Abstract

The 15N isotope pairing technique is widely used to quantify anammox, denitrification, and dissimilatory nitrate reduction to ammonium (DNRA) in sediments. However, the effects of DNRA on anammox and denitrification in slurry incubations and on genuine N2 production in intact core incubations have not been fully explored. We developed a mathematical model describing these effects of DNRA, and tested this model in field and computational studies. Our model calculations revealed that for slurry incubations the presence of DNRA tends to under -and overestimate the actual anammox and denitrification rates, respectively, when calculated according to Thamdrup and Dalsgaard (2002). We found this underestimate of anammox to be proportional to the 15 mole fraction (FA), and the overestimate of denitrification to be related to both FA and the relative contribution of anammox to the total N2 production (ra). We propose three alternative procedures to better quantify anammox and denitrification rates in slurry incubations and two procedures for intact core incubations. Our model calculations also revealed that for intact core incubations, the presence of DNRA leads to an overestimate of the genuine N2 production rate when calculated according to Risgaard-Petersen et al. (2003). This overestimate depends on the ra and the mole fractions of 15 and 15 in intact core incubations. The results of our field experiments and numerical modeling indicated that the overestimate of the genuine N2 production was less than 1% at two sites in the East China Sea.