These findings validate QCLAS as a viable alternative technique with even higher precision than state-of-the-art IRMS. Thus, laser spectroscopy has the potential to contribute significantly to a better understanding of N turnover in soils, which is crucial for advancing strategies to mitigate emissions of this efficient greenhouse gas.
Both experiments showed that the N2O/(N2O+N2) product ratio of denitrification is not solely controlled by the available carbon content of the soil or by the denitrification rate. Differences in N2O SP values could not be explained by variations in N2O reduction between soils, but rather originate from other processes involved in denitrification. The linear δ(18)O vs SP relationship may be indicative for N2O reduction; however, it deviates significantly from the findings of previous studies.
Rationale
Field measurement of denitrification in agricultural ecosystems using the 15N gas flux method has been limited by poor sensitivity because current isotope ratio mass spectrometry is not precise enough to detect low 15N2 fluxes in the presence of a high atmospheric N2 background. For laboratory studies, detection limits are improved by incubating soils in closed systems and under N2‐depleted atmospheres.
Methods
We developed a new procedure to conduct the 15N gas flux method suitable for field application using an artificially N2‐depleted atmosphere to improve the detection limit at the given precision of mass spectrometry. Laboratory experiments with and without 15N‐labelling and using different flushing strategies were conducted to develop a suitable field method. Subsequently, this method was tested in the field and results were compared with those obtained from the conventional 15N gas flux method.
Results
Results of the two methods were in close agreement showing that the denitrification rates determined were not biased by the flushing procedure. Best sensitivity for N2 + N2O fluxes was 10 ppb, which was 80‐fold better than that of the reference method. Further improvement can be achieved by lowering the N2 background concentration below the values established in the present study.
Conclusions
In view of this progress in sensitivity, the new method will be suitable to measure denitrification dynamics in the field beyond peak events.
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