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Physical and bacterial controls on inorganic nutrients and dissolved organic carbon during a sea ice growth and decay experiment
Zhou, J.; Delille, B.; Kaartokallio, H; Kattner, G; Kuosa, H; Tison, J.-L.; Autio, R; Dieckmann, S; Evers, U; Jorgensen, L; Kennedy, H; Kotovitch, M.; Luhtanen, M; Stedmon, A; Thomas, N (2014). Physical and bacterial controls on inorganic nutrients and dissolved organic carbon during a sea ice growth and decay experiment. Mar. Chem. 166: 59-69. dx.doi.org/10.1016/j.marchem.2014.09.013
In: Marine Chemistry. Elsevier: Amsterdam. ISSN 0304-4203; e-ISSN 1872-7581, more
Peer reviewed article  

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Keyword
    Marine/Coastal
Author keywords
    Sea ice; Brine dynamics; Bacterial activity; Inorganic nutrients;Dissolved organic carbon

Authors  Top 
  • Zhou, J., more
  • Delille, B., more
  • Kaartokallio, H
  • Kattner, G
  • Kuosa, H
  • Tison, J.-L., more
  • Autio, R
  • Dieckmann, S
  • Evers, U
  • Jorgensen, L
  • Kennedy, H
  • Kotovitch, M., more
  • Luhtanen, M
  • Stedmon, A
  • Thomas, N

Abstract
    We investigated how physical incorporation, brine dynamics and bacterial activity regulate the distribution of inorganic nutrients and dissolved organic carbon (DOG) in artificial sea ice during a 19-day experiment that included periods of both ice growth and decay. The experiment was performed using two series of mesocosms: the first consisted of seawater and the second consisted of seawater enriched with humic-rich river water. We grew ice by freezing the water at an air temperature of -14 degrees C for 14 days after which ice decay was induced by increasing the air temperature to -1 degrees C. Using the ice temperatures and bulk ice salinities, we derived the brine volume fractions, brine salinities and Rayleigh numbers. The temporal evolution of these physical parameters indicates that there was two main stages in the brine dynamics: bottom convection during ice growth, and brine stratification during ice decay. The major findings are: (1) the incorporation of dissolved compounds (nitrate, nitrite, ammonium, phosphate, silicate, and DOC) into the sea ice was not conservative (relative to salinity) during ice growth. Brine convection clearly influenced the incorporation of the dissolved compounds, since the non-conservative behavior of the dissolved compounds was particularly pronounced in the absence of brine convection. (2) Bacterial activity further regulated nutrient availability in the ice: ammonium and nitrite accumulated as a result of remineralization processes, although bacterial production was too low to induce major changes in DOC concentrations. (3) Different forms of DOC have different properties and hence incorporation efficiencies. In particular, the terrestrially-derived DOC from the river water was less efficiently incorporated into sea ice than the DOC in the seawater. Therefore the main factors regulating the distribution of the dissolved compounds within sea ice are clearly a complex interaction of brine dynamics, biological activity and in the case of dissolved organic matter, the physico-chemical properties of the dissolved constituents themselves.

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