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Carbon Cycle Modeling

Carbon Cycle Modeling. Terrestrial Ecosystem Models W.M. Post, ORNL Atmospheric Measurements and Models S. Denning, CSU Global and Regional Inferences from Monitoring C.D. Keeling, SIO. Terrestrial Modeling. Objectives Progress New Directions Future Challenges.

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Carbon Cycle Modeling

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  1. Carbon Cycle Modeling Terrestrial Ecosystem Models W.M. Post, ORNL Atmospheric Measurements and Models S. Denning, CSU Global and Regional Inferences from Monitoring C.D. Keeling, SIO

  2. Terrestrial Modeling • Objectives • Progress • New Directions • Future Challenges

  3. Terrestrial Modeling - Objectives • Quantify CO2 exchanges with the atmosphere • Project how terrestrial CO2 exchanges will change in the future • Provide estimates of trace gas sources and sinks for use with atmospheric models or in Earth System Models

  4. Terrestrial Modeling - Progress • Photosynthesis, evapotranspiration - detailed characterization, • Biochemical models • Light-use efficiency models • Soil organic matter decomposition – robust representation, model/data comparisons at different temporal scales • Multicompartment structure • C, N and nutrient dynamics

  5. Terrestrial Models - Progress (cont.) • Model intercomparison projects • CMEAL, VEMAP, CCMLP • Model - data comparison projects • Individual experimental and monitoring sites • AmeriFlux modeling activity • Ecosystem Model-Data Intercomparison (EMDI)

  6. MAESTRA Simulations vs. Eddy Covariance Measurements – Duke FACE (Luo et al. 2001)

  7. Global Biogeochemical Simulations

  8. Regional Light-Use Efficiency Model Calculations

  9. Model - Experimental Observations Interaction • Detailed process level description allows: • Incorporation of new experimental findings • Model comparison to experimental and field measurements • Identify measurements and processes that suggest additional hypotheses

  10. North America Historical Simulation

  11. Increase in Photosynthesis with Diffuse Radiation for Different Ecosystems

  12. Role of clouds, aerosols in global carbon cycle • Diffuse radiation results in higher light use efficiencies by plant canopies • Diffuse radiation has a much less tendency to cause canopy photosynthetic saturation • Under a turbid atmospheric environment caused by natural events such as volcanic eruptions, canopy photosynthesis can be enhanced if part of the reduction in direct solar radiation is converted into diffuse radiation

  13. Terrestrial Modeling - New Directions • Additional processes • Phenology • Allocation • Biogeography shifts • Land-use change • Inventories and surveys • Remote sensing

  14. Terrestrial Modeling - Challenges • Continue to increase spatial and temporal resolution • improves process representation of regional and global spatial variation • allows use of wider range of observations for tests of consistency/validation • Data assimilation • Parameter estimation • Initial condition or state estimation

  15. North America Carbon Cycle (GTEC)

  16. Level of NEP Depends on Initial Conditions

  17. Initial Condition Strategy • Model spin-up with conditions “typical” of pre-simulation period • Adjust initial conditions with simulation using available historical observations (land-use statistics, age-class structure, remote sensing) • Use numerical weather prediction like data assimilation techniques to continually adjust model states to be consistent with “real time” monitoring information (Ameriflux, Globalview, MODIS, FIA, etc.)

  18. Terrestrial Modeling - Summary • Biogeochemical process understanding results in: • Improving generality of terrestrial models • Improving representation of interactions and feedbacks between CO2, radiation, climate, nutrient cycles • Terrestrial models are increasing in spatial and temporal resolution • Integration with atmospheric models will be critical for identifying terrestrial C sources and sinks

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