Journal
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
Volume 106, Issue 51, Pages 21713-21716Publisher
NATL ACAD SCIENCES
DOI: 10.1073/pnas.0912111106
Keywords
denitrification; isotope; nitrogen; ecosystem; microbe
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Funding
- Andrew W. Mellon Foundation
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Loss of nitrogen (N) from land limits the uptake and storage of atmospheric CO2 by the biosphere, influencing Earth's climate system and myriads of the global ecological functions and services on which humans rely. Nitrogen can be lost in both dissolved and gaseous phases; however, the partitioning of these vectors remains controversial. Particularly uncertain is whether the bacterial conversion of plant available N to gaseous forms (denitrification) plays a major role in structuring global N supplies in the nonagrarian centers of Earth. Here, we use the isotope composition of N (N-15/N-14) to constrain the transfer of this nutrient from the land to the water and atmosphere. We report that the integrated N-15/N-14 of the natural terrestrial biosphere is elevated with respect to that of atmospheric N inputs. This cannot be explained by preferential loss of N-14 to waterways; rather, it reflects a history of low N-15/N-14 gaseous N emissions to the atmosphere owing to denitrifying bacteria in the soil. Parameterizing a simple model with global N isotope data, we estimate that soil denitrification (including N-2) accounts for approximate to 1/3 of the total N lost from the unmanaged terrestrial biosphere. Applying this fraction to estimates of N inputs, N2O and NOx fluxes, we calculate that approximate to 28 Tg of N are lost annually via N-2 efflux from the natural soil. These results place isotopic constraints on the widely held belief that denitrifying bacteria account for a significant fraction of the missing N in the global N cycle.
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