Assimilation of Aqua Ocean Chlorophyll Data in a Global Three-Dimensional Model

1. Assimilation of Aqua Ocean Chlorophyll Data in a Global Three-Dimensional Model Watson Gregg NASA/Global Modeling and Assimilation Office

2. Motivations for Assimilation 1. Data use maximization 2. Parameter Estimation (model improvement) 3. State and Flux Estimation 4. Prediction

3. NASA Ocean Biogeochemical Model (NOBM) Winds, ozone, rel. humidity, pressure, precip. H2O,cloud %, LWP, droplet radius, aerosols Atmospheric Forcing Data Winds, SST Dust (Fe) Sea Ice Radiative Model Circulation Model Heat Layer Depths Abundances Biogeochemical Model Temp. Spectral Irradiance Layer Depths Current Velocities Particles Advection/ Diffusion Primary Production Chlorophyll,Nutrients, Spectral Radiance

4. Biogeochemical Model Nutrients Phytoplankton Si Diatoms Silica Detritus NO3 Chloro- phytes Herbivores NH4 Cyano- bacteria Fe Cocco- lithophores N/C Detritus Iron Detritus

5. Spectral Absorption m-1; m2 mg-1 Spectral Scattering Wavelength (nm)

6. North Pacific North Atlantic North Central Pacific North Central Atlantic North Indian Equatorial Indian Equatorial Pacific Equatorial Atlantic Chlorophyll (mg m-3) South Indian South Pacific South Atlantic Antarctic Day of Year Statistically positively correlated (P < 0.05) all 12 basins Gregg, W.W., 2002. Tracking the SeaWiFS record with a coupled physical/biogeochemical/radiative model of the global oceans. Deep-Sea Research II 49: 81-105. Gregg, W.W., P. Ginoux, P.S. Schopf, and N.W. Casey, 2003. Phytoplankton and Iron: Validation of a global three-dimensional ocean biogeochemical model. Deep-Sea Research II, 50: 3143-3169.

7. 2 2 Assimilation of Satellite Ocean Chlorophyll Conditional Relaxation Analysis Method M = M,S Advantages: Very strongly weighted toward data, less susceptible to model errors Fast Disadvantages Very susceptible to data errors

8. To keep assimilation model bounded requires: • Smoothing of data (25% monthly mean, 75% daily weight) • 2) Increase model weighting relative to data 0.75 0.85 0.5 0.25 Model Weight (fraction) 0.5

9. M

10. Motivations for Assimilation 1. Data use maximization 2. Parameter Estimation (model improvement) 3. State and Flux Estimation 4. Prediction

11. NASA Ocean Biogeochemical EOS Assimilation Model (OBEAM) Winds, ozone, rel. humidity, pressure, precip. H2O,cloud %, LWP, droplet radius, aerosols Atmospheric Forcing Data Winds, SST Dust (Fe) Sea Ice Radiative Model Circulation Model Heat Layer Depths Abundances Biogeochemical Model Temp. Spectral Irradiance Red = EOS Data product Green = assimilated variable Layer Depths Current Velocities Particles Advection/ Diffusion Primary Production Chlorophyll,Nutrients, POC?, PIC? Spectral Radiance

12. Feb. 1, 2003

13. Motivations for Assimilation 1. Data use maximization 2. Parameter Estimation (model improvement) 3. State and Flux Estimation 4. Prediction

16. Annual RMS Log Error √ ∑ log10Cassim – log10Caqua X 100 RMSmon = n ∑ RMSmon RMSann = 12

19. North Pacific North Atlantic North Central Pacific North Central Atlantic North Indian Equatorial Indian Equatorial Pacific Equatorial Atlantic Chlorophyll (mg m-3) South Indian South Pacific South Atlantic Antarctic Red = model monthly mean Diamonds = SeaWiFS monthly mean

20. Equatorial Pacific Diatoms Chloro Percent of Total Cocco Cyano 1997 2001 1998 1999 2000 2002 2003

22. Motivations for Assimilation 1. Data use maximization 2. Parameter Estimation (model improvement) 3. State and Flux Estimation 4. Prediction

24. Summary and Plans Initial assimilation results promising Need further analysis new methodologies Awaiting new SeaWiFS data Proceed on incorporation of MODIS/GMAO products

25. NASA Ocean Biogeochemical EOS Assimilation Model (OBEAM) Winds, ozone, rel. humidity, pressure, precip. H2O,cloud %, LWP, droplet radius, aerosols Atmospheric Forcing Data Winds, SST Dust (Fe) Sea Ice Radiative Model Circulation Model Heat Layer Depths Abundances Biogeochemical Model Temp. Spectral Irradiance Red = EOS Data product Green = assimilated variable Layer Depths Current Velocities Particles Advection/ Diffusion Primary Production Chlorophyll,Nutrients, POC?, PIC? Spectral Radiance