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Global Meteorology (NCEP FNL). Mesoscale Meteorology (MM5). Data Assimilation (STEM 4D-Var). Observations CO 2 (Vay et al) OCS (Blake et al). Global Transport (ECMWF/TM5 ). Mesoscale Transport (STEM). Surface Flux (SiB and Kettle). Flux Correction Scaling Factor. CO 2. OCS.
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Global Meteorology (NCEP FNL) Mesoscale Meteorology (MM5) Data Assimilation (STEM 4D-Var) Observations CO2 (Vay et al) OCS (Blake et al) Global Transport (ECMWF/TM5) Mesoscale Transport (STEM) Surface Flux (SiB and Kettle) Flux Correction Scaling Factor CO2 OCS Fig. 1. The dominant land fluxes of CO2 are photosynthesis and respiration while OCS uptake is influenced by a process linked to photosynthesis. Simultaneous assimilation of carbon dioxide and carbonyl sulfide observations for regional surface flux optimization 1Campbell, J.E., 1Stanier, C.O., 1Carmichael, G.R., 2Blake, N.J., 3Vay, S.A., 3Choi, Y.H., 1Chai, T., 1Tang, Y., 1Mena-Carrasco, M., 1Schnoor, J.L.1Center for Global and Regional Env’l. Research, University of Iowa, 2Dept. of Chemistry, University of California, Irvine, 3NASA Langley Introduction The fraction of future fossil fuel CO2 emissions that will remain in the atmosphere depends in part on how much CO2 will be taken up and released by terrestrial environments. There is currently a poor understanding of the processes responsible for regional land surface fluxes of CO2, a prerequisite for optimizing climate predictions. Regional-scale atmospheric inverse models can be used to study the processes controlling CO2 surface fluxes. Inverse models have been applied to correct surface flux estimates based on the differences between modeled and observed CO2 concentrations. It is often unclear whether the corrections should be associated with photosynthesis, respiration, or other processes. Carbonyl sulfide (OCS) is a new tracer of photosynthesis [Montzka and Tans, 2004] that is shown here to provide a crucial link between the flux corrections and processes. Results The July 25th flight, has highly correlated (r2 = 0.92) observations of CO2 and OCS, providing an opportunity for simultaneous assimilation. The model CO2 concentrations overestimate the observations at each low altitude pass (Fig. 3). These low altitude errors are strongly influenced by errors in the model surface fluxes and can be corrected with the inverse model. The errors could be due to underestimates of the photosynthesis sink and overestimates of the respiration and fossil fuel sources. Which surface fluxes should be corrected? First, we assimilate only CO2 observations and correct the model errors by calculating scaling factors for the photosynthesis surface sink. The average RMS error is reduced by 50% (Fig. 4) with scaling factors that increase the photosynthesis sink upstream of the low altitude flight passes (Fig. 5). • Although the CO2-only data assimilation shows excellent reduction of the model error, it may provide the right answer for the wrong reasons. Comparison of observation and model results for CO2 and OCS provide evidence of when the model concentration error (Fig. 3) is due to photosynthesis flux error or other errors. This information can be used to determine which surface fluxes should be modified by the inverse model and ultimately, which surface flux processes are constrained by data assimilation. • For the July 25th flight, the CO2 and OCS errors are highly correlated (r2 = 0.86) for the second and third low altitude passes (20hr and 21hr) but not correlated for the first low altitude pass (Fig. 6). Because the photosynthesis surface fluxes are used to drive the CO2 model and the OCS model (in addition to non-related fluxes) the correlated errors are likely due to errors in the photosynthesis flux. Thus, the error in the plant uptake should be corrected for the second two low altitude passes but not for the first pass. • When the observations of CO2 and OCS are included in the cost function (equation 1) the errors of both species will constrain the improvements calculated by the scaling factors. The corrected model results show that the simultaneous assimilation successfully prevents the photosynthesis surface flux from being increased for the first low altitude pass (Fig. 7). Overall there is less of a reduction in error in the second two low altitude passes due to error in the fixed ratio that converts photosynthesis fluxes into OCS plant uptake. • If photosynthesis fluxes cannot be corrected to improve the model error in the first low altitude pass then what process is responsible? Reduction of the CO2 fossil fuel and respiration sources could also provide a solution. The fossil fuel source has very small errors in this air mass as indicated by alternative methods for estimating fossil fuel CO2 (Campbell et al., In Press). The respiration flux is likely the source of error because: • The first low altitude pass is sensitive to changes in the respiration because the observation is made earlier in the day. • The modeled respiration concentrations during this low altitude pass are higher than at any other point on the ICARTT flight paths. • When the inverse model is used to estimate scaling factors for the respiration surface fluxes, the average RMS error is reduced . Conclusions The goal of regional-scale carbon science is to understand terrestrial biosphere processes in order to predict future surface fluxes. Simultaneous analysis of carbon dioxide and carbonyl sulfide provides a needed link between model error and land surface processes. The results of an assimilation with aircraft observations presented here lead to a number of conclusion concerning CO2 data assimilation: 1) With a CO2-only data assimilation framework it is possible for model errors due to large overestimates in respiration surface fluxes to be interpreted as underestimates in photosynthesis fluxes. 2) The correlation of CO2 errors and OCS errors can be used to guide the inverse model towards correcting model errors by modifying photosynthesis fluxes verses other fluxes. 3) The simultaneous assimilation can be achieved by applying CO2 photosynthesis land surface fluxes to both CO2 and OCS modeled species. The results shown here are promising for further studies of the ICARTT data set that will simultaneously recover photosynthesis and respiration surface fluxes with an added constraint of OCS for the photosynthesis flux. These results are also promising for future studies of OCS surface fluxes that will separate the influence of plant uptake of OCS from soil uptake of OCS. CO2 Error (ppm) Fig. 3 July 25th ICARTT flight path altitudes (exaggerated height of bars) and CO2 error as observed – modeled concentrations (color of bars). Fig. 6. Model errors (observed - modeled concentrations) for CO2 and OCS. Assimilation Framework A regional atmospheric transport model and atmospheric concentration observations are synthesized to obtain optimal estimates of surface fluxes using the four dimensional variational (4D-Var) data assimilation technique (Fig.2). Observations of CO2, OCS, and related species are made from the NASA DC8 aircraft during daytime flights over North America in July/August 2004. The STEM mesoscale transport model provides the atmospheric transport and 4D-Var data assimilation [Carmichael et al., 2003]. The optimal surface fluxes are obtained by minimizing the cost function, where y is the vector of observed concentration, h(c) is the vector of modeled concentrations, Ef is the correction factor applied to surface fluxes, and B and O are the model and observation error matrices. Literature cited Campbell J.E., Carmichael G.R., Tang Y.H., Chai T., Vay S.A., Choi Y.H., Sachse G.W., Singh H.B., Schnoor, J.L., Stanier C.O. (In Press), Analysis of anthropogenic CO2 signal in ICARTT observations using a regional chemical transport model and its adjoint. Tellus B. Carmichael, G.R., Daescu, D.N., Sandu, A., Chai, T. (2003), Computational aspects of chemical data assimilation into atmospheric models, in Computational Science: ICCS 2003. Lect. Notes Comput. Sci., vol. 4, pp 26—278, Springer, New York. Montzka S. A., Tans P. P. (2004), Can carbonyl sulfide help constrain gross vegetative fluxes of carbon dioxide?, Eos Trans. AGU Fall Meet. Suppl., Abstract B21E-04. Fig. 7. CO2 and OCS observations (black), model concentrations (orange), and model concentrations corrected during simultaneous assimilation (blue). Fig. 4. Time series for CO2 observations (black), model concentrations (orange), and model concentrations corrected by the inverse model (blue). Acknowledgments We thank Wouter Peters and Ian Baker for providing TM5 boundary conditions and SiB biosphere surface fluxes respectively. Funding for this project was provided by the NASA Earth System Science Fellowship program. For further information Please contact Elliott Campbell at cae@engineering.uiowa.edu, (319)351-0175. Fig. 2. Process diagram for regional atmospheric inversion including the forward model (black), assimilation model (red) and airborne observations (blue). Fig. 5. Optimal surface flux scaling factors (shaded squares) that adjust the photosynthetic modeled flux in each surface grid cell. Colored dots are the initial observed to model concentration error.
