Effects of rainwater iron and hydrogen peroxide on iron speciation and phytoplankton growth in seawater near Bermuda
Rainwater is a major source of dissolved iron to much of the world's oceans, including regions where iron may be a limiting nutrient for marine phytoplankton primary production. Rainwater iron is therefore potentially important in regulating global photosynthetic uptake of CO^sub 2^, and hence...
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| Veröffentlicht in: | Journal of atmospheric chemistry 2004-03, Vol.47 (3), p.209-222 |
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| creator | WILLEY, Joan D KIEBER, Robert J AVERY, G. Brooks |
| description | Rainwater is a major source of dissolved iron to much of the world's oceans, including regions where iron may be a limiting nutrient for marine phytoplankton primary production. Rainwater iron is therefore potentially important in regulating global photosynthetic uptake of CO^sub 2^, and hence climate. Two rainwater addition bioassay experiments (2% rain) conducted at the Bermuda Atlantic Time-series Station (BATS) during March 2000 using 50 or 100 nM FeCl^sub 2^ or FeCl^sub 3^ in synthetic rain (pH 4.5 H^sub 2^SO^sub 4^) showed an increase in chlorophyll a 50% greater than controls after three days. Addition of 20 μM hydrogen peroxide, a typical rainwater concentration at BATS, completely removed the chlorophyll a increase with both forms of iron additions, suggesting stimulation of phytoplankton growth by rainwater iron can be limited by rainwater H^sub 2^O^sub 2^. In laboratory experiments using Gulf Stream seawater, iron-enriched (100 nM Fe(III)) synthetic rain was mixed with seawater in a 5% rain 95% seawater ratio. Dissolved iron concentrations increased two times above concentrations predicted based on dilution alone. The increase in soluble iron probably resulted from release from seawater particles and was maintained for more than 24 hours. No increase was observed in controls that did not have iron added to the synthetic rain, or with synthetic rainwater containing both added iron and H^sub 2^O^sub 2^. The increase in iron concentration above that predicted by dilution indicates rain may have a larger effect on seawater iron concentrations than that calculated for rainwater iron addition alone.[PUBLICATION ABSTRACT] |
| doi_str_mv | 10.1023/B:JOCH.0000021087.19846.e1 |
| format | Article |
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Brooks</creator><creatorcontrib>WILLEY, Joan D ; KIEBER, Robert J ; AVERY, G. Brooks</creatorcontrib><description>Rainwater is a major source of dissolved iron to much of the world's oceans, including regions where iron may be a limiting nutrient for marine phytoplankton primary production. Rainwater iron is therefore potentially important in regulating global photosynthetic uptake of CO^sub 2^, and hence climate. Two rainwater addition bioassay experiments (2% rain) conducted at the Bermuda Atlantic Time-series Station (BATS) during March 2000 using 50 or 100 nM FeCl^sub 2^ or FeCl^sub 3^ in synthetic rain (pH 4.5 H^sub 2^SO^sub 4^) showed an increase in chlorophyll a 50% greater than controls after three days. Addition of 20 μM hydrogen peroxide, a typical rainwater concentration at BATS, completely removed the chlorophyll a increase with both forms of iron additions, suggesting stimulation of phytoplankton growth by rainwater iron can be limited by rainwater H^sub 2^O^sub 2^. In laboratory experiments using Gulf Stream seawater, iron-enriched (100 nM Fe(III)) synthetic rain was mixed with seawater in a 5% rain 95% seawater ratio. Dissolved iron concentrations increased two times above concentrations predicted based on dilution alone. The increase in soluble iron probably resulted from release from seawater particles and was maintained for more than 24 hours. No increase was observed in controls that did not have iron added to the synthetic rain, or with synthetic rainwater containing both added iron and H^sub 2^O^sub 2^. 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Brooks</creatorcontrib><title>Effects of rainwater iron and hydrogen peroxide on iron speciation and phytoplankton growth in seawater near Bermuda</title><title>Journal of atmospheric chemistry</title><description>Rainwater is a major source of dissolved iron to much of the world's oceans, including regions where iron may be a limiting nutrient for marine phytoplankton primary production. Rainwater iron is therefore potentially important in regulating global photosynthetic uptake of CO^sub 2^, and hence climate. Two rainwater addition bioassay experiments (2% rain) conducted at the Bermuda Atlantic Time-series Station (BATS) during March 2000 using 50 or 100 nM FeCl^sub 2^ or FeCl^sub 3^ in synthetic rain (pH 4.5 H^sub 2^SO^sub 4^) showed an increase in chlorophyll a 50% greater than controls after three days. Addition of 20 μM hydrogen peroxide, a typical rainwater concentration at BATS, completely removed the chlorophyll a increase with both forms of iron additions, suggesting stimulation of phytoplankton growth by rainwater iron can be limited by rainwater H^sub 2^O^sub 2^. In laboratory experiments using Gulf Stream seawater, iron-enriched (100 nM Fe(III)) synthetic rain was mixed with seawater in a 5% rain 95% seawater ratio. Dissolved iron concentrations increased two times above concentrations predicted based on dilution alone. The increase in soluble iron probably resulted from release from seawater particles and was maintained for more than 24 hours. No increase was observed in controls that did not have iron added to the synthetic rain, or with synthetic rainwater containing both added iron and H^sub 2^O^sub 2^. 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Brooks</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Effects of rainwater iron and hydrogen peroxide on iron speciation and phytoplankton growth in seawater near Bermuda</atitle><jtitle>Journal of atmospheric chemistry</jtitle><date>2004-03-01</date><risdate>2004</risdate><volume>47</volume><issue>3</issue><spage>209</spage><epage>222</epage><pages>209-222</pages><issn>0167-7764</issn><eissn>1573-0662</eissn><coden>JATCE2</coden><abstract>Rainwater is a major source of dissolved iron to much of the world's oceans, including regions where iron may be a limiting nutrient for marine phytoplankton primary production. Rainwater iron is therefore potentially important in regulating global photosynthetic uptake of CO^sub 2^, and hence climate. Two rainwater addition bioassay experiments (2% rain) conducted at the Bermuda Atlantic Time-series Station (BATS) during March 2000 using 50 or 100 nM FeCl^sub 2^ or FeCl^sub 3^ in synthetic rain (pH 4.5 H^sub 2^SO^sub 4^) showed an increase in chlorophyll a 50% greater than controls after three days. Addition of 20 μM hydrogen peroxide, a typical rainwater concentration at BATS, completely removed the chlorophyll a increase with both forms of iron additions, suggesting stimulation of phytoplankton growth by rainwater iron can be limited by rainwater H^sub 2^O^sub 2^. In laboratory experiments using Gulf Stream seawater, iron-enriched (100 nM Fe(III)) synthetic rain was mixed with seawater in a 5% rain 95% seawater ratio. Dissolved iron concentrations increased two times above concentrations predicted based on dilution alone. The increase in soluble iron probably resulted from release from seawater particles and was maintained for more than 24 hours. No increase was observed in controls that did not have iron added to the synthetic rain, or with synthetic rainwater containing both added iron and H^sub 2^O^sub 2^. The increase in iron concentration above that predicted by dilution indicates rain may have a larger effect on seawater iron concentrations than that calculated for rainwater iron addition alone.[PUBLICATION ABSTRACT]</abstract><cop>Dordrecht</cop><pub>Springer</pub><doi>10.1023/B:JOCH.0000021087.19846.e1</doi><tpages>14</tpages></addata></record> |
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| ispartof | Journal of atmospheric chemistry, 2004-03, Vol.47 (3), p.209-222 |
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| subjects | Bioassays Chemical analysis Chlorophyll Earth sciences Earth, ocean, space Exact sciences and technology External geophysics Geochemistry Hydrogen peroxide Iron Marine Mineralogy Oceans Physical and chemical properties of sea water Physics of the oceans Phytoplankton Plankton Primary production Rain Seawater Silicates Speciation Water analysis Water geochemistry |
| title | Effects of rainwater iron and hydrogen peroxide on iron speciation and phytoplankton growth in seawater near Bermuda |
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