Sediment denitrification in the Gulf of Mexico zone of hypoxia

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The largest zone of anthropogenic bottom water hypoxia in the Western Hemisphere occurs seasonally in the northern Gulf of Mexico between the Mississippi River delta and the coast of eastern Texas. This zone of hypoxia reaches its greatest extent in the summer months and is a conse- quence of seasonal stratification of the water column com- bined with the decomposition of organic matter derived from accelerated rates of primary production. This enhanced pro- ductivity is driven primarily by the input of inorganic nitrogen from the Mississippi River. There are 3 likely sinks for fixed nitrogen within this zone of hypoxia: sequestration in the sediment, dispersion and dilution into the Gulf of Mexico, and denitrification. We assessed potential denitrification rates at 7 stations in the zone of hypoxia during the summer of 1999. Those data are compared with bottom water nitrate, ammo- nium and dissolved oxygen (DO) concentrations. No denitri- fication was observed in the water column. Denitrification potential rates in the surface sediments were unexpectedly low and ranged between 39.8 and 108.1 µmol m -2 h -1 . The highest rates were observed at stations with bottom water DO concentrations between 1 and 3 mg l -1 . Denitrification activity was significantly lower at stations where DO was lower than 1 mg l -1 or higher than 3 mg l -1 . Nutrient data for these sta- tions demonstrate that as anoxia is approached, the dominant species of nitrogen shifts from nitrate to ammonium. The shift in nitrogen species suggests competition between microbial populations in the sediment community. The lower denitrifi- cation rates at stations with bottom water DO <1 mg l -1 may be due to nitrate limitation or an increase in the competitive advantage of microorganisms capable of dissimilatory nitrate reduction to ammonium (DNRA). Suppression of denitrifica- tion at low DO by any mechanism will increase the residence time of bioavailable nitrogen. This trend could act as a posi- tive feedback mechanism in the formation of hypoxic bottom waters.