Relationship between carbon- and oxygen-based primary productivity in the Arctic Ocean, svalbard archipelago

Phytoplankton contribute half of the primary production in the biosphere and are the major source of energy for the Arctic Ocean ecosystem. While primary production measurements are therefore fundamental to our understanding of marine biogeochemical cycling, the extent to which current methods provi...

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Bibliographic Details
Published in:Frontiers in Marine Science
Main Authors: Sanz-Martín, Marina, Vernet, María, Cape, Mattias R., Mesa, Elena, Delgado Huertas, Antonio, Reigstad, Marit, Wassmann, Paul F., Duarte, Carlos M.
Other Authors: Norwegian Research Council, La Caixa, Ministerio de Trabajo, Migraciones y Seguridad Social (España), National Science Foundation (US), National Aeronautics and Space Administration (US), Institute for Advanced Study (Germany)
Format: Article in Journal/Newspaper
Language:unknown
Published: Frontiers Media 2019
Subjects:
primary production
Arctic Ocean
oxygen method
carbon methodology
Svalbard (Arctic) and plankton
Arctic
Svalbard
Svalbard Archipelago
Climate change
Phytoplankton
Online Access:http://hdl.handle.net/10261/202916
https://doi.org/10.3389/fmars.2019.00468
https://doi.org/10.13039/501100005416
https://doi.org/10.13039/100000001
https://doi.org/10.13039/100000104
Description
Summary:Phytoplankton contribute half of the primary production in the biosphere and are the major source of energy for the Arctic Ocean ecosystem. While primary production measurements are therefore fundamental to our understanding of marine biogeochemical cycling, the extent to which current methods provide a definitive estimate of this process remains uncertain given differences in their underlying approaches and assumptions. This is especially the case in the Arctic Ocean, a region of the planet undergoing rapid evolution as a result of climate change, yet where primary production measurements are sparse. In this study, we compared three common methods for estimating primary production in the European Arctic Ocean: 1) production of 18O-labeled oxygen (GPP-18O), 2) changes in dissolved oxygen (GPP-DO) and 3) incorporation rates of 14C-labelled carbon into particulate organic carbon (14C-POC) and into total organic carbon (14C-TOC, the sum of dissolved and particulate organic carbon). Results show that primary production rates derived using oxygen methods showed good agreement across season and were strongly positively correlated. While also strongly correlated, higher scatter associated with seasonal changes was observed between 14C-POC and 14C-TOC. The 14C-TOC-derived rates were, on average, approximately 50 % of the oxygen-based estimates. However, the relationship between these estimates changed seasonally. In May, during a spring bloom of Phaeocystis sp., 14C-TOC was 52 % and 50 % of GPP-DO and GPP-18O respectively, while in August, during post-bloom conditions dominated by flagellates, 14C-TOC was 125 % of GPP-DO and 14C-TOC was 175 % of GPP-18O. Varying relationship between C and O rates may be the result of varying importance of respiration, where C-based rates estimate Net Primary Production (NPP) and O-based rates estimate Gross Primary Production (GPP).However, uncertainty remains in this comparison, given differing assumptions of the methods and the photosynthetic quotients.The median O:C ratio of 4.75 in ...

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