O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 1 Vegetation/Ecosystem Modeling and Analysis Project (VEMAP) Lessons Learned or How to Do.

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Presentation transcript:

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 1 Vegetation/Ecosystem Modeling and Analysis Project (VEMAP) Lessons Learned or How to Do It Right; How to Get What You Need Anthony W. King Environmental Sciences Division Oak Ridge National Laboratory With contribution from Tim Kittel University of Colorado, Boulder NACP Data Management Planning Workshop January New Orleans, LA

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 2 Where I’m coming from…  I’m speaking from VEMAP or of VEMAP not for VEMAP  I come to praise Caesar, not to bury him.

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 3

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 4 Outline  An overview of VEMAP  A few VEMAP findings  Lessons learned relevant to NACP data management  Good  Not so good  Summary/Conclusions

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 5

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 6 Overview of VEMAP  The Vegetation-Ecosystem Modeling and Analysis Project (VEMAP) was a large, collaborative, international, multi-agency effort to simulate and understand ecosystem dynamics for the conterminous United States.  VEMAP objectives were to intercompare biogeochemistry and biogeography models and determine their sensitivity to changing climate and elevated atmospheric CO 2 concentrations.  An intermodel comparison, with explicit and structured control for differences in model inputs.

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 7 Overview of VEMAP “To accomplish [VEMAP] objectives, the models require common boundary conditions and driving variables so that differences in model results arise only from the models and their implementation rather than from differences in inputs.” (p. 858, Kittel et al., 1995, J. Biogeography 22)

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 8 Overview of VEMAP: VEMAP had two phases  Phase 1 (VEMAP 1) was structured as a sensitivity analysis, with factorial combinations of climate (current and projected under doubled CO 2 ), atmospheric CO 2, and mapped and model- generated vegetation distributions.  Phase 2 (VEMAP 2) compared time-dependent ecological responses of biogeochemical models and coupled biogeochemical-biogeographical models to historical and projected transient forcings (time-series) of climate and CO 2.

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 9 VEMAP Datasets  A lot of effort and resources led by Tim Kittel and Dave Schimel and the VEMAP data group at NCAR went into the creation and QA of the common model inputs.  VEMAP 1 database is gridded (0.5º) data layers of bioclimate, climate change scenarios, soil properties, and potential natural vegetation. The set has both daily and monthly, physically consistent, representations of the same long- term climate.  VEMAP 2 database added a historical ( ) gridded dataset of climate and transient climate change scenarios based on coupled atmosphere- ocean GCM experiments.

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 10 VEMAP findings  Strong forcing of one or a few processes does not necessarily result in large changes in ecosystem carbon because of constraints from other limiting resources (e.g., N or PAR).  Variation among models was “relatively modest”; the variation present was linked to differential sensitivities of hydrologic and nitrogen cycles to increases in temperature and CO 2.  Understanding, modeling and predicting changes in carbon require understanding and modeling of integrated carbon, nitrogen and water cycles.

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 11 VEMAP findings  Models were sensitive to disturbance; knowledge of spatial and temporal patterns of disturbance and ecosystem response to is needed for spatial modeling of ecosystems.  Models simulated a smaller sink than estimated by inversions, highlighting the important role of forest regrowth in a North American carbon sink.  Spatially extended terrestrial ecosystem models must incorporate spatial patterns of disturbance and recovery from disturbance.  Intermodel variability was higher at the regional scale than for the entire continent.

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 12 Lessons Learned “To accomplish [VEMAP] objectives, the models require common boundary conditions and driving variables so that differences in model results arise only from the models and their implementation rather than from differences in inputs.” (p. 858, Kittel et al., 1995, J. Biogeography 22)

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 13 Lessons learned: model requirements strongly guided data requirements [The model intercomparison required] “physical consistency among driving variables and boundary conditions…that did not violate the conceptual basis of any of the models.” “matching model requirements was…a key constraint in the development of consistent…data sets.” “Matching model requirements…played a role in the classification of vegetation types”.

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 14 Lessons learned: Good  Explicit objectives or goals measured by tangible products generate specific requirements that in turn provide the required specifications and constraints for the data systems.  Assumptions in the data and data processing need to be made explicit and transparent to the user.  Need to establish and follow a clear protocol for QA

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 15 Lessons learned: Good  A dissemination plan with considerations of version control, metadata and distribution strategy is required.  Need to create essential user tools but just the essentials; avoid the distraction of super-tools or toolboxes.

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 16 Lessons learned: Good  It takes resources, money, people, infrastructure and time to meet the data system specifications and requirements.  It requires close, real integration and dialogue between the modeling and data systems to both define and realize requirements.

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 17 Lessons learned: not so good  Comparisons against experimental data are needed leading to model-data intercomparisons rather than just model intercomparisons.  More common biological/ecologial parameterization, not just common forcings and boundary conditions, are needed.  More attention to uncertainty analysis and error propagation.

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 18 Summary/Conclusions  VEMAP was a success, both as a model intercomparison, and, inextricably, as a data system.  VEMAP is a model for NACP data systems.  NACP data systems should include data for model testing, process parameterization and provide for formal uncertainty analysis.  Resources are required.  Explicit program objectives/deliverables similar to project objectives are needed to provide the necessary specifications for a NACP data system.

O AK R IDGE N ATIONAL L ABORATORY U. S. D EPARTMENT OF E NERGY 19