Technical Note: Simultaneous measurement of sedimentary N₂ and N₂O production and a modified ¹⁵N isotope pairing technique

Dinitrogen (N₂) and/or nitrous oxide (N₂O) are produced through denitrification, anaerobic ammonium oxidation (anammox) or nitrification in sediments, of which entangled processes complicate the absolute rate estimations of gaseous nitrogen production from individual pathways. The classical isotope pairing technique (IPT), the most common ¹⁵N nitrate enrichment method to quantify denitrification, has recently been modified by different researchers to (1) discriminate between the N₂ produced by denitrification and anammox or to (2) provide a more accurate denitrification rate under considering production of both N₂O and N₂. In case 1, the revised IPT focused on N₂ production being suitable for the environments of a low N₂O-to-N₂ production ratio, while in case 2, anammox was neglected. This paper develops a modified method to refine previous versions of IPT. Cryogenic traps were installed to separately preconcentrate N₂ and N₂O, thus allowing for subsequent measurement of the two gases generated in one sample vial. The precision is better than 2% for N₂ (<i>m/z</i> 28, <i>m/z</i> 29 and <i>m/z</i> 30), and 1.5% for N₂O (<i>m/z</i> 44, <i>m/z</i> 45 and <i>m/z</i> 46). Based on the six <i>m/z</i> peaks of the two gases, the ¹⁵N nitrate traceable processes including N₂ and N₂O from denitrification and N₂ from anammox were estimated. Meanwhile, N₂O produced by nitrification was estimated via the production rate of unlabeled ⁴⁴N₂O. To validate the applicability of our modified method, incubation experiments were conducted using sediment cores taken from the Danshuei Estuary in Taiwan. Rates of the aforementioned nitrogen removal processes were successfully determined. Moreover, N₂O yield was as high as 66%, which would significantly bias previous IPT approaches if N₂O was not considered. Our modified method not only complements previous versions of IPT but also provides more comprehensive information to advance our understanding of nitrogen dynamics of the water–sediment interface.