2017
DOI: 10.3354/meps12359
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Denitrification in an oligotrophic estuary: a delayed sink for riverine nitrate

Abstract: Estuaries are often seen as natural filters of riverine nitrate, but knowledge of this nitrogen sink in oligotrophic systems is limited. We measured spring and summer dinitrogen production (denitrification, anammox) in muddy and non-permeable sandy sediments of an oligotrophic estuary in the northern Baltic Sea, to estimate its function in mitigating the riverine nitrate load. Both sediment types had similar denitrification rates, and no anammox was detected. In spring at high nitrate loading, denitrification … Show more

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Cited by 38 publications
(80 citation statements)
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“…N in the ecosystem while anaerobic ammonium oxidation (anammox) was not detectable (Hellemann et al 2017). These activities are corroborated by the genetic potential of dominant taxa identified in this study.…”
Section: Respiratory Nitrogen (N) Cyclementioning
confidence: 99%
“…N in the ecosystem while anaerobic ammonium oxidation (anammox) was not detectable (Hellemann et al 2017). These activities are corroborated by the genetic potential of dominant taxa identified in this study.…”
Section: Respiratory Nitrogen (N) Cyclementioning
confidence: 99%
“…In this region, the spring flood (April, May) is the major annual hydrological event. The spring flood results in a brief period of enhanced water flow in streams and rivers (Hölemann et al, 2005;Björkvald et al, 2008) and export of Fe and terrestrial organic matter to the coastal zone (Rember and Trefry, 2004;Algesten et al, 2006). During high flow, total and dissolved Fe and Mn in streams can increase by a factor of up to 10, with concentrations being highly variable between years (Björkvald et al, 2008).…”
Section: Study Area and Samplingmentioning
confidence: 99%
“…1b), with water depths varying from 10 to 33 m (Table 1). Sediments at all sites are fine-grained and rich in organic matter (Hellemann et al, 2017; Table 1). 63.54° N 63.52° N 63.5° N 63.48° N 63.46° N 19.7° E 19 75°E 19 8°E 19 85°E . .…”
Section: Study Area and Samplingmentioning
confidence: 99%
“…Using diffusive methods (here IPT) in an advective environment may lead to 15 NO 3 − not reaching the deep zone of NO 3 − reduction in the appropriate amount and within a reasonable timeframe, which is further complicated by the presence of three-dimensional redox zones (Huettel et al 1998). However, sandy sediments with insufficient permeability to facilitate pore water flow, e.g., at locations exposed only to very slow bottom water currents may not experience advective flow (Forster et al 2003) and the application of the conventional diffusive whole-core IPT is possible (Hellemann et al 2017). In general NO 3 − reduction process rates from permeable sands are relatively scarce compared to those from cohesive muddy sediments but several studies have made efforts to overcome specific issues related to the application of the IPT on permeable sediments.…”
Section: Permeable Sedimentmentioning
confidence: 99%