Abstract
Rising concentrations of nitrous oxide (N2O) in the atmosphere are causing widespread concern because this trace gas plays a key role in the destruction of stratospheric ozone and it is a strong greenhouse gas. The successful mitigation of N2O emissions requires a solid understanding of the relative importance of all N2O sources and sinks. Stable isotope ratio measurements (δ15N-N2O and δ18O-N2O), including the intramolecular distribution of 15N (site preference), are one way to track different sources if they are isotopically distinct. ‘Top-down’ isotope mass-balance studies have had limited success balancing the global N2O budget thus far because the isotopic signatures of soil, freshwater, and marine sources are poorly constrained and a comprehensive analysis of global N2O stable isotope measurements has not been done. Here we used a robust analysis of all available in situ measurements to define key global N2O sources. We showed that the marine source is isotopically distinct from soil and freshwater N2O (the continental source). Further, the global average source (sum of all natural and anthropogenic sources) is largely controlled by soils and freshwaters. These findings substantiate past modelling studies that relied on several assumptions about the global N2O cycle. Finally, a two-box-model and a Bayesian isotope mixing model revealed marine and continental N2O sources have relative contributions of 24–26% and 74–76% to the total, respectively. Further, the Bayesian modeling exercise indicated the N2O flux from freshwaters may be much larger than currently thought.
Highlights
Since the advent of the Haber-Bosch process one century ago, humans have vastly perturbed the global nitrogen (N) cycle
One negative consequence of this is an increase in atmospheric nitrous oxide (N2O) [2], a long-lived trace gas that contributes to climate warming and the destruction of stratospheric ozone [3]
SLS: STPGP 336807-06, www.nserc-crsng.gc.ca and www.biocap.ca; Natural Sciences and Engineering Research Council of Canada 'Strategic Project' awarded to JS and SLS: STPGP 357056-07, www. nserc-crsng.gc.ca; Natural Sciences and Engineering Research Council of Canada 'Discovery Grant' awarded to SLS: RGPIN 33854, www.nserc-crsng.gc. ca; Ontario Ministry of Agriculture and Food 'Environmental Sustainability Directed Research Program' projects awarded to JS: Project 09M1, Project 11M1, www.omafra.gov.on.ca; Canadian Foundation for Climate and Atmospheric Sciences project awarded to SLS: GR-428; Banting Postdoctoral Fellowship awarded to DMS, www. banting.fellowships-bourses.gc.ca; and Norfolk Land Stewardship Council project awarded to JS, www. hnstewardshipcouncils.org/norfolk_land_stewardship_council
Summary
Since the advent of the Haber-Bosch process one century ago, humans have vastly perturbed the global nitrogen (N) cycle. Future concentrations of atmospheric N2O are difficult to predict, yet this information is an essential input parameter for global climate change models Both the prediction and mitigation of N2O concentrations depend on an accurate understanding of the emissions from key N2O sources. Several accounts of the global N2O budget have used ‘top-down’ isotope mass-balance models to estimate the strength and isotopic composition of anthropogenic and natural N2O sources [2,6,7,8,9,10,11]. We use a ‘bottom-up’ approach to define key N2O sources and demonstrate that their global average δ15N and δ18O values are isotopically unique Further we use these in situ N2O isotope data to substantiate what ‘top-down’ global atmospheric models have predicted; soils, and not marine or freshwater ecosystems, are the main source of rising atmospheric N2O levels
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