Abstract
Fixed nitrogen (N) loss to biogenic N2 in intense oceanic O 2 minimum zones (OMZ) accounts for a large fraction of the global N sink and is an essential control on the ocean's N-budget. However, major uncertainties exist regarding microbial pathways as well as net impact on the magnitude of N-loss and the ocean's overall N-budget. Here we report the discovery of a N-loss hotspot in the Peru OMZ associated with a coastally trapped mesoscale eddy that is marked by an extreme N-deficit matched by biogenic N2 production, high NO2 levels, and the highest isotope enrichments observed so far in OMZ's for the residual NO3. High sea surface chlorophyll in seaward flowing streamers provides evidence for offshore eddy transport of highly productive, inshore water. Resulting pulses in the downward flux of particles likely stimulated heterotrophic dissimilatory NO3 reduction and subsequent production of biogenic N2 within the OMZ. A shallower biogenic N2 maximum within the oxycline is likely a feature advected by the eddy streamer from the shelf. Eddy-associated temporal-spatial heterogeneity of N-loss, mediated by a local succession of microbial processes, may explain inconsistencies observed among prior studies. Similar transient enhancements of N-loss likely occur within all other major OMZ's exerting a major influence on global ocean N and N isotope budgets. © 2013 © 2013 Author(s).
Figures
![Fig. 1. Biogeochemical maps of the Peru OMZ from a series of stations constituting 6 transects normal and 1 transect parallel to the coast occupied during cruises M77/3 and M77/4 of the German research vessel R/V Meteor in January and February of 2009. Properties are shown along a constant density surface (σθ = 26.3 kg m−3) within the upper portion of the OMZ corresponding to a depth range of 100 to 170 m. (A) O2 concentration (µmol kg−1), station locations, and depth of the σθ = 26.3 kg m−3 surface. (B) NO − 2 concentration (µmol kg −1). (C) Nitrogen anomaly (N′, µmol kg−1) calculated as [NO−3 ]+ [NO − 2 ]− 16× [PO −3 4 ]. (D) The δ 15N of NO−3 . When southward intensification of suboxic conditions reaches [O2]< 5 µmol kg −1, the onset of N-loss processes is evident. Location of Station 7, a hotspot for N-loss, is marked by an “X”. Data smoothing to produce this visualization diminishes somewhat the extrema found at Station 7 (see Fig. 2). A second hotspot (Station 29) was also detected (marked by a “Y”), but is not discussed in the text due to a less comprehensive data set for this site. The position of a more normal comparison station (see Fig. 2) is marked by a “Z”.](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/59d1c8fc-b8de-3e79-a52e-c4979f09b34b/thumbnail-617c843c-e730-4c37-b917-0c66f2692f7f-0.png)
![Fig. 2. Depth profiles for N-loss indicators at Station 7 showing extreme values as compared to nearby, shoreward Station 9. OMZ (O2 < 3 µmol kg −1) indicated as a shaded depth interval (see also Fig. 3). (A) NO−2 and N-deficit (N ′) concentration profiles (µmol kg−1). (B) Profiles for δ15NO−3 (‰ relative to atmospher N2). (C) Crossplot of the δ 18O vs. the δ15N of NO−3 . (D) Rayleigh plot of δ 15NO−3 vs. the ln of the residual NO−3 fraction assuming the NO − 3 concentration prior to removal is approximated as 16×[PO −3 4 ]. The inverse slope estimates the fractionation effect (ε) at ∼ 17 ‰.](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/59d1c8fc-b8de-3e79-a52e-c4979f09b34b/thumbnail-ba6fa1f5-ecb9-430f-8417-75a5ace2d9d2-1.png)
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Altabet, M. A., Ryabenko, E., Stramma, L., Wallace, D. W. R., Frank, M., Grasse, P., & Lavik, G. (2012). An eddy-stimulated hotspot for fixed nitrogen-loss from the Peru oxygen minimum zone. Biogeosciences, 9(12), 4897–4908. https://doi.org/10.5194/bg-9-4897-2012
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