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A primary magmatic source of nitrogen to Earth’s crust

Nature Geoscience volume 16pages 521–526 (2023)Cite this article

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Abstract

The igneous portion of Earth’s continental crust represents a long-term sink of terrestrial nitrogen, but the origin of the nitrogen in this reservoir remains ambiguous. Possible sources include magmatic differentiation of mantle-derived melts (that is, magmatic nitrogen) and/or the burial of biomass (that is, fixed atmospheric nitrogen). Identifying the sources of crustal nitrogen is required to accurately reconstruct the evolution of Earth’s atmospheric pressure, and therefore habitability, over geologic timescales. Here we present analyses of the nitrogen geochemistry of extrusive igneous rocks from Hekla volcano, Iceland, which has been previously used as a natural laboratory to study the effects of magmatic differentiation on stable isotope systems. We find that bulk rock nitrogen abundance increases as rocks become more evolved, with up to 23 μg g−1 of nitrogen in felsic igneous samples and non-systematic and negligible nitrogen isotopic fractionation across the suite. Our findings indicate that this nitrogen is magmatic in origin and provides evidence that nitrogen behaves as an incompatible trace element during magmatic differentiation. Assuming Hekla is representative of differentiating systems more broadly, the observed nitrogen enrichment would satisfy 31–52% of Earth’s felsic crust-hosted nitrogen. We suggest that continental crust formation can act as nitrogen trap between the mantle and the atmosphere. Therefore, nitrogen degassing from Earth’s interior to the atmosphere over geological time may have been previously overestimated.

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Fig. 1: Earth reservoir size and abundance estimates for nitrogen.
Fig. 2: Nitrogen abundance and isotope systematics for the Hekla volcanic suite.
Fig. 3: Nitrogen versus rubidium for the Hekla suite and fractional crystallization model.

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Data availability

All supporting data for this study are included in the extended data files associated with this manuscript and are deposited in a figshare repository that can be accessed at https://doi.org/10.6084/m9.figshare.22242517.

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Acknowledgements

Funding was provided by a Natural Environment Research Council (NERC) studentship (grant NE/R012253/1) to T.J.B. and a National Environmental Isotope Facility access in-kind grant (NEIF–2313.0920) to E.E.S., S.M. and T.J.B. S.M. acknowledges support from NERC standard grant NE/PO12167/1. E.E.S. is financially supported by a NERC Frontiers grant (NE/V010824/1). We thank A. MacDonald at Scottish Universities Environmental Research Centre for technical support when obtaining the bulk oxygen isotope data.

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Authors and Affiliations

  1. School of Earth and Environmental Sciences, University of St Andrews, St Andrews, UK

    Toby J. Boocock, Sami Mikhail, Paul S. Savage & Eva E. Stüeken

  2. Scottish Universities Environmental Research Centre, East Kilbride, UK

    Adrian J. Boyce

  3. Department of Earth Sciences, University of Durham, Durham, UK

    Julie Prytulak

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Contributions

T.J.B., S.M., J.P. and E.E.S. designed the study. P.S.S. collected the samples and undertook initial sample preparation and major/trace element characterization. T.J.B. collected the nitrogen data and wrote the original manuscript draft. A.J.B. collected the oxygen isotope data. All authors contributed to the interpretation of the results and the review and editing of the manuscript and supplemental information.

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Correspondence to Toby J. Boocock or Sami Mikhail.

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Nature Geoscience thanks Tobias Fischer, Ralf Halama, Olgeir Sigmarsson and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. Primary handling editors: Tamara Goldin and Rebecca Neely, in collaboration with the Nature Geoscience team.

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Boocock, T.J., Mikhail, S., Boyce, A.J. et al. A primary magmatic source of nitrogen to Earth’s crust. Nat. Geosci. 16, 521–526 (2023). https://doi.org/10.1038/s41561-023-01194-3

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