions (EPA)
link

How does carbon get into the atmosphere?

Atmospheric carbon dioxide comes from two primary sources—natural and human activities. Natural sources of carbon dioxide include most animals, which exhale carbon dioxide as a waste product. Human activities that lead to carbon dioxide emissions come primarily from energy production, including burning coal, oil, or natural gas. Learn more: Sources of Greenhouse Gas Emissions (EPA)
Learn More
link
imaging from Mars

How much carbon dioxide can the United States store via geologic sequestration?

In 2013, the USGS released the first-ever comprehensive, nation-wide assessment of geologic carbon sequestration, which estimates a mean storage potential of 3,000 metric gigatons of carbon dioxide. The assessment is the first geologically-based, probabilistic assessment, with a range of 2,400 to 3,700 metric gigatons of potential carbon dioxide storage. In addition, the assessment is for the...
link

How much carbon dioxide can the United States store via geologic sequestration?

In 2013, the USGS released the first-ever comprehensive, nation-wide assessment of geologic carbon sequestration, which estimates a mean storage potential of 3,000 metric gigatons of carbon dioxide. The assessment is the first geologically-based, probabilistic assessment, with a range of 2,400 to 3,700 metric gigatons of potential carbon dioxide storage. In addition, the assessment is for the...
Learn More
link
Image shows a drill core in a box with cardboard dividers

Which area is the best for geologic carbon sequestration?

It is difficult to characterize one area as “the best” for carbon sequestration because the answer depends on the question: best for what? However, the area of the assessment with the most storage potential for carbon dioxide is the Coastal Plains region, which includes coastal basins from Texas to Georgia. That region accounts for 2,000 metric gigatons, or 65 percent, of the storage potential...
link

Which area is the best for geologic carbon sequestration?

It is difficult to characterize one area as “the best” for carbon sequestration because the answer depends on the question: best for what? However, the area of the assessment with the most storage potential for carbon dioxide is the Coastal Plains region, which includes coastal basins from Texas to Georgia. That region accounts for 2,000 metric gigatons, or 65 percent, of the storage potential...
Learn More
link
Image: Coal Burning Power Plant

How much carbon dioxide does the United States and the World emit each year from energy sources?

The U.S. Energy Information Administration estimates that in 2019, the United States emitted 5,130 million metric tons of energy-related carbon dioxide, while the global emissions of energy-related carbon dioxide totaled 33,621.5 million metric tons.
link

How much carbon dioxide does the United States and the World emit each year from energy sources?

The U.S. Energy Information Administration estimates that in 2019, the United States emitted 5,130 million metric tons of energy-related carbon dioxide, while the global emissions of energy-related carbon dioxide totaled 33,621.5 million metric tons.
Learn More
UAS operations near Moab, Utah for carbon sequestration research on public lands
UAS operations near Moab, Utah for carbon sequestration research on public lands
UAS operations near Moab, Utah for carbon sequestration research on public lands
UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

By
Geosciences and Environmental Change Science Center
UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

By
Geosciences and Environmental Change Science Center
Infographic describing biological sequestration, showing how carbon can be stored in soil and large root structures of plants
Biological Carbon Sequestration
Biological Carbon Sequestration
Infographic describing biological sequestration, showing how carbon can be stored in soil and large root structures of plants

Biological Carbon Sequestration

Biological Carbon Sequestration

Biological carbon sequestration is the natural ability of life and ecosystems to store carbon. Forests, peat marshes, and coastal wetlands are particularly good as storing carbon. Carbon can be stored in plant tissue, such as long-lived tree bark or in extensive root systems. Microbes break down plant and animal tissue through decomposition.

By
Climate Adaptation Science Centers
Infographic describing biological sequestration, showing how carbon can be stored in soil and large root structures of plants

Biological Carbon Sequestration

Biological Carbon Sequestration

Biological carbon sequestration is the natural ability of life and ecosystems to store carbon. Forests, peat marshes, and coastal wetlands are particularly good as storing carbon. Carbon can be stored in plant tissue, such as long-lived tree bark or in extensive root systems. Microbes break down plant and animal tissue through decomposition.

By
Climate Adaptation Science Centers
How Does Carbon Get Into the Atmosphere?
How Does Carbon Get Into the Atmosphere?

How Does Carbon Get Into the Atmosphere?

How Does Carbon Get Into the Atmosphere?

A short video on how carbon can get into the atmosphere. 

By
Communications and Publishing

How Does Carbon Get Into the Atmosphere?

How Does Carbon Get Into the Atmosphere?

A short video on how carbon can get into the atmosphere. 

By
Communications and Publishing
Measuring soil CO2 efflux
Measuring soil CO2 efflux
Measuring soil CO2 efflux
Measuring soil CO2 efflux

Measuring soil CO2 efflux

Measuring soil CO2 efflux

Measuring soil CO2 efflux at the Bemidji Crude Oil Spill research site

Measuring soil CO2 efflux

Measuring soil CO2 efflux

Measuring soil CO2 efflux

Measuring soil CO2 efflux at the Bemidji Crude Oil Spill research site

PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide
PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide

PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide

PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide

Is Sequestration Necessary? Can We Do It at an Acceptable Total Cost?

By Yousif Kharaka, USGS National Research Program

 

By
Communications and Publishing, Public Lecture Series

PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide

PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide

Is Sequestration Necessary? Can We Do It at an Acceptable Total Cost?

By Yousif Kharaka, USGS National Research Program

 

By
Communications and Publishing, Public Lecture Series
video thumbnail: Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands
Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands
video thumbnail: Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

This video provides an overview of direct and indirect effects of increases in atmospheric CO2 on coastal wetlands using a salt marsh-mangrove community as an example.

By
Ecosystems
video thumbnail: Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

This video provides an overview of direct and indirect effects of increases in atmospheric CO2 on coastal wetlands using a salt marsh-mangrove community as an example.

By
Ecosystems
Filter Total Items: 13

Federal lands greenhouse gas emissions and sequestration in the United States: Estimates for 2005–22

In 2016, the Secretary of the U.S. Department of the Interior requested that the U.S. Geological Survey (USGS) produce a publicly available and annually updated database of estimated greenhouse gas emissions associated with the extraction and use of fossil fuels from Federal lands. The first report in this series included emissions estimates from 2005 to 2014 and were reported for 29...
Authors
Matthew D. Merrill, Benjamin M. Sleeter, Philip A. Freeman
By
Energy Resources Program, Geology, Energy & Minerals Science Center, Western Geographic Science Center

Baseline and projected future carbon storage and carbon fluxes in ecosystems of Hawai‘i

This assessment was conducted to fulfill the requirements of section 712 of the Energy Independence and Security Act of 2007 and to improve understanding of factors influencing carbon balance in ecosystems of Hawai‘i. Ecosystem carbon storage, carbon fluxes, and carbon balance were examined for major terrestrial ecosystems on the seven main Hawaiian islands in two time periods: baseline...
By
Core Science Systems Mission Area, Land Change Science Program, Western Geographic Science Center, Geosciences and Environmental Change Science Center

Assessing wildlife benefits and carbon storage from restored and natural coastal marshes in the Nisqually River Delta: Determining marsh net ecosystem carbon balance

Working in partnership since 1996, the U.S. Fish and Wildlife Service and the Nisqually Indian Tribe have restored 902 acres of tidally influenced coastal marsh in the Nisqually River Delta (NRD), making it the largest estuary-restoration project in the Pacific Northwest to date. Marsh restoration increases the capacity of the estuary to support a diversity of wildlife species...
Authors
Frank E. Anderson, Brian Bergamaschi, Lisamarie Windham-Myers, Isa Woo PR, Susan E.W. De La Cruz, Judith Z. Drexler, Kristin B. Byrd, Karen M. Thorne
By
Water Resources Mission Area, California Water Science Center

Baseline and projected future carbon storage and greenhouse-gas fluxes in ecosystems of Alaska

This assessment was conducted to fulfill the requirements of section 712 of the Energy Independence and Security Act of 2007 and to contribute to knowledge of the storage, fluxes, and balance of carbon and methane gas in ecosystems of Alaska. The carbon and methane variables were examined for major terrestrial ecosystems (uplands and wetlands) and inland aquatic ecosystems in Alaska in...
By
Core Science Systems Mission Area, Climate Adaptation Science Centers, Land Change Science Program, Earth Resources Observation and Science (EROS) Center

Baseline and projected future carbon storage and greenhouse-gas fluxes in ecosystems of the eastern United States

This assessment was conducted to fulfill the requirements of section 712 of the Energy Independence and Security Act of 2007 and to conduct a comprehensive national assessment of storage and flux (flow) of carbon and the fluxes of other greenhouse gases in ecosystems of the Eastern United States. These carbon and greenhouse gas variables were examined for major terrestrial ecosystems...
By
Core Science Systems Mission Area, Land Change Science Program, Earth Resources Observation and Science (EROS) Center

A long-term comparison of carbon sequestration rates in impounded and naturally tidal freshwater marshes along the lower Waccamaw River, South Carolina

Carbon storage was compared between impounded and naturally tidal freshwater marshes along the Lower Waccamaw River in South Carolina, USA. Soil cores were collected in (1) naturally tidal, (2) moist soil (impounded, seasonally drained since ~1970), and (3) deeply flooded “treatments” (impounded, flooded to ~90 cm since ~2002). Cores were analyzed for % organic carbon, % total carbon...
Authors
Judith Z. Drexler, Ken W. Krauss, M. Craig Sasser, Christopher C. Fuller, Christopher M. Swarzenski, Amber Powell, Kathleen Swanson, James L. Orlando
By
Ecosystems Mission Area, Water Resources Mission Area, California Water Science Center, South Atlantic Water Science Center (SAWSC), Wetland and Aquatic Research Center

A new data set for estimating organic carbon storage to 3 m depth in soils of the northern circumpolar permafrost region

High-latitude terrestrial ecosystems are key components in the global carbon cycle. The Northern Circumpolar Soil Carbon Database (NCSCD) was developed to quantify stocks of soil organic carbon (SOC) in the northern circumpolar permafrost region (a total area of 18.7 × 106 km2). The NCSCD is a geographical information system (GIS) data set that has been constructed using harmonized...
Authors
Gustaf Hugelius, James G. Bockheim, Philip Camill, Bo Elberling, G. Grosse, Jennifer W. Harden, Kevin K. Johnson, T. Jorgenson, C.D. Koven, Peter Kuhry, G. J. Michaelson, U. Mishra, J. Palmtag, Chien-Lu Ping, J. P. O'Donnell, Lutz Schirrmeister, E.A.G. Schuur, Y. Sheng, L.C. Smith, J. V. Strauss, Z. Yu

Baseline 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...
Authors
Zhiliang Zhu, Bradley C. Reed
By
Geosciences and Environmental Change Science Center, Land Use Land Cover Modeling

Baseline and projected future carbon storage and greenhouse-gas fluxes in the Great Plains region of the 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 the Great Plains region in the central part of the United States. The assessment examined carbon storage, carbon fluxes, and other GHG fluxes (methane and nitrous oxide) in all major...
Authors
Michelle Bouchard, David Butman, Todd Hawbaker, Zhengpeng Li, Jinxun Liu, Shuguang Liu, Cory P. McDonald, Ryan R. Reker, Kristi Sayler, Benjamin M. Sleeter, Terry L. Sohl, Sarah M. Stackpoole, Anne Wein, Zhiliang Zhu
By
Earth Resources Observation and Science (EROS) Center , Land Use Land Cover Modeling

Hydrologic support of carbon dioxide flux revealed by whole-lake carbon budgets

Freshwater lakes are an important component of the global carbon cycle through both organic carbon (OC) sequestration and carbon dioxide (CO 2) emission. Most lakes have a net annual loss of CO2 to the atmosphere and substantial current evidence suggests that biologic mineralization of allochthonous OC maintains this flux. Because net CO 2 flux to the atmosphere implies net...
Authors
Edward G. Stets, Robert G. Striegl, George R. Aiken, Donald Rosenberry, T. C. Winter

A Holocene record of climate-driven shifts in coastal carbon sequestration

A sediment core collected in the mesohaline portion of Chesapeake Bay was found to contain periods of increased delivery of refractory black carbon (BC) and polycyclic aromatic hydrocarbons (PAHs). The BC was most likely produced by biomass combustion during four centennialscale dry periods as indicated by the Palmer Drought Severity Index (PDSI), beginning in the late Medieval Warm...
Authors
Siddhartha Mitra, A.R. Zimmerman, G.B. Hunsinger, Debra A. Willard, J.C. Dunn

A first-order analysis of the potential role of CO2 fertilization to affect the global carbon budget: A comparison of four terrestrial biosphere models

We compared the simulated responses of net primary production, heterotrophic respiration, net ecosystem production and carbon storage in natural terrestrial ecosystems to historical (1765 to 1990) and projected (1990 to 2300) changes of atmospheric CO2 concentration of four terrestrial biosphere models: the Bern model, the Frankfurt Biosphere Model (FBM), the High-Resolution Biosphere...
Authors
David W. Kicklighter, M. Bruno, S. Donges, G. Esser, Martin Heimann, J. V. K. Helfrich, F. Ift, F. Joos, J. Kaduk, G.H. Kohlmaier, A. V. McGuire, J. M. Melillo, R. R. Meyer, B. Moore, A. Nadler, I.C. Prentice, W. Sauf, A. L. Schloss, Stephen Sitch, U. Wittenberg, G. Wurth
Researchers Connect Satellite and Soil Data to Refine Salt Marsh Carbon Storage Estimates

Researchers Connect Satellite and Soil Data to Refine Salt Marsh Carbon Storage Estimates

Salt marshes store vast amounts of carbon, and new research supported by the Northeast CASC provides the most precise estimates yet – offering...

Read Article
Plant Biodiversity: An Often Overlooked Factor in Carbon Storage Models

Plant Biodiversity: An Often Overlooked Factor in Carbon Storage Models

Research from the National, North Central, and Northeast CASCs highlights the link between climate change, plant biodiversity loss, and future carbon...

Read Article
Amazon Carbon Dynamics: Understanding the Photosynthesis-Climate Link

Amazon Carbon Dynamics: Understanding the Photosynthesis-Climate Link

What controls the response of photosynthesis in Amazon tropical forests to seasonal variations in climate?

Read Article

Related

link
Major Carbon Pools

What is carbon sequestration?

Carbon dioxide is the most commonly produced greenhouse gas. Carbon sequestration is the process of capturing and storing atmospheric carbon dioxide. It is one method of reducing the amount of carbon dioxide in the atmosphere with the goal of reducing global climate change. The USGS is conducting assessments on two major types of carbon sequestration: geologic and biologic.
link

What is carbon sequestration?

Carbon dioxide is the most commonly produced greenhouse gas. Carbon sequestration is the process of capturing and storing atmospheric carbon dioxide. It is one method of reducing the amount of carbon dioxide in the atmosphere with the goal of reducing global climate change. The USGS is conducting assessments on two major types of carbon sequestration: geologic and biologic.
Learn More
link
Uncovering the Ecosystem Service Value of Carbon Sequestration in National Parks. Photo by Robert Crootof, NPS.

What’s the difference between geologic and biologic carbon sequestration?

Geologic carbon sequestration is the process of storing carbon dioxide (CO2) in underground geologic formations. The CO2 is usually pressurized until it becomes a liquid, and then it is injected into porous rock formations in geologic basins. This method of carbon storage is also sometimes a part of enhanced oil recovery, otherwise known as tertiary recovery, because it is typically used later in...
link

What’s the difference between geologic and biologic carbon sequestration?

Geologic carbon sequestration is the process of storing carbon dioxide (CO2) in underground geologic formations. The CO2 is usually pressurized until it becomes a liquid, and then it is injected into porous rock formations in geologic basins. This method of carbon storage is also sometimes a part of enhanced oil recovery, otherwise known as tertiary recovery, because it is typically used later in...
Learn More
link
Orthoimage of a four-way interchange, Los Angeles, CA

How does carbon get into the atmosphere?

Atmospheric carbon dioxide comes from two primary sources—natural and human activities. Natural sources of carbon dioxide include most animals, which exhale carbon dioxide as a waste product. Human activities that lead to carbon dioxide emissions come primarily from energy production, including burning coal, oil, or natural gas. Learn more: Sources of Greenhouse Gas Emissions (EPA)
link

How does carbon get into the atmosphere?

Atmospheric carbon dioxide comes from two primary sources—natural and human activities. Natural sources of carbon dioxide include most animals, which exhale carbon dioxide as a waste product. Human activities that lead to carbon dioxide emissions come primarily from energy production, including burning coal, oil, or natural gas. Learn more: Sources of Greenhouse Gas Emissions (EPA)
Learn More
link
imaging from Mars

How much carbon dioxide can the United States store via geologic sequestration?

In 2013, the USGS released the first-ever comprehensive, nation-wide assessment of geologic carbon sequestration, which estimates a mean storage potential of 3,000 metric gigatons of carbon dioxide. The assessment is the first geologically-based, probabilistic assessment, with a range of 2,400 to 3,700 metric gigatons of potential carbon dioxide storage. In addition, the assessment is for the...
link

How much carbon dioxide can the United States store via geologic sequestration?

In 2013, the USGS released the first-ever comprehensive, nation-wide assessment of geologic carbon sequestration, which estimates a mean storage potential of 3,000 metric gigatons of carbon dioxide. The assessment is the first geologically-based, probabilistic assessment, with a range of 2,400 to 3,700 metric gigatons of potential carbon dioxide storage. In addition, the assessment is for the...
Learn More
link
Image shows a drill core in a box with cardboard dividers

Which area is the best for geologic carbon sequestration?

It is difficult to characterize one area as “the best” for carbon sequestration because the answer depends on the question: best for what? However, the area of the assessment with the most storage potential for carbon dioxide is the Coastal Plains region, which includes coastal basins from Texas to Georgia. That region accounts for 2,000 metric gigatons, or 65 percent, of the storage potential...
link

Which area is the best for geologic carbon sequestration?

It is difficult to characterize one area as “the best” for carbon sequestration because the answer depends on the question: best for what? However, the area of the assessment with the most storage potential for carbon dioxide is the Coastal Plains region, which includes coastal basins from Texas to Georgia. That region accounts for 2,000 metric gigatons, or 65 percent, of the storage potential...
Learn More
link
Image: Coal Burning Power Plant

How much carbon dioxide does the United States and the World emit each year from energy sources?

The U.S. Energy Information Administration estimates that in 2019, the United States emitted 5,130 million metric tons of energy-related carbon dioxide, while the global emissions of energy-related carbon dioxide totaled 33,621.5 million metric tons.
link

How much carbon dioxide does the United States and the World emit each year from energy sources?

The U.S. Energy Information Administration estimates that in 2019, the United States emitted 5,130 million metric tons of energy-related carbon dioxide, while the global emissions of energy-related carbon dioxide totaled 33,621.5 million metric tons.
Learn More
UAS operations near Moab, Utah for carbon sequestration research on public lands
UAS operations near Moab, Utah for carbon sequestration research on public lands
UAS operations near Moab, Utah for carbon sequestration research on public lands
UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

By
Geosciences and Environmental Change Science Center
UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

UAS operations near Moab, Utah for carbon sequestration research on public lands

By
Geosciences and Environmental Change Science Center
Infographic describing biological sequestration, showing how carbon can be stored in soil and large root structures of plants
Biological Carbon Sequestration
Biological Carbon Sequestration
Infographic describing biological sequestration, showing how carbon can be stored in soil and large root structures of plants

Biological Carbon Sequestration

Biological Carbon Sequestration

Biological carbon sequestration is the natural ability of life and ecosystems to store carbon. Forests, peat marshes, and coastal wetlands are particularly good as storing carbon. Carbon can be stored in plant tissue, such as long-lived tree bark or in extensive root systems. Microbes break down plant and animal tissue through decomposition.

By
Climate Adaptation Science Centers
Infographic describing biological sequestration, showing how carbon can be stored in soil and large root structures of plants

Biological Carbon Sequestration

Biological Carbon Sequestration

Biological carbon sequestration is the natural ability of life and ecosystems to store carbon. Forests, peat marshes, and coastal wetlands are particularly good as storing carbon. Carbon can be stored in plant tissue, such as long-lived tree bark or in extensive root systems. Microbes break down plant and animal tissue through decomposition.

By
Climate Adaptation Science Centers
How Does Carbon Get Into the Atmosphere?
How Does Carbon Get Into the Atmosphere?

How Does Carbon Get Into the Atmosphere?

How Does Carbon Get Into the Atmosphere?

A short video on how carbon can get into the atmosphere. 

By
Communications and Publishing

How Does Carbon Get Into the Atmosphere?

How Does Carbon Get Into the Atmosphere?

A short video on how carbon can get into the atmosphere. 

By
Communications and Publishing
Measuring soil CO2 efflux
Measuring soil CO2 efflux
Measuring soil CO2 efflux
Measuring soil CO2 efflux

Measuring soil CO2 efflux

Measuring soil CO2 efflux

Measuring soil CO2 efflux at the Bemidji Crude Oil Spill research site

Measuring soil CO2 efflux

Measuring soil CO2 efflux

Measuring soil CO2 efflux

Measuring soil CO2 efflux at the Bemidji Crude Oil Spill research site

PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide
PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide

PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide

PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide

Is Sequestration Necessary? Can We Do It at an Acceptable Total Cost?

By Yousif Kharaka, USGS National Research Program

 

By
Communications and Publishing, Public Lecture Series

PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide

PubTalk 1/2011 — Capture and Geologic Sequestration of Carbon Dioxide

Is Sequestration Necessary? Can We Do It at an Acceptable Total Cost?

By Yousif Kharaka, USGS National Research Program

 

By
Communications and Publishing, Public Lecture Series
video thumbnail: Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands
Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands
video thumbnail: Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

This video provides an overview of direct and indirect effects of increases in atmospheric CO2 on coastal wetlands using a salt marsh-mangrove community as an example.

By
Ecosystems
video thumbnail: Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

Potential Effects of Elevated CO2 and Climate Change on Coastal Wetlands

This video provides an overview of direct and indirect effects of increases in atmospheric CO2 on coastal wetlands using a salt marsh-mangrove community as an example.

By
Ecosystems
Filter Total Items: 13

Federal lands greenhouse gas emissions and sequestration in the United States: Estimates for 2005–22

In 2016, the Secretary of the U.S. Department of the Interior requested that the U.S. Geological Survey (USGS) produce a publicly available and annually updated database of estimated greenhouse gas emissions associated with the extraction and use of fossil fuels from Federal lands. The first report in this series included emissions estimates from 2005 to 2014 and were reported for 29...
Authors
Matthew D. Merrill, Benjamin M. Sleeter, Philip A. Freeman
By
Energy Resources Program, Geology, Energy & Minerals Science Center, Western Geographic Science Center

Baseline and projected future carbon storage and carbon fluxes in ecosystems of Hawai‘i

This assessment was conducted to fulfill the requirements of section 712 of the Energy Independence and Security Act of 2007 and to improve understanding of factors influencing carbon balance in ecosystems of Hawai‘i. Ecosystem carbon storage, carbon fluxes, and carbon balance were examined for major terrestrial ecosystems on the seven main Hawaiian islands in two time periods: baseline...
By
Core Science Systems Mission Area, Land Change Science Program, Western Geographic Science Center, Geosciences and Environmental Change Science Center

Assessing wildlife benefits and carbon storage from restored and natural coastal marshes in the Nisqually River Delta: Determining marsh net ecosystem carbon balance

Working in partnership since 1996, the U.S. Fish and Wildlife Service and the Nisqually Indian Tribe have restored 902 acres of tidally influenced coastal marsh in the Nisqually River Delta (NRD), making it the largest estuary-restoration project in the Pacific Northwest to date. Marsh restoration increases the capacity of the estuary to support a diversity of wildlife species...
Authors
Frank E. Anderson, Brian Bergamaschi, Lisamarie Windham-Myers, Isa Woo PR, Susan E.W. De La Cruz, Judith Z. Drexler, Kristin B. Byrd, Karen M. Thorne
By
Water Resources Mission Area, California Water Science Center

Baseline and projected future carbon storage and greenhouse-gas fluxes in ecosystems of Alaska

This assessment was conducted to fulfill the requirements of section 712 of the Energy Independence and Security Act of 2007 and to contribute to knowledge of the storage, fluxes, and balance of carbon and methane gas in ecosystems of Alaska. The carbon and methane variables were examined for major terrestrial ecosystems (uplands and wetlands) and inland aquatic ecosystems in Alaska in...
By
Core Science Systems Mission Area, Climate Adaptation Science Centers, Land Change Science Program, Earth Resources Observation and Science (EROS) Center

Baseline and projected future carbon storage and greenhouse-gas fluxes in ecosystems of the eastern United States

This assessment was conducted to fulfill the requirements of section 712 of the Energy Independence and Security Act of 2007 and to conduct a comprehensive national assessment of storage and flux (flow) of carbon and the fluxes of other greenhouse gases in ecosystems of the Eastern United States. These carbon and greenhouse gas variables were examined for major terrestrial ecosystems...
By
Core Science Systems Mission Area, Land Change Science Program, Earth Resources Observation and Science (EROS) Center

A long-term comparison of carbon sequestration rates in impounded and naturally tidal freshwater marshes along the lower Waccamaw River, South Carolina

Carbon storage was compared between impounded and naturally tidal freshwater marshes along the Lower Waccamaw River in South Carolina, USA. Soil cores were collected in (1) naturally tidal, (2) moist soil (impounded, seasonally drained since ~1970), and (3) deeply flooded “treatments” (impounded, flooded to ~90 cm since ~2002). Cores were analyzed for % organic carbon, % total carbon...
Authors
Judith Z. Drexler, Ken W. Krauss, M. Craig Sasser, Christopher C. Fuller, Christopher M. Swarzenski, Amber Powell, Kathleen Swanson, James L. Orlando
By
Ecosystems Mission Area, Water Resources Mission Area, California Water Science Center, South Atlantic Water Science Center (SAWSC), Wetland and Aquatic Research Center

A new data set for estimating organic carbon storage to 3 m depth in soils of the northern circumpolar permafrost region

High-latitude terrestrial ecosystems are key components in the global carbon cycle. The Northern Circumpolar Soil Carbon Database (NCSCD) was developed to quantify stocks of soil organic carbon (SOC) in the northern circumpolar permafrost region (a total area of 18.7 × 106 km2). The NCSCD is a geographical information system (GIS) data set that has been constructed using harmonized...
Authors
Gustaf Hugelius, James G. Bockheim, Philip Camill, Bo Elberling, G. Grosse, Jennifer W. Harden, Kevin K. Johnson, T. Jorgenson, C.D. Koven, Peter Kuhry, G. J. Michaelson, U. Mishra, J. Palmtag, Chien-Lu Ping, J. P. O'Donnell, Lutz Schirrmeister, E.A.G. Schuur, Y. Sheng, L.C. Smith, J. V. Strauss, Z. Yu

Baseline 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...
Authors
Zhiliang Zhu, Bradley C. Reed
By
Geosciences and Environmental Change Science Center, Land Use Land Cover Modeling

Baseline and projected future carbon storage and greenhouse-gas fluxes in the Great Plains region of the 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 the Great Plains region in the central part of the United States. The assessment examined carbon storage, carbon fluxes, and other GHG fluxes (methane and nitrous oxide) in all major...
Authors
Michelle Bouchard, David Butman, Todd Hawbaker, Zhengpeng Li, Jinxun Liu, Shuguang Liu, Cory P. McDonald, Ryan R. Reker, Kristi Sayler, Benjamin M. Sleeter, Terry L. Sohl, Sarah M. Stackpoole, Anne Wein, Zhiliang Zhu
By
Earth Resources Observation and Science (EROS) Center , Land Use Land Cover Modeling

Hydrologic support of carbon dioxide flux revealed by whole-lake carbon budgets

Freshwater lakes are an important component of the global carbon cycle through both organic carbon (OC) sequestration and carbon dioxide (CO 2) emission. Most lakes have a net annual loss of CO2 to the atmosphere and substantial current evidence suggests that biologic mineralization of allochthonous OC maintains this flux. Because net CO 2 flux to the atmosphere implies net...
Authors
Edward G. Stets, Robert G. Striegl, George R. Aiken, Donald Rosenberry, T. C. Winter

A Holocene record of climate-driven shifts in coastal carbon sequestration

A sediment core collected in the mesohaline portion of Chesapeake Bay was found to contain periods of increased delivery of refractory black carbon (BC) and polycyclic aromatic hydrocarbons (PAHs). The BC was most likely produced by biomass combustion during four centennialscale dry periods as indicated by the Palmer Drought Severity Index (PDSI), beginning in the late Medieval Warm...
Authors
Siddhartha Mitra, A.R. Zimmerman, G.B. Hunsinger, Debra A. Willard, J.C. Dunn

A first-order analysis of the potential role of CO2 fertilization to affect the global carbon budget: A comparison of four terrestrial biosphere models

We compared the simulated responses of net primary production, heterotrophic respiration, net ecosystem production and carbon storage in natural terrestrial ecosystems to historical (1765 to 1990) and projected (1990 to 2300) changes of atmospheric CO2 concentration of four terrestrial biosphere models: the Bern model, the Frankfurt Biosphere Model (FBM), the High-Resolution Biosphere...
Authors
David W. Kicklighter, M. Bruno, S. Donges, G. Esser, Martin Heimann, J. V. K. Helfrich, F. Ift, F. Joos, J. Kaduk, G.H. Kohlmaier, A. V. McGuire, J. M. Melillo, R. R. Meyer, B. Moore, A. Nadler, I.C. Prentice, W. Sauf, A. L. Schloss, Stephen Sitch, U. Wittenberg, G. Wurth
Researchers Connect Satellite and Soil Data to Refine Salt Marsh Carbon Storage Estimates

Researchers Connect Satellite and Soil Data to Refine Salt Marsh Carbon Storage Estimates

Salt marshes store vast amounts of carbon, and new research supported by the Northeast CASC provides the most precise estimates yet – offering...

Read Article
Plant Biodiversity: An Often Overlooked Factor in Carbon Storage Models

Plant Biodiversity: An Often Overlooked Factor in Carbon Storage Models

Research from the National, North Central, and Northeast CASCs highlights the link between climate change, plant biodiversity loss, and future carbon...

Read Article
Amazon Carbon Dynamics: Understanding the Photosynthesis-Climate Link

Amazon Carbon Dynamics: Understanding the Photosynthesis-Climate Link

What controls the response of photosynthesis in Amazon tropical forests to seasonal variations in climate?

Read Article
Updated Date: March 21, 2025
Was this page helpful?