Particle-Size Variability of Aerosol Iron and Impact on Iron Solubility and Dry Deposition Fluxes to the Arctic Ocean

Abstract This study provides unique insights into the properties of iron (Fe) in the marine atmosphere over the late summertime Arctic Ocean. Atmospheric deposition of aerosols can deliver Fe, a limiting micronutrient, to the remote ocean. Aerosol particle size influences aerosol Fe fractional solub...

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Bibliographic Details
Published in:Scientific Reports
Main Authors: Gao, Yuan, Marsay, Christopher M., Yu, Shun, Fan, Songyun, Mukherjee, Pami, Buck, Clifton S., Landing, William M.
Other Authors: National Science Soundation, United States
Format: Article in Journal/Newspaper
Language:English
Published: Springer Science and Business Media LLC 2019
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Online Access:http://dx.doi.org/10.1038/s41598-019-52468-z
http://www.nature.com/articles/s41598-019-52468-z.pdf
http://www.nature.com/articles/s41598-019-52468-z
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Summary:Abstract This study provides unique insights into the properties of iron (Fe) in the marine atmosphere over the late summertime Arctic Ocean. Atmospheric deposition of aerosols can deliver Fe, a limiting micronutrient, to the remote ocean. Aerosol particle size influences aerosol Fe fractional solubility and air-to-sea deposition rate. Size-segregated aerosols were collected during the 2015 US GEOTRACES cruise in the Arctic Ocean. Results show that aerosol Fe had a single-mode size distribution, peaking at 4.4 µm in diameter, suggesting regional dust sources of Fe around the Arctic Ocean. Estimated dry deposition rates of aerosol Fe decreased from 6.1 µmol m −2 yr −1 in the areas of ~56°N–80°N to 0.73 µmol m −2 yr −1 in the areas north of 80°N. Aerosol Fe solubility was higher in fine particles (<1 µm) which were observed mainly in the region north of 80°N and coincided with relatively high concentrations of certain organic aerosols, suggesting interactions between aerosol Fe and organic ligands in the high-latitude Arctic atmosphere. The average molar ratio of Fe to titanium (Ti) was 2.4, substantially lower than the typical crustal ratio of 10. We speculate that dust sources around the Arctic Ocean may have been altered because of climate warming.