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Zusammenfassung:
Sediment cores of 20 cm diameter containing the natural benthic fauna were subjected to low oxygen conditions in a laboratory microcosm system. After several days of oxic conditions ('oxic stage') the oxygen content of the water was reduced to 25% saturation for 15 d ('hypoxic stage'), followed by a 'reoxygenation stage'. Effective solute transport rates were calculated using measurements with the conservative tracer ion bromide. Profiles of oxygen and Sigma CO2 were measured and molecular diffusive as well as effective fluxes, accounting for effective solute exchange, were calculated. The overall response of the benthic community was to compensate for low oxygen content of the overlying water by increased pumping activity. On average, effective diffusion coefficients (D-eff) were 3 times higher in hypoxia than under oxic conditions. D-eff reached 1.5 x 10(-4) cm(2) s(-1), a Value 30 times that of molecular diffusion. During hypoxia we observed low molecular diffusive O-2 flux, higher effective O-2 flux, as well as an increase in Sigma CO2 within the sediment. We interpret this as a shift of transport away from diffusion within the bulk sediment interstices (oxic conditions) to the advective transport pathways along burrows during hypoxia. This facilitates fast transport of oxygen and bromide along burrows and contrasts with the slower transport of CO2 from the interstices governed by molecular diffusion. In this transient situation calulations based on gradients result in an unrealistic molar ratio of fluxes (CO2/O-2) as high as 11.
