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RUI: Do Dimethyl Sulfide (DMS) and Isoprene Control Iron Bioavailability in Marine Aerosols?

$146,254FY2009GEONSF

Central Washington University, Ellensburg WA

Investigators

Abstract

The Principal Investigator (PI) plans a 2-year program to determine the significance of previously identified mechanisms that may control atmospheric iron speciation before and after deposition into the ocean. Photochemical experiments will be carried out on previously collected marine aerosol samples (South Atlantic Ocean, 2005; Equatorial Pacific Ocean, 2006) in the presence of dimethyl sulfide (DMS) and isoprene oxidation products, as these compounds have been shown to increase iron bioavailability in laboratory simulations. By optimizing analytical capabilities for low concentrations of essential chemical constituents, results from this study will provide further evidence to support or refute the hypothesis that phytoplankton themselves are key protagonists in a feedback cycle to manipulate the form of iron in aerosol particles for their optimal metabolic use. Crustal aerosol particles deposited at sea constitute a significant source of scarce micronutrient iron that limits phytoplankton growth in remote open oceans. Phytoplankton, in turn, modulate global climate by accounting for half the earth's photosynthetic absorption of CO2, as well as by emission of climate forcing gases, such as DMS and nitrous oxide (N2O). The systematics of open-ocean aerosol iron delivery as well as the chemistry that controls iron bioavailability to phytoplankton, however, remains ill defined thus prohibiting any quantitative analysis of how phytoplankton affect global climate. The work will be carried out by undergraduate and M.S. students at Central Washington University (CWU) with existing and new instrumentation, the latter of which will significantly increase the capacity of the PI's lab to investigate iron in the atmosphere-ocean context. Students involved in this research will obtain valuable hands-on experience in the field and the laboratory, and will interact with scientists from diverse research areas and countries, preparing them for the intricate nature of present and future scientific challenges. Outreach activities specifically designed for K-12 students that include global warming and its regulation by feedback mechanisms will be an integral part of this research program.

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