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Indicator Specification
Emissions of non-methane volatile organic compounds (NMVOCs), nitrogen oxides, carbon monoxide and methane contribute to the formation of ground-level (tropospheric) ozone.
Ozone is a powerful oxidant and tropospheric ozone can have adverse effects on human health and ecosystems. It is a problem mainly during the summer months. High concentrations of ground-level ozone adversely affects the human respiratory system and there is evidence that long-term exposure accelerates the decline in lung function with age and may impair the development of lung function. Some people are more vulnerable to high concentrations than others, with the worst effects generally being seen in children, asthmatics and the elderly. High concentrations in the environment are harmful to crops and forests, decreasing yields, causing leaf damage and reducing disease resistance.
Detailed information on individual acidifying pollutant emissions may also be found in the accompanying indicator fact-sheets for nitrogen oxides and non-methane volatile organic compounds.
ktonnes (1000 tonnes)
Within the European Union, the National Emission Ceilings Directive (NEC Directive) imposes emission ceilings (or limits) for emissions of NOX and NMVOCs (the NEC Directive also sets emissions ceilings for ammonia NH3 and sulphur dioxide SO2). There are no specific EU emission targets set for either carbon monoxide (CO) or methane (CH4). However, there are several Directives and Protocols that affect the emissions of CO and CH4. Methane is included in the basket of six greenhouse gases under the Kyoto protocol (see CSI 010: Greenhouse gas emissions and removals).
Internationally, the issue of air pollution emissions is also being addressed by the UNECE Convention on Long-range Transboundary Air Pollution (the LRTAP Convention) and its protocols. A key objective of the protocol is to regulate emissions on a regional basis within Europe and to protect eco-systems from transboundary pollution by setting emission reduction ceilings to be reached by 2010 for the same 4 pollutants as addressed in the NECD (i.e. SO2, NOX, NH3 and NMVOCs). Overall for the EU Member States, the ceilings set within the Gothenburg protocol are generally either slightly less strict or the same as the emission ceilings specified in the NECD.
Emissions of NOXand NMVOC are covered by the EU National Emission Ceilings Directive (NECD) (2001/81/EC) and the Gothenburg protocol under the United Nations Convention on Long-Range Transboundary Air Pollution (LRTAP Convention) (UNECE 1999). The NECD generally involves slightly stricter emission reduction targets than the Gothenburg Protocol for EU-15 Member States for the period 1990-2010.
Table: 2010 Targets under the NEC Directive and the Gothenburg Protocol, in kt
2010 NECD ceilings |
2010 CLRTAP Gothenburg Protocol ceilings |
|||
NOX |
NMVOC |
NOX |
NMVOC |
|
Austria | 103 | 159 | 107 | 159 |
Belgium | 176 | 139 | 181 | 144 |
Bulgaria | 247 | 175 | 266 | 185 |
Cyprus | 23 | 14 | ||
Czech Republic | 286 | 220 | 286 | 220 |
Denmark | 127 | 85 | 127 | 85 |
Estonia | 60 | 49 | ||
Finland | 170 | 130 | 170 | 130 |
France | 810 | 1050 | 860 | 1100 |
Germany | 1051 | 995 | 1081 | 995 |
Greece | 344 | 261 | 344 | 261 |
Hungary | 198 | 137 | 198 | 137 |
Iceland* | ||||
Ireland | 65 | 55 | 65 | 55 |
Italy | 990 | 1159 | 1000 | 1159 |
Latvia | 61 | 136 | 84 | 136 |
Liechtenstein | 0.37 | 0.86 | ||
Lithuania | 110 | 92 | 110 | 92 |
Luxembourg | 11 | 9 | 11 | 9 |
Malta | 8 | 12 | ||
Netherlands | 260 | 185 | 266 | 191 |
Norway | 156 | 195 | ||
Poland | 879 | 800 | 879 | 800 |
Portugal | 250 | 180 | 260 | 202 |
Romania | 437 | 523 | 437 | 523 |
Slovakia | 130 | 140 | 130 | 140 |
Slovenia | 45 | 40 | 45 | 40 |
Spain | 847 | 662 | 847 | 669 |
Switzerland | 79 | 144 | ||
Sweden | 148 | 241 | 148 | 241 |
Turkey* | ||||
United Kingdom | 1167 | 1200 | 1181 | 1200 |
* Iceland and Turkey do not have a ceiling under either the NEC Directive or the Gothenburg protocol.
This indicator is based on officially reported national total and sectoral emissions to 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) Convention on Long-range Transboundary Air Pollution (LRTAP Convention), submission 2011. For the EU-27 Member States, the data used is 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, 2009). Base data are available from the EEA Data Service (http://dataservice.eea.europa.eu/dataservice/metadetails.asp?id=1096) and the EMEP web site (http://www.ceip.at/). Where necessary, gaps in reported data are filled by ETC/ACM using simple interpolation techniques (see below). The final gap-filled data used in this indicator are available from the EEA Data Service (http://dataservice.eea.europa.eu/PivotApp/pivot.aspx?pivotid=478).
Base data, reported in the UNECE/EMEP Nomenclature for Reporting (NFR) 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 Nomenclature for Reporting (NFR) sector codes used for reporting by countries into EEA sector codes:
EEA classification |
Non-GHGs (NFR) |
GHG - CH4 (CRF) |
National totals |
National total |
National totals without LUCF |
Energy production and distribution |
1A1, 1A3e, 1B |
1A1 |
Energy use in industry |
1A2 |
1A2 |
Road transport |
1A3b |
1A3b |
Non-road transport (non-road mobile machinery) |
1A3 (exl 1A3b) |
1A3a, 1A3c, 1A3d, 1A3e |
Industrial processes |
2 |
2 |
Solvent and product use |
3 |
|
Agriculture |
4 |
4 |
Waste |
6 |
6 |
Commercial, institutional and households |
1A4ai, 1A4aii, 1A4bi, 1A4bii, 1A4ci, 1A4cii, 1A5a, 1A5b |
1A4, 1A5 |
Other |
7 |
3 + 7 |
In addition to historic emissions, Figure 1 of the indicator factsheet also shows the latest 2010 projection estimates reported by the EU-27 Member States under the NEC Directive. The "with measures" (WM) projections reported by Member States take into account currently implemented and adopted policies and measures. Where countries have instead reported "business as usual" or "current legislation" projections, it is assumed for comparison purposes that these are equivalent to a WM projection. The "with additional measures" projections reported by Member States take into account additional future planned policies and measures but which are not yet implemented.
An improved gap-filling methodology was implemented in 2010 that enables a complete time series trend for the main air pollutants (eg NOX, SOX, NMVOC, NH3 and CO) to be compiled. In cases where 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 1.4.2 Data gaps and gap-filling of the European Union emission inventory report 1990–2009 under the UNECE Convention on Long-range Transboundary Air Pollution (LRTAP).
No methodology references available.
The use of gap-filling for when countries 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 emissions data for European countries is required for policy analysis purposes.
NMVOC emission estimates in Europe are thought to have an uncertainty of about ±30% due in part to the difficulty in obtaining good emission estimates for some sectors and partly due to the absence of good activity data for some sources. The trend is likely to be more accurate than the individual absolute annual values - the annual values are not independent of each other.
Overall scoring: (1-3, 1=no major problems, 3=major reservations)
NOX emission estimates in Europe are thought to have an uncertainty of about ±20% (EMEP, 2010), as the NOX emitted comes both from the fuel burnt and the combustion air and so cannot be estimated accurately from fuel nitrogen alone. However, because of the need for interpolation to account for missing data, the complete dataset used will have higher uncertainty. The trend is likely to be more accurate than the individual absolute annual values - the annual values are not independent of each other.
Overall scoring: (1-3, 1=no major problems, 3=major reservations)
Uncertainties in emissions of CO are likely to have a similar magnitude of uncertainty as for NOX. NMVOC emissions data have been verified by EMEP and others by means of comparison between modelled and measured concentration throughout Europe. From these studies total uncertainty ranges have been estimated to about ±50%. Some main source categories are less uncertain.
CH4 estimates are reasonably reliable as they are based on a few well-known emission sources. The IPCC believes that the uncertainty in CH4 emission estimates from all sources, in Europe, is likely to be about ±20 %. CH4 emissions from some sources, such as rice fields, are much larger (possibly an order of magnitude), but are a minor emission source in Europe. In 2004, EU Member States reported uncertainties in their estimates of CH4 emissions from enteric fermentation as ranging between 0.5 % (UK) and 2.8 % (Ireland) of the total national GHG emissions (EEA 2004).
This indicator is regularly updated by EEA and is used in state of the environment assessments. The uncertainties related to methodology and data sets are therefore of importance.
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For references, please go to https://www.eea.europa.eu/data-and-maps/indicators/emissions-of-ozone-precursors-version-2 or scan the QR code.
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