Late spring bloom development of pelagic diatoms in Baffin Bay

The Arctic Ocean is particularly affected by climate change, with changes in sea ice cover expected to impact phytoplankton primary production. During the Green Edge expedition, the development of the late spring-early summer diatom bloom was studied in relation with the sea ice retreat by multiple...

Full description

Bibliographic Details
Published in:Elementa: Science of the Anthropocene
Main Authors: Lafond, Augustin, Leblanc, Karine, Queguiner, Bernard, Moriceau, Brivaela, Leynaert, Aude, Cornet, Veronique, Legras, Justine, Ras, Josephine, Parenteau, Marie, Garcia, Nicole, Babin, Marcel, Tremblay, Jean-eric
Format: Article in Journal/Newspaper
Language:English
Published: Univ California Press 2019
Subjects:
Diatoms
Spring bloom
Sea ice
Community composition
Baffin Bay
Arctic
Arctic Ocean
Greenland
Pacific
Baffin
Climate change
ice pack
Phytoplankton
Online Access:https://archimer.ifremer.fr/doc/00615/72752/72021.pdf
https://archimer.ifremer.fr/doc/00615/72752/72022.pdf
https://doi.org/10.1525/elementa.382
https://archimer.ifremer.fr/doc/00615/72752/
Description
Summary:The Arctic Ocean is particularly affected by climate change, with changes in sea ice cover expected to impact phytoplankton primary production. During the Green Edge expedition, the development of the late spring-early summer diatom bloom was studied in relation with the sea ice retreat by multiple transects across the marginal ice zone. Biogenic silica concentrations and uptake rates were measured. In addition, diatom assemblage structures and their associated carbon biomass were determined, along with taxon-specific contributions to total biogenic silica production using the fluorescent dye PDMPO. Results indicate that a diatom bloom developed in open waters close to the ice edge, following the alleviation of light limitation, and extended 20-30 km underneath the ice pack. This actively growing diatom bloom (up to 0.19 mu mol Si L-1 d(-1)) was associated with high biogenic silica concentrations (up to 2.15 mu mol L-1), and was dominated by colonial fast-growing centric (Chaetoceros spp. and Thalassiosira spp.) and ribbon-forming pennate species (Fragilariopsis spp./Fossula arctica). The bloom remained concentrated over the shallow Greenland shelf and slope, in Atlantic-influenced waters, and weakened as it moved westwards toward ice-free Pacific-influenced waters. The development resulted in a near depletion of all nutrients eastwards of the bay, which probably induced the formation of resting spores of Melosira arctica. In contrast, under the ice pack, nutrients had not yet been consumed. Biogenic silica and uptake rates were still low (respectively <0.5 mu mol L-1 and <0.05 mu mol L-1 d(-1)), although elevated specific Si uptake rates (up to 0.23 d(-1)) probably reflected early stages of the bloom. These diatoms were dominated by pennate species (Pseudo-nitzschia spp., Ceratoneis closterium, and Fragilariopsis spp./Fossula arctica). This study can contribute to predictions of the future response of Arctic diatoms in the context of climate change.

Similar Items