Summary
Laboratory and field studies have demonstrated that fluid motion occurs at two locations in growing sea ice: in a network of brine channels and within the skeletal layer at the ice-water interface. Brine channel fluxes estimated using brine channel areal density from natural sea ice and channel velocities from laboratory studies are compared with recent measurements reported in the literature. Fluxes into the porous skeletal layer of sea ice may be estimated using rates of nutrient uptake by ice algae and adjacent seawater nutrient concentrations. Both approaches indicate fluxes of the order of 10-6 cc cm-2 s-1 (l m-2 h-1), which are about equal to fluxes reported in bioirrigated sediments. Fluxes of this magnitude indicate a very short residence time for the liquid phase in the skeletal layer, suggesting that this fluid motion may be important in maintaining the ice algae community.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Alexander V, Horner R, Clasby RC (1974) Metabolism of arctic sea ice organisms. Report R74-4. Institute of Marine Science, University of Alaska. Fairbanks, 117 pp
Alexander V, Chapman T (1981) The role of epontic algal communities in Bering Sea ice. In: Hood DW, Calder JW (eds) The eastern Bering Sea shelf: Oceanography and Resources, vol 2. NOAA, pp 773–780
Aller RC (1977) The influence of macrobenthos on chemical diagnesis of marine sediments. PhD Dissertation, Yale University, 600 pp
Clasby RC, Horner R, Alexander V (1973) An in situ method for measuring primary productivity of arctic sea ice algae. J Fish Res Board Can 30:835–838
Clasby RC, Alexander V, Horner R (1976) Primary productivity of sea ice algae. In: Hood DW, Burrell DC (eds) Assessment of the Arctic marine environment: selected topics. Institute of Marine Science, University of Alaska, Fairbanks
Eide L, Martin S (1975) The formation of brine drainage features in young sea ice. J Glaciol 14:137–154
Elderfield H, Leudtke N, McCaffrey RJ, Bender M (1981) Benthic flux studies in Narragansett Bay. Am J Sci 281:768–787
Hammond DE, Fuller C (1979) The use of radon-222 to estimate benthic exchange and atmospheric exchange rates in San Francisco Bay. In: T John Conomos (ed) San Francisco Bay: the urbanized estuary, pacific division. Am Assoc Adv Sci. San Francisco Calif, pp 213–230
Lake RA, Lewis EL (1970) Salt rejection by sea ice during growth. J Geophys Res 75:583–597
Martens CS, Berner RA (1977) Intersititial water chemistry of anoxic Long Island Sound sediments. 1. Dissolved gases. Limnol Oceanogr 22:10–25
Martin S (1970) A hydrodynamic curiosity: the salt oscillator. Geophys Fluid Dynamics 1:143–160
Martin S (1979) A field study of brine drainage and oil entrainment in first-year sea ice. J Glaciol 88:473–502
McCaffrey RJ, Myers AC, Davey E, Morrison G, Bender M, Luedke N, Cullen D, Froelich P, Klinkhammer G (1980) The relation between pore water chemistry and benthic fluxes of nutrients and manganese in Narraganset Bay, Rhode Island. Limnol Oceanogr 25:31–44
Meguro H, Ito K, Fukushima H (1967) Ice flora (bottom type): a mechanism of primary production in polar seas and the growth of diatoms in sea ice. Arctic 20:114–133
Niedrauer TM, Martin S (1979) An experimental study of brine drainage and convection in young sea ice. J Geophys Res 84(C3): 1176–1186
Smethie WM Jr, Nittrouer CA, Self RFL (1981) The use of radon-222 as a tracer of sediment irrigation and mixing on the Washington continental shelf. Mar Geol 42:173–200
Schlichting H (1968) Boundary layer theory, 6th edn. McGraw-Hill, New York, 748 pp
Wakatsuchi M (1977) Experiments on haline convection occurring under growing sea ice (in Japanese with English summary). Low Temp Sci, Ser A 35:249–258
Wakatsuchi M, Ono N (1983) Measurements of salinity and volume of brine excluded from growing sea ice. J Geophys Res 88(C5): 2943–2951
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Reeburgh, W.S. Fluxes associated with brine motion in growing sea ice. Polar Biol 3, 29–33 (1984). https://doi.org/10.1007/BF00265564
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00265564