Emissions of air pollutants from transport in Europe

With the introduction of targeted policies and measures in recent decades, the emission of most air pollutants from transport in the EU-27 has decreased. Reductions in the road transport sector account for the greatest share of this progress, while emissions from shipping and aviation increased for some pollutants. The dramatic reduction in transport volumes linked to the COVID-19 pandemic led to significant but only temporary reductions in emissions, and an upturn in pollution from transportation is already visible for 2021 and 2022 alongside the rebound of transport volumes.

Pollutants emitted by transport activities contribute to ambient air pollution and put significant pressure on the environment and human health in Europe. In recent decades, significant policy efforts have addressed transport-related air pollution from various transport modes (road transport, rail, aviation, maritime) and have led to some notable improvements.

Together, such policies have delivered progress in reducing the emissions of many pollutants from the transport sector. Between 1990 and 2022, emissions of nitrogen oxides (NO_x) from transport across the EU-27 decreased by 51%, sulphur oxides (expressed as SO₂) by 82%, carbon monoxide (CO) by 90%, methane (CH₄) and non-methane volatile organic compounds (NMVOCs) by 76% and 91% respectively. In the same time frame, transport emissions of particulate matter (including non-exhaust emissions) with particle diameter of 10µm/2.5µm or less (PM_10/2.5) decreased by 46%/58%, respectively.

The onset of the COVID-19 pandemic had an influence on these figures, due to the significant reduction in transport volumes during 2020. However, many of the pollutant levels have rebounded.

At the same time, two air pollutants have demonstrated substantial growth in recent decades. Between 1990 and 2022, transport emissions of ammonia (NH₃) increased by 121% (138% in 1990-2019) while nitrous oxide (N₂O) increased by 35%. Although transport contributions of NH₃ emissions are limited compared to other sectors such as agriculture, their impact on air quality, especially within cities, is reported to be very high. While a powerful greenhouse gas, N₂O is also currently considered a dominant ozone depleting substance .

Although most pollutant emissions declined since 1990, the situation is uneven across transport modes. This in part reflects differences in the stringencies of emissions standards.

Road transport has significantly reduced its pollutant emissions since 1990, with the exception of compounds NH₃ and N₂O. Their recent increase is mainly due to new catalytic systems for the reduction of NO_x in diesel engines and the use of enriched fuel mixtures to control NO_x at high load in petrol engines . While a significant reduction can be seen for both PM₁₀ and PM_2.5, the non-exhaust fraction of these emissions (i.e. from brake and tyre wear or road abrasion) is increasing in percentage and constituted 75% and 59% of PM₁₀ and PM_2.5 emissions from road transport in 2022. Non-exhaust emissions will become even more relevant with the progressive decarbonisation of the sector and increases in vehicles mass due to batteries.

Variations (1990-2022) in the emissions of pollutants from transport by mode in EU-27

Emissions from the aviation sector (i.e. including domestic and international), increased for most pollutants, with the exception of CH₄, CO, NMVOC, rebounding after the significant contraction in traffic volumes that occurred during the COVID-19 pandemic. Increases in emissions since 1990 ranged between 47% and 117%, depending on the compound considered.

Differences exist between domestic and international aviation trends for some pollutants (Figure 2). This can be partially explained by the difference in demand evolution and the technology used in domestic and international aviation. The aviation sector's reduction of air pollutant emissions is mainly done at engine design level since the application of advanced aftertreatment systems (as mentioned above) is technologically very challenging.

Maritime sector emissions from domestic navigation decreased during 1990-2022, for all pollutants considered (excluding CH₄, which increased by 7%). These reductions range between 88.7% and 0.3%, depending on the compound considered. Conversely, in international navigation most pollutants have increased, aside from PM₁₀, PM_2.5 and SO₂. This increase in emissions ranged between 5% and 58%, depending on the compound considered. In the maritime sector, many of the pollution reduction technologies already developed in the road sector could in principle be adapted to marine diesel engines. This would yield a significant reduction in air pollutants emissions from the sector with clear environmental benefits.

Supporting information

DefinitionMethodology

For CO, NO_x, NMVOC, SO_x, NH₃, PM₁₀ and PM_2.5, data officially reported to the European Monitoring and Evaluation Programme (EMEP)/LRTAP Convention were used. For CH₄ and N₂O data officially reported under the United Nations Framework Convention on Climate Change (UNFCCC) and also under the Kyoto Protocol (KP) were used.

Where a complete time series of emission data has not been reported for CO, NO_x, NMVOC, SO_x, NH₃, PM₁₀ and PM_2.5, data have been gap filled according to the methodologies of the European Environment Agency's (EEA's) European Topic Centre on Air and Climate Change (ETC/ACC). Details of the gap-filling procedure for the air pollutant data set are described in the EU emission inventory report under the UNECE's Convention on LRTAP. Similarly, for CH₄ and N₂O additional information on the gap-filling procedure can be found in the Annual European Union greenhouse gas inventory and inventory report Submission to the UNFCCC Secretariat.

Policy/environmental relevance

The mobility system contributes to overall air pollution emissions and air quality deterioration across Europe. Additional information on its relative contribution to the overall situation in Europe can be found by consulting the EEA interactive data viewer, while up-to-date information on air quality in Europe can be found in the EEA interactive maps.

For instance, since 2008, the Ambient air quality Directive has set limits or target values for concentrations of pollutants in the ambient air, while the NEC Directive has set emission reduction commitments since 2016 for total national emissions for five air pollutants (NO_x, SO₂, NMVOC, NH₃ and PM_2.5). Recently, the European Commission proposed a revision of the Ambient air quality Directive, to more closely align air quality standards with WHO guidelines, while putting the EU on a trajectory to achieve the zero pollution ambition by 2050.

Emissions from the transport sector are further regulated by vehicle emissions standardsand fuel quality requirements . Local and regional air quality management plans, including initiatives such as low-emission zones and congestion charges in cities, are active in many areas. SO_x and NO_x emissions from international shipping are regulated by Annex VI to MARPOL Convention of the International Maritime Organisation. SO_x requirements are transposed in EU law by the Directive on sulphur content in certain liquid fuels including marine fuels. Aviation emission of NO_x and nvPM are regulated at ICAO level.

Transport emissions of ammonia (NH₃) and nitrous oxide (N₂O) are increasing and are of concern: NH₃ emitted within the cities have a very high impact on air quality; N₂O, beside a powerful greenhouse gas, is also currently considered a dominant ozone depleting substance. Both these pollutants are currently unregulated.

Accuracy and uncertainties

For CO, NO_x, NMVOC, SO_x, NH₃, PM₁₀ and PM_2.5, data officially reported to the European Monitoring and Evaluation Programme (EMEP)/LRTAP Convention were used. For CH₄and N₂O data officially reported under the United Nations Framework Convention on Climate Change (UNFCCC) and also under the Kyoto Protocol (KP) were used.

Where a complete time series of emission data has not been reported for CO, NO_x, NMVOC, SO_x, NH₃, PM₁₀ and PM_2.5, data have been gap filled according to the methodologies of the European Environment Agency's (EEA's) European Topic Centre on Air and Climate Change (ETC/ACC). Details of the gap-filling procedure for the air pollutant data set are described in the EU emission inventory report 1990-2021 under the UNECE's Convention on LRTAP. Similarly, for CH₄ and N₂O additional information on the gap-filling procedure can be found in the Annual European Union greenhouse gas inventory 1990–2021 and inventory report 2022 Submission to the UNFCCC Secretariat.

Data sources and providers

Metadata

DPSIRTopicsTagsTemporal coverageGeographic coverage

TypologyUN SDGsUnit of measureFrequency of dissemination

References and footnotes

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Emissions of air pollutants from transport in Europe

Figure 1. Emissions of pollutants from transport in EU-27

Figure 2. Variations (1990-2022) in the emissions of pollutants from transport by mode in EU-27

Supporting information

Metadata

References and footnotes