Phytoplankton growth rates from microzooplankton experiments on the R/V Seward Johnson SJ0516 cruise between Ireland and Iceland during the 2005 North Atlantic Spring Bloom (NASB 2005 project, Antarctic microzooplankton project)

<p><strong>Experiment Description:</strong><br /> The experiment was conducted onboard the RV Seward Johnson II, from June 20 to July 4, 2005, with water collected at 57° 58’ N, 15° 32’W. Four treatments were used with 6 replicates each: (1) 12°C and 390 ppm CO<sub>2<...

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Main Authors: Dr Julie Rose, Dr Christopher Gobler, David A. Hutchins
Format: Dataset
Language:unknown
Published: Biological and Chemical Oceanography Data Management Office (BCO-DMO) 2013
Subjects:
oceans
Antarctic
Bering Sea
Rowe
LeBlanc
Bruland
Antarc*
Iceland
North Atlantic
Online Access:https://search.dataone.org/view/sha256:3cdec632d9bbff276b57796dad4a900ecff01a72cc61c00905bb5ac3f41a0048
id dataone:sha256:3cdec632d9bbff276b57796dad4a900ecff01a72cc61c00905bb5ac3f41a0048
record_format openpolar
institution Open Polar
collection Biological and Chemical Oceanography Data Management Office (BCO-DMO) (via DataONE)
op_collection_id dataone:urn:node:BCODMO
language unknown
topic oceans
spellingShingle oceans
Dr Julie Rose
Dr Christopher Gobler
David A. Hutchins
Phytoplankton growth rates from microzooplankton experiments on the R/V Seward Johnson SJ0516 cruise between Ireland and Iceland during the 2005 North Atlantic Spring Bloom (NASB 2005 project, Antarctic microzooplankton project)
topic_facet oceans
description <p><strong>Experiment Description:</strong><br /> The experiment was conducted onboard the RV Seward Johnson II, from June 20 to July 4, 2005, with water collected at 57° 58’ N, 15° 32’W. Four treatments were used with 6 replicates each: (1) 12°C and 390 ppm CO<sub>2</sub> (LTLC), (2) 12°C and 690 ppm CO<sub>2</sub> (LTHC), (3) 16°C and 390 ppm CO<sub>2</sub> (HTLC), and (4) 16°C and 690 ppm CO<sub>2 </sub>(HTHC). Sea surface temperature at this location was 12°C at the time of water collection. Experiments were run using a seawater continuous culture system, termed an ‘Ecostat’ (Hutchins et al. 2003, Hare et al. 2005, 2007). Briefly, whole seawater was collected from 5 to 10 m depth using a trace-metal-clean, towed-intake Teflon pump system (Hutchins et al. 2003), prefiltered through 200 μm Nitex mesh to remove mesozooplankton and incubated in twenty-four 2.7 l trace-metal-clean, clear polycarbonate bottles. Bottles were placed in racks in a temperature-controlled deck incubator with recirculating water and shaded to 30 percent of surface irradiance (I0) using a neutral-density shade screen. Temperatures in the 16°C incubator were gradually increased over a period of 24 h to avoid heat-shocking the plankton. Bottles were bubbled with either air or a commercially prepared air/CO2 mixture with 750 ppm CO2 using an inflow tube through the cap and an airstone to maximize gas transfer to the liquid phase. The gases used for bubbling were filtered through a 0.2 μm HEPA filter to avoid contamination of experimental bottles by trace metals (Hare et al. 2005). The system was run in batch mode for 3 days prior to turning on the pumps, in order to stimulate phytoplankton growth and prevent wash-out of slower growing species. After this batch growth period, whole seawater in each incubation bottle was slowly diluted at a continuous rate using seawater collected at the initial site. This seawater medium was filtered through a 0.2 μm inline capsule filter initially, then re-filtered through a second 0.2 μm inline capsule filter immediately prior to use as a diluent. The medium was stored in trace-metal-clean, 50 l carboys in the dark. Initial in situ nutrient concentrations were low (0.32 umol nitrate l<sup>–1</sup>, 0.12 umol phosphate l<sup>–1</sup>, 0.7 umol silicate l<sup>–1</sup>), so the medium and the whole water in the incubation bottles were amended with 5 and 0.31 umol l<sup>–1</sup> (final concentration) of nitrate and phosphate. The dilution rate of 0.5 d<sup>–1</sup> was controlled in each incubation bottle using a peristaltic pump and calibrated daily to ensure constant flow rate. This flow rate constituted a 50 percent dilution of the experimental bottle volume daily. Incubation bottles were mixed by inverting the rack 120° every 5 to 15 min using a compressed-air-driven system. Diluted seawater flowed out of the incubation bottles at a continuous rate and into 2.7 l polycarbonate bottles stored in the dark, which were used as outflow collection vessels.&nbsp; Seawater carbonate system measurements were performed as described in Feng et al. (2009).</p> <p><strong>References:</strong><br /> Feng, Y., C.E. Hare, K. Leblanc, G.R. DiTullio, P.A. Lee, S.W. Wilhelm, J. Sun, J.M. Rose, N. Nemcek, I. Benner, and D.A. Hutchins. 2009. The effects of increased pCO2 and temperature on the North Atlantic Spring Bloom: I. The phytoplankton community and biogeochemical response. Marine Ecology Progress Series 388: 13-25.<br /> <br /> Hare, C.E., G.R. DiTullio, C.G. Trick, S.W. Wilhelm, K.W. Bruland, E.L. Rue, and D.A. Hutchins. 2005. Phytoplankton community structure changes following simulated upwelled iron inputs in the Peru upwelling region. Aquatic Microbial Ecology 38: 269-282.<br /> <br /> Hare, C.E., K. Leblanc, G.R. DiTullio, R.M. Kudela, Y. Zhang, P.A. Lee, S.F. Riseman, and D.A. Hutchins. 2007. Consequences of increased temperature and CO2 for phytoplankton community structure in the Bering Sea. Marine Ecology Progress Series 352: 9-16.<br /> <br /> Hutchins, D.A., F. Pustizzi, C.E. Hare, and G.R. DiTullio. 2003. A shipboard natural community continuous culture system for ecologically relevant low-level nutrient enrichment experiments. Limnology and Oceanography: Methods 1: 82-91.</p> <p><strong>Related files and references:</strong><br /> Rose, J.M., Y. Feng, C.J. Gobler, R. Gutierrez, C.E. Hare, K. Leblanc, and D.A. Hutchins. 2009. The effects of increased pCO2 and temperature on the North Atlantic Spring Bloom. II. Microzooplankton abundance and grazing. Marine Ecology Progress Series 388: 27-40.<br /> <br /> Additional parameters measured during these experiments are described in: Feng, Y., C.E. Hare, K. Leblanc, G.R. DiTullio, P.A. Lee, S.W. Wilhelm, J. Sun, J.M. Rose, N. Nemcek, I. Benner, and D.A. Hutchins. 2009. The effects of increased pCO2 and temperature on the North Atlantic Spring Bloom: I. The phytoplankton community and biogeochemical response. Marine Ecology Progress Series 388: 13-25.<br /> <br /> Lee, P.A., J.R. Rudisill, A.R. Neeley, D.A. Hutchins, Y. Feng, C.E. Hare, K. Leblanc, J.M. Rose, S.W. Wilhelm, J.M. Rowe, and G.R. DiTullio. 2009. The effects of increased pCO2 and temperature on the North Atlantic Spring Bloom: III. Dimethylsulfoniopropionate. Marine Ecology Progress Series 388: 41-49.</p>
format Dataset
author Dr Julie Rose
Dr Christopher Gobler
David A. Hutchins
author_facet Dr Julie Rose
Dr Christopher Gobler
David A. Hutchins
author_sort Dr Julie Rose
title Phytoplankton growth rates from microzooplankton experiments on the R/V Seward Johnson SJ0516 cruise between Ireland and Iceland during the 2005 North Atlantic Spring Bloom (NASB 2005 project, Antarctic microzooplankton project)
title_short Phytoplankton growth rates from microzooplankton experiments on the R/V Seward Johnson SJ0516 cruise between Ireland and Iceland during the 2005 North Atlantic Spring Bloom (NASB 2005 project, Antarctic microzooplankton project)
title_full Phytoplankton growth rates from microzooplankton experiments on the R/V Seward Johnson SJ0516 cruise between Ireland and Iceland during the 2005 North Atlantic Spring Bloom (NASB 2005 project, Antarctic microzooplankton project)
title_fullStr Phytoplankton growth rates from microzooplankton experiments on the R/V Seward Johnson SJ0516 cruise between Ireland and Iceland during the 2005 North Atlantic Spring Bloom (NASB 2005 project, Antarctic microzooplankton project)
title_full_unstemmed Phytoplankton growth rates from microzooplankton experiments on the R/V Seward Johnson SJ0516 cruise between Ireland and Iceland during the 2005 North Atlantic Spring Bloom (NASB 2005 project, Antarctic microzooplankton project)
title_sort phytoplankton growth rates from microzooplankton experiments on the r/v seward johnson sj0516 cruise between ireland and iceland during the 2005 north atlantic spring bloom (nasb 2005 project, antarctic microzooplankton project)
publisher Biological and Chemical Oceanography Data Management Office (BCO-DMO)
publishDate 2013
url https://search.dataone.org/view/sha256:3cdec632d9bbff276b57796dad4a900ecff01a72cc61c00905bb5ac3f41a0048
long_lat ENVELOPE(-60.904,-60.904,-62.592,-62.592)
ENVELOPE(-98.767,-98.767,-71.733,-71.733)
ENVELOPE(15.262,15.262,68.757,68.757)
geographic Antarctic
Bering Sea
Rowe
LeBlanc
Bruland
geographic_facet Antarctic
Bering Sea
Rowe
LeBlanc
Bruland
genre Antarc*
Antarctic
Bering Sea
Iceland
North Atlantic
genre_facet Antarc*
Antarctic
Bering Sea
Iceland
North Atlantic
_version_ 1800869947884175360
spelling dataone:sha256:3cdec632d9bbff276b57796dad4a900ecff01a72cc61c00905bb5ac3f41a0048 2024-06-03T18:46:23+00:00 Phytoplankton growth rates from microzooplankton experiments on the R/V Seward Johnson SJ0516 cruise between Ireland and Iceland during the 2005 North Atlantic Spring Bloom (NASB 2005 project, Antarctic microzooplankton project) Dr Julie Rose Dr Christopher Gobler David A. Hutchins 2013-03-18T00:00:00Z https://search.dataone.org/view/sha256:3cdec632d9bbff276b57796dad4a900ecff01a72cc61c00905bb5ac3f41a0048 unknown Biological and Chemical Oceanography Data Management Office (BCO-DMO) oceans Dataset 2013 dataone:urn:node:BCODMO 2024-06-03T18:08:38Z <p><strong>Experiment Description:</strong><br /> The experiment was conducted onboard the RV Seward Johnson II, from June 20 to July 4, 2005, with water collected at 57° 58’ N, 15° 32’W. Four treatments were used with 6 replicates each: (1) 12°C and 390 ppm CO<sub>2</sub> (LTLC), (2) 12°C and 690 ppm CO<sub>2</sub> (LTHC), (3) 16°C and 390 ppm CO<sub>2</sub> (HTLC), and (4) 16°C and 690 ppm CO<sub>2 </sub>(HTHC). Sea surface temperature at this location was 12°C at the time of water collection. Experiments were run using a seawater continuous culture system, termed an ‘Ecostat’ (Hutchins et al. 2003, Hare et al. 2005, 2007). Briefly, whole seawater was collected from 5 to 10 m depth using a trace-metal-clean, towed-intake Teflon pump system (Hutchins et al. 2003), prefiltered through 200 μm Nitex mesh to remove mesozooplankton and incubated in twenty-four 2.7 l trace-metal-clean, clear polycarbonate bottles. Bottles were placed in racks in a temperature-controlled deck incubator with recirculating water and shaded to 30 percent of surface irradiance (I0) using a neutral-density shade screen. Temperatures in the 16°C incubator were gradually increased over a period of 24 h to avoid heat-shocking the plankton. Bottles were bubbled with either air or a commercially prepared air/CO2 mixture with 750 ppm CO2 using an inflow tube through the cap and an airstone to maximize gas transfer to the liquid phase. The gases used for bubbling were filtered through a 0.2 μm HEPA filter to avoid contamination of experimental bottles by trace metals (Hare et al. 2005). The system was run in batch mode for 3 days prior to turning on the pumps, in order to stimulate phytoplankton growth and prevent wash-out of slower growing species. After this batch growth period, whole seawater in each incubation bottle was slowly diluted at a continuous rate using seawater collected at the initial site. This seawater medium was filtered through a 0.2 μm inline capsule filter initially, then re-filtered through a second 0.2 μm inline capsule filter immediately prior to use as a diluent. The medium was stored in trace-metal-clean, 50 l carboys in the dark. Initial in situ nutrient concentrations were low (0.32 umol nitrate l<sup>–1</sup>, 0.12 umol phosphate l<sup>–1</sup>, 0.7 umol silicate l<sup>–1</sup>), so the medium and the whole water in the incubation bottles were amended with 5 and 0.31 umol l<sup>–1</sup> (final concentration) of nitrate and phosphate. The dilution rate of 0.5 d<sup>–1</sup> was controlled in each incubation bottle using a peristaltic pump and calibrated daily to ensure constant flow rate. This flow rate constituted a 50 percent dilution of the experimental bottle volume daily. Incubation bottles were mixed by inverting the rack 120° every 5 to 15 min using a compressed-air-driven system. Diluted seawater flowed out of the incubation bottles at a continuous rate and into 2.7 l polycarbonate bottles stored in the dark, which were used as outflow collection vessels.&nbsp; Seawater carbonate system measurements were performed as described in Feng et al. (2009).</p> <p><strong>References:</strong><br /> Feng, Y., C.E. Hare, K. Leblanc, G.R. DiTullio, P.A. Lee, S.W. Wilhelm, J. Sun, J.M. Rose, N. Nemcek, I. Benner, and D.A. Hutchins. 2009. The effects of increased pCO2 and temperature on the North Atlantic Spring Bloom: I. The phytoplankton community and biogeochemical response. Marine Ecology Progress Series 388: 13-25.<br /> <br /> Hare, C.E., G.R. DiTullio, C.G. Trick, S.W. Wilhelm, K.W. Bruland, E.L. Rue, and D.A. Hutchins. 2005. Phytoplankton community structure changes following simulated upwelled iron inputs in the Peru upwelling region. Aquatic Microbial Ecology 38: 269-282.<br /> <br /> Hare, C.E., K. Leblanc, G.R. DiTullio, R.M. Kudela, Y. Zhang, P.A. Lee, S.F. Riseman, and D.A. Hutchins. 2007. Consequences of increased temperature and CO2 for phytoplankton community structure in the Bering Sea. Marine Ecology Progress Series 352: 9-16.<br /> <br /> Hutchins, D.A., F. Pustizzi, C.E. Hare, and G.R. DiTullio. 2003. A shipboard natural community continuous culture system for ecologically relevant low-level nutrient enrichment experiments. Limnology and Oceanography: Methods 1: 82-91.</p> <p><strong>Related files and references:</strong><br /> Rose, J.M., Y. Feng, C.J. Gobler, R. Gutierrez, C.E. Hare, K. Leblanc, and D.A. Hutchins. 2009. The effects of increased pCO2 and temperature on the North Atlantic Spring Bloom. II. Microzooplankton abundance and grazing. Marine Ecology Progress Series 388: 27-40.<br /> <br /> Additional parameters measured during these experiments are described in: Feng, Y., C.E. Hare, K. Leblanc, G.R. DiTullio, P.A. Lee, S.W. Wilhelm, J. Sun, J.M. Rose, N. Nemcek, I. Benner, and D.A. Hutchins. 2009. The effects of increased pCO2 and temperature on the North Atlantic Spring Bloom: I. The phytoplankton community and biogeochemical response. Marine Ecology Progress Series 388: 13-25.<br /> <br /> Lee, P.A., J.R. Rudisill, A.R. Neeley, D.A. Hutchins, Y. Feng, C.E. Hare, K. Leblanc, J.M. Rose, S.W. Wilhelm, J.M. Rowe, and G.R. DiTullio. 2009. The effects of increased pCO2 and temperature on the North Atlantic Spring Bloom: III. Dimethylsulfoniopropionate. Marine Ecology Progress Series 388: 41-49.</p> Dataset Antarc* Antarctic Bering Sea Iceland North Atlantic Biological and Chemical Oceanography Data Management Office (BCO-DMO) (via DataONE) Antarctic Bering Sea Rowe ENVELOPE(-60.904,-60.904,-62.592,-62.592) LeBlanc ENVELOPE(-98.767,-98.767,-71.733,-71.733) Bruland ENVELOPE(15.262,15.262,68.757,68.757)

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