Member State report / Art8-2024 / 2024 / D8 / Sweden / NE Atlantic: Greater North Sea
| Report type | Member State report to Commission |
| MSFD Article | Art8 |
| Report due | 2024-10-15 |
| GES Descriptor | D8 Contaminants |
| Member State | Sweden |
| Region/subregion | NE Atlantic: Greater North Sea |
| Report date | 2025-10-30 08:59:20 |
ANS-SE-AA-B_Kattegatt
Regional assessment area |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
HELCOML2_SEA-001 |
|
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
||||||||||||||||||||
GES component |
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
Feature |
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Species
|
Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Cesium-137 |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Nassarius nitidus |
|
Element extent |
||||||||||||||||||||
Trend element |
Deteriorating |
Stable |
Improving |
Improving |
Improving |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Stable |
|
Element 2 |
||||||||||||||||||||
Element source |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
|
Criterion |
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
|
D8C3
|
Parameter |
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in water
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Imposex
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
20.0 |
20.0 |
40.0 |
52000.0 |
30.0 |
2000.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.3 |
|
Threshold value lower |
||||||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
<= |
Threshold qualitative |
||||||||||||||||||||
Threshold value source |
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
National
|
National
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
OSPAR Convention
|
Helsinki Convention
|
Value achieved upper |
37.0 |
161.0 |
0.3 |
0.6 |
12.0 |
54900.0 |
11.7 |
385.0 |
0.37 |
62400.0 |
14.3 |
0.1 |
1100.0 |
0.13 |
102.0 |
0.4 |
0.3 |
8.4 |
1.0 |
1.3118 |
Value achieved lower |
||||||||||||||||||||
Value unit |
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
Becquerels per kilogram of wet weight
|
Becquerels per kilogram of wet weight
|
Bq/m3
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
index VDSI
|
m3
|
Proportion threshold value |
||||||||||||||||||||
Proportion value achieved |
||||||||||||||||||||
Proportion threshold value unit |
||||||||||||||||||||
Trend parameter |
Deteriorating |
Stable |
Improving |
Improving |
Improving |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Stable |
Stable |
Parameter achieved |
No |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
No |
No |
Yes |
No |
No |
No |
Description parameter |
Concentration in flatfish, Pleuronectes platessa
|
Concentration in herring, Clupea harengus
|
Concentrations in surface water
|
Observed value is higher than threshold, but assessed as achieved taking natural background into account. Det observerade värdet överskrider tröskelvärdet men när hänsyn tas till naturliga bakgrunden bedöms att tröskelvärdet klaras.
|
||||||||||||||||
Related indicator |
||||||||||||||||||||
Criteria status |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Not good |
Description criteria |
||||||||||||||||||||
Element status |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
|
Description element |
||||||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type A |
Trend feature |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Stable |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
||||||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
||||||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
|
GES extent achieved |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
||
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
GES achieved |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
GES later than 2024, Art14ExceptionNotReported |
Description overall status |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
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Indicators under D8C2 are not integrated to criteria level |
|
Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2024 |
2016-2021 |
Related pressures |
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|
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|
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|
|
|
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|
|
|
|
|
|
|
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Related targets |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Test TV |
No |
Yes |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
No |
No |
Yes |
No |
No |
NA |
Test results |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
ANS-SE-AA-B_Oresund
Regional assessment area |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
HELCOML2_SEA-003 |
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|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
|||||||||||||||||
GES component |
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
Feature |
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Species
|
Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Peringia ulvae |
|
Element extent |
|||||||||||||||||
Trend element |
Unknown |
Unknown |
Improving |
Unknown |
Unknown |
Unknown |
Unknown |
Unknown |
Unknown |
Unknown |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Unknown |
Stable |
|
Element 2 |
|||||||||||||||||
Element source |
WaterFD |
WaterFD |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
|
Criterion |
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
|
D8C3
|
Parameter |
Concentration in sediment
|
Concentration in sediment
|
Concentration in water
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Imposex
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
40.0 |
52000.0 |
30.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.1 |
|
Threshold value lower |
|||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
<= |
Threshold qualitative |
|||||||||||||||||
Threshold value source |
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Helsinki Convention
|
National
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Helsinki Convention
|
Helsinki Convention
|
Value achieved upper |
17.0 |
3.9 |
43.0 |
0.8 |
199.0 |
1.0 |
1.1 |
0.9 |
0.009 |
||||||||
Value achieved lower |
|||||||||||||||||
Value unit |
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
Bq/m3
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
index VDSI
|
m3
|
Proportion threshold value |
|||||||||||||||||
Proportion value achieved |
|||||||||||||||||
Proportion threshold value unit |
|||||||||||||||||
Trend parameter |
Unknown |
Unknown |
Improving |
Unknown |
Unknown |
Unknown |
Unknown |
Unknown |
Unknown |
Unknown |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Unknown |
Stable |
Stable |
Parameter achieved |
Not assessed |
Not assessed |
Yes |
Not assessed |
Yes |
Not assessed |
Not assessed |
Yes |
Yes |
Not assessed |
Yes |
No |
No |
Yes |
Not assessed |
No |
Yes |
Description parameter |
Concentrations in surface water
|
Although no value was available for the assessment area, the parameter is assessed as """"""""achieved"""""""". The reason is that results for surrounding areas were lower than the threshold value by two magnitudes. Ingen mätning har gjorts i bedömningsområdet men då det uppmätta värdet i övriga bedömningsområden understiger tröskelvärdet med cirka två magnituder bedöms tröskelvärdet klaras även i denna bassäng.
|
|||||||||||||||
Related indicator |
|||||||||||||||||
Criteria status |
Not assessed |
Not assessed |
Good |
Not assessed |
Good |
Not assessed |
Not assessed |
Good |
Good |
Not assessed |
Good |
Not good |
Not good |
Good |
Not assessed |
Not good |
Good |
Description criteria |
|||||||||||||||||
Element status |
Not assessed |
Not assessed |
Good |
Not assessed |
Good |
Not assessed |
Not assessed |
Good |
Good |
Not assessed |
Good |
Not good |
Not good |
Good |
Not assessed |
Not good |
|
Description element |
|||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type A |
Trend feature |
Improving |
Improving |
Improving |
Improving |
Improving |
Improving |
Improving |
Improving |
Unknown |
Unknown |
Unknown |
Unknown |
Unknown |
Unknown |
Unknown |
Not assessed |
Stable |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
|||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
|||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
|
GES extent achieved |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
60.00 |
60.00 |
60.00 |
60.00 |
60.00 |
60.00 |
60.00 |
100.00 |
|
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
GES achieved |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
GES achieved by 2018 |
Description overall status |
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
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Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
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Indicators under D8C2 are not integrated to criteria level |
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Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2025 |
2016-2021 |
Related pressures |
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|
|
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|
|
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|
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Related targets |
|
|
|
|
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|
|
|
|
|
|
|
|
|
|
|
Test TV |
NA |
NA |
Yes |
NA |
Yes |
NA |
NA |
Yes |
Yes |
NA |
NA |
No |
No |
Yes |
NA |
No |
NA |
Test results |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
ANS-SE-AA-B_Skagerrak
Regional assessment area |
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|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
||||||||||||||||||
GES component |
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
Feature |
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Species
|
Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Nassarius nitidus |
|
Element extent |
||||||||||||||||||
Trend element |
Unknown |
Unknown |
Improving |
Stable |
Unknown |
Unknown |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Stable |
Stable |
Not assessed |
Stable |
|
Element 2 |
||||||||||||||||||
Element source |
WaterFD |
WaterFD |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
|
Criterion |
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
|
D8C3
|
Parameter |
Concentration in sediment
|
Concentration in sediment
|
Concentration in water
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Imposex
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
40.0 |
52000.0 |
30.0 |
2000.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.3 |
|
Threshold value lower |
||||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
<= |
Threshold qualitative |
||||||||||||||||||
Threshold value source |
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Helsinki Convention
|
National
|
National
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
OSPAR Convention
|
National
|
Value achieved upper |
29.0 |
202.0 |
6.7 |
42351.0 |
12.0 |
268.0 |
0.39 |
67467.0 |
12.0 |
0.01 |
340.0 |
0.15 |
18.0 |
0.15 |
0.39 |
0.57 |
0.29 |
0.5545 |
Value achieved lower |
||||||||||||||||||
Value unit |
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
Bq/m3
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
index VDSI
|
m3
|
Proportion threshold value |
||||||||||||||||||
Proportion value achieved |
||||||||||||||||||
Proportion threshold value unit |
||||||||||||||||||
Trend parameter |
Unknown |
Unknown |
Improving |
Stable |
Stable |
Unknown |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Stable |
Stable |
Not assessed |
Stable |
Stable |
Parameter achieved |
No |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
Description parameter |
Concentration in herring, Clupea harengus
|
Ospar lacks an indicator for oil spill, hence regional harmonisation is not possible in the Swedish marine reporting unit Skagerrak. To promote a coherent national assessment and regional coordination, the Helcom methodology has been applied also to the assessment in Skagerrak. |
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Related indicator |
||||||||||||||||||
Criteria status |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
Good |
Description criteria |
||||||||||||||||||
Element status |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
|
Description element |
||||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Trend feature |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Stable |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
||||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
||||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
|
GES extent achieved |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
85.70 |
85.70 |
85.70 |
85.70 |
85.70 |
85.70 |
85.70 |
100.00 |
|
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
GES achieved |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
GES achieved by 2018 |
Description overall status |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). |
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Sweden applies exceptions from achieving good environmental status for PBDEs, mercury and TBT. För Västerhavet tillämpar Sverige undantag från att nå god miljöstatus för PBDE, kvicksilver och TBT enligt 29 § havsmiljöförordningen. On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a).
|
Indicators under D8C2 are not integrated to criteria level |
Ospar lacks an indicator for oil spill, hence regional harmonisation is not possible in the Swedish marine reporting unit Skagerrak. To promote a coherent national assessment and regional coordination, the Helcom methodology has been applied also to the assessment in Skagerrak. |
Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2026 |
2016-2021 |
Related pressures |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Related targets |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Test TV |
No |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
NA |
Test results |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
ANS-SE-AA-BG_Vasterhavet
Regional assessment area |
|||
|---|---|---|---|
Component MRUs |
|||
GES component |
D8
|
D8
|
D8
|
Feature |
Species
|
Species
|
Species
|
Element |
Zoarces viviparus |
Zoarces viviparus |
Zoarces viviparus |
Element extent |
|||
Trend element |
Stable |
Stable |
Stable |
Element 2 |
|||
Element source |
National |
National |
National |
Criterion |
D8C2
|
D8C2
|
D8C2
|
Parameter |
Proportion - dead fry early
|
Proportion - dead fry late
|
Proportion - fry malformed
|
Threshold value upper |
5.0 |
4.0 |
2.0 |
Threshold value lower |
|||
Threshold value operator |
< |
< |
< |
Threshold qualitative |
|||
Threshold value source |
National
|
National
|
National
|
Value achieved upper |
1.8 |
1.7 |
0.8 |
Value achieved lower |
|||
Value unit |
percentage
|
percentage
|
percentage
|
Proportion threshold value |
|||
Proportion value achieved |
|||
Proportion threshold value unit |
|||
Trend parameter |
Stable |
Stable |
Stable |
Parameter achieved |
Yes |
Yes |
Yes |
Description parameter |
|||
Related indicator |
|||
Criteria status |
Good |
Good |
Good |
Description criteria |
|||
Element status |
Good |
Good |
Good |
Description element |
|||
Source assessment feature |
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Trend feature |
Not assessed |
Not assessed |
Not assessed |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
Integration rule description parameter |
|||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
|||
GES extent threshold |
|||
GES extent achieved |
|||
GES extent unit |
Not relevant |
Not relevant |
Not relevant |
GES achieved |
Not assessed |
Not assessed |
Not assessed |
Description overall status |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
Related pressures |
|
|
|
Related targets |
|
|
|
Test TV |
Yes |
Yes |
Yes |
Test results |
Correct |
Correct |
Correct |
BAL-SE-AA-B_Alands_hav
Regional assessment area |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
HELCOML2_SEA-014 |
||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
||||||||||||||||||||
GES component |
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
Feature |
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Species
|
Species
|
Species
|
Species
|
Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Haliaeetus albicilla |
Haliaeetus albicilla |
Haliaeetus albicilla |
Monoporeia affinis |
|
Element extent |
||||||||||||||||||||
Trend element |
Unknown |
Unknown |
Improving |
Deteriorating |
Stable |
Stable |
Stable |
Unknown |
Unknown |
Unknown |
Not assessed |
Unknown |
Not assessed |
Unknown |
Deteriorating |
Deteriorating |
Deteriorating |
Deteriorating |
Stable |
|
Element 2 |
||||||||||||||||||||
Element source |
WaterFD |
WaterFD |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
|
Criterion |
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
|
D8C2
|
D8C2
|
D8C2
|
D8C3
|
Parameter |
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Other
|
Other
|
Other
|
Other
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
20.0 |
52000.0 |
2000.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.97 |
1.64 |
59.0 |
||
Threshold value lower |
||||||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
> |
> |
> |
<= |
|
Threshold qualitative |
proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
|||||||||||||||||||
Threshold value source |
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Helsinki Convention
|
National
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Value achieved upper |
10.6 |
460.0 |
3.0 |
75900.0 |
140.0 |
0.76 |
42000.0 |
1.8 |
1.0 |
1.61 |
62.0 |
0.013 |
||||||||
Value achieved lower |
||||||||||||||||||||
Value unit |
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
Becquerels per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
Other
|
Other
|
percentage
|
m3
|
|
Proportion threshold value |
||||||||||||||||||||
Proportion value achieved |
||||||||||||||||||||
Proportion threshold value unit |
||||||||||||||||||||
Trend parameter |
Unknown |
Unknown |
Improving |
Deteriorating |
Stable |
Stable |
Stable |
Unknown |
Unknown |
Unknown |
Not assessed |
Unknown |
Not assessed |
Unknown |
Deteriorating |
Stable |
Deteriorating |
Stable |
Unknown |
Improving |
Parameter achieved |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
Not assessed |
Not assessed |
Not assessed |
Yes |
Not assessed |
No |
Not assessed |
No |
Yes |
No |
Yes |
Unknown |
Yes |
Description parameter |
Concentration in herring, Clupea harengus
|
Although no value was available for the assessment area, the parameter is assessed as """"""""achieved"""""""". The reason is that results for surrounding areas were lower than the threshold value by two magnitudes. Ingen mätning har gjorts i bedömningsområdet men då det uppmätta värdet i övriga bedömningsområden understiger tröskelvärdet med cirka två magnituder bedöms tröskelvärdet klaras även i denna bassäng.
|
Although no value is available in the area, the parameter is assessed as """"""""Not achieved"""""""". This because assessment values in surrounding areas exceed the threshold value by approximately two orders of magnitude. Ingen mätning har gjorts i bedömningsområdet men då det uppmätta värdet i övriga bedömningsområden överstiger tröskelvärdet med cirka två magnituder bedöms tröskelvärdet inte klaras även i denna bassäng.
|
Productivity > 0,97 (nestlings). Produktivitet > 0,97 ungar per par.
|
Brood size > 1,64 (nestlings per successfully breeding pair). Kullstorlek > 1,64 ungar. |
Breeding success rate > 59 % (reproducing pairs). Häckningsframgång > 59 % |
||||||||||||||
Related indicator |
||||||||||||||||||||
Criteria status |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
Not assessed |
Not assessed |
Not assessed |
Good |
Not assessed |
Not good |
Not assessed |
Not good |
Not good |
Not good |
Not good |
Unknown |
Good |
Description criteria |
Criteria assessment based on two parameters: proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
|||||||||||||||||||
Element status |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
Not assessed |
Not assessed |
Not assessed |
Good |
Not assessed |
Not good |
Not assessed |
Not good |
Not good |
Not good |
Not good |
Unknown |
|
Description element |
||||||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type A |
Trend feature |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Deteriorating |
Deteriorating |
Deteriorating |
Deteriorating |
Deteriorating |
Deteriorating |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Improving |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
||||||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
||||||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
||||
GES extent achieved |
85.70 |
85.70 |
85.70 |
85.70 |
85.70 |
85.70 |
85.70 |
85.70 |
100.00 |
|||||||||||
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
GES achieved |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
GES achieved by 2024 |
Description overall status |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020). |
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
|
Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2027 |
2016-2027 |
2016-2027 |
2016-2027 |
2016-2021 |
Related pressures |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Related targets |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Test TV |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
NA |
NA |
NA |
NA |
NA |
NA |
NA |
No |
Yes |
No |
Yes |
NA |
NA |
Test results |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
Correct |
False |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
BAL-SE-AA-B_Arkonahavet_och_S_Oresund
Regional assessment area |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
HELCOML2_SEA-006 |
|
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
||||||||||||||||||||
GES component |
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
Feature |
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Species
|
Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Cesium-137 |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Peringia ulvae |
|
Element extent |
||||||||||||||||||||
Trend element |
Unknown |
Unknown |
Improving |
Improving |
Improving |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Stable |
Unknown |
Stable |
Stable |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
|
Element 2 |
||||||||||||||||||||
Element source |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
|
Criterion |
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
|
D8C3
|
Parameter |
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in water
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Imposex
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
20.0 |
20.0 |
40.0 |
52000.0 |
30.0 |
2000.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.1 |
|
Threshold value lower |
||||||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
<= |
Threshold qualitative |
||||||||||||||||||||
Threshold value source |
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
National
|
National
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Helsinki Convention
|
Helsinki Convention
|
Value achieved upper |
29.8 |
644.0 |
1.8 |
2.5 |
20.0 |
65100.0 |
2.1 |
350.0 |
0.76 |
153600.0 |
26.3 |
0.65 |
2000.0 |
0.9 |
36.0 |
0.7 |
0.5 |
7.6 |
0.7 |
1.2275 |
Value achieved lower |
||||||||||||||||||||
Value unit |
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
Becquerels per kilogram of wet weight
|
Becquerels per kilogram of wet weight
|
Bq/m3
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
index VDSI
|
m3
|
Proportion threshold value |
||||||||||||||||||||
Proportion value achieved |
||||||||||||||||||||
Proportion threshold value unit |
||||||||||||||||||||
Trend parameter |
Unknown |
Unknown |
Improving |
Improving |
Improving |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Stable |
Unknown |
Stable |
Stable |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Stable |
Parameter achieved |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
No |
No |
Yes |
No |
No |
Yes |
Description parameter |
Concentration in herring, Clupea harengus
|
Concentration in flatfish, Pleuronectes platessa
|
Concentrations in seawater
|
Observed value is higher than threshold, but assessed as achieved taking natural background into account. Det observerade värdet överskrider tröskelvärdet men när hänsyn tas till naturliga bakgrunden bedöms att tröskelvärdet klaras.
|
||||||||||||||||
Related indicator |
||||||||||||||||||||
Criteria status |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Good |
Description criteria |
||||||||||||||||||||
Element status |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
|
Description element |
||||||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type A |
Trend feature |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Stable |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
||||||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
||||||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
|
GES extent achieved |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
100.00 |
|
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
GES achieved |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
GES achieved by 2018 |
Description overall status |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020). |
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Indicators under D8C2 are not integrated to criteria level |
|
Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2028 |
2016-2021 |
Related pressures |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Related targets |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Test TV |
No |
Yes |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
No |
No |
Yes |
No |
No |
NA |
Test results |
False |
Correct |
Correct |
Correct |
Correct |
False |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
BAL-SE-AA-B_Bornholmshavet_och_Hanobukten
Regional assessment area |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
HELCOML2_SEA-007 |
|||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
||||||||||||||||||||||||
GES component |
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
Feature |
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Species
|
Species
|
Species
|
Species
|
Species
|
Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Cesium-137 |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Haliaeetus albicilla |
Haliaeetus albicilla |
Haliaeetus albicilla |
Monoporeia affinis |
Peringia ulvae |
|
Element extent |
||||||||||||||||||||||||
Trend element |
Unknown |
Unknown |
Improving |
Improving |
Improving |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Stable |
Unknown |
Stable |
Stable |
Deteriorating |
Stable |
Stable |
Stable |
Deteriorating |
Deteriorating |
Deteriorating |
Stable |
Stable |
|
Element 2 |
||||||||||||||||||||||||
Element source |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
|
Criterion |
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
|
D8C2
|
D8C2
|
D8C2
|
D8C2
|
D8C3
|
Parameter |
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in water
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Other
|
Other
|
Other
|
Other
|
Imposex
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
20.0 |
20.0 |
40.0 |
52000.0 |
30.0 |
2000.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.97 |
1.64 |
59.0 |
0.1 |
||
Threshold value lower |
||||||||||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
> |
> |
> |
< |
<= |
|
Threshold qualitative |
proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
|||||||||||||||||||||||
Threshold value source |
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
National
|
National
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Value achieved upper |
13.9 |
1978.0 |
2.6 |
3.0 |
19.0 |
68100.0 |
0.9 |
133.0 |
0.86 |
98400.0 |
7.5 |
0.2 |
2200.0 |
0.15 |
30.0 |
0.3 |
0.7 |
7.0 |
1.0 |
1.61 |
62.0 |
1.3 |
1.0835 |
|
Value achieved lower |
||||||||||||||||||||||||
Value unit |
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
Becquerels per kilogram of wet weight
|
Becquerels per kilogram of wet weight
|
Bq/m3
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
Other
|
Other
|
percentage
|
index VDSI
|
m3
|
|
Proportion threshold value |
||||||||||||||||||||||||
Proportion value achieved |
||||||||||||||||||||||||
Proportion threshold value unit |
||||||||||||||||||||||||
Trend parameter |
Unknown |
Unknown |
Improving |
Improving |
Improving |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Stable |
Unknown |
Stable |
Stable |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Stable |
Unknown |
Stable |
Stable |
Parameter achieved |
Yes |
Yes |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
No |
No |
Yes |
No |
Yes |
No |
Yes |
Unknown |
No |
Yes |
Description parameter |
Concentration in herring, Clupea harengus
|
Concentration in flatfish, Pleuronectes platessa
|
Concentrations in seawater
|
Productivity > 0,97 (nestlings). Produktivitet > 0,97 ungar per par.
|
Brood size > 1,64 (nestlings per successfully breeding pair). Kullstorlek > 1,64 ungar. |
Breeding success rate > 59 % (reproducing pairs). Häckningsframgång > 59 % |
||||||||||||||||||
Related indicator |
||||||||||||||||||||||||
Criteria status |
Good |
Good |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Not good |
Not good |
Unknown |
Not good |
Good |
Description criteria |
Criteria assessment based on two parameters: proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
|||||||||||||||||||||||
Element status |
Good |
Good |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Not good |
Not good |
Unknown |
Not good |
|
Description element |
||||||||||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type A |
Trend feature |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Stable |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
||||||||||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
||||||||||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
|||||
GES extent achieved |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
100.00 |
|||||
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
GES achieved |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
GES achieved by 2018 |
Description overall status |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
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Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
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Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
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Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2029 |
2016-2029 |
2016-2029 |
2016-2029 |
2016-2029 |
2016-2021 |
Related pressures |
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Related targets |
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Test TV |
Yes |
Yes |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
No |
No |
Yes |
No |
Yes |
No |
Yes |
NA |
No |
NA |
Test results |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
BAL-SE-AA-B_Bottenhavet
Regional assessment area |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
HELCOML2_SEA-015 |
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|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
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GES component |
D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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D8
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Feature |
Contaminants - non UPBT substances
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Contaminants - non UPBT substances
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Contaminants - non UPBT substances
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Contaminants - non UPBT substances
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Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
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Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
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Contaminants - UPBT substances
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Contaminants - UPBT substances
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Contaminants - UPBT substances
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Contaminants - UPBT substances
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Contaminants - UPBT substances
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Species
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Species
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Species
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Species
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Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Haliaeetus albicilla |
Haliaeetus albicilla |
Haliaeetus albicilla |
Monoporeia affinis |
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Element extent |
|||||||||||||||||||||
Trend element |
Unknown |
Unknown |
Improving |
Improving |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Unknown |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Deteriorating |
Deteriorating |
Deteriorating |
Stable |
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Element 2 |
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Element source |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
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Criterion |
D8C1
|
D8C1
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D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
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D8C2
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D8C2
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D8C2
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D8C3
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Parameter |
Concentration in sediment
|
Concentration in sediment
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Concentration in biota
|
Concentration in water
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Concentration in sediment
|
Concentration in sediment
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Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
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Concentration in sediment
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Other
|
Other
|
Other
|
Other
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
20.0 |
40.0 |
52000.0 |
2000.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.97 |
1.64 |
59.0 |
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Threshold value lower |
|||||||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
> |
> |
> |
<= |
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Threshold qualitative |
proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
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Threshold value source |
Water Framework Directive (2000/60/EC)
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Water Framework Directive (2000/60/EC)
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Helsinki Convention
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Helsinki Convention
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National
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National
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Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
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National
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
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Value achieved upper |
8.2 |
345.0 |
3.7 |
21.0 |
73500.0 |
105.0 |
1.3 |
37200.0 |
13.0 |
2300.0 |
0.53 |
26.0 |
0.4 |
1.0 |
1.1 |
1.02 |
1.6 |
63.0 |
0.3263 |
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Value achieved lower |
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Value unit |
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
Becquerels per kilogram of wet weight
|
Bq/m3
|
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
Other
|
Other
|
percentage
|
m3
|
|
Proportion threshold value |
|||||||||||||||||||||
Proportion value achieved |
|||||||||||||||||||||
Proportion threshold value unit |
|||||||||||||||||||||
Trend parameter |
Unknown |
Unknown |
Improving |
Improving |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Unknown |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Stable |
Stable |
Stable |
Stable |
Stable |
Parameter achieved |
Yes |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
Not assessed |
Yes |
Yes |
No |
No |
Yes |
Yes |
Yes |
No |
Yes |
No |
No |
Description parameter |
Concentration in herring, Clupea harengus
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Concentrations in seawater
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Productivity > 0,97 (nestlings). Produktivitet > 0,97 ungar per par.
|
Brood size > 1,64 (nestlings per successfully breeding pair). Kullstorlek > 1,64 ungar. |
Breeding success rate > 59 % (reproducing pairs). Häckningsframgång > 59 %
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Related indicator |
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Criteria status |
Good |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
Good |
Not assessed |
Good |
Good |
Not good |
Not good |
Good |
Good |
Not good |
Not good |
Not good |
Not good |
Not good |
Description criteria |
Criteria assessment based on two parameters: proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
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Element status |
Good |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
Good |
Not assessed |
Good |
Good |
Not good |
Not good |
Good |
Good |
Not good |
Not good |
Not good |
Not good |
|
Description element |
|||||||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type A |
Trend feature |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Stable |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
|||||||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
|||||||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
||||
GES extent achieved |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
66.70 |
66.70 |
66.70 |
66.70 |
66.70 |
66.70 |
66.70 |
|||||
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
GES achieved |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
GES later than 2024, Art14ExceptionNotReported |
Description overall status |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020). |
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
|
Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2030 |
2016-2030 |
2016-2030 |
2016-2030 |
2016-2021 |
Related pressures |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Related targets |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Test TV |
Yes |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
NA |
Yes |
Yes |
No |
No |
Yes |
Yes |
Yes |
No |
Yes |
NA |
NA |
Test results |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
False |
BAL-SE-AA-B_Bottenviken
Regional assessment area |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
HELCOML2_SEA-017 |
||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
|||||||||||||||||||||
GES component |
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
Feature |
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Species
|
Species
|
Species
|
Species
|
Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Haliaeetus albicilla |
Haliaeetus albicilla |
Haliaeetus albicilla |
Monoporeia affinis |
|
Element extent |
|||||||||||||||||||||
Trend element |
Unknown |
Unknown |
Improving |
Improving |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Unknown |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
|
Element 2 |
|||||||||||||||||||||
Element source |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
|
Criterion |
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
|
D8C2
|
D8C2
|
D8C2
|
D8C3
|
Parameter |
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in water
|
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Other
|
Other
|
Other
|
Other
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
20.0 |
40.0 |
52000.0 |
2000.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.97 |
1.64 |
59.0 |
||
Threshold value lower |
|||||||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
> |
> |
> |
<= |
|
Threshold qualitative |
proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
||||||||||||||||||||
Threshold value source |
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Helsinki Convention
|
Helsinki Convention
|
National
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Value achieved upper |
5.3 |
1311.0 |
4.0 |
14.0 |
70200.0 |
60.0 |
0.75 |
74400.0 |
45.0 |
7600.0 |
10.0 |
90.0 |
5.7 |
2.1 |
2.2 |
1.02 |
1.6 |
63.0 |
0.0507 |
||
Value achieved lower |
|||||||||||||||||||||
Value unit |
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
Becquerels per kilogram of wet weight
|
Bq/m3
|
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
Other
|
Other
|
percentage
|
m3
|
|
Proportion threshold value |
|||||||||||||||||||||
Proportion value achieved |
|||||||||||||||||||||
Proportion threshold value unit |
|||||||||||||||||||||
Trend parameter |
Unknown |
Unknown |
Improving |
Improving |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Unknown |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Stable |
Stable |
Stable |
Unknown |
Improving |
Parameter achieved |
Yes |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
Not assessed |
No |
Yes |
No |
No |
Yes |
No |
Yes |
No |
Yes |
Unknown |
Yes |
Description parameter |
Concentration in herring, Clupea harengus
|
Concentrations in seawater
|
Productivity > 0,97 (nestlings). Produktivitet > 0,97 ungar per par.
|
Brood size > 1,64 (nestlings per successfully breeding pair). Kullstorlek > 1,64 ungar. |
Breeding success rate > 59 % (reproducing pairs). Häckningsframgång > 59 %
|
||||||||||||||||
Related indicator |
|||||||||||||||||||||
Criteria status |
Good |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
Good |
Not assessed |
Not good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Not good |
Not good |
Unknown |
Good |
Description criteria |
Criteria assessment based on two parameters: proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
||||||||||||||||||||
Element status |
Good |
Good |
Good |
Good |
Not good |
Good |
Good |
Good |
Good |
Not assessed |
Not good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Not good |
Not good |
Unknown |
|
Description element |
|||||||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type A |
Trend feature |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Improving |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
|||||||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
|||||||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
||||
GES extent achieved |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
33.30 |
33.30 |
33.30 |
33.30 |
33.30 |
33.30 |
33.30 |
100.00 |
||||
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
GES achieved |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionNotReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
GES achieved by 2024 |
Description overall status |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
|
Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2031 |
2016-2031 |
2016-2031 |
2016-2031 |
2016-2021 |
Related pressures |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Related targets |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Test TV |
Yes |
Yes |
Yes |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
NA |
No |
Yes |
No |
No |
Yes |
No |
Yes |
No |
Yes |
NA |
NA |
Test results |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
BAL-SE-AA-B_N_Gotlandshavet
Regional assessment area |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
HELCOML2_SEA-012 |
|||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
|||||||||||||||||||||
GES component |
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
Feature |
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Species
|
Species
|
Species
|
Species
|
Species
|
Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Haliaeetus albicilla |
Haliaeetus albicilla |
Haliaeetus albicilla |
Monoporeia affinis |
Peringia ulvae |
|
Element extent |
|||||||||||||||||||||
Trend element |
Unknown |
Unknown |
Improving |
Stable |
Stable |
Stable |
Stable |
Stable |
Unknown |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Deteriorating |
Deteriorating |
Stable |
Stable |
|
Element 2 |
|||||||||||||||||||||
Element source |
WaterFD |
WaterFD |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
|
Criterion |
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
|
D8C2
|
D8C2
|
D8C2
|
D8C2
|
D8C3
|
Parameter |
Concentration in sediment
|
Concentration in sediment
|
Concentration in water
|
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Other
|
Other
|
Other
|
Other
|
Imposex
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
40.0 |
52000.0 |
2000.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.97 |
1.64 |
59.0 |
0.1 |
||
Threshold value lower |
|||||||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
> |
> |
> |
< |
<= |
|
Threshold qualitative |
proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
||||||||||||||||||||
Threshold value source |
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Helsinki Convention
|
National
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Value achieved upper |
8.6 |
14076.0 |
19.0 |
52500.0 |
81.0 |
0.68 |
67200.0 |
7.4 |
1900.0 |
0.22 |
52.0 |
0.2 |
1.1 |
16.5 |
1.0 |
1.61 |
62.0 |
0.6 |
1.705 |
||
Value achieved lower |
|||||||||||||||||||||
Value unit |
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
Bq/m3
|
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
Other
|
Other
|
percentage
|
index VDSI
|
m3
|
|
Proportion threshold value |
|||||||||||||||||||||
Proportion value achieved |
|||||||||||||||||||||
Proportion threshold value unit |
|||||||||||||||||||||
Trend parameter |
Unknown |
Deteriorating |
Improving |
Stable |
Stable |
Stable |
Stable |
Stable |
Unknown |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Parameter achieved |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Not assessed |
Yes |
Yes |
No |
No |
Yes |
No |
Yes |
No |
Yes |
No |
No |
Yes |
Description parameter |
Concentrations in seawater
|
Observed value is higher than threshold, but assessed as achieved taking natural background into account. Det observerade värdet överskrider tröskelvärdet men när hänsyn tas till naturliga bakgrunden bedöms att tröskelvärdet klaras.
|
Productivity > 0,97 (nestlings). Produktivitet > 0,97 ungar per par.
|
Brood size > 1,64 (nestlings per successfully breeding pair). Kullstorlek > 1,64 ungar. |
Breeding success rate > 59 % (reproducing pairs). Häckningsframgång > 59 % |
||||||||||||||||
Related indicator |
|||||||||||||||||||||
Criteria status |
Good |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Not assessed |
Good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Not good |
Not good |
Not good |
Not good |
Good |
Description criteria |
Criteria assessment based on two parameters: proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
||||||||||||||||||||
Element status |
Good |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Not assessed |
Good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Not good |
Not good |
Not good |
Not good |
|
Description element |
|||||||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type A |
Trend feature |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Stable |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
|||||||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
|||||||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
|||||
GES extent achieved |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
50.00 |
50.00 |
50.00 |
50.00 |
50.00 |
50.00 |
50.00 |
100.00 |
|||||
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
GES achieved |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
GES achieved by 2018 |
Description overall status |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
|
Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2032 |
2016-2032 |
2016-2032 |
2016-2032 |
2016-2032 |
2016-2021 |
Related pressures |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Related targets |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Test TV |
Yes |
No |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
NA |
Yes |
Yes |
No |
No |
Yes |
No |
Yes |
No |
Yes |
NA |
No |
NA |
Test results |
Correct |
Correct |
Correct |
False |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
Correct |
False |
BAL-SE-AA-B_N_Kvarken
Regional assessment area |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
HELCOML2_SEA-016 |
||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
||||||||||||||||||||
GES component |
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
Feature |
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Species
|
Species
|
Species
|
Species
|
Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Haliaeetus albicilla |
Haliaeetus albicilla |
Haliaeetus albicilla |
Monoporeia affinis |
|
Element extent |
||||||||||||||||||||
Trend element |
Unknown |
Unknown |
Improving |
Not assessed |
Unknown |
Stable |
Unknown |
Stable |
Unknown |
Stable |
Stable |
Stable |
Stable |
Stable |
Unknown |
Deteriorating |
Deteriorating |
Deteriorating |
Stable |
|
Element 2 |
||||||||||||||||||||
Element source |
WaterFD |
WaterFD |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
|
Criterion |
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
|
D8C2
|
D8C2
|
D8C2
|
D8C3
|
Parameter |
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Other
|
Other
|
Other
|
Other
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
20.0 |
52000.0 |
2000.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.97 |
1.64 |
59.0 |
||
Threshold value lower |
||||||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
> |
> |
> |
<= |
|
Threshold qualitative |
proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
|||||||||||||||||||
Threshold value source |
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Helsinki Convention
|
National
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Value achieved upper |
3.3 |
1.2 |
34.0 |
4000.0 |
1.2 |
113.0 |
0.8 |
0.9 |
1.02 |
1.6 |
63.0 |
|||||||||
Value achieved lower |
||||||||||||||||||||
Value unit |
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
Becquerels per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
Other
|
Other
|
percentage
|
m3
|
|
Proportion threshold value |
||||||||||||||||||||
Proportion value achieved |
||||||||||||||||||||
Proportion threshold value unit |
||||||||||||||||||||
Trend parameter |
Unknown |
Unknown |
Improving |
Not assessed |
Unknown |
Stable |
Unknown |
Stable |
Unknown |
Stable |
Stable |
Stable |
Stable |
Stable |
Unknown |
Stable |
Deteriorating |
Stable |
Stable |
Improving |
Parameter achieved |
Not assessed |
Not assessed |
Yes |
Not assessed |
Not assessed |
Yes |
Not assessed |
Yes |
Not assessed |
Yes |
Yes |
No |
No |
Yes |
Not assessed |
Yes |
No |
Yes |
Yes |
Yes |
Description parameter |
Concentration in herring, Clupea harengus
|
Productivity > 0,97 (nestlings). Produktivitet > 0,97 ungar per par.
|
Brood size > 1,64 (nestlings per successfully breeding pair). Kullstorlek > 1,64 ungar. |
Breeding success rate > 59 % (reproducing pairs). Häckningsframgång > 59 % |
||||||||||||||||
Related indicator |
||||||||||||||||||||
Criteria status |
Not assessed |
Not assessed |
Good |
Not assessed |
Not assessed |
Good |
Not assessed |
Good |
Not assessed |
Good |
Good |
Not good |
Not good |
Good |
Not assessed |
Not good |
Not good |
Not good |
Good |
Good |
Description criteria |
Criteria assessment based on two parameters: proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
|||||||||||||||||||
Element status |
Not assessed |
Not assessed |
Good |
Not assessed |
Not assessed |
Good |
Not assessed |
Good |
Not assessed |
Good |
Good |
Not good |
Not good |
Good |
Not assessed |
Not good |
Not good |
Not good |
Good |
|
Description element |
||||||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type A |
Trend feature |
Improving |
Improving |
Improving |
Improving |
Improving |
Improving |
Improving |
Improving |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Improving |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
||||||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
||||||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
||||
GES extent achieved |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
60.00 |
60.00 |
60.00 |
60.00 |
60.00 |
60.00 |
60.00 |
100.00 |
||||
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
GES achieved |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES achieved by 2024 |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
GES achieved by 2024 |
Description overall status |
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020). |
Sweden applies exceptions from achieving good environmental status for PBDEs and mercury. För hela Östersjön tillämpas undantag för PBDE och kvicksilver.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
|||||||||
Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2033 |
2016-2033 |
2016-2033 |
2016-2033 |
2016-2021 |
Related pressures |
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Related targets |
|
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Test TV |
NA |
NA |
Yes |
NA |
NA |
Yes |
NA |
Yes |
NA |
Yes |
Yes |
No |
No |
Yes |
NA |
Yes |
No |
Yes |
NA |
NA |
Test results |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
False |
BAL-SE-AA-B_O_Gotlandshavet
Regional assessment area |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
HELCOML2_SEA-009 |
|||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
|||||||||||||||||||||||
GES component |
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
Feature |
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Species
|
Species
|
Species
|
Species
|
Species
|
Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Cesium-137 |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Haliaeetus albicilla |
Haliaeetus albicilla |
Haliaeetus albicilla |
Monoporeia affinis |
Peringia ulvae |
|
Element extent |
|||||||||||||||||||||||
Trend element |
Unknown |
Unknown |
Improving |
Improving |
Improving |
Stable |
Stable |
Stable |
Stable |
Stable |
Unknown |
Unknown |
Stable |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Deteriorating |
Deteriorating |
Stable |
Stable |
|
Element 2 |
|||||||||||||||||||||||
Element source |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
|
Criterion |
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
|
D8C2
|
D8C2
|
D8C2
|
D8C2
|
D8C3
|
Parameter |
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in water
|
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Other
|
Other
|
Other
|
Other
|
Imposex
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
20.0 |
20.0 |
40.0 |
52000.0 |
2000.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.97 |
1.64 |
59.0 |
0.1 |
||
Threshold value lower |
|||||||||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
> |
> |
> |
< |
<= |
|
Threshold qualitative |
proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
||||||||||||||||||||||
Threshold value source |
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
National
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Value achieved upper |
5.5 |
11500.0 |
2.7 |
3.3 |
17.0 |
51900.0 |
70.0 |
1.4 |
79200.0 |
14.3 |
0.23 |
39.0 |
0.7 |
1.4 |
13.0 |
1.0 |
1.61 |
62.0 |
0.0563 |
||||
Value achieved lower |
|||||||||||||||||||||||
Value unit |
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
Becquerels per kilogram of wet weight
|
Becquerels per kilogram of wet weight
|
Bq/m3
|
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
Other
|
Other
|
percentage
|
index VDSI
|
m3
|
|
Proportion threshold value |
|||||||||||||||||||||||
Proportion value achieved |
|||||||||||||||||||||||
Proportion threshold value unit |
|||||||||||||||||||||||
Trend parameter |
Unknown |
Unknown |
Improving |
Improving |
Improving |
Stable |
Stable |
Stable |
Stable |
Stable |
Unknown |
Unknown |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Stable |
Unknown |
Unknown |
Improving |
Parameter achieved |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Not assessed |
Not assessed |
Yes |
No |
No |
Yes |
No |
Yes |
No |
Yes |
Unknown |
Unknown |
Yes |
Description parameter |
Concentration in herring, Clupea harengus
|
Concentration in flatfish, Pleuronectes platessa
|
Concentrations in seawater
|
Productivity > 0,97 (nestlings). Produktivitet > 0,97 ungar per par.
|
Brood size > 1,64 (nestlings per successfully breeding pair). Kullstorlek > 1,64 ungar. |
Breeding success rate > 59 % (reproducing pairs). Häckningsframgång > 59 % |
|||||||||||||||||
Related indicator |
|||||||||||||||||||||||
Criteria status |
Good |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not assessed |
Not assessed |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Not good |
Not good |
Unknown |
Unknown |
Good |
Description criteria |
Criteria assessment based on two parameters: proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
||||||||||||||||||||||
Element status |
Good |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not assessed |
Not assessed |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Not good |
Not good |
Unknown |
Unknown |
|
Description element |
|||||||||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type A |
Trend feature |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Improving |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
|||||||||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
|||||||||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
|||||
GES extent achieved |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
40.00 |
40.00 |
40.00 |
40.00 |
40.00 |
40.00 |
40.00 |
100.00 |
|||||
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
GES achieved |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
GES achieved by 2024 |
Description overall status |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020). |
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
|
Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2034 |
2016-2034 |
2016-2034 |
2016-2034 |
2016-2034 |
2016-2021 |
Related pressures |
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|
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|
|
|
|
|
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|
|
|
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Related targets |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Test TV |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
NA |
NA |
Yes |
No |
No |
Yes |
No |
Yes |
No |
Yes |
NA |
NA |
NA |
Test results |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
BAL-SE-AA-B_V_Gotlandshavet
Regional assessment area |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
HELCOML2_SEA-010 |
|||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Component MRUs |
||||||||||||||||||||||
GES component |
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
D8
|
Feature |
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - non UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Contaminants - UPBT substances
|
Species
|
Species
|
Species
|
Species
|
Species
|
Acute pollution events
|
Element |
Anthracene |
Cadmium and its compounds |
Cesium-137 |
Cesium-137 |
Copper and its compounds |
Fluoranthene |
Hexachlorobenzene |
Lead and its compounds |
Non-dioxin like PCB (sum of 6 PCB: 28, 52, 101, 138, 153 and 180) |
Benzo(a)pyrene |
Dioxins and dioxin-like compounds (7 PCDDs + 10 PCDFs + 12 PCB-DLs) |
Hexabromocyclododecanes (HBCDD) |
Mercury and its compounds |
Pentabromodiphenylether |
Perfluorooctane sulfonic acid (PFOS) and its derivatives |
Tributyltin compounds |
Haliaeetus albicilla |
Haliaeetus albicilla |
Haliaeetus albicilla |
Monoporeia affinis |
Peringia ulvae |
|
Element extent |
||||||||||||||||||||||
Trend element |
Unknown |
Unknown |
Improving |
Improving |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Deteriorating |
Deteriorating |
Stable |
Stable |
|
Element 2 |
||||||||||||||||||||||
Element source |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
WaterFD |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
HELCOM |
|
Criterion |
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C1
|
D8C2
|
D8C2
|
D8C2
|
D8C2
|
D8C2
|
D8C3
|
Parameter |
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in water
|
Concentration in sediment
|
Concentration in sediment
|
Concentration in biota
|
Concentration in sediment
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in biota
|
Concentration in sediment
|
Other
|
Other
|
Other
|
Other
|
Imposex
|
Volume of oil
|
Threshold value upper |
24.0 |
2300.0 |
20.0 |
40.0 |
52000.0 |
2000.0 |
10.0 |
120000.0 |
75.0 |
5.0 |
6500.0 |
167.0 |
20.0 |
0.0085 |
9.1 |
1.6 |
0.97 |
1.64 |
59.0 |
0.1 |
||
Threshold value lower |
||||||||||||||||||||||
Threshold value operator |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
< |
> |
> |
> |
< |
<= |
|
Threshold qualitative |
proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
|||||||||||||||||||||
Threshold value source |
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Helsinki Convention
|
Helsinki Convention
|
National
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
Water Framework Directive (2000/60/EC)
|
National
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Helsinki Convention
|
Value achieved upper |
4.6 |
7820.0 |
3.6 |
20.0 |
50700.0 |
63.0 |
0.69 |
55200.0 |
13.5 |
0.2 |
2400.0 |
0.41 |
64.0 |
0.6 |
1.3 |
6.7 |
1.0 |
1.61 |
62.0 |
1.3 |
0.384 |
|
Value achieved lower |
||||||||||||||||||||||
Value unit |
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
Becquerels per kilogram of wet weight
|
Bq/m3
|
microgram per kilogram of dry weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
pg TEQ/g ww
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of wet weight
|
microgram per kilogram of dry weight
|
Other
|
Other
|
percentage
|
index VDSI
|
m3
|
|
Proportion threshold value |
||||||||||||||||||||||
Proportion value achieved |
||||||||||||||||||||||
Proportion threshold value unit |
||||||||||||||||||||||
Trend parameter |
Unknown |
Unknown |
Improving |
Improving |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Deteriorating |
Stable |
Stable |
Stable |
Stable |
Parameter achieved |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
No |
No |
Yes |
No |
Yes |
No |
Yes |
Yes |
No |
No |
Description parameter |
Concentration in herring, Clupea harengus
|
Concentrations in seawater
|
Productivity > 0,97 (nestlings). Produktivitet > 0,97 ungar per par.
|
Brood size > 1,64 (nestlings per successfully breeding pair). Kullstorlek > 1,64 ungar. |
Breeding success rate > 59 % (reproducing pairs). Häckningsframgång > 59 % |
|||||||||||||||||
Related indicator |
||||||||||||||||||||||
Criteria status |
Good |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Not good |
Not good |
Good |
Not good |
Not good |
Description criteria |
Criteria assessment based on two parameters: proportion of malformed embryos (threshold 5,9%) and the proportion of females with more than one malformed embryo (threshold 30%) |
|||||||||||||||||||||
Element status |
Good |
Not good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Good |
Not good |
Not good |
Good |
Not good |
Not good |
Not good |
Not good |
Good |
Not good |
|
Description element |
||||||||||||||||||||||
Source assessment feature |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type D |
Type A |
Trend feature |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Stable |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Stable |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
OOAO
|
Not relevant
|
Integration rule description parameter |
||||||||||||||||||||||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
||||||||||||||||||||||
GES extent threshold |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
100.00 |
|||||
GES extent achieved |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
87.50 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
57.10 |
||||||
GES extent unit |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Proportion of substances in good status |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
Not relevant |
GES achieved |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
GES later than 2024, Art14ExceptionReported |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
Not assessed |
GES later than 2024, Art14ExceptionNotReported |
Description overall status |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Article 14 exception reported for Cadmium. It is not possible to estimate when GES can be achieved in all assessment areas because there is no clear trend for all substances. |
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Sweden applies exceptions in Baltic Proper from achieving good environmental status for PBDE, mercury, TBT, dioxins and dioxin-like compounds. För hela Östersjön tillämpas undantag för PBDE och kvicksilver. För Egentliga Östersjön även för TBT och dioxin och dioxinlika föreningar.
On GESachievedDate: Concentrations of the substances that do not meet the threshold value are decreasing in many sea basins, but as these are long-lived, the threshold values are not expected to be reached in the near future. For PDBE, it has been estimated that it will take at least 18 years for concentrations to reach thresholds in the areas with the lowest concentrations of PBDEs in flows, while in most areas of the Baltic Sea it will take 30–40 years or longer (Undeman & Johansson 2020). Concentrations of TBT are decreasing in sediments, but degradation is slow and it is expected to take a long time before the threshold value can be met in all sea basins (Josefsson 2022). For mercury, there is no clear trend in Swedish marine waters and there is no estimate of when the threshold value can be met (Soerensen & Faxneld 2023a). The threshold for dioxins, furans and dioxin-like PCBs in fish is expected to be met in all stations in the Baltic Sea in 2025–2045 with a continued reduction corresponding to 2–6% per year (McLachlan & Undeman 2020).
Koncentrationer av de ämnen som inte klarar tröskelvärdet minskar i många havsbassänger men då dessa är långlivade förväntas tröskelvärdena inte nås i närtid. För PDBE har det beräknats ta minst 18 år för koncentrationerna att klara tröskelvärden i de områden med de lägsta koncentrationerna av PBDE i strömning, medan i de flesta områden i Östersjön kommer det att ta 30–40 år eller längre (Undeman & Johansson 2020). Koncentrationer av TBT minskar i sediment men nedbrytningen går långsamt och det förväntas ta lång tid innan tröskelvärdet kan klaras i samtliga havsbassänger (Josefsson 2022). För kvicksilver saknas en entydig trend i svenska marina vatten och det saknas en uppskattning om när tröskelvärdet kan klaras (Soerensen & Faxneld 2023a). Tröskelvärdet för dioxiner, furaner och dioxinlika PCB:er i fisk förväntas klaras i alla stationer i Östersjön 2025–2045 under en fortsatt minskning motsvarande 2–6 % per år (McLachlan & Undeman 2020).
|
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
|
Assessments period |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2021 |
2016-2035 |
2016-2035 |
2016-2035 |
2016-2035 |
2016-2035 |
2016-2021 |
Related pressures |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Related targets |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Test TV |
Yes |
No |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
No |
No |
Yes |
No |
Yes |
No |
Yes |
NA |
No |
NA |
Test results |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
Correct |
False |
Correct |
False |
BAL-SE-AA-BG_Bottniska_Viken
Regional assessment area |
|||
|---|---|---|---|
Component MRUs |
|||
GES component |
D8
|
D8
|
D8
|
Feature |
Species
|
Species
|
Species
|
Element |
Zoarces viviparus |
Zoarces viviparus |
Zoarces viviparus |
Element extent |
|||
Trend element |
Stable |
Stable |
Stable |
Element 2 |
|||
Element source |
National |
National |
National |
Criterion |
D8C2
|
D8C2
|
D8C2
|
Parameter |
Proportion - dead fry early
|
Proportion - dead fry late
|
Proportion - fry malformed
|
Threshold value upper |
5.0 |
4.0 |
2.0 |
Threshold value lower |
|||
Threshold value operator |
< |
< |
< |
Threshold qualitative |
|||
Threshold value source |
National
|
National
|
National
|
Value achieved upper |
0.5 |
0.4 |
0.3 |
Value achieved lower |
|||
Value unit |
percentage
|
percentage
|
percentage
|
Proportion threshold value |
|||
Proportion value achieved |
|||
Proportion threshold value unit |
|||
Trend parameter |
Stable |
Stable |
Stable |
Parameter achieved |
Yes |
Yes |
Yes |
Description parameter |
|||
Related indicator |
|||
Criteria status |
Good |
Good |
Good |
Description criteria |
|||
Element status |
Good |
Good |
Good |
Description element |
|||
Source assessment feature |
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Trend feature |
Not assessed |
Not assessed |
Not assessed |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
Integration rule description parameter |
|||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
|||
GES extent threshold |
|||
GES extent achieved |
|||
GES extent unit |
Not relevant |
Not relevant |
Not relevant |
GES achieved |
Not assessed |
Not assessed |
Not assessed |
Description overall status |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Assessments period |
2016-2022 |
2016-2022 |
2016-2022 |
Related pressures |
|
|
|
Related targets |
|
|
|
Test TV |
Yes |
Yes |
Yes |
Test results |
Correct |
Correct |
Correct |
BAL-SE-AA-BG_Egentliga_Ostersjon
Regional assessment area |
|||
|---|---|---|---|
Component MRUs |
|||
GES component |
D8
|
D8
|
D8
|
Feature |
Species
|
Species
|
Species
|
Element |
Zoarces viviparus |
Zoarces viviparus |
Zoarces viviparus |
Element extent |
|||
Trend element |
Stable |
Stable |
Stable |
Element 2 |
|||
Element source |
National |
National |
National |
Criterion |
D8C2
|
D8C2
|
D8C2
|
Parameter |
Proportion - dead fry early
|
Proportion - dead fry late
|
Proportion - fry malformed
|
Threshold value upper |
5.0 |
4.0 |
2.0 |
Threshold value lower |
|||
Threshold value operator |
< |
< |
< |
Threshold qualitative |
|||
Threshold value source |
National
|
National
|
National
|
Value achieved upper |
1.5 |
1.7 |
0.3 |
Value achieved lower |
|||
Value unit |
percentage
|
percentage
|
percentage
|
Proportion threshold value |
|||
Proportion value achieved |
|||
Proportion threshold value unit |
|||
Trend parameter |
Stable |
Stable |
Stable |
Parameter achieved |
Yes |
Yes |
Yes |
Description parameter |
|||
Related indicator |
|||
Criteria status |
Good |
Good |
Good |
Description criteria |
|||
Element status |
Good |
Good |
Good |
Description element |
|||
Source assessment feature |
|
|
|
Reporting method feature |
Type D |
Type D |
Type D |
Trend feature |
Not assessed |
Not assessed |
Not assessed |
Integration rule type parameter |
OOAO
|
OOAO
|
OOAO
|
Integration rule description parameter |
|||
Integration rule type criteria |
Not relevant
|
Not relevant
|
Not relevant
|
Integration rule description criteria |
|||
GES extent threshold |
|||
GES extent achieved |
|||
GES extent unit |
Not relevant |
Not relevant |
Not relevant |
GES achieved |
Not assessed |
Not assessed |
Not assessed |
Description overall status |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Indicators under D8C2 are not integrated to criteria level |
Assessments period |
2016-2023 |
2016-2023 |
2016-2023 |
Related pressures |
|
|
|
Related targets |
|
|
|
Test TV |
Yes |
Yes |
Yes |
Test results |
Correct |
Correct |
Correct |