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Simulating the dynamics of sulfur species and zinc in wetland sediments

Simulating the dynamics of sulfur species and zinc in wetland sediments
Choi J.H.Park S.S.Jaffe P.R.
Ewha Authors
박석순scopus; 최정현scopus
Issue Date
Journal Title
Ecological Modelling
0304-3800JCR Link
Ecological Modelling vol. 199, no. 3 SPEC. ISS., pp. 315 - 323
Document Type
In situ measurements comparing vertical SO4 2- profiles in vegetated and non-vegetated sediments showed that SO4 2- concentrations in vegetated sediments increased significantly at the beginning of the growing season and then gradually decreased during the rest of the growing season. Throughout the growing season, SO4 2- concentrations remained higher in the vegetated sediments than in the sediments without plants. The higher SO4 2- concentrations in the vegetated sediments indicate that oxygen release from roots and evapotranspiration-induced advection by plants play an important role in the dynamics of sulfur species in sediments. Since the total pool of solid-phase sulfide is relatively large compared to the mass of SO4 2- in the sediments, the gradual decrease of SO4 2- concentrations may result from limitation of the solid-phase sulfide that is in direct contact with or very close to the roots and rhizomes. This would mean that the main pool of solid-phase sulfide and associated trace metals are not affected by the oxygen release from roots, and the associated trace metals will not become bioavailable during the growing season. A mathematical model was developed to gain a better understanding of how oxygen release from roots is linked to the dynamics of solid-phase sulfide, associated trace metals and dissolved SO4 2- concentrations in sediments throughout the growing season. The model consists of one-dimensional mass balance equations formulated for the reactive transport of organic carbon, terminal electron acceptors and their corresponding reduced species in the sediments. It accounts for the combined effects of oxygen release by roots and evapotranspiration as well as physical and biological reactions, and includes formulations for the oxidative dissolution of solid species, such as FeS(s) and ZnS(s), as well as the formation of these species. Model simulations indicate that only 0.1% of the total solid-phase sulfide in the sediment is available to be oxidized by the oxygen released from roots. The oxidation of solid-phase sulfide associated with oxygen release from roots not only produces oxidized sulfur species (i.e. SO4 2-, S0), it also releases the associated metals to the sediment pore-water and perhaps the water column. Simulation results indicate that this oxidation of AVS (acid-volatile sulfide) does not result in the flux of trace metals into the water column. © 2006 Elsevier B.V. All rights reserved.
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