Modelling the impact of riverine DON removal by marine bacterioplankton on primary production in the Arctic Ocean

TitleModelling the impact of riverine DON removal by marine bacterioplankton on primary production in the Arctic Ocean
Publication TypeJournal Article
Year of Publication2015
AuthorsLe Fouest V., Manizza M, Tremblay B., Babin M.
JournalBiogeosciences
Volume12
Pagination3385-3402
Date Published2015/08
Type of ArticleArticle
ISBN Number1726-4170
Accession NumberWOS:000356179800014
Keywordsbarents; Beaufort Sea; dissolved organic-matter; growth-rate; heterotrophic bacteria; microbial food-web; phytoplankton blooms; primary nitrite maximum; sea; sea-ice; st-lawrence canada
Abstract

The planktonic and biogeochemical dynamics of the Arctic shelves exhibit a strong variability in response to Arctic warming. In this study, we employ a biogeochemical model coupled to a pan-Arctic ocean-sea ice model (MIT- gcm) to elucidate the processes regulating the primary production (PP) of phytoplankton, bacterioplankton (BP), and their interactions. The model explicitly simulates and quantifies the contribution of usable dissolved organic nitrogen (DON) drained by the major circum-Arctic rivers to PP and BP in a scenario of melting sea ice (1998-2011). Model simulations suggest that, on average between 1998 and 2011, the removal of usable riverine dissolved organic nitrogen (RDON) by bacterioplankton is responsible for a similar to 26% increase in the annual BP for the whole Arctic Ocean. With respect to total PP, the model simulates an increase of similar to 8% on an annual basis and of similar to 18% in summer. Recycled ammonium is responsible for the PP increase. The recycling of RDON by bacterioplankton promotes higher BP and PP, but there is no significant temporal trend in the BP : PP ratio within the ice-free shelves over the 1998-2011 period. This suggests no significant evolution in the balance between autotrophy and heterotrophy in the last decade, with a constant annual flux of RDON into the coastal ocean, although changes in RDON supply and further reduction in sea-ice cover could potentially alter this delicate balance.

DOI10.5194/bg-12-3385-2015
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