Accounting for non-linear chemistry of ship plumes in the GEOS-Chem global chemistry transport model

Vinken, G. C. M.; Boersma, K. Folkert; Jacob, Daniel J.; Meijer, E.

doi:10.5194/acp-11-11707-2011

Cited by 118 publications

(136 citation statements)

References 29 publications

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“…Model calculations with a parameterization of the ship plumes suggest that with this approach we overestimate NO x concentrations and ozone formation (Huszar et al, 2010;Vinken et al, 2011). Our results may not be directly comparable as we use a much finer horizontal model resolution.…”

Section: Discussionmentioning

confidence: 42%

“…Our results may not be directly comparable as we use a much finer horizontal model resolution. In addition Vinken et al (2011) find that the differences between the plume calculations and instant dilution are smallest over strongly polluted seas such as the North Sea. This suggests that implementing a parameterization of the ship plumes would not change our results significantly.…”

Section: Discussionmentioning

confidence: 95%

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Model calculations of the effects of present and future emissions of air pollutants from shipping in the Baltic Sea and the North Sea

et al. 2015

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Abstract. Land-based emissions of air pollutants in Europe have steadily decreased over the past two decades, and this decrease is expected to continue. Within the same time span emissions from shipping have increased in EU ports and in the Baltic Sea and the North Sea, defined as SECAs (sulfur emission control areas), although recently sulfur emissions, and subsequently particle emissions, have decreased. The maximum allowed sulfur content in marine fuels in EU ports is now 0.1 %, as required by the European Union sulfur directive. In the SECAs the maximum fuel content of sulfur is currently 1 % (the global average is about 2.4 %). This will be reduced to 0.1 % from 2015, following the new International Maritime Organization (IMO) rules.In order to assess the effects of ship emissions in and around the Baltic Sea and the North Sea, regional model calculations with the EMEP air pollution model have been made on a 1/4 • longitude × 1/8 • latitude resolution, using ship emissions in the Baltic Sea and the North Sea that are based on accurate ship positioning data. The effects on depositions and air pollution and the resulting number of years of life lost (YOLLs) have been calculated by comparing model calculations with and without ship emissions in the two sea areas. In 2010 stricter regulations for sulfur emissions were implemented in the two sea areas, reducing the maximum sulfur content allowed in marine fuels from 1.5 to 1 %. In addition ships were required to use fuels with 0.1 % sulfur in EU harbours. The calculations have been made with emissions representative of 2009 and 2011, i.e. before and after the implementation of the stricter controls on sulfur emissions from 2010. The calculations with present emissions show that per person, an additional 0.1-0.2 years of life lost is estimated in areas close to the major ship tracks with current emission levels. Comparisons of model calculations with emissions before and after the implementation of stricter emission control on sulfur show a general decrease in calculated particle concentration. At the same time, however, an increase in ship activity has resulted in higher emissions of other components, and subsequently air concentrations, in particular of NO x , especially in and around several major ports.Additional model calculations have been made with landbased and ship emissions representative of year 2030. Following a decrease in emissions from all sectors, air quality is expected to improve, and depositions to be reduced. Particles from shipping are expected to decrease as a result of emission controls in the SECAs. Further controls of NO x emissions from shipping are not decided, and calculations are presented with and without such controls.

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Section: Discussionmentioning

confidence: 42%

Section: Discussionmentioning

confidence: 95%

Model calculations of the effects of present and future emissions of air pollutants from shipping in the Baltic Sea and the North Sea

et al. 2015

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“…Liang and Jacobson (2000) showed that premature mixing of urban and background air masses can lead to either overestimates or underestimates of OPE. Model simulations of ship plumes indicate particularly large ozone overestimates when mixing NO x from the plumes into otherwise clean grid cells (Davis et al, 2001;Vinken et al, 2011). On a global scale, Wild and Prather (2006) found from an asymptotic error convergence method that grid averaging in a 2.8 • × 2.8 • model caused a +4 % bias in the global tropospheric ozone burden, with larger errors on regional scales.…”

Section: Introductionmentioning

confidence: 99%

“…Model simulations of ship plumes indicate particularly large ozone overestimates when mixing NO x from the plumes into otherwise clean grid cells (Davis et al, 2001;Vinken et al, 2011). On a global scale, Wild and Prather (2006) found from an asymptotic error convergence method that grid averaging in a 2.8 • × 2.8 • model caused a +4 % bias in the global tropospheric ozone burden, with larger errors on regional scales. Ito et al (2009) compared global models of varying resolutions and concluded that artificial mixing of biogenic VOC emissions into coarse grid cells drives excessive conversion of NO x to organic nitrate reservoirs, leading to release of NO x downwind under higher OPE conditions and thereby causing excessive ozone production.…”

Section: Introductionmentioning

confidence: 99%

Sensitivity to grid resolution in the ability of a chemical transport model to simulate observed oxidant chemistry under high-isoprene conditions

Jacob

Fisher

et al. 2016

Atmos. Chem. Phys.

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Abstract. Formation of ozone and organic aerosol in continental atmospheres depends on whether isoprene emitted by vegetation is oxidized by the high-NO x pathway (where peroxy radicals react with NO) or by low-NO x pathways (where peroxy radicals react by alternate channels, mostly with HO 2 ). We used mixed layer observations from the SEAC 4 RS aircraft campaign over the Southeast US to test the ability of the GEOS-Chem chemical transport model at different grid resolutions (0.25to simulate this chemistry under high-isoprene, variable-NO x conditions. Observations of isoprene and NO x over the Southeast US show a negative correlation, reflecting the spatial segregation of emissions; this negative correlation is captured in the model at 0.25 • × 0.3125 • resolution but not at coarser resolutions. As a result, less isoprene oxidation takes place by the high-NO x pathway in the model at 0.25 • × 0.3125 • resolution (54 %) than at coarser resolution (59 %). The cumulative probability distribution functions (CDFs) of NO x , isoprene, and ozone concentrations show little difference across model resolutions and good agreement with observations, while formaldehyde is overestimated at coarse resolution because excessive isoprene oxidation takes place by the high-NO x pathway with high formaldehyde yield. The good agreement of simulated and observed concentration variances implies that smaller-scale non-linearities (urban and power plant plumes) are not important on the regional scale. Correlations of simulated vs. observed concentrations do not improve with grid resolution because finer modes of variability are intrinsically more difficult to capture. Higher model resolution leads to decreased conversion of NO x to organic nitrates and increased conversion to nitric acid, with total reactive nitrogen oxides (NO y ) changing little across model resolutions. Model concentrations in the lower free troposphere are also insensitive to grid resolution. The overall low sensitivity of modeled concentrations to grid resolution implies that coarse resolution is adequate when modelPublished by Copernicus Publications on behalf of the European Geosciences Union. K. Yu et al.: Sensitivity to grid resolution under high-isoprene conditionsing continental boundary layer chemistry for global applications.

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“…[109] Alternative attempts to address this have included a box model approach, [110] a large eddy model approach [116] and a ship plume parameterisation in a regional model. [117] A promising approach is the 'plume-in-grid' formulation by Vinken et al, [118] which, when incorporated in a global model, showed that ignoring these effects leads to overestimation of NO x and O 3 concentrations in the North Atlantic by 50 and 10-25 % respectively. Further work is clearly required to determine how grid-scale ship plumes can be parameterised in numerical models.…”

Section: Atmospheric Nutrient Supply To the Surface Oceanmentioning

confidence: 99%

Evolving research directions in Surface Ocean - Lower Atmosphere (SOLAS) science

Law¹,

Breviere²,

Leeuw³

et al. 2013

Environ. Chem.

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Environmental context. Understanding the exchange of energy, gases and particles at the ocean-atmosphere interface is critical for the development of robust predictions of, and response to, future climate change. The international Surface Ocean-Lower Atmosphere Study (SOLAS) coordinates multi-disciplinary oceanatmosphere research projects that quantify and characterise this exchange. This article details five new SOLAS research strategies -upwellings and associated oxygen minimum zones, sea ice, marine aerosols, atmospheric nutrient supply and ship emissions -that aim to improve knowledge in these critical areas.Abstract. This review focuses on critical issues in ocean-atmosphere exchange that will be addressed by new research strategies developed by the international Surface Ocean-Lower Atmosphere Study (SOLAS) research community. Eastern boundary upwelling systems are important sites for CO 2 and trace gas emission to the atmosphere, and the proposed research will examine how heterotrophic processes in the underlying oxygen-deficient waters interact with the climate system. The second regional research focus will examine the role of sea-ice biogeochemistry and its interaction with atmospheric chemistry. Marine aerosols are the focus of a research theme directed at understanding the processes that determine their abundance, chemistry and radiative properties. A further area of aerosol-related research examines atmospheric nutrient deposition in the surface ocean, and how differences in origin, atmospheric processing and composition influence surface ocean biogeochemistry. Ship emissions are an increasing source of aerosols, nutrients and toxins to the atmosphere and ocean surface, and an emerging area of research will examine their effect on ocean biogeochemistry and atmospheric chemistry. The primary role of SOLAS is to coordinate coupled multi-disciplinary research within research strategies that address these issues, to achieve robust representation of critical ocean-atmosphere exchange processes in Earth System models.

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Accounting for non-linear chemistry of ship plumes in the GEOS-Chem global chemistry transport model

Cited by 118 publications

References 29 publications

Model calculations of the effects of present and future emissions of air pollutants from shipping in the Baltic Sea and the North Sea

Model calculations of the effects of present and future emissions of air pollutants from shipping in the Baltic Sea and the North Sea

Sensitivity to grid resolution in the ability of a chemical transport model to simulate observed oxidant chemistry under high-isoprene conditions

Evolving research directions in Surface Ocean - Lower Atmosphere (SOLAS) science

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