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Modeling 210Pb-derived mixing activity in ocean margin sediments: diffusive versus nonlocal mixing
Soetaert, K.; Herman, P.M.J.; Middelburg, J.J.; Heip, C.H.R.; deStigter, H.S.; van Weering, T.C.E.; Epping, E.; Helder, W. (1996). Modeling 210Pb-derived mixing activity in ocean margin sediments: diffusive versus nonlocal mixing. J. Mar. Res. 54: 1207-1227
In: Journal of Marine Research. Sears Foundation for Marine Research, Yale University: New Haven, Conn.. ISSN 0022-2402; e-ISSN 1543-9542, more
Peer reviewed article  

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Keywords
    Isotopes > Lead isotopes > Lead 210
    Modelling
    Physics > Mechanics > Kinetics > Chemical kinetics
    Sediment mixing
    Topographic features > Submarine features > Continental margins
    Transport processes > Diffusion
    ANE, Goban Spur [Marine Regions]
    Marine/Coastal

Authors  Top 
  • deStigter, H.S.
  • van Weering, T.C.E., more
  • Epping, E.
  • Helder, W.

Abstract
    The influence of sediment mixing on activity versus depth profiles of the radionuclide 210Pb in the upper 20 cm of the sediments has been investigated along a depth transect (208 m-4500 m, 17 stations) in the OMEX study area (Goban Spur, NE Atlantic Ocean). A hierarchical family of bioturbation/nonlocal exchange models was derived. Each member of the hierarchy includes all processes of the previous model, and adds a one- or two-parameter process. The significance of the additional parameters is tested using a one-tailed F-test. It was found that (1) in five cases there is a significant improvement when direct injection of part of the flux into deeper sediment layers (nonlocal exchange) is added to the diffusive mixing model. (2) In these five cases, the best model required only two additional parameters, compared to the diffusive mixing model. More elaborate models, including additional parameters did not result in a significantly better fit. (3) In four cases, the inclusion of diffusive mixing (bioturbation) to an advection/decay model does not result in a significant better fit of modeled versus measured 210Pb activity-depth profiles. Using the simplest nonlocal exchange model, the amount of particulates that are directly injected at depth into the sediment was estimated and compared with the amount incorporated at the sediment surface. Along the OMEX transect, between 8-86% of the total flux enters the sediment by nonlocal exchange rather than by mere bioturbation/advection at the sediment surface. The importance of nonlocal exchange decreases with increasing water depth. To allow comparison with other measurements, we have also calculated the diffusive mixing coefficient using the classical bioturbation model. The sediments in the OMEX area have low bioturbation coefficients, especially at the deeper sites. Finally our models have also been used to reproduce and to explore some aberrant 210Pb profiles reported in the literature.

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