Factors influencing the stable carbon isotopic composition of suspended and sinking organic matter in the coastal Antarctic sea ice environment

A high resolution time-series analysis of stable carbon isotopic signatures in particulate organic carbon (δ 13 CPOC) and associated biogeochemical parameters in sea ice and surface waters provides an insight into the factors affecting δ 13 CPOC in the coastal western Antarctic Peninsula sea ice env...

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Bibliographic Details
Published in:Biogeosciences
Main Authors: Henley, S.F., Annett, A.L., Ganeshram, R.S., Carson, D.S., Weston, K., Crosta, X., Tait, A., Dougans, J., Fallick, A.E., Clarke, A.
Format: Article in Journal/Newspaper
Language:English
Published: 2012
Subjects:
Antarctic
Antarctic Peninsula
Austral
Marguerite
Marguerite Bay
Ryder
Ryder Bay
Southern Ocean
Antarc*
Sea ice
Online Access:https://eprints.soton.ac.uk/418605/
Description
Summary:A high resolution time-series analysis of stable carbon isotopic signatures in particulate organic carbon (δ 13 CPOC) and associated biogeochemical parameters in sea ice and surface waters provides an insight into the factors affecting δ 13 CPOC in the coastal western Antarctic Peninsula sea ice environment. The study covers two austral summer seasons in Ryder Bay, northern Marguerite Bay between 2004 and 2006. A shift in diatom species composition during the 2005/06 summer bloom to near-complete biomass dominance of Proboscia inermis is strongly correlated with a large ∼10 ‰ negative isotopic shift in δ 13 CPOC that cannot be explained by a concurrent change in concentration or isotopic signature of CO2. We hypothesise that the δ 13 CPOC shift may be driven by the contrasting biochemical mechanisms and utilisation of carbon-concentrating mechanisms (CCMs) in different diatom species. Specifically, very low δ 13 CPOC in P. inermis may be caused by the lack of a CCM, whilst some diatom species abundant at times of higher δ 13 CPOC may employ CCMs. These short-lived yet pronounced negative δ 13 CPOC excursions drive a 4 ‰ decrease in the seasonal average δ 13 CPOC signal, which is transferred to sediment traps and core-top sediments and consequently has the potential for preservation in the sedimentary record. This 4 ‰ difference between seasons of contrasting sea ice conditions and upper water column stratification matches the full amplitude of glacial-interglacial Southern Ocean δ 13 CPOC variability and, as such, we invoke phytoplankton species changes as a potentially important factor influencing sedimentary δ 13 CPOC. We also find significantly higher δ 13 CPOC in sea ice than surface waters, consistent with autotrophic carbon fixation in a semi-closed environment and possible contributions from post-production degradation, biological utilisation of HCO3− and production of exopolymeric substances. This study demonstrates the importance of surface water diatom speciation effects and isotopically heavy sea ...

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