Primary production throughout austral fall, during a time of decreasing daylength in the western Antarctic Peninsula

Primary production throughout austral fall, during a time of decreasing daylength in the western Antarctic Peninsula

Antarctic phytoplankton is characterized by a pronounced seasonality in abundance, driven mainly by changes in sunlight. We combined measurements and modeling to describe the influence of changing daylength on fall and winter phytoplankton production in coastal waters of the western Antarctic Penins...

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Bibliographic Details
Published in:Marine ecology. Progress series (Halstenbek) Vol. 452; pp. 45 - 61
Main Authors: Vernet, Maria, Kozlowski, Wendy A., Yarmey, Lynn R., Lowe, Alexander T., Ross, Robin M., Quetin, Langdon B., Fritsen, Christian H.
Format: Journal Article
Language:English
Published: Inter-Research 25-04-2012
Subjects:
Biomass
Biomass production
Krill
Larvae
Marine
Photoperiod
Phytoplankton
Primary productivity
Sea ice
Sea water
Seasons
PSW, Antarctica, Antarctic Peninsula, Marguerite Bay
PS, Antarctic Ocean
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Summary:Antarctic phytoplankton is characterized by a pronounced seasonality in abundance, driven mainly by changes in sunlight. We combined measurements and modeling to describe the influence of changing daylength on fall and winter phytoplankton production in coastal waters of the western Antarctic Peninsula (wAP) in 2001 and 2002. The model was parameterized with field observations from the Palmer Long-Term Ecological program in the wAP during summer and early fall and from the Southern Ocean Global Ecosystems Dynamics program fall and winter cruises to Marguerite Bay and shelf waters. Shorter daylength and a deepening of the mixed layer account for most of the decrease in primary production during March, April, and May. At this time, biomass decreases by an order of magnitude and remains low and constant until the end of August. An additional loss rate was added to the primary production model to fit output to observations. This loss rate, estimated at ~0.1 to 0.15 d−1, is due to physical, chemical, and biological processes such as scavenging by sea ice, zooplankton grazing, cell lysis, and cell sedimentation, which are expected to be high at this time of year. Growth and loss rates of phytoplankton populations are similar on 1 March, with growth decreasing rapidly over time while the loss rates remain constant. By the beginning of winter (1 June), growth is low, with minimum rates in July and increasing towards September. During a period of diminishing food supply, preliminary estimates of grazing indicate that fall biomass could support existing macrozooplankton populations, but the timing and concentration of food supply is variable and expected to affect health of zooplankton as they enter the winter.
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ISSN:0171-8630
1616-1599
DOI:10.3354/meps09704