Heavy metal emissions in Europe

Heavy metals accumulate in ecosystems and damage human health. In accordance with the European Union’s commitments under the Air Convention, specific legislation led to reductions in emissions of heavy metals across Europe from 1990 levels. Between 2005 and 2022, emissions have continued to decline, with lead emissions decreasing by 44%, mercury emissions by 53% and cadmium emissions by 39% across the EU-27 Member States. Germany, Italy and Poland contributed the most to heavy metal emissions during 2022 within the EU.

Percentage emission reductions in 2022 of primary heavy metals compared with 2005 levels

Heavy metals such as cadmium (Cd), mercury (Hg) and lead (Pb) are toxic to human health, animals and plants. Ambient air concentrations are above limit values in only a few areas in Europe. These are typically linked to specific industrial plants. The atmospheric deposition of heavy metals leads to exposure of ecosystems and organisms and bioaccumulation in the food chain, with damaging effects on human health. Reducing emissions of heavy metals is therefore a focus of international and EU action.

The EU is a party to the Air Convention, a pan-European framework for reducing air pollution including heavy metals (under the Aarhus Protocol). Releases of mercury (Hg) are also controlled by the United Nations Environment Programme Minamata Convention.

Improvements in abatement technologies and targeted legislation, such as the Industrial Emissions Directive and the European Industrial Emissions Portal Regulation, have contributed to good progress being made in reducing heavy metal emissions.

The 1998 Aarhus Protocol was amended in 2012, with more stringent controls on heavy metals introduced. Moreover, in 2016, the EU’s National Emission reduction Commitments Directive (NECD) presented new reporting requirements for Member States, including the requirement to provide annual inventories of heavy metal emissions.

Between 2005 and 2022, emissions of Cd, Hg and Pb declined in the EU-27 Member States by 39%, 53% and 44%, respectively. The industrial processes and product use sector still accounts for the majority of Cd, Hg and Pb emissions (52%, 42% and 58%, respectively). However emissions from this sector have declined since 2005, with both Hg and Pb emissions declining by 40% and 42% respectively.

The industrial processes and product use sector grouping refers to emissions from industrial sources other than those arising from fuel combustion within the industrial sector. Declines in emissions from the energy supply sector are also notable, with Cd and Hg emissions declining by 26% and 8%, respectively. The sharp decline in heavy metal emissions between 2008 and 2009 coincides with the economic downturn at that time.

Percentage emission reductions of primary heavy metals of EU Member States in 2022 compared with 2005 levels

Between 2005 and 2022, most EU-27 Member States reduced their heavy metals emissions. Emission increases of heavy metals seen during this period are not necessarily cause for concern. They reflect relatively small increases in absolute emissions from low baseline levels, for instance in the cases of Austria, Bulgaria, Estonia, Ireland, Latvia, Lithuania and Poland.

In 2022, the countries with the highest emissions were Germany, Poland, Spain and Italy, accounting for around half of total EU emissions for all three heavy metals. However, these Member States have reduced their emissions of all three heavy metals since 2005.

Supporting information

Definition

This indicator tracks trends in anthropogenic emissions of heavy metals over time, since 2005. Heavy metals (such as Cd, Hg and Pb) are known to be directly toxic to biota. All heavy metals are progressively accumulated relatively high up the food chain, such that chronic exposure of lower organisms to relatively low concentrations of heavy metals can lead to the exposure of predatory organisms, including humans, to potentially harmful concentrations. They are of concern for human health because of their toxicity, their potential to cause cancer and their ability to cause harmful effects even at low concentrations. Their toxic/carcinogenic potencies are metal/compound specific.

Methodology

Methodology for indicator calculation

This indicator is based on the national total and sectoral emissions data that were officially reported to the EEA and the UNECE/Co-operative Programme for Monitoring and Evaluation of the Long-range Transmission of Air Pollutants in Europe (EMEP) LRTAP Convention in 2024 For the 27 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 included in the EMEP/EEA air pollutant emission inventory guidebook. Base data are available from the EEA Data Service. Where necessary, gaps in reported data are filled by the European Environment Agency using Methodology for gap-filling (see below). The final gap-filled data used in this indicator are available from the EEA DataHub.

Methodology for gap filling
An improved gap-filling methodology was implemented in 2010 that enables a complete time-series trend for the main air pollutants to be compiled. Where countries did not report emissions for any year, it meant that gap filling could not be performed. 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 the European Union emission inventory report 1990-2022 under the UNECE Convention on Long-range Transboundary Air Pollution (LRTAP).

References

CEIP, 2021, ‘EMEP Centre on Emission Inventories and Projections’, Centre on Emission Inventories and Projections (https://www.ceip.at) accessed 8 August 2024.

EEA, 2023, EMEP/EEA air pollutant emission inventory guidebook 2023 — technical guidance to prepare national emission inventories, EEA Report No 06/2023, European Environment Agency (https://www.eea.europa.eu/publications/emep-eea-guidebook-2023).

EEA, 2024, Europe’s air quality status 2024, Briefing no. 06/2024, European Environment Agency (https://www.eea.europa.eu//publications/europes-air-quality-status-2024) accessed 1 April 2024.

EEA, 2024, European Union emission inventory report 1990-2022, under the UNECE Convention on Long-range Transboundary Air Pollution (LRTAP), EEA Report No 5/2021, European Environment Agency (https://www.eea.europa.eu/publications/european-union-emissions-inventory-report-1990-2022) accessed 8 August 2024.

EEA, 2024, ‘National emissions reported to the Convention on Long-range Transboundary Air Pollution (LRTAP Convention)’, European Environment Agency (https://www.eea.europa.eu/en/topics/in-depth/air-pollution/air-pollutant-emissions-data-viewer-1990-2022) accessed 8 August 2024.

UNECE, 2024, ‘Air’ (https://unece.org/environment-policy/air) accessed 8 August 2024.

UNECE, 2021b, ‘Protocol on heavy metals’, United Nations Economic Commission for Europe (https://unece-modl.dotsoft.gr/environment-policyair/protocol-heavy-metals) accessed 8 August 2024.

UNEP, 2021, ‘UN Environment Programme — Minamata Convention on Mercury’, United Nations Environment Programme (http://www.mercuryconvention.org) accessed 8 August 2024.

Policy/environmental relevance

In particular, exposure to heavy metals has been linked to developmental retardation, various cancers, kidney damage and even death in some instances of exposure to very high concentrations. The heavy metals that cause these effects are already a focus of international and EU action. Their possible carcinogenic, immunological and reproductive effects are of major concern, but more recently concern has also been expressed over their possible harmful effects on human development.

Coupled with improved control and abatement techniques, targeted international and EU legislation has led to good progress being made in most EEA member countries towards reducing heavy metal emissions. Such legislation includes:

the 1998 Aarhus Protocol on Heavy Metals (under the 1979 United Nations Economic Commission for Europe (UNECE) LRTAP Convention), which targets three particularly harmful substances — Cd, Hg and Pb — and obliges parties to reduce their emissions of these heavy metals from 1990 levels (or an alternative year from 1985 to 1995 inclusive);

the new Industrial and Livestock Rearing Emissions Directive 2024/1785 (IED 2.0) is the main EU instrument to reduce these emissions into air, water and land, and to prevent waste generation from large industrial installations and intensive livestock farms (pig and poultry). It amends Directive 2010/75/EU industrial emissions (integrated pollution prevention and control), which aimed to prevent or minimise pollution of water, air and soil; this directive targets certain industrial, agricultural and waste treatment installations;

the European Pollutant Release and Transfer Register (E-PRTR) Regulation (166/2006/EC), under the requirements of which emissions of a number of heavy metals released from certain industrial facilities are estimated and reported;

Directive 2008/50/EC on ambient air quality and cleaner air for Europe and Directive 2004/107/EC relating to heavy metals and polycyclic aromatic hydrocarbons in ambient air, which contain provisions, and target and limit values for the further control of air pollutants in ambient air.

There are also several specific EU environmental quality and emission standards for heavy metals 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 the Water Framework Directive (Directive 2000/60/EC).

Other measures include restrictions on the use of heavy metals in certain consumer products, such as Regulation (EC) No 1102/2008 on the banning of exports of metallic mercury and certain mercury compounds and mixtures, and the safe storage of metallic mercury, as well as Directive 2007/51/EC amending Council Directive 7/769/EEC relating to restrictions on the marketing of certain measuring devices containing mercury.

The Minamata Convention on Mercury — a global, legally binding treaty — was agreed on by governments in January 2013 and formally adopted as international law on 10 October 2013.

Targets

No targets have been specified.

Methodology uncertainty

The use of gap filling for countries that have not reported emissions for one or more years can potentially lead to artificial trends but is considered unavoidable for obtaining a comprehensive and comparable set of emissions data for European countries for policy analysis purposes.

Data sets uncertainty

The certainty of the emissions data for Pb varies over the time series. This is because different source sectors have dominated at different times as a result of the very significant reductions in emissions from key sources in 1990, notably from the road transport sector. The Pb emission estimates from key sources in 1990 were based on measured concentrations of Pb in fuels, which were tightly regulated prior to being phased out in the late 1990s. This gives a high degree of confidence in the estimates for the fuel combustion sources that dominated emissions in the early 1990s but are now much reduced. In more recent years, to which this indicator relates, the level of emissions is estimated to be very much lower, and emissions are derived from a smaller number of sources. The metal processing industries are mainly regulated under the Integrated Pollution Prevention and Control (IPPC) Directive and the estimates provided by plant operators are based on emission measurements or emission factors that have been researched for the specific process type, and are, therefore, likely to be relatively accurate. Emissions from other smaller scale combustion and process sources from industrial and commercial activities are less well documented and the estimates are based on emission factors that are less certain.

Rationale uncertainty

This indicator is regularly updated by the EEA and is used in state-of-the-environment assessments. The uncertainties related to the methodology and the data sets are therefore of importance. Any uncertainties in the calculations and data sets need to be accurately communicated in the assessment, to prevent erroneous information from influencing policy actions or processes.

Data sources and providers

Metadata

DPSIRTopicsTagsTemporal coverageGeographic coverage

TypologyUN SDGsUnit of measureFrequency of dissemination

References and footnotes

EU, 2006, Regulation (EC) No 166/2006 of the European Parliament and of the Council of 18 January 2006 concerning the establishment of a European Pollutant Release and Transfer Register and amending Council Directives 91/689/EEC and 96/61/EC

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EU, 2008, Directive 2008/50/EC of the European Parliament and of the Council of 21 May 2008 on ambient air quality and cleaner air for Europe

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EU, 2004, Directive 2004/107/EC of the European Parliament and of the Council of 15 December 2004 relating to arsenic, cadmium, mercury, nickel and polycyclic aromatic hydrocarbons in ambient air

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EU, 2000, Directive 2000/60/EC of the European Parliament and of the Council of 23 October 2000 establishing a framework for community action in the field of water policy, OJ L 327, 22.12.2000, p. 1-73.

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EU, 2008, Regulation (EC) No 1102/2008 of the European Parliament and of the Council of 22 October 2008 on the banning of exports of metallic mercury and certain mercury compounds and mixtures and the safe storage of metallic mercury

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EU, 2007, Directive 2007/51/EC of the European Parliament and of the Council of 25 September 2007 amending Council Directive 76/769/EEC relating to restrictions on the marketing of certain measuring devices containing mercury, OJ L 257, 3.10.2007, p. 13–15.

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EU, 2008, Directive 2008/1/EC of the European Parliament and of the Council of 15 January 2008 concerning integrated pollution prevention and control

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