Abstract
A continuously recording multiple redox sensor was used to measure oxygenation effects in otherwise anoxic sediments. The sensor reacted within three minutes (increase > 50 mV) to oxygen penetrating into the sediment. Different patterns of oxidation/reduction were observed along burrows of sediment-dwelling infauna. Examples of an increase of more than 600 mV lasting 50 hours and short, 1 to 4 hours long, oxidation pulses of ∼ 280 mV increase are given. Redox patterns similar to the ones observed along natural burrows were generated using ‘artificial burrows’. Oxygen penetrated up to 1 mm by diffusion from burrow walls into the adjacent sediment, whereas elevated Eh values were measured within 3 mm of the burrow. The oxygenation effect of a burrowing shrimp, Callianassa subterranea, was studied in a 3-month experiment with ten sensors and five animals. For one individual we recorded 108 events with Eh increasing by more than 300 mV. It was estimated that below every square meter of sediment surface 0.7 m2. burrow surface are subjected to oxygenation at least once per day by the population of Callianassa in the southern North Sea.
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References
Aller, A. C., 1983. The importance of the diffusion permeability of animal burrow linings in determining marine sediment chemistry. J. mar. Res. 41: 299–322.
Aller, J. Y. & R. C. Aller, 1986. Evidence for localized enhancement of biological activity associated with tube and burrow structures in deep-sea sediments at the HEBBLE site, western North Atlantic. Deep-Sea Res. 33: 755–790.
Aller, R. C. & J. Y. Yingst, 1985. Effects of the marine deposit-feeders Heteromastus filiformis (Polychaeta), Macoma baltica (Bivalva), and Tellina texana (Bivalva) on averaged sedimentary solute transport, reaction rates and microbial distributions. J. mar. Res. 43: 615–645.
Berner, R. A., 1963. Electrode studies of hydrogen sulfide in marine sediments. Geochim. Cosmochim. Acta 27: 563–575.
Bockris, J. O'M. & A. K. N. Reddy, 1970. Modern Electrochemistry, 2. McDonald.
Broecker, W. S. & T.-H. Peng, 1974. Gas exchange rates between air and sea. Tellus 26: 21–35.
Hartmann Hansen, M., K. Ingvorsen & B. B. Jørgensen, 1978. Mechanisms of hydrogen sulfide release from coastal marine sediments to the atmosphere. Limnol. Oceanogr. 23: 68–76.
Hayes, F. R., B. L. Reid & M. L. Cameron, 1958. Lake water and sediment. 2. Oxidation-reduction relations at the mud water interface. Limnol. Oceanogr. 3: 308–317.
Jørgensen, B. B. & N. P. Revsbech, 1989. Oxygen uptake, bacterial distribution and carbon-nitrogen-sulfur cycling in sediments from the Baltic Sea — North Sea transition. Ophelia 31: 29–49.
Kristensen, E., 1983. Ventilation and oxygen uptake by three species of Nereis (Annelida: Polychaeta). I. Effects of hypoxia. Mar. Ecol. Prog. Ser. 12: 289–297.
Kristensen, E., M. H. Jensen & T. K. Andersen, 1985. The impact of polychaete (Nereis virens Sars) burrows on nitrification and nitrate reduction in estuarine sediments. J. exp. mar. Biol. Ecol. 85: 75–91.
Meyers, M. B., E. N. Powell & H. Fossing, 1988. Movement of oxybiotic and thiobiotic meiofauna in response to changes in pore-water oxygen and sulfide gradients around macro-infaunal tubes. Mar. Biol. 98: 395–414.
Ott, J. A. & R. Machan, 1971. Dynamics of climatic parameters in intertidal sediments. Thalassia Jugosl. 7: 219–229.
Rachor, E., 1990. Changes in sublittoral zoobenthos in the German Bight with regard to eutrophication. Neth. J. Sea Res. 25 (1–2): 209–214.
Reichardt, W., 1989. Microbial aspects of bioturbation. Scient. Mar. 53 (2–3): 301–306.
Revsbech, N. P., 1983. in situ measurement of oxygen profiles of sediments by use of oxygen microelectrodes. In: E. Gnaiger & H. Forstner (eds), Polarographic Oxygen Sensors. Springer-Verlag, Heidelberg: 265–273.
Revsbech, N. P. & D. M. Ward, 1983. Oxygen microelectrode that is insensitive tomedium chamical composition: use in acid microbial mat dominated by Cyanidium caldarium. Appl. envir. Microbiol. 45: 755–759.
Romero-Wetzel, M. B., 1987. Sipunculans as inhabitants of very deep, narrow burrows in deep-sea sediments. Mar. Biol. 96: 87–91.
Sørensen, J., B. B. Jørgensen & T. H. Blackburn, 1980. Oxygen in the sea bottom measured with a microelectrode. Science 207: 1355–1356.
Whitfield, M., 1969. Eh as an operational parameter in estuarine studies. Limnol. Oceanogr. 14: 547–558.
Whitfield, M., 1974. Thermodynamic limitations on the use of platinum electrode in Eh measurements. Limnol. Oceanogr. 19: 857–865.
Witbaard, R. & G.C.A. Duineveld, 1989. Some aspects of the biology and ecology of the burrowing shrimp Callianassa subterranea (Montagu) (Thalassinidea) from the southern North Sea. Sarsia 74: 209–219.
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Forster, S., Graf, G. Continuously measured changes in redox potential influenced by oxygen penetrating from burrows of Callianassa subterranea . Hydrobiologia 235, 527–532 (1992). https://doi.org/10.1007/BF00026240
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DOI: https://doi.org/10.1007/BF00026240