Abstract
Abstract. The Arabian Sea harbours one of the three major oxygen minimum zones (OMZs) in the world's oceans, and it alone is estimated to account for ~10–20 % of global oceanic nitrogen (N) loss. While actual rate measurements have been few, the consistently high accumulation of nitrite (NO2−) coinciding with suboxic conditions in the central-northeastern part of the Arabian Sea has led to the general belief that this is the region where active N-loss takes place. Most subsequent field studies on N-loss have thus been drawn almost exclusively to the central-NE. However, a recent study measured only low to undetectable N-loss activities in this region, compared to orders of magnitude higher rates measured towards the Omani Shelf where little NO2− accumulated (Jensen et al., 2011). In this paper, we further explore this discrepancy by comparing the NO2−-producing and consuming processes, and examining the relationship between the overall NO2− balance and active N-loss in the Arabian Sea. Based on a combination of 15N-incubation experiments, functional gene expression analyses, nutrient profiling and flux modeling, our results showed that NO2− accumulated in the central-NE Arabian Sea due to a net production via primarily active nitrate (NO3−) reduction and to a certain extent ammonia oxidation. Meanwhile, NO2− consumption via anammox, denitrification and dissimilatory nitrate/nitrite reduction to ammonium (NH4+) were hardly detectable in this region, though some loss to NO2− oxidation was predicted from modeled NO3− changes. No significant correlation was found between NO2− and N-loss rates (p>0.05). This discrepancy between NO2− accumulation and lack of active N-loss in the central-NE Arabian Sea is best explained by the deficiency of labile organic matter that is directly needed for further NO2− reduction to N2O, N2 and NH4+, and indirectly for the remineralized NH4+ required by anammox. Altogether, our data do not support the long-held view that NO2− accumulation is a direct activity indicator of N-loss in the Arabian Sea or other OMZs. Instead, NO2− accumulation more likely corresponds to long-term integrated N-loss that has passed the prime of high and/or consistent in situ activities.
Highlights
In global oceans, nitric oxide (NO)−2 is the least abundant of the major inorganic nitrogen ions (NH+4, NO−2, NO−3 ), representing only < 0.025 % of the 6.6 × 105 Tg N global oceanic inventory of fixed nitrogen (Gruber, 2008)
Based on a combination of 15N-incubation experiments, functional gene expression analyses, nutrient profiling and flux modeling, our results showed that NO−2 accumulated in the centralNE Arabian Sea due to a net production via primarily active nitrate (NO−3 ) reduction and to a certain extent ammonia oxidation
NO−2 is produced via nitrate reduction, which may further lead to the production of gaseous nitrous oxide (N2O) and dinitrogen (N2), in the stepwise N-loss process known as denitrification (NO−3 →NO−2 →NO→N2O→N2)
Summary
NO−2 is the least abundant of the major inorganic nitrogen ions (NH+4 , NO−2 , NO−3 ), representing only < 0.025 % of the 6.6 × 105 Tg N global oceanic inventory of fixed nitrogen (Gruber, 2008). At the second highest oxidation state (+III) of nitrogen, NO−2 often occurs as an intermediate in either oxidative or reductive pathways of the N-cycle. It can be produced during the first step of nitrification, when specific groups of archaea or bacteria oxidize ammonia to NO−2 , most of which is oxidized by a separate group of bacteria to NO−3. NO−2 is produced via nitrate reduction, which may further lead to the production of gaseous nitrous oxide (N2O) and dinitrogen (N2), in the stepwise N-loss process known as denitrification (NO−3 →NO−2 →NO→N2O→N2). Denitrification can occur heterotrophically or autotrophically, but the former is presumably more common in seawater.
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