Light Is the Primary Driver of Early Season Phytoplankton Production Along the Western Antarctic Peninsula

Light and dissolved iron (dFe) availability control net primary production (NPP) in much of the Southern Ocean, but the primary controller during spring in the western Antarctic Peninsula has never been assessed. Underwater light and dFe availability are sensitive to climate‐induced changes in upper...

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Bibliographic Details
Published in:Journal of geophysical research. Oceans 2019-11, Vol.124 (11), p.7375-7399
Main Authors: Joy‐Warren, Hannah L., Dijken, Gert L., Alderkamp, Anne‐Carlijn, Leventer, Amy, Lewis, Kate M., Selz, Virginia, Lowry, Kate E., Poll, Willem, Arrigo, Kevin R.
Format: Article
Language:English
Subjects:
Acclimation
Availability
Bacillariophyceae
Carbon
Carbon cycle
Climate change
Community composition
Diatoms
Drawdown
Exposure
Food
Food chains
Food webs
Foods
Geophysics
Growth
Ice cover
Iron
Light
Light effects
Light intensity
Luminous intensity
Marine animals
Marine organisms
Mineral nutrients
Mixed layer
Mixed layer depth
Net Primary Productivity
Nutrients
Ocean circulation
Ocean currents
Oceans
Phaeocystis
photophysiology
Photosynthesis
Phytoplankton
Phytoplankton production
Plankton
Primary production
Sea ice
Spring
Stratification
Sunlight
Upper ocean
Water circulation
western Antarctic Peninsula
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Summary:Light and dissolved iron (dFe) availability control net primary production (NPP) in much of the Southern Ocean, but the primary controller during spring in the western Antarctic Peninsula has never been assessed. Underwater light and dFe availability are sensitive to climate‐induced changes in upper ocean circulation, stratification, and sea ice cover, which can affect NPP and phytoplankton community composition, both of which can alter carbon drawdown and food web structure. We estimated in situ NPP, net community production, and heterotrophic respiration and contextualized our field measurements with satellite‐based historical NPP estimates. Average light exposure mainly controlled NPP, while low dFe was associated with greatest NPP, indicating that spring phytoplankton growth is light‐limited and not dFe‐limited. Using experiments that simulated varying mixed layer depths by exposing phytoplankton to a short period of in situ surface light (up to 150× the mean light in the mixed layer, comparable to the difference in light experienced by phytoplankton mixed from 50 m to the surface), we assessed the effect of phytoplankton photoacclimation on NPP and relative success of individual taxa. At moderate light exposure (60×) experienced significant photodamage, declines in NPP, and declines in P. antarctica, with no consistent changes in diatoms. These results support the idea that P. antarctica is better adapted to variable light than diatoms and suggest that deeper mixed layers with variable light will favor P. antarctica. Plain Language Summary Phytoplankton are single‐celled marine photosynthetic organisms that require sunlight and nutrients to grow, but climate change is rapidly altering their environment. Marine animals depend either directly or indirectly on phytoplankton for food, so changes in phytoplankton impact the entire ecosystem. We studied whether lack of light or nutrients limits spring phytoplankton growth in the ocean near Antarctica. Although by spring there are many hours of sunlight, ice on the surface of the ocean partially blocks sunlight from reaching phytoplankton. Similarly, phytoplankton have access to most nutrients they need for growth but often lack iron. Field measurements showed that phytoplankton growth was limited by light, despite low iron. In experiments
ISSN:2169-9275
2169-9291
DOI:10.1029/2019JC015295