Will nitrogen limitation and high CO₂ concentrations impact upon the sinking velocity of phytoplankton?

The biological carbon pump in the ocean plays an important role in controlling atmospheric CO₂ levels. Approximately 1-3% of the yearly 50–60 Pg C of marine primary production settles in the deep ocean, where it is effectively sequestered for centuries to millennia. Central to the strength of the pu...

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Main Author: Mannfolk, Amanda
Format: Thesis
Language:unknown
Published: 2017
Subjects:
1959.1/1250115
ethesis-20160301-100654
Nitrogen limitation
monash:168067
Climate change
Biological carbon pump
Phytoplankton
Emiliania huxleyi
Ocean acidification
Open access
thesis(doctorate)
Sinking velocity
High CO₂
Chaetoceros didymus
2016
Transparent exopolymers
Online Access:https://doi.org/10.4225/03/58b79d337d1d1
https://figshare.com/articles/thesis/Will_nitrogen_limitation_and_high_CO_concentrations_impact_upon_the_sinking_velocity_of_phytoplankton_/4713610
id ftmonashunivfig:oai:figshare.com:article/4713610
record_format openpolar
spelling ftmonashunivfig:oai:figshare.com:article/4713610 2023-05-15T17:52:08+02:00 Will nitrogen limitation and high CO₂ concentrations impact upon the sinking velocity of phytoplankton? Mannfolk, Amanda 2017-03-02T04:18:57Z https://doi.org/10.4225/03/58b79d337d1d1 https://figshare.com/articles/thesis/Will_nitrogen_limitation_and_high_CO_concentrations_impact_upon_the_sinking_velocity_of_phytoplankton_/4713610 unknown doi:10.4225/03/58b79d337d1d1 https://figshare.com/articles/thesis/Will_nitrogen_limitation_and_high_CO_concentrations_impact_upon_the_sinking_velocity_of_phytoplankton_/4713610 In Copyright 1959.1/1250115 ethesis-20160301-100654 Nitrogen limitation monash:168067 Climate change Biological carbon pump Phytoplankton Emiliania huxleyi Ocean acidification Open access thesis(doctorate) Sinking velocity High CO₂ Chaetoceros didymus 2016 Transparent exopolymers Text Thesis 2017 ftmonashunivfig https://doi.org/10.4225/03/58b79d337d1d1 2022-06-06T15:45:46Z The biological carbon pump in the ocean plays an important role in controlling atmospheric CO₂ levels. Approximately 1-3% of the yearly 50–60 Pg C of marine primary production settles in the deep ocean, where it is effectively sequestered for centuries to millennia. Central to the strength of the pump is the sinking velocity of phytoplankton cells and other organic debris. Stokes' Law indicates that the sinking velocity of a spherical cell will depend on its size and density, where larger, heavier cells will sink at a faster rate. Given that growth conditions can result in changes in cell size and macromolecular composition of phytoplankton, it might be expected that such changes could cause alterations in sinking velocity and carbon drawdown via the biological carbon pump. In the future, phytoplankton cells in the open ocean are predicted to be more subject to nutrient limitation due to enhanced stratification reducing the upwelling of nutrients. This will be driven by the warming of surface waters and an increase in the difference between the temperature of the surface and deeper ocean. Therefore the effects of nitrogen limitation on the sinking velocity of Emiliania huxleyi, a coccolithophore responsible for significant phytoplankton blooms and biological drawdown of carbon was examined. Nitrogen limitation caused changes in macromolecular composition, especially lipid content and also alters coccosphere thickness. However, the overall density of the cells remained similar, and, as a consequence, cell size was the major determinant of sinking rate with N-limited cells in exponential phase sinking more slowly than N-replete cells. Cells in stationary phase showed the reverse trend with N-limited cells sinking faster, although not as fast as N-replete cells in exponential phase. N-limited cells produced more transparent exopolymers (TEP), suggesting an increased capacity for aggregation and marine snow formation. Phytoplankton cells are also expected to be to be exposed to higher concentrations of CO₂ in the ... Thesis Ocean acidification Monash University: Figshare
institution Open Polar
collection Monash University: Figshare
op_collection_id ftmonashunivfig
language unknown
topic 1959.1/1250115
ethesis-20160301-100654
Nitrogen limitation
monash:168067
Climate change
Biological carbon pump
Phytoplankton
Emiliania huxleyi
Ocean acidification
Open access
thesis(doctorate)
Sinking velocity
High CO₂
Chaetoceros didymus
2016
Transparent exopolymers
spellingShingle 1959.1/1250115
ethesis-20160301-100654
Nitrogen limitation
monash:168067
Climate change
Biological carbon pump
Phytoplankton
Emiliania huxleyi
Ocean acidification
Open access
thesis(doctorate)
Sinking velocity
High CO₂
Chaetoceros didymus
2016
Transparent exopolymers
Mannfolk, Amanda
Will nitrogen limitation and high CO₂ concentrations impact upon the sinking velocity of phytoplankton?
topic_facet 1959.1/1250115
ethesis-20160301-100654
Nitrogen limitation
monash:168067
Climate change
Biological carbon pump
Phytoplankton
Emiliania huxleyi
Ocean acidification
Open access
thesis(doctorate)
Sinking velocity
High CO₂
Chaetoceros didymus
2016
Transparent exopolymers
description The biological carbon pump in the ocean plays an important role in controlling atmospheric CO₂ levels. Approximately 1-3% of the yearly 50–60 Pg C of marine primary production settles in the deep ocean, where it is effectively sequestered for centuries to millennia. Central to the strength of the pump is the sinking velocity of phytoplankton cells and other organic debris. Stokes' Law indicates that the sinking velocity of a spherical cell will depend on its size and density, where larger, heavier cells will sink at a faster rate. Given that growth conditions can result in changes in cell size and macromolecular composition of phytoplankton, it might be expected that such changes could cause alterations in sinking velocity and carbon drawdown via the biological carbon pump. In the future, phytoplankton cells in the open ocean are predicted to be more subject to nutrient limitation due to enhanced stratification reducing the upwelling of nutrients. This will be driven by the warming of surface waters and an increase in the difference between the temperature of the surface and deeper ocean. Therefore the effects of nitrogen limitation on the sinking velocity of Emiliania huxleyi, a coccolithophore responsible for significant phytoplankton blooms and biological drawdown of carbon was examined. Nitrogen limitation caused changes in macromolecular composition, especially lipid content and also alters coccosphere thickness. However, the overall density of the cells remained similar, and, as a consequence, cell size was the major determinant of sinking rate with N-limited cells in exponential phase sinking more slowly than N-replete cells. Cells in stationary phase showed the reverse trend with N-limited cells sinking faster, although not as fast as N-replete cells in exponential phase. N-limited cells produced more transparent exopolymers (TEP), suggesting an increased capacity for aggregation and marine snow formation. Phytoplankton cells are also expected to be to be exposed to higher concentrations of CO₂ in the ...
format Thesis
author Mannfolk, Amanda
author_facet Mannfolk, Amanda
author_sort Mannfolk, Amanda
title Will nitrogen limitation and high CO₂ concentrations impact upon the sinking velocity of phytoplankton?
title_short Will nitrogen limitation and high CO₂ concentrations impact upon the sinking velocity of phytoplankton?
title_full Will nitrogen limitation and high CO₂ concentrations impact upon the sinking velocity of phytoplankton?
title_fullStr Will nitrogen limitation and high CO₂ concentrations impact upon the sinking velocity of phytoplankton?
title_full_unstemmed Will nitrogen limitation and high CO₂ concentrations impact upon the sinking velocity of phytoplankton?
title_sort will nitrogen limitation and high co₂ concentrations impact upon the sinking velocity of phytoplankton?
publishDate 2017
url https://doi.org/10.4225/03/58b79d337d1d1
https://figshare.com/articles/thesis/Will_nitrogen_limitation_and_high_CO_concentrations_impact_upon_the_sinking_velocity_of_phytoplankton_/4713610
genre Ocean acidification
genre_facet Ocean acidification
op_relation doi:10.4225/03/58b79d337d1d1
https://figshare.com/articles/thesis/Will_nitrogen_limitation_and_high_CO_concentrations_impact_upon_the_sinking_velocity_of_phytoplankton_/4713610
op_rights In Copyright
op_doi https://doi.org/10.4225/03/58b79d337d1d1
_version_ 1766159480496586752

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