Abstract
Time-series measurements of temperature, salinity, suspended matter and beam attenuation coefficient (α) were measured at four hour intervals for about two days in June/ July 1982 in the middle shelf region and the coastal region of the southeastern Bering Sea. Current meters were also moored at the same locations.
Depth-time distributions ofα indicated that profiles of suspended matter resulted from a combined process of resuspension of underlying sediments and sinking of suspended particles. Average-values for all measurements for particles revealed that the upward transport of particles due to resuspension formed a boundary layer, with a thickness apparently related to scalar speed. The average-profiles of the particle volume concentration were assumed to result from a balance between the sinking and diffusive flux of particles under a steady state, and the upward fluxes were calculated. Within the boundary layer, values of the upward fluxes of particulate organic matter linearly decreased with the logarithm of distance from the bottom. Fluxes of organic carbon at the upper edge of the boundary layer were 0.375 gC·m−2·day−1 in the middle shelf region (18 m above the bottom, bottom depth=78m) and 0.484gC·m−2·day−1 in the coastal region (25 m above the bottom, bottom depth=33m), and fluxes of nitrogen in both regions were 0.067 gN·m−2·day−1. The flux of organic carbon obtained in the middle shelf region (18 m above the bottom) agreed approximately with the flux (0.416 gC·m−2·day−1) calculated by substituting primary production data into the empirical equation of Suess (1980).
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Kajihara, M., Morinaga, T. & Sekine, A. Distributions and upward fluxes of particulate matter near bottom in the southeastern Bering Sea Shelf. J Oceanogr 42, 389–401 (1986). https://doi.org/10.1007/BF02110434
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DOI: https://doi.org/10.1007/BF02110434