The impact of ship emissions on air quality and human health in the Gothenburg area – Part 1: 2012 emissions

Tang, Lin; Ramacher, Martin Otto Paul; Moldanová, Jana; Matthias, Volker; Karl, Matthias; Johansson, Lasse; Jalkanen, Jukka-Pekka; Yaramenka, Katarina; Aulinger, Armin; Gustafsson, Malin

doi:10.5194/acp-20-7509-2020

Cited by 40 publications

(53 citation statements)

References 37 publications

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“…Also, different methods of health impact assessment used in these studies are briefly reviewed. In Tang et al (2020) we discuss that shipping in Gothenburg in 2012 was a significant source of air pollution, contributing with 35 % and 12.5 % to the annual exposure to NO2 and PM2.5, respectively, and that the regional shipping outside the city was responsible for 20 % and 10 % of the NO2 and PM2.5 exposure, contributing more than the local shipping in and around the harbours. According to the study of Karl et al (2019a), the introduction of the SECA with a fuel Sulphur limit of 0.1 % decreased the exposure to PM2.5 at the Swedish West coast by approximately 35 %.…”

Section: Introductionmentioning

confidence: 96%

“…However, the abatement measures considered as well as the methods used differ from our approach. The first part of our study (Tang et al, 2020) gives a brief overview of previous studies about impacts of shipping emissions on air quality and health at the Swedish west coast. It provides discussion on how the legislation changed between the base year used in our study (2012) and the situation today.…”

Section: Introductionmentioning

confidence: 99%

“…This paper is the second part of a study about the current and future air quality situation in the Gothenburg urban area. Part 1 by Tang et al (2020) is published in the same spacial issue.…”

Section: Introductionmentioning

confidence: 99%

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The impact of ship emissions on air quality and human health in the Gothenburg area – Part II: Scenarios for 2040

Ramacher¹,

Tang²,

Moldanová³

et al. 2020

Preprint

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Abstract. Shipping is an important source of air pollutants, from the global to the local scale. Ships are emitting substantial amounts of sulphur dioxides, nitrogen dioxides and particulate matter in the vicinity of coasts, threatening the health of the coastal population, especially in harbour cities. Reductions of emissions due to shipping have been targeted by several regulations. Nevertheless, effects of these regulations come into force with temporal delays, global ship traffic is expected to grow in the future, and other land-based anthropogenic emissions might decrease. Thus, it is necessary to investigate combined impacts to identify the impact of shipping activities on air quality, population exposure and health-effects in the future. We investigated the future effect of shipping emissions on air quality and related health effects considering different scenarios of the development of shipping under current regional trends of economic growth and already decided regulations in the Gothenburg urban area in 2040. Additionally, we investigated the impact of a large-scale implementation of shore electricity in the port of Gothenburg. For this purpose, we established a one-way nested chemistry transport modelling (CTM) system from the global to the urban scale, to calculate pollutant concentrations, population weighted concentrations and health-effects related to NO2, PM2.5 and O3. The simulated concentrations of NO2 and PM2.5 in future scenarios for the year 2040 are in general very low with up to 4 ppb for NO2 and up to 3.5 µg/m3 PM2.5 in the urban areas which are not close to the port area. From 2012 the simulated overall exposure to PM2.5 decreased by approximately 30 % in simulated future scenarios, for NO2 the decrease was over 60 %. The simulated concentrations of O3 increased from year 2012 to 2040 by about 20 %. In general, the contributions of local shipping emissions in 2040 focus on the harbour area but to some extent also influence the rest of the city domain. The simulated impact of wide use of shore-site electricity for shipping in 2040 shows reductions for NO2 in the port with up to 30 %, while increasing O3 of up to 3 %. Implementation of on-shore electricity for ships at berth leads to additional local reduction potentials of up to 3 % for PM2.5 and 12 % for SO2 in the port area. All future scenarios show substantial decreases in population weighted exposure and health-effect impacts.

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Section: Introductionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

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The impact of ship emissions on air quality and human health in the Gothenburg area – Part II: Scenarios for 2040

Ramacher¹,

Tang²,

Moldanová³

et al. 2020

Preprint

Self Cite

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“…In combination with no exceedances of measured PM2.5 limit values in 2012 in any of the domains and large negative BIAS for PM2.5 due to underestimated regional background concentrations, we decided not to show the total air quality and contribution of shipping to PM2.5 here and in the exposure evaluation. Besides this, a study in preparation (Tang et al 2019) for the city of Gothenburg, showed a small impact of local shipping to PM2.5 contribution (0.07 µg m -³) but higher PM2.5 contribution from regional shipping (0.49 µg m -³).…”

Section: Predicted Concentrations and Impact Of Shipping On No2 In 2012mentioning

confidence: 88%

“…The same regional CTM system was used in a study in preparation (Tang et al, 2019) to perform local CTM simulations in the Gothenburg area with the chemistry transport module of TAPM but with a different preparation of boundary concentrations from CMAQ: TAPM allows just 1-d boundary concentration fields with time being the only variable, and therefore the TAPM boundary concentrations were calculated using horizontal wind components on each of the four lateral boundaries for weighting the boundary concentrations. Matthias et al (2018) have discussed the necessity to utilize emission data in high spatial and temporal resolution on a coordinate grid that is in agreement with the CTM grid, due to emission data being probably the most important input for chemistry transport model (CTM) systems.…”

Section: Boundary Conditionsmentioning

confidence: 99%

Urban population exposure to NOx emissions from local shipping in three Baltic Sea harbour cities – a generic approach

Ramacher¹,

Karl²,

Jalkanen³

et al. 2019

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Abstract. Ship emissions in ports can have a significant impact on local air quality (AQ), population exposure, and therefore human health in harbour cities. We determined the impact of shipping emissions on local AQ and population exposure in the Baltic Sea harbour cities Rostock (Germany), Riga (Latvia) and the urban agglomeration of Gdansk-Gdynia (Poland) for 2012. An urban AQ study was performed using a global-to-local Chemistry Transport Model chain with the EPISODE-CityChem model for the urban scale. We simulated NO2, O3 and PM concentrations in 2012 with the aim to determine the impact of local shipping activities to outdoor population exposure in Baltic Sea harbour cities. Based on simulated concentrations, dynamic population exposure on outdoor NO2 concentrations for all urban domains was calculated. We developed and used a novel generic approach to model dynamic population activity in different microenvironments based on publicly available data. The results of the new approach are hourly microenvironment-specific population grids with a spatial resolution of 100&#8201;&#215;&#8201;100&#8201;m2. We multiplied these grids with surface pollutant concentration fields of the same resolution to calculate total population exposure. We found that the local shipping impact on NO2 concentrations is significant, contributing with 22&#8201;%, 11&#8201;%, and 16&#8201;% to the total annually averaged grid mean concentration for Rostock, Riga and Gdansk-Gdynia, respectively. For PM2.5, the contribution of shipping is substantially lower with 1&#8211;3&#8201;%. When it comes to microenvironment-specific exposure to annual NO2, the highest exposure to NO2 from all emission sources was found in the home environment (54&#8211;59&#8201;%). Emissions from shipping have a high impact on NO2 exposure in the port area (50&#8211;80&#8201;%) while the influence in home, work and other environments is lower on average (3&#8211;14&#8201;%), but still with high impacts close to the port areas and downwind of them. Besides this, the newly developed generic approach allows for dynamic population exposure calculations in European cities without the necessity of individually measured data or large-scale surveys on population data.

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Possible influence of shipping emissions on metals in size-segregated particulate matter in Guanabara Bay (Rio de Janeiro, Brazil)

Silveira

Corrêa

Neto

2022

Environ Monit Assess

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In the world of growing maritime fleets, ships powered by fossil fuels are being widely used that are responsible for atmospheric emissions such as particulate matter (PM). When inhaled, these can cause serious injury to the body and affect internal organs, because the particle size is on a tiny scale. The International Convention for the Prevention of Pollution from Ships (MARPOL) regulates the standards for emissions from marine diesel engines. However, although they pose risks to human health and the environment, the metals present in PM are not covered by Brazilian national current legislation. This study is based on the results of sampling of PM in the atmosphere of Guanabara Bay, Rio de Janeiro, Brazil, by means of the MOUDI cascade impactor, followed by acid opening of the collected PM and subsequent chemical analysis by ICP-MS for the determination of Ba, Ca, Cd, Co, Cu, Cr, Fe, Mg, Mn, Ni, Pb, V, and Zn. In coarse particles, the mean values ranged from 0.11 ng m −3 for Ba to 24.9 ng m −3 for Fe; in fine particles, from 0.07 ng m −3 for Co to 25.0 ng m −3 for Fe; and in ultrafine particles, from 0.11 ng m −3 for Ba to 9.71 ng m −3 for Fe. Finally, the nanoparticles (Ba and Ca) were not detected and the maximum value obtained was 5.32 ng m −3 for Mn.

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The impact of ship emissions on air quality and human health in the Gothenburg area – Part 1: 2012 emissions

Cited by 40 publications

References 37 publications

The impact of ship emissions on air quality and human health in the Gothenburg area – Part II: Scenarios for 2040

The impact of ship emissions on air quality and human health in the Gothenburg area – Part II: Scenarios for 2040

Urban population exposure to NO<sub>x</sub> emissions from local shipping in three Baltic Sea harbour cities – a generic approach

Possible influence of shipping emissions on metals in size-segregated particulate matter in Guanabara Bay (Rio de Janeiro, Brazil)

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The impact of ship emissions on air quality and human health in the Gothenburg area – Part 1: 2012 emissions

Cited by 40 publications

References 37 publications

The impact of ship emissions on air quality and human health in the Gothenburg area – Part II: Scenarios for 2040

The impact of ship emissions on air quality and human health in the Gothenburg area – Part II: Scenarios for 2040

Urban population exposure to NO&lt;sub&gt;x&lt;/sub&gt; emissions from local shipping in three Baltic Sea harbour cities – a generic approach

Possible influence of shipping emissions on metals in size-segregated particulate matter in Guanabara Bay (Rio de Janeiro, Brazil)

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Product

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Urban population exposure to NO<sub>x</sub> emissions from local shipping in three Baltic Sea harbour cities – a generic approach