Seasonality of Mesoscale Phytoplankton Control in Eastern Fram Strait

Globally, mesoscale processes create a rich and filamented pattern in biological productivity. Despite of remoteness and a harsh environment, observations likewise show an impact of mesoscale processes on phytoplankton growth in the Arctic. Observations of sufficiently high resolution are, however,...

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Bibliographic Details
Published in:Journal of Geophysical Research: Oceans
Main Authors: Schourup-Kristensen, Vibe, Wekerle, Claudia, Danilov, Sergey, Völker, Christoph
Format: Article in Journal/Newspaper
Language:English
Published: 2021
Subjects:
Fram Strait
Mesoscale
biogeochemistry
eddies
seasonality
Arctic
Phytoplankton
Sea ice
Spitzbergen
Online Access:https://pure.au.dk/portal/da/publications/seasonality-of-mesoscale-phytoplankton-control-in-eastern-fram-strait(a66d4191-4bf3-4480-8c18-054b98048a9e).html
https://doi.org/10.1029/2021JC017279
https://pure.au.dk/ws/files/223739012/2021JC017279.pdf
Description
Summary:Globally, mesoscale processes create a rich and filamented pattern in biological productivity. Despite of remoteness and a harsh environment, observations likewise show an impact of mesoscale processes on phytoplankton growth in the Arctic. Observations of sufficiently high resolution are, however, difficult to carry out. Large-scale models are another way to gain knowledge about the system. In the current study, we use a global sea ice-ocean biogeochemical model, which is eddy resolving in Fram Strait, to show that the mesoscale dynamics has a strong effect on shaping phytoplankton growth. For the year 2009, we demonstrate that the growth season in the West Spitzbergen Current can be divided into two regimes; during Regime I, which takes place in May and June before and during the spring bloom, high chlorophyll concentrations are associated with areas of positive vorticity and a shallow mixed layer, pointing toward light limitation controlling growth. During Regime II, which occurs after the bloom from mid-July to late August, the highest chlorophyll concentration is found in areas of negative vorticity. Here, upwelling of nutrient-rich water occurs, through doming isopycnals, acting to raise the nutricline, may also play a role in alleviating nutrient limitation in the surface water. The study suggests that the mesoscale eddy environment locally modulates the seasonal cycle of light and nutrient limitation. Knowledge of the eddy field should be taken into consideration for making conclusions from point-wise measurements in Fram Strait.

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