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- Title
Ocean Ammonia Outgassing: Modulation by CO<sub>2</sub> and Anthropogenic Nitrogen Deposition.
- Authors
Paulot, Fabien; Stock, Charles; John, Jasmin G.; Zadeh, Niki; Horowitz, Larry W.
- Abstract
The imprint of anthropogenic activities on the marine nitrogen (N) cycle remains challenging to represent in global models, in part because of uncertainties regarding the source of marine N to the atmosphere. While N inputs of terrestrial origin present a truly external perturbation, a significant fraction of N deposition over the ocean arises from oceanic ammonia (NH3) outgassing that is subsequently deposited in other ocean regions. Here, we describe advances in the Geophysical Fluid Dynamics Laboratory's (GFDL) Earth System Model 4 (ESM4.1) aimed at improving the representation of the exchange of N between atmosphere and ocean and its response to changes in ocean acidity and N deposition. We find that the simulated present‐day NH3 outgassing (3.1 TgN yr−1) is 7% lower than under preindustrial conditions, which reflects the compensating effects of increasing CO2 (−16%) and N enrichment of ocean waters (+9%). This change is spatially heterogeneous, with decreases in the open ocean (−13%) and increases in coastal regions (+15%) dominated by coastal N enrichment. The ocean outgassing of ammonia is shown to increase the transport of N from N‐rich to N‐poor ocean regions, where carbon export at 100 m increases by 0.5%. The implications of the strong response of NH3 ocean outgassing to CO2 for the budget of NH3 in the remote marine atmosphere and its imprint in ice cores are discussed. Key Points: Development of an interactive representation of N exchange between ocean and atmosphere in the GFDL ESM4.1, including ammonia outgassingLittle change in the ocean NH3 outgassing over the historical period due to compensation between acidification and increasing N depositionOcean NH3 outgassing increases carbon export at 100 m in N‐limited regions by 0.5%
- Subjects
ATMOSPHERIC nitrogen; GEOPHYSICAL fluid dynamics; OUTGASSING; OCEAN; ICE cores; AMMONIA; GEOLOGICAL carbon sequestration
- Publication
Journal of Advances in Modeling Earth Systems, 2020, Vol 12, Issue 10, p1
- ISSN
1942-2466
- Publication type
Article
- DOI
10.1029/2019MS002026