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Colloquia Archive
Untitled Document
| DATE: |
Friday, January 18th, 2008 |
| TITLE: |
GLOBAL MONITORING OF PARTICULATE ORGANIC CARBON USING SATELLITE
OCEAN COLOR OBSERVATIONS |
| TIME: |
3:30 PM |
| LOCATION: |
GMCS 214 |
| SPEAKER: |
Malgorzata Stramska
Modeling Ecosystems Dynamics Group
CHORS and CSRC
San Diego State University |
| ABSTRACT: |
The development of bio-optical algorithms linking measurable
optical properties to Chla has been the focus of numerous studies over the
last three decades. These algorithms and the successful operation of Sea-viewing
Wide Field-of-view Sensor (SeaWiFS) on OrbView-2 satellite since 1997, allowed
for the fact that the multi-year global time series data on ocean surface
chlorophyll a concentrations (Chl) with excellent temporal coverage have
become available. Although such satellite-based Chl estimates are subject
to some uncertainty (nominal accuracy goal of 30%), they have become an
invaluable research tool for studying phytoplankton biomass of ocean waters.
However, for studies of ocean biogeochemistry and its potential role in
climate it is carbon, not chlorophyll, which is of most direct interest.
The particulate organic carbon (POC) pool in the surface ocean, which includes
autotrophic and heterotrophic organisms and biogenic detrital particles,
represents one of carbon reservoirs of substantial interest. Sinking of
POC from surface waters is part of the biological pump that provides a mechanism
for storing carbon in the deep ocean and a long-term sink for atmospheric
CO2. Satellite capabilities to monitor changes in particulate carbon pools
can effectively aid in studies related to global carbon cycling and the
role of the biological pump in the ocean. This is why we have proposed to
develop ocean color POC algorithms. In this presentation I will show a summary
of our recent work where we have examined several approaches for estimating
the surface concentration of particulate organic carbon, POC, from optical
measurements of remote-sensing reflectance, Rrs(l). The best error statistics
were found for power function fits to the data of POC vs. Rrs(443)/Rrs(555)
and POC vs. Rrs(490)/Rrs(555). For the data set collected by us, which includes
over 50 data pairs, these relationships are characterized by the mean normalized
bias of about 2% and the normalized root mean square error of about 20%.
We recommended that these algorithms be implemented for routine NASA processing
of ocean color satellite data to produce global maps of surface ocean POC
with the status of an evaluation data product for continued work on algorithm
development and refinements. In this presentation I will also discuss our
future plans to use satellite derived POC maps to study oceanic POC budgets
and fluxes. |
| HOST: |
Jose Castillo |
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Computational Science Research Center :: 5500 Campanile Drive :: San Diego, CA 92182-1245 :: (619) 594-3430
©2007 Computational Science Research Center, SDSU - All rights
reserved.
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Last
updated:
February 21, 2008 8:38 AM
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