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Indicator Assessment
Emission trends of persistent organic pollutants (EEA member countries - indexed 1990 = 100)
In the EEA-32 region, emissions of PAHs have fallen by 52% between 1990 and 2010 (Figure 1). A combination of targeted legislation, details of which are set out in the 'Indicator specification - policy context' section, coupled with improved controls and abatement techniques has led in general to significant progress being made in most countries to reduce PAH emissions (Figure 2-6).
While the majority of individual countries report decreased PAH emissions since 1990, there are six countries (Denmark, Iceland, Estonia, Italy, Latvia and Lithuania) in which emissions have increased by 10% or more. Of these countries, emissions in Denmark and Iceland have more than doubled since 1990. One cause of these increased emissions has been due to the introduction of policy measures that have encouraged the burning of renewable materials (e.g. wood by Danish households). Wood-burning produces emissions of PAHs, and hence in this instance policies that have been implemented to address one environmental issue (climate change) have had unintended consequences in terms of air pollution. In absolute terms, emissions of PAHs from both countries are relatively low compared to other countries, but the effect on local population and environmental quality may nevertheless be notable. Of the EEA-32 group of countries, the largest PAH emissions are reported by Spain and Germany, where emissions are more than 11 times greater than in Denmark.
Emissions of HCB have fallen sharply in the EEA-32 since 1990, mostly due to a drop in HCB emissions in the United Kingdom of 4.3 tonnes between 1998 and 1999, accounting for 98% of the EEA-32 emissions decrease in 1999. This large decrease was due to the introduction of regulations in the UK to control the use of hexachloroethane (HCE) tablets as a degassing agent in secondary aluminium production. Across all EEA-32 countries, the decrease in 1999 accounts for 91% of the overall change in HCB emissions between 1990 and 2010. 64% of the reduction across all EEA-32 countries since 1990 is due to the fall in HCB emissions in the United Kingdom since 1990.
HCH emissions in EEA-32 countries have fallen overall by 93% from 1990 to 2010 (Figure 1); only Belgium has reported increases in emissions. Of the overall decrease in emissions, 45% may be accounted for by decreased emissions from the 'Agriculture' sector, 33% from 'Industrial processes', and 23% from 'Solvent and product use'. In 2010, 33% of emissions of HCH were from 'Agriculture' sources.
Emissions of PCBs in the EEA-32 have fallen 74% between 1990 and 2010, due mainly to reductions in 'Industrial processes' emissions, which accounted for 85% of the decrease over this period. Within the EEA-32, the only countries in which PCB emissions have risen from 1990 levels are Estonia, Portugal and Sweden. 18 countries reported lower emissions in 2010 than 1990, and the remaining 11 countries either did not report data, or reported zero emissions for 1990.
EEA-32 countries' reported emissions of dioxins & furans show a decrease of 83% by 2010 when compared with 1990 levels. Of 30 countries which reported non-zero emissions, only Latvia and Liechtenstein reported an increase in emissions from 1990 to 2010. The overall decrease in emissions across all EEA-32 countries was due to significantly reduced emissions from the 'Energy production and distribution' sector (29% of overall decrease), 'Waste' (23%) and 'Commercial, institutional and households' (20%). In 2010, 37% of dioxin and furan emissions were from sources in the sectors 'Commercial, institutional and households', 18.2% from 'Energy use in industry' and 18.0% from 'Waste'.
Contribution to total change in PAH emissions for each sector between 1990 and 2010 (EEA member countries)
Note: The contribution made by each sector to the total change in emissions of selected persistent organic pollutants (POPs) between 1990 and 2010: HCB - hexachlorobenzene, HCH - hexachlorocyclohexane, PCBs - polychlorinated biphenyls; dioxins & furans; and PAHs - polyaromatic hydrocarbons.
Sector split of emissions of selected POPs in 2010 (EEA member countries)
Important emission sources of POPs typically include residential combustion processes (open fires, coal and wood burning for heating purposes etc.), industrial metal production processes, and the road transport sector (Figure 5).
Emissions from each of these sources have in general declined since 1990 as a result of decreased residential use of coal, improvements in abatement technologies for metal refining and smelting, and stricter regulations on emissions from the road transport sector (Figure 4). In particular, the majority of the PAH emission reduction observed in Europe since 1990 has been due to reduced emissions from within the industrial processes sector (Figure 4). This reflects various initiatives designed to reduce the formation and emission of (unintended) POPs through improved process design, control and pollution abatement technology.
The units used in this indicator are the tonne (metric ton).
Targeted European Commission legislation (directives and regulations), coupled with improved control and abatement techniques, have led to good progress being made by the EEA-33 countries towards reducing air emissions of POPs, including the PAH group of chemicals. Such legislation is described below.
In May 2009, additional chemicals were added to the Stockholm Convention:
The EC Communication on a Community Strategy for Dioxins, Furans and PCBs (COM (2001) 593 final) aims to assess the current state of the environment and to reduce human exposure and long-term environmental effects. This communication does not propose legislative measures, but could be the basis for a Community action plan.
The Directive on the Limitation of Emissions of Certain Pollutants into the Air from Large Combustion Plants (2001/80/EC) has had the effect of reducing heavy metal and PAH emissions via dust control and absorption.
Regulation (EC) No 850/2004 on Persistent Organic Pollutants entered into force on 20 May 2004. The main purpose of this regulation is to enable the European Community to ratify the Stockholm Convention and the Aarhus Protocol. The regulation also deals with stockpiles of redundant substances.
Emissions of a number of heavy metals released from certain industrial facilities are also estimated and reported under the requirements of the European Pollutant Release and Transfer Register Regulation (E-PRTR) (166/2006/EC).
The EU Directive on Ambient Air Quality and Cleaner Air for Europe (2008/50/EC) and Directive 2004/107/EC relating to heavy metals and polycyclic aromatic hydrocarbons in ambient air contain provisions, and target and limit values for the further control of air pollutants in ambient air.
There are also a number of specific EU environmental quality and emission standards for heavy metals and POPs in coastal and inland waters, drinking waters, etc. These have only indirect relevance to air emissions as they do not directly specify emission or precipitation quality requirements, but rather specify the required quality of receiving waters. Such measures include Directive 84/491/EEC on HCH discharges; Directives 76/464/EC and 86/280/EC on dangerous substances; and the Water Framework Directive (2000/60/EC).
As noted above, the Aarhus Protocol on POPs to the UNECE LRTAP Convention obliges parties to reduce their emissions of dioxins, furans, PAHs and HCB to below their 1990 levels (or an alternative year between 1985 and 1995 inclusive).
This indicator is based on the national total and sectoral emissions officially reported to the EEA and UNECE/EMEP (United Nations Economic Commission for Europe/Co-operative programme for monitoring and evaluation of the long-range transmission of air pollutants in Europe) LRTAP Convention. For the EU-28 Member States, the data used are consistent with the emissions data reported by the EU in its annual submission to the LRTAP Convention.
Recommended methodologies for emission inventory estimation are compiled in the EMEP/EEA Air Pollutant Emission Inventory Guidebook (EMEP/EEA, 2016). Base data are available from the EEA Data Service and the EMEP web site. If necessary, gaps in reported data are filled by the European Topic Centre for Air and Climate Change using simple interpolation techniques (see below). The final gap-filled data used in this indicator are available from the EEA Data Service .
Base data, reported in the UNECE/EMEP nomenclature for reporting (NFR14) sector format, are aggregated into the following EEA sector codes to obtain a consistent reporting format across all countries and pollutants:
The following table shows the conversion of NFR sector codes used for reporting by countries into EEA sector codes:
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An improved gap-filling methodology was implemented in 2010 that enables a complete time-series trend for the main air pollutants (nitrogen oxides (NOx), sulphur oxides (SOx), non-methane volatile organic compounds (NMVOCs), ammonia (NH3) and carbon monoxide (CO)) to be compiled. In cases in which countries did not report emissions for any year, it meant that gap filling could not be applied. For these pollutants, therefore, the aggregated data are not yet complete and are likely to underestimate true emissions. Further methodological details of the gap-filling procedure are provided in section 'Data gaps and gap-filling' of the European Union emission inventory report 1990–2017 under the UNECE Convention on Long-range Transboundary Air Pollution (LRTAP).
The use of gap filling for countries that have not reported emissions for one of more years can potentially lead to artificial trends, but it is considered unavoidable if a comprehensive and comparable set of emission data for European countries is required for policy analysis purposes.
Uncertainties in the emission estimates of PAHs reported by countries are considered to be higher than for other more 'traditional' air pollutants, such as NOx and SO2, because of the relatively high uncertainties that exist with regard to both activity data and emission factors for this group of pollutants. Emission estimates for the other POPs are also considered to have a high degree of uncertainty.
This indicator is regularly updated by the EEA and is used in state of the environment assessments. The uncertainties related to methodology and data sets are therefore important. Any uncertainties involved in the calculation and the data sets must be accurately communicated in the assessment, in order to prevent erroneous messages from influencing policy actions or processes.
For references, please go to https://www.eea.europa.eu/data-and-maps/indicators/eea32-persistent-organic-pollutant-pop-emissions-1/assessment-2 or scan the QR code.
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