Primary production across the Scotia Sea in relation to the physico-chemical environment
Korb, Rebecca E.; Whitehouse, Mick J.; Thorpe, Sally E.; Gordon, Marina. 2005 Primary production across the Scotia Sea in relation to the physico-chemical environment. Journal of Marine Systems, 57 (3-4). 231-249. 10.1016/j.jmarsys.2005.04.009Full text not available from this repository.
During the austral summer of 2003, a large scale survey of the Scotia Sea was undertaken by the British Antarctic Survey as part of the Southern Ocean Global Ocean Ecosystems Dynamics programme. This cruise provided a unique opportunity to examine the distribution of phytoplankton biomass and primary production in relation to the physico-chemical environment of the Scotia Sea. Phytoplankton were sampled from a range of oceanographic regimes including the open ocean, in the wake of oceanic islands, across major fronts such as the Southern Antarctic Circumpolar Current Front, submarine topographical features such as the South Scotia Ridge and the marginal ice zone. Generally the Scotia Sea was characterised by low biomass (< 30 mg chlorophyll-a m− 2), low production rates (< 0.31 g C m− 2 d− 1) and an abundance of macronutrients (e.g., surface nitrate > 28 mmol m− 3) despite favourable environmental conditions for growth caused by shallow mixed layers and deep euphotic depths. Three areas of elevated biomass (77–295 mg chlorophyll-a m− 2) and production (0.73–2.04 g C m− 2 d− 1) as well as substantial macronutrient depletion (e.g., surface nitrate not, vert, similar12 mmol m− 3) were observed during the cruise: to the northwest of the island of South Georgia, to the southwest of South Georgia and further south over the South Scotia Ridge in a region of rapid ice retreat. These productive regions were also characterised by shallow mixed layer depths, although near to South Georgia euphotic depths were reduced due to the high biomass of phytoplankton in the water column. The biomass was composed of over 80% diatoms. We speculate that the contrasting production regimes observed during the cruise were the result of differences in iron availability. Throughout much of the survey area, the eastward flowing Antarctic Circumpolar Current is unlikely to have encountered any shallow bathymetric features that may introduce sedimentary iron into the euphotic zone. However, shallow topographic features may cause upwelling of iron into the euphotic zone. This, together with shallow mixed layers and a favourable light environment, may then account for the dense blooms observed near topographic features during our cruise.
|Item Type:||Publication - Article|
|Digital Object Identifier (DOI):||10.1016/j.jmarsys.2005.04.009|
|Programmes:||BAS Programmes > Antarctic Science in the Global Context (2000-2005) > Dynamics and Management of Ocean Ecosystems|
|Additional Keywords:||Phytoplankton, Chlorophyll-a, Physical oceanography, Nutrients|
|NORA Subject Terms:||Marine Sciences
Biology and Microbiology
|Date made live:||21 Dec 2007 13:45|
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