Control of the phytoplankton response during the SAGE experiment: A synthesis
The SOLAS Air-Sea Gas Exchange (SAGE) experiment was conducted in Sub-Antarctic waters off the east coast of the South Island of New Zealand in the late summer of 2004. This mesoscale iron enrichment experiment was unique in that chlorophyll a (chl a) and primary productivity were only 2× OUT statio...
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| Format: | Article in Journal/Newspaper |
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Pergamon-Elsevier Ltd
2015
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| Online Access: | http://hdl.handle.net/1885/68546 |
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ftanucanberra:oai:digitalcollections.anu.edu.au:1885/68546 |
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ftanucanberra:oai:digitalcollections.anu.edu.au:1885/68546 2023-05-15T13:56:44+02:00 Control of the phytoplankton response during the SAGE experiment: A synthesis Peloquin, J. Hall, Julie A Safi, Karl A Ellwood, Michael Law, Cliff S Thompson, Karen Kuparinen, J. Harvey, Michael Pickmere, Stuart 2015-12-10T23:31:16Z http://hdl.handle.net/1885/68546 unknown Pergamon-Elsevier Ltd 0967-0645 http://hdl.handle.net/1885/68546 Deep-Sea Research Part II: Tropical studies in oceanography Journal article 2015 ftanucanberra 2015-12-21T23:44:53Z The SOLAS Air-Sea Gas Exchange (SAGE) experiment was conducted in Sub-Antarctic waters off the east coast of the South Island of New Zealand in the late summer of 2004. This mesoscale iron enrichment experiment was unique in that chlorophyll a (chl a) and primary productivity were only 2× OUT stations values toward the end of the experiment and this enhancement was due to increased activity of non-diatomaceous species. In addition, this enhancement in activity appeared to occur without a significant build up of particulate organic carbon. Picoeukaryotes (<2 γm) were the only members of the phytoplankton assemblage that showed a statistically significant increase, a doubling in biomass. To better understand the controls of phytoplankton growth and biomass, we present results from a series of on-deck perturbation experiments conducted during SAGE. Results suggest that the pico-dominated phytoplankton assemblage was only weakly inhibited by iron. Diatoms with high growth rates comprised a small (<1%) fraction of the phytoplankton assemblage, were likely iron limited, and potentially further limited by silicic acid and therefore did not significantly contribute to bloom dynamics. On deck experiments and comparison of SAGE with other iron addition experiments suggested that neither light availability nor deep mixed layers limited phytoplankton growth. Although no substantial increase in grazing rate or specific phytoplankton growth rate was detected, microzooplankton biomass doubled over SAGE as a result of an increase in cell size. The importance of microzooplankton grazing was highlighted by the fact that they were capable of consuming 15-49% of the total phytoplankton production per day. Removal was highest on eukaryotic picophytoplankton production with a mean value of 72% (29-143%). Patch dilution played an important role during SAGE; the mean patch net algal growth:dilution rate, 1.13 (0.4-2.2) was the lowest reported for a mesoscale iron enrichment experiment. Phytoplankton biomass, estimated by chlorophyll a, only accumulated when phytoplankton growth exceeded grazing and when net algal growth exceeded dilution rate. The SAGE results highlight the function of the smallest phytoplankton size fraction described by the ecumenical Iron Hypothesis. Thus, adding iron to HNLC-low silicic acid regions during certain times of the year may simply transfer more carbon through the microbial food web. A primary implication of this study is that any iron-mediated gain in fixed carbon with this set of environmental conditions has a high probability of being recycled in surface waters. Article in Journal/Newspaper Antarc* Antarctic Australian National University: ANU Digital Collections Antarctic New Zealand |
| institution |
Open Polar |
| collection |
Australian National University: ANU Digital Collections |
| op_collection_id |
ftanucanberra |
| language |
unknown |
| description |
The SOLAS Air-Sea Gas Exchange (SAGE) experiment was conducted in Sub-Antarctic waters off the east coast of the South Island of New Zealand in the late summer of 2004. This mesoscale iron enrichment experiment was unique in that chlorophyll a (chl a) and primary productivity were only 2× OUT stations values toward the end of the experiment and this enhancement was due to increased activity of non-diatomaceous species. In addition, this enhancement in activity appeared to occur without a significant build up of particulate organic carbon. Picoeukaryotes (<2 γm) were the only members of the phytoplankton assemblage that showed a statistically significant increase, a doubling in biomass. To better understand the controls of phytoplankton growth and biomass, we present results from a series of on-deck perturbation experiments conducted during SAGE. Results suggest that the pico-dominated phytoplankton assemblage was only weakly inhibited by iron. Diatoms with high growth rates comprised a small (<1%) fraction of the phytoplankton assemblage, were likely iron limited, and potentially further limited by silicic acid and therefore did not significantly contribute to bloom dynamics. On deck experiments and comparison of SAGE with other iron addition experiments suggested that neither light availability nor deep mixed layers limited phytoplankton growth. Although no substantial increase in grazing rate or specific phytoplankton growth rate was detected, microzooplankton biomass doubled over SAGE as a result of an increase in cell size. The importance of microzooplankton grazing was highlighted by the fact that they were capable of consuming 15-49% of the total phytoplankton production per day. Removal was highest on eukaryotic picophytoplankton production with a mean value of 72% (29-143%). Patch dilution played an important role during SAGE; the mean patch net algal growth:dilution rate, 1.13 (0.4-2.2) was the lowest reported for a mesoscale iron enrichment experiment. Phytoplankton biomass, estimated by chlorophyll a, only accumulated when phytoplankton growth exceeded grazing and when net algal growth exceeded dilution rate. The SAGE results highlight the function of the smallest phytoplankton size fraction described by the ecumenical Iron Hypothesis. Thus, adding iron to HNLC-low silicic acid regions during certain times of the year may simply transfer more carbon through the microbial food web. A primary implication of this study is that any iron-mediated gain in fixed carbon with this set of environmental conditions has a high probability of being recycled in surface waters. |
| format |
Article in Journal/Newspaper |
| author |
Peloquin, J. Hall, Julie A Safi, Karl A Ellwood, Michael Law, Cliff S Thompson, Karen Kuparinen, J. Harvey, Michael Pickmere, Stuart |
| spellingShingle |
Peloquin, J. Hall, Julie A Safi, Karl A Ellwood, Michael Law, Cliff S Thompson, Karen Kuparinen, J. Harvey, Michael Pickmere, Stuart Control of the phytoplankton response during the SAGE experiment: A synthesis |
| author_facet |
Peloquin, J. Hall, Julie A Safi, Karl A Ellwood, Michael Law, Cliff S Thompson, Karen Kuparinen, J. Harvey, Michael Pickmere, Stuart |
| author_sort |
Peloquin, J. |
| title |
Control of the phytoplankton response during the SAGE experiment: A synthesis |
| title_short |
Control of the phytoplankton response during the SAGE experiment: A synthesis |
| title_full |
Control of the phytoplankton response during the SAGE experiment: A synthesis |
| title_fullStr |
Control of the phytoplankton response during the SAGE experiment: A synthesis |
| title_full_unstemmed |
Control of the phytoplankton response during the SAGE experiment: A synthesis |
| title_sort |
control of the phytoplankton response during the sage experiment: a synthesis |
| publisher |
Pergamon-Elsevier Ltd |
| publishDate |
2015 |
| url |
http://hdl.handle.net/1885/68546 |
| geographic |
Antarctic New Zealand |
| geographic_facet |
Antarctic New Zealand |
| genre |
Antarc* Antarctic |
| genre_facet |
Antarc* Antarctic |
| op_source |
Deep-Sea Research Part II: Tropical studies in oceanography |
| op_relation |
0967-0645 http://hdl.handle.net/1885/68546 |
| _version_ |
1766264314049593344 |