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Conservation status of species of European Union interest in wetland ecosystems per group
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Endemism of EU native species — amphibians, reptiles, mammals, dragonflies and butterflies
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CLC changes between 1990 and 2006 (km2)
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Status of marine fish stocks (CSI 032) - Assessment published Sep 2011
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Most of the EU commercial catch is currently taken from stocks that are assessed. There is, however, a clear trend from north to south: almost all catches in the north come from assessed stocks, whereas in the south this only happens for around half of the catch.
Of the assessed commercial stocks in the NE Atlantic, about one third is outside safe biological limits. In the Mediterranean, about half of the assessed stocks are fished outside safe biological limits. In the Black Sea no stocks are assessed.
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Status of marine fish stocks
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Nitrogen oxides (NOx) emissions (APE 002) - Assessment published Oct 2010
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EEA-32 emissions of nitrogen oxides (NO X ) have decreased by 34% between 1990 and 2008. In 2008, the most significant sources of NO X emissions were the road transport sector (39%), combustion processes from within the energy industries sector (21%), the commercial, institutional and households sector (15%) and from industrial energy use (14%). The largest reduction of emissions since 1990 has occurred in the road transport sector. These reductions have been achieved despite the general increase in activity within this sector since the early 1990s and have primarily been achieved as a result of fitting three-way catalysts to petrol fuelled vehicles. In the electricity/energy production sector reductions have also occurred, in these instances as a result of measures such as the introduction of combustion modification technologies (such as use of low NO X burners), implementation of flue-gas abatement techniques (e.g. NO X scrubbers and selective (SCR) and non-selective (SNCR) catalytic reduction techniques) and fuel-switching from coal to gas. The National Emission Ceilings Directive (NECD) specifies NO X emission ceilings for Member States that must be met by 2010. In general, the newer EU Member States have made substantially better progress towards meeting their respective NO X ceilings than the older Member States of the EU-15. Ten of the twelve post-2004 Member States have already reduced emissions beyond what is required under the NECD, and one (Slovenia) reported NO X emissions just 5% above the NECD target in 2008. In contrast, only one EU-15 Member State (Finland) had 2008 emissions within its respective national ceiling. Many Member States though require a significant reduction of NO X emissions to have been made in 2009 and 2010 if they are to meet their obligations under the NECD. Of the three non-EU countries having emission ceilings set under the UNECE/CLRTAP Gothenburg protocol (Liechtenstein, Norway and Switzerland) only for Switzerland were emissions in 2008 below the level of the respective 2010 ceilings Environmental context: NO X contributes to acid deposition and eutrophication. The subsequent impacts of acid deposition can be significant, including adverse effects on aquatic ecosystems in rivers and lakes and damage to forests, crops and other vegetation. Eutrophication can lead to severe reductions in water quality with subsequent impacts including decreased biodiversity, changes in species composition and dominance, and toxicity effects. It is NO 2 that is associated with adverse affects on human health, as at high concentrations it can cause inflammation of the airways. NO 2 also contributes to the formation of secondary particulate aerosols and tropospheric ozone in the atmosphere - both are important air pollutants due to their adverse impacts on human health.
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Nitrogen oxides (NOx) emissions
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EEA-32 Nitrogen oxides (NOx) emissions (APE 002) - Assessment published Feb 2010
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EEA-32 emissions of nitrogen oxides (NO x ) have decreased by 31% between 1990 and 2007. In 2007, the most significant sources of NO x emissions were the road transport sector (36%), combustion processes from within the energy industries sector (21%) and industrial energy use (15%) and the non-road transport sector (16%). The largest reduction of emissions since 1990 has occurred in the road transport sector. These reductions have been achieved despite the general increase in activity within this sector since the early 1990s and have primarily been achieved as a result of fitting three-way catalysts to petrol fuelled vehicles. In the electricity/energy production sector reductions have also occurred, in these instances as a result of measures such as the introduction of combustion modification technologies (such as use of low NO x burners), implementation of flue-gas abatement techniques (e.g. NO x scrubbers and selective (SCR) and selective non-catalytic (SNCR) reduction techniques) and fuel-switching from coal to gas. The National Emission Ceilings Directive (NECD) specifies NO x emission ceilings for Member States that must be met by 2010. In general, the newer Member States have made substantially better progress towards meeting their respective NOx ceilings than the older Member States of the EU-15. Eleven of the twelve post-2004 Member States have already reduced emissions beyond what is required under the NECD, or are very close to doing so (Bulgaria, Cyprus, the Czech Republic, Estonia, Hungary, Latvia, Lithuania, Poland, Romania, Slovakia and Slovenia). In contrast, only one EU-15 Member State (Portugal) has emissions within its respective national ceiling. Many Member States therefore must make significant cuts to NO x emissions in the immediate coming years if they are to meet their obligations under the NECD. Environmental context: NO x contributes to acid deposition and eutrophication. The subsequent impacts of acid deposition can be significant, including adverse effects on aquatic ecosystems in rivers and lakes and damage to forests, crops and other vegetation. Eutrophication can lead to severe reductions in water quality with subsequent impacts including decreased biodiversity, changes in species composition and dominance, and toxicity effects. It is NO 2 that is associated with adverse affects on human health, as at high concentrations it can cause inflammation of the airways. NO 2 also contributes to the formation of secondary particulate aerosols and tropospheric ozone in the atmosphere - both are important air pollutants due to their adverse impacts on human health.
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EEA-32 Nitrogen oxides (NOx) emissions
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Chlorophyll in transitional, coastal and marine waters (CSI 023) - Assessment published Jul 2011
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In 2008, the highest summer chlorophyll-a concentrations were observed in coastal areas and estuaries where nutrient concentrations are high, namely in the Gulf of Riga, the Gulf of Finland and along the coast of France and Belgium. Although nutrient concentrations in some European sea areas decreased from 1985 to 2008 (see Core Set Indicator 21), these changes were not clearly reflected in chlorophyll-a concentrations: of the 546 stations reported to the EEA the majority of the stations (89%) indicated no statistically significant change. Changes were detected mainly in Finnish, Dutch, Norwegian, Swedish and Italian coastal waters. At the Finnish and Swedish monitoring stations chlorophyll-a concentrations showed both decreasing and increasing trends, whereas in Italy, Netherlands and Norway concentrations were mainly decreasing. An analysis of changes based on satellite imagery show significantly increasing trends of ocean colour (equivalent to chl-a)along the Mediterranean coast, whereas trends are significantly decreasing in large parts of the central Mediterranean and Black Seas. It also shows significantly increasing trends in the Baltic Sea, but here the analysis is less certain.
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Chlorophyll in transitional, coastal and marine waters
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Exposure of ecosystems to acidification, eutrophication and ozone (CSI 005) - Assessment published Dec 2009
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Eutrophication The magnitude of the risk of ecosystem eutrophication and its geographical coverage has diminished only slightly over the years. The predictions for 2010 and 2020 indicate that the risk is still widespread over Europe. This is in conflict with the EU's long-term objective of not exceeding critical loads of airborne acidifying and eutrophying substances in sensitive ecosystem areas (National Emission Ceilings Directive, 6th Environmental Action Programme, Thematic Strategy on Air Pollution). Acidification The situation has considerably improved and it is predicted to improve further. The interim environmental objective for 2010 (National Emission Ceilings Directive) will most likely not be met completely. However, the European ecosystem areas where the critical load will be exceeded is predicted to have declined by more than 80 % in 2010 with 1990 as a base year. By 2020, it is expected that the risk of ecosystem acidification will only be an issue at some hot spots, in particular at the border area between the Netherlands and Germany. Ozone (O 3 ) Most vegetation and agricultural crops are exposed to ozone levels exceeding the long term objective given in the EU Air Quality Directive. A significant fraction is also exposed to levels above the 2010 target value defined in the Directive. The effect-related accumulated concentrations, addressing exposure of crops to ozone over several summer months, tend to increase.
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Exposure of ecosystems to acidification, eutrophication and ozone
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Exposure of ecosystems to acidification, eutrophication and ozone (CSI 005) - Assessment published Aug 2010
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Eutrophication The magnitude of the risk of ecosystem eutrophication and its geographical coverage has diminished only slightly over the years. The predictions for 2010 and 2020 indicate that the risk is still widespread over Europe. This is in conflict with the EU's long-term objective of not exceeding critical loads of airborne acidifying and eutrophying substances in sensitive ecosystem areas (National Emission Ceilings Directive, 6th Environmental Action Programme, Thematic Strategy on Air Pollution).
Acidification The situation has considerably improved and it is predicted to improve further. The interim environmental objective for 2010 (National Emission Ceilings Directive) will most likely not be met completely. However, the European ecosystem areas where the critical load will be exceeded is predicted to have declined by more than 80 % in 2010 with 1990 as a base year. By 2020, it is expected that the risk of ecosystem acidification will only be an issue at some hot spots, in particular at the border area between the Netherlands and Germany. Ozone (O 3 )
Most vegetation and agricultural crops are exposed to ozone levels exceeding the long term objective given in the EU Air Quality Directive. A significant fraction is also exposed to levels above the 2010 target value defined in the Directive. Concentrations in 2007 were lower than in 2006. The effect-related accumulated concentrations, addressing exposure of crops to ozone over several summer months, shows large year-to-year variations, there is a non-significance tendency to increase.
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Exposure of ecosystems to acidification, eutrophication and ozone
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Impact of climate change on bird populations (SEBI 011) - Assessment published May 2010
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Climate change is having a detectable effect on bird populations at a European scale, including both negative and positive effects. The number of bird species whose populations are observed to be negatively impacted by climatic change is three times larger than those observed to be positively affected by climate warming in this set of widespread European land birds. The Climatic Impact Indicator, which illustrates the impact of climate change on bird populations, has increased strongly in the past twenty years, coinciding with a period of rapid climatic warming in Europe. Potential links between changes in bird populations and ecosystem functioning and resilience are not well understood.
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Impact of climate change on bird populations
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