Coupling between ocean biota and atmospheric aerosols: Dust, dimethylsulphide, or artIfact?

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Cropp, RA
Gabric, AJ
McTainsh, GH
Braddock, RD
Tindale, N
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Mheinrat Andreae

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2005
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Abstract

Two hypotheses that postulate interactions between ocean biota and aerosols in the atmosphere have generated substantial research into marine systems. The stimulation of phytoplankton photosynthesis by the provision of iron, a micronutrient contained in deposited aeolian dust, (the "Iron Hypothesis"), and the contribution of dimethylsulphide (DMS) produced by marine ecosystems to the atmospheric burden of aerosols (the "CLAW Hypothesis") have been the focus of much research. Satellite sensors, such as the Sea-viewing Wide Field-of-view Sensor (SeaWiFS) now provide moderate-resolution time series of measurements of the optical properties of the oceans and atmosphere over most of the earth's surface. These data provide an unprecedented opportunity to investigate the ubiquity of biotic linkages between the ocean and atmosphere at the global scale. We analysed five years of SeaWiFS 8-day fields of two variables, chlorophyll concentration and aerosol optical depth, for the global oceans. This first global, multi-year approach does not yet allow unequivocal conclusions as satellite measurements of chlorophyll can be influenced by aerosol properties of the atmosphere and several variables we do not yet examine are likely to play a role. We find correlation between optical properties of the ocean and atmosphere over much of the globe, in particular the mid-latitudes. While some regional analyses indicate that SeaWiFS chlorophyll retrievals are biased by dust in the atmosphere, our results do not support the existence of widespread bias in the SeaWiFS products, but are consistent with global-scale couplings posited by the Iron and CLAW hypotheses.

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Global Biogeochemical Cycles

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19

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4

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© 2005 American Geophysical Union. Reproduced in accordance with the copyright policy of the publisher. This journal is available online, use hypertext links.

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Atmospheric sciences

Geochemistry

Oceanography

Geoinformatics

Climate change impacts and adaptation

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