Revisiting the contribution of land transport and shipping emissions to tropospheric ozone

We quantify the contribution of land transport and shipping emissions to tropospheric ozone for the first time with a chemistry-climate model including an advanced tagging method (also known as source apportionment), which considers not only the emissions of nitrogen oxides (NOx, NO, and NO2), carbo...

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Bibliographic Details
Published in:Atmospheric Chemistry and Physics
Main Authors: Mertens, Mariano (author), Grewe, V. (author), Rieger, V.S. (author), Jöckel, Patrick (author)
Format: Article in Journal/Newspaper
Language:English
Published: 2018
Subjects:
North Atlantic
Online Access:http://resolver.tudelft.nl/uuid:ca72f6c0-050f-4a06-9f73-ed37e5ef1245
https://doi.org/10.5194/acp-18-5567-2018
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Summary:We quantify the contribution of land transport and shipping emissions to tropospheric ozone for the first time with a chemistry-climate model including an advanced tagging method (also known as source apportionment), which considers not only the emissions of nitrogen oxides (NOx, NO, and NO2), carbon monoxide (CO), and volatile organic compounds (VOC) separately, but also their non-linear interaction in producing ozone. For summer conditions a contribution of land transport emissions to ground-level ozone of up to 18% in North America and Southern Europe is estimated, which corresponds to 12 and 10nmolĝ€†mol-1, respectively. The simulation results indicate a contribution of shipping emissions to ground-level ozone during summer on the order of up to 30% in the North Pacific Ocean (up to 12nmolĝ€†mol-1) and 20% in the North Atlantic Ocean (12nmolĝ€†mol-1). With respect to the contribution to the tropospheric ozone burden, we quantified values of 8 and 6% for land transport and shipping emissions, respectively. Overall, the emissions from land transport contribute around 20% to the net ozone production near the source regions, while shipping emissions contribute up to 52% to the net ozone production in the North Pacific Ocean. To put these estimates in the context of literature values, we review previous studies. Most of them used the perturbation approach, in which the results for two simulations, one with all emissions and one with changed emissions for the source of interest, are compared. For a better comparability with these studies, we also performed additional perturbation simulations, which allow for a consistent comparison of results using the perturbation and the tagging approach. The comparison shows that the results strongly depend on the chosen methodology (tagging or perturbation approach) and on the strength of the perturbation. A more in-depth analysis for the land transport emissions reveals that the two approaches give different results, particularly in regions with large emissions (up to a ...

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