Integrating Biogeochemistry and Ecology Into Ocean Data Assimilation Systems

• Main Authors: Pierre Brasseur, Nicolas Gruber, Rosa Barciela, Keith Brander, Maéva Doron, Abdelali El Moussaoui, Alister J. Hobday, Martin Huret, Anne-Sophie Kremeur, Patrick Lehodey, Richard Matear, Cyril Moulin, Raghu Murtugudde, Inna Senina, Einar Svendsen
• Format: Article
• Language: English
• Published: The Oceanography Society 2009-09-01
• Series: Oceanography
• Subjects: GODAE; ocean biogeochemistry; biogeochemical models; data assimilation
• Online Access: http://tos.org/oceanography/issues/issue_archive/issue_pdfs/22_3/22-3_brasseur.pdf

Monitoring and predicting the biogeochemical state of the ocean and marine ecosystems is an important application of operational oceanography that needs to be expanded. The accurate depiction of the ocean’s physical environment enabled by Global Ocean Data Assimilation Experiment (GODAE) systems, in both real-time and reanalysis modes, is already valuable for various applications, such as the fishing industry and fisheries management. However, most of these applications require accurate estimates of both physical and biogeochemical ocean conditions over a wide range of spatial and temporal scales. In this paper, we discuss recent developments that enable the coupling new biogeochemical models and assimilation components with the existing GODAE systems, and we examine the potential of such systems in several areas of interest: phytoplankton biomass monitoring in open oceans, ocean carbon cycle monitoring and assessment, marine ecosystem management at seasonal and longer time scales, and downscaling in coastal areas. A number of key requirements and research priorities are then identified for the future. The GODAE systems will need to improve their representation of physical variables that currently are not yet considered essential, such as upper-ocean vertical fluxes that are critically important to biological activity. Further, the observing systems will need to be expanded in terms of in situ platforms (with intensified deployments of sensors for O2 and chlorophyll, and inclusion of new sensors for nutrients, zooplankton, micronekton biomass, and others), satellite missions (e.g., hyperspectral instruments for ocean color, light detection and ranging (LIDAR) systems for mixed-layer depths, wide-swath altimeters for coastal sea levels), and improved methods to assimilate these new measurements.