Program Goal
Research provides scientific knowledge of terrestrial components of the global carbon cycle – for the purposes of accurate predictions of atmospheric CO2 change, evaluating terrestrial sources and sinks for CO2, and assessing effectiveness of ecosystem processes for controlling and squestering CO2 – thereby slowing the rate of atmospheric CO2 increase.Program Objectives
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(1) To advance the scientific understanding of terrestrial processes
that regulate carbon balance of ecosystems, including mechanistic controls
on exchanges of CO2 with the atmosphere;
(2) To understand fundamental carbon cycling mechanisms of the atmoshere
and biosphere as a basis for enhancing carbon sequestration by terrestrial
ecosystems;
(3) To measure changes of carbon quantities of ecosystems in relation
to the rising concentration of atmospheric CO2, and altered
temperature and precipitation regimes;
(4) To model terrestrial carbon processes, and use terrestrial ecosystem
models coupled with atmosphere-ocean carbon models to estimate rate and
timing of atmospheric CO2 change.
Program Description and Components
Terrestrial Carbon Processes (TCP) research provides the scientific underpinnings for predicting future concentrations of CO2 in the atmosphere. In particular, TCP research focuses on (i) understanding the processes controlling exchange rate of CO2 between atmosphere and terrestrial biosphere; (ii) developing process-based models of atmosphere-terrestrial carbon exchange; (iii) evaluating source-sink mechanisms for atmospheric CO2; and (iv) improving reliability of global carbon models for predicting future atmospheric concentrations of CO2. The research focuses on natural systems that regulate the abundance of CO2 in the atmosphere, including the role of terrestrial ecosystems in determining exchanges of CO2 with the atmosphere. Focus of the research is on the processes and mechanisms that influence quantities fixed by terrestrial ecosystems, and the potential for long-term carbon sequestration is evaluated. This research is distinct from, yet complimentary to continental scale carbon cycle observations of the National Oceanic and Atmospheric Administration (NOAA) and other laboratories. BER's TCP research responds to the U.S. Carbon Cycle Science Plan, and significantly contributes to the Interagency Carbon Cycle Implementation Plan. The research supports AmeriFlux measurements and modeling, and experiments on the effects of CO2 and changing climate variables on plants and ecosystems. Research also investigates plant physiological controls that affect exchange of CO2 between the atmosphere and terrestrial biota, changes of carbon content of plants and soil, and mechanisms of carbon transformation in soil. A major uncertainty of the greenhouse gas and potential climate change issue is what happens to the excess CO2 generated from the burning of fossil fuels. Rate and magnitude by which excess carbon is assimilated into sinks affects the balance that remains in the atmosphere. Terrestrial ecosystems play an important role in this process and fundamental TCP research provides the scientific foundation for estimating the capacity of ecosystems to sequester and store the considerable quantities of CO2 anticipated from fossil sources in the future. At the larger scale, the research focuses on ecosystem productivity and structural and functional properties of ecosystems, including roles of plant-animal-microbial communities that process carbon. Fundamental plant processes (e.g., photosynthesis, carbon metabolism and water balance) and ecosystem processes (e.g., productivity and nutrient turnover) are examined as they might be affected directly by CO2 and indirectly by changing climate conditions. Components of field and modeling activities include:- Carbon (CO2) flux and biometric measurements in terrestrial ecosystems for evaluating changes of carbon quantities.
- AmeriFlux, the network of CO2 flux, for directly estimating net ecosystem production (NEP), and carbon sequestration by terrestrial ecosystems.
- Experiments for determining effects of CO2, climate and other environmental variables on carbon uptake, sequestration by ecosystems (focus is on different environments and biogeochemical and climate-related feedbacks); FACE represents multi-disciplinary experiments to evaluate the responses of terrestrial plants and ecosystems to increased concentrations of atmospheric CO2 and changing climate variables.
- Mechanistic terrestrial carbon models for evaluating the role of the biosphere in atmospheric CO2 changes, and the influence of climate and other feedbacks on the biogeochemical cycle of carbon.
Program Announcements
No additional Program Announcement is anticipated in 2003.Program Linkages
The TCP research is central to DOE's policy concerns about excess CO2, which is the anticipated major human cause of climate change. Experiments and measurements of TCP provide critical data for tracking atmospheric CO2 changes, and for quantifying the terrestrial term of the excess CO2 budget. TCP data contribute to integrated Programs of the U. S. Global Change Research Program, particularly the "Carbon Cycle" interdisciplinary research element. The experiments contribute measurably to IGBP research on Global Change and Terrestrial Ecosystems (GCTE), and the AmeriFlux Network represents the North American component of the international FLUXNET Program. Carbon Cycle research contributes fundamental scientific information that underpins carbon sequestration and management programs in the Office of Science and the Office of Fossil Energy. TCP research contributes to the Administration's National Climate Change Technology Initiative (NCCTI) to quantify carbon affects due to carbon sequestration by terrestrial ecosystems. The TCP Program, especially AmeriFlux, contributes to the planned North American Carbon Program.Program Manager
Dr. Roger C. DahlmanClimate Change Research Division, SC-23.3
Department of Energy, GTN Bldg.
1000 Independence Ave, SW
Washington, DC 20585-1290
(301) 903-4951
Fax: (301) 903-8519
Internet: roger.dahlman@science.doe.gov