Art11

Member State report / Art11 / 2014-2020 / D2 / Sweden / Baltic Sea

Report type	Member State report to Commission
MSFD Article	Art. 11 Monitoring programmes (and Art. 17 updates)
Report due	2014-10-15; 2020-10-15
GES Descriptor	D2 Non-indigenous species
Member State	Sweden
Region/subregion	Baltic Sea
Reported by	Swedish Agency for Marine and Water Management
Report date	2014-10-31; 2020-10-16
Report access	http://cdr.eionet.europa.eu/se/eu/msfd_mp/envvmgxwa/BALSE_MSFD11Mon_201410__REV.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/envvmgxwa/BALSE-EUTRO-D58-Atmosfartillforsel_20141031_REV.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/envvmgxwa/BALSE-HAZ-D8-Sediment_20141031_REV.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE_MSFD11Mon_201410__1.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-PEL-D145-Algblomning_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-PEL-D145-Djurplankton_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-PEL-D145-Vaxtplankton_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-PEL-D145-Pigment_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-BENT-D165-Vegetation_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-mammals-D14-Sal_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-mammals-D14-Tumlare_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-Birds-D14-Overvintrande_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HAZfood-D9-Fiskmuskel_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HAZ-D8-Imposex_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HAZ-D814-Fiskhalsa_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HAZ-D814-Salhalsa_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HAZ-D814-Havsorn_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HAZ-D8-Vitmarla_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HAZ-D8-Biota_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HAZ-D8-Sediment_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HYDRO-D72-Kylvatten_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-EUTRO-D58-Landtillforsel_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-EUTRO-D5-Forsurning_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-EUTRO-D5-Transparens_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-EUTRO-D5-Naringsed_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-COMFISH-D314-Lax_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-COMFISH-D314-Al_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-NIS-D2-Hamn_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-NIS-D2-Utsattning_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-BENT-D168-MudDump_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-BENT-D16-Tralning_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-BENT-D165-Bottenfauna_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-Fish-D14-Kust_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-Birds-D14-Hackande_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-Litter-D10-Botten_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-Litter-D10-Strand_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HAZ-D8-Olja_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HAZ-D8-Radionuklider_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HYDRO-D7-Strommar_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-HYDRO-D7-Tempsalt_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-EUTRO-D58-Atmosfartillforsel_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-EUTRO-D5-Patogener_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-EUTRO-D514-Syre_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-EUTRO-D5-Naringvatt_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-COMFISH-D3-Utkast_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-COMFISH-D3-Pelagisk_20141031.xml http://cdr.eionet.europa.eu/se/eu/msfd_mp/copy_of_ansse/copy_of_envu7aqjg/BALSE-COMFISH-D3-Bottenlevande_20141031.xml https://cdr.eionet.europa.eu/se/eu/msfd_art17/2020reporting/xmldata/envx4laeq/ART11_SE_MONprog_v5.xml https://cdr.eionet.europa.eu/se/eu/msfd_art17/2020reporting/xmldata/envx4laeq/ART11_SE_MONstrat_v4.xml

Simplified table

2014 data

2020 data

Monitoring programme	Monitoring programme name	MP_D2	MP_D2	MP_D2	MP_D2	MP_D2	MP_D2
Monitoring programme	Reference existing programme
Monitoring programme	Marine Unit ID
Q4e - Programme ID		BALSE-NIS-D2	BALSE-NIS-D2	BALSE-NIS-D2	BALSE-NIS-D2	BALSE-NIS-D2	BALSE-NIS-D2
Q4f - Programme description		See programme Främmande arter (D2), chapter Programets generella ansats	See programme Främmande arter (D2), chapter Programets generella ansats	See programme Främmande arter (D2), chapter Programets generella ansats	See programme Främmande arter (D2), chapter Programets generella ansats	See programme Främmande arter (D2), chapter Programets generella ansats	See programme Främmande arter (D2), chapter Programets generella ansats
Q5e - Natural variability		ExpertOpinion	ExpertOpinion	ExpertOpinion	ExpertOpinion	ExpertOpinion	ExpertOpinion
Q5d - Adequacy for assessment of GES	Q5d - Adequate data	N	N	N	N	N	N
Q5d - Adequacy for assessment of GES	Q5d - Established methods	N	N	N	N	N	N
Q5d - Adequacy for assessment of GES	Q5d - Adequate understanding of GES	Y	Y	Y	Y	Y	Y
Q5d - Adequacy for assessment of GES	Q5d - Adequate capacity	Y	Y	Y	Y	Y	Y
Q5f - Description of programme for GES assessment		a. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet b. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet c. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet d. See programme Främmande arter (D2), chapter Programets generella ansats e. See programme Främmande arter (D2), chapter Programets generella ansats	a. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet b. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet c. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet d. See programme Främmande arter (D2), chapter Programets generella ansats e. See programme Främmande arter (D2), chapter Programets generella ansats	a. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet b. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet c. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet d. See programme Främmande arter (D2), chapter Programets generella ansats e. See programme Främmande arter (D2), chapter Programets generella ansats	a. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet b. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet c. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet d. See programme Främmande arter (D2), chapter Programets generella ansats e. See programme Främmande arter (D2), chapter Programets generella ansats	a. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet b. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet c. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet d. See programme Främmande arter (D2), chapter Programets generella ansats e. See programme Främmande arter (D2), chapter Programets generella ansats	a. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet b. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet c. See programme Främmande arter (D2), chapter Bedömning av tillräcklighet d. See programme Främmande arter (D2), chapter Programets generella ansats e. See programme Främmande arter (D2), chapter Programets generella ansats
Q5g - Gap-filling date for GES assessment		By2018	By2018	By2018	By2018	By2018	By2018
Q5h - Plans to implement monitoring for GES assessment		See programme Främmande arter (D2), chapter Slutsatser	See programme Främmande arter (D2), chapter Slutsatser	See programme Främmande arter (D2), chapter Slutsatser	See programme Främmande arter (D2), chapter Slutsatser	See programme Främmande arter (D2), chapter Slutsatser	See programme Främmande arter (D2), chapter Slutsatser
Q6a -Relevant targets	Q6a - Environmental target	C.1 C.2	C.1 C.2	C.1 C.2	C.1 C.2	C.1 C.2	C.1 C.2
Q6a -Relevant targets	Q6a - Associated indicator
Q6b - Adequacy for assessment of targets	Q6b_SuitableData	N	N	N	N	N	N
Q6b - Adequacy for assessment of targets	Q6b_EstablishedMethods	N	N	N	N	N	N
Q6b - Adequacy for assessment of targets	Q6d_AdequateCapacity	Y	Y	Y	Y	Y	Y
Q6c - Target updating		Y	Y	Y	Y	Y	Y
Q6d - Description of programme for targets assessment		See programme Främmande arter (D2), chapter Bedömning av tillräcklighet, section Miljökvalitetsnormer	See programme Främmande arter (D2), chapter Bedömning av tillräcklighet, section Miljökvalitetsnormer	See programme Främmande arter (D2), chapter Bedömning av tillräcklighet, section Miljökvalitetsnormer	See programme Främmande arter (D2), chapter Bedömning av tillräcklighet, section Miljökvalitetsnormer	See programme Främmande arter (D2), chapter Bedömning av tillräcklighet, section Miljökvalitetsnormer	See programme Främmande arter (D2), chapter Bedömning av tillräcklighet, section Miljökvalitetsnormer
Q6e - Gap-filling date for targets assessment		By2018	By2020	By2018	By2020	By2018	By2020
Q6f - Plans to implement monitoring for targets assessment		See programme Främmande arter (D2), chapter Slutsatser	See programme Främmande arter (D2), chapter Slutsatser	See programme Främmande arter (D2), chapter Slutsatser	See programme Främmande arter (D2), chapter Slutsatser	See programme Främmande arter (D2), chapter Slutsatser	See programme Främmande arter (D2), chapter Slutsatser
Q7a - Relevant activities		Release of non-indigenous species (based on permits) UsesActivitiesOther	Release of non-indigenous species (based on permits) UsesActivitiesOther	Release of non-indigenous species (based on permits) UsesActivitiesOther	Release of non-indigenous species (based on permits) UsesActivitiesOther	Release of non-indigenous species (based on permits) UsesActivitiesOther	Release of non-indigenous species (based on permits) UsesActivitiesOther
Q7b - Description of monitoring of activities		See programme Främmande arter (D2), chapter Programmets generella ansats, (three last sections)	See programme Främmande arter (D2), chapter Programmets generella ansats, (three last sections)	See programme Främmande arter (D2), chapter Programmets generella ansats, (three last sections)	See programme Främmande arter (D2), chapter Programmets generella ansats, (three last sections)	See programme Främmande arter (D2), chapter Programmets generella ansats, (three last sections)	See programme Främmande arter (D2), chapter Programmets generella ansats, (three last sections)
Q7c - Relevant measures
Q7e - Adequacy for assessment of measures	Q7d - Adequate data
Q7e - Adequacy for assessment of measures	Q7d - Established methods
Q7e - Adequacy for assessment of measures	Q7d - Adequate understanding of GES
Q7e - Adequacy for assessment of measures	Q7d - Adequate capacity
Q7e - Adequacy for assessment of measures	Q7d - Addresses activities and pressures
Q7e - Adequacy for assessment of measures	Q7d - Addresses effectiveness of measures
Q7d - Description of monitoring for measures
Q7f - Gap-filling date for activities and measures		By2020	By2014	By2020	By2014	By2020	By2014
Q8a - Links to existing Monitoring Programmes		CBD (Article 8h), Ballast Water Management Convention HELCOM WFD	CBD (Article 8h), Ballast Water Management Convention HELCOM WFD	CBD (Article 8h), Ballast Water Management Convention HELCOM WFD	CBD (Article 8h), Ballast Water Management Convention HELCOM WFD	CBD (Article 8h), Ballast Water Management Convention HELCOM WFD	CBD (Article 8h), Ballast Water Management Convention HELCOM WFD
Reference sub-programme	Sub-programme ID	BALSE-HYDRO-D72-Kylvatten	BALSE-HYDRO-D72-Kylvatten	BALSE-NIS-D2-Hamn	BALSE-NIS-D2-Hamn	BALSE-NIS-D2-Utsattning	BALSE-NIS-D2-Utsattning
Reference sub-programme	Sub-programme name	Other	Other	Non-indigenous species - abundance and/or biomass	Non-indigenous species - abundance and/or biomass	Non-indigenous species inputs - from specific sources	Non-indigenous species inputs - from specific sources
Q4g - Sub-programmes	Sub-programme ID	BALSE-HYDRO-D72-Kylvatten	BALSE-HYDRO-D72-Kylvatten	BALSE-NIS-D2-Hamn	BALSE-NIS-D2-Hamn	BALSE-NIS-D2-Utsattning	BALSE-NIS-D2-Utsattning
Q4g - Sub-programmes	Sub-programme name	Other	Other	Non-indigenous species - abundance and/or biomass	Non-indigenous species - abundance and/or biomass	Non-indigenous species inputs - from specific sources	Non-indigenous species inputs - from specific sources



Q4k - Monitoring purpose		StateImpact	StateImpact	StateImpact	StateImpact	Activities	Activities
Q4l - Links of monitoring programmes of other Directives and Conventions		Not relevant	Not relevant	Monitoring for the WFD Protocol developed for HELCOM and OSPAR regions for monitoring NIS in ports (Ballast Water Management Convention ) Monitoring for implementing of Article 8 of the Convention of Biological Diversity (CBD)	Monitoring for the WFD Protocol developed for HELCOM and OSPAR regions for monitoring NIS in ports (Ballast Water Management Convention ) Monitoring for implementing of Article 8 of the Convention of Biological Diversity (CBD)	Monitoring for the WFD Monitoring for implementing of Article 8 of the Convention of Biological Diversity (CBD)	Monitoring for the WFD Monitoring for implementing of Article 8 of the Convention of Biological Diversity (CBD)




Q5c - Features	Q5c - Habitats
Q5c - Features	Q5c - Species list
Q5c - Features	Q5c - Physical/Chemical features
Q5c - Features	Q5c - Pressures	IntroNIS	IntroNIS	IntroNIS	IntroNIS	IntroNIS	IntroNIS
Q9a - Elements		All coastal fish (including parr, and warm-/coldwater species), for example - Atlantic eel (Anguilla anguilla), perch (Perca fluviatilis), roach (Rutilus rutilus), european flounder (Platichthys flesus),, pike (Esox lucius ), banstickle (Gasterosteus aculeatus ), pike perch (Sander lucioperca ), whitefish (Coregonidae ), baltic herring (Clupea harengus)Swimbladder parasites (Anguillicola)	All coastal fish (including parr, and warm-/coldwater species), for example - Atlantic eel (Anguilla anguilla), perch (Perca fluviatilis), roach (Rutilus rutilus), european flounder (Platichthys flesus),, pike (Esox lucius ), banstickle (Gasterosteus aculeatus ), pike perch (Sander lucioperca ), whitefish (Coregonidae ), baltic herring (Clupea harengus)Swimbladder parasites (Anguillicola)	Nationally listed non-indigenous species	Nationally listed non-indigenous species	Release of NIS based on permits and that deviates from the strategy.	Release of NIS based on permits and that deviates from the strategy.
Q5a - GES criteria	Relevant GES criteria	2.1	2.1	2.1	2.1	2.1	2.1
Q5b - GES indicators	Relevant GES indicators	2.1.1 GESOther See bilaga 5 Indikatorer	2.1.1 GESOther See bilaga 5 Indikatorer	2.1.1 GESOther See bilaga 5 Indikatorer	2.1.1 GESOther See bilaga 5 Indikatorer	2.1.1 GESOther See bilaga 5 Indikatorer	2.1.1 GESOther See bilaga 5 Indikatorer
Q9b - Parameters monitored (state/impact)	Species distribution
Q9b - Parameters monitored (state/impact)	Species population size	MP-9b-1-2-1	MP-9b-1-2-1
Q9b - Parameters monitored (state/impact)	Species population characteristics	MP-9b-1-3-1	MP-9b-1-3-1
Q9b - Parameters monitored (state/impact)	Species impacts	MP-9b-1-4-7	MP-9b-1-4-7
Q9b - Parameters monitored (state/impact)	Habitat distribution
Q9b - Parameters monitored (state/impact)	Habitat extent
Q9b - Parameters monitored (state/impact)	Habitat condition (physical-chemical)
Q9b - Parameters monitored (state/impact)	Habitat condition (biological)	MP-9b-1-8-1	MP-9b-1-8-1
Q9b - Parameters monitored (state/impact)	Habitat impacts	MP-9b-1-9-1	MP-9b-1-9-1
Q9b - Parameters monitored (pressures)	Pressure input
Q9b - Parameters monitored (pressures)	Pressure output	MP-9b-2-2-1	MP-9b-2-2-1	MP-9b-2-2-5	MP-9b-2-2-5
Q9b - Parameters monitored (activity)	Activity					MP-9b-3-1-1 MP-9b-3-1-2 MP-9b-3-1-3 MP-9b-3-1-4	MP-9b-3-1-1 MP-9b-3-1-2 MP-9b-3-1-3 MP-9b-3-1-4
Q9b Parameters monitored (other)	Other	MP-9b-4-1-1	MP-9b-4-1-1
Q41 Spatial scope		WFD_CW	WFD_CW	WFD_TW WFD_CW TerritorialWaters	WFD_TW WFD_CW TerritorialWaters	WFD_TW WFD_CW TerritorialWaters	WFD_TW WFD_CW TerritorialWaters
Q4j - Description of spatial scope		See sub-programme Effekter av kylvatten, chapter Rumslig och tidsmässig täckning	See sub-programme Effekter av kylvatten, chapter Rumslig och tidsmässig täckning	See sub-programme Främmande arter i hamnar, farleder och utsattta områden, chapter Rumslig och tidsmässig täckning	See sub-programme Främmande arter i hamnar, farleder och utsattta områden, chapter Rumslig och tidsmässig täckning	See sub-programme Utsättning av främmande arter, chapter Rumslig och tidsmässig täckning	See sub-programme Utsättning av främmande arter, chapter Rumslig och tidsmässig täckning
Marine Unit IDs		BAL-SE-RG-Ostersjon	BAL-SE-RG-Ostersjon	BAL-SE-RG-Ostersjon	BAL-SE-RG-Ostersjon	BAL-SE-RG-Ostersjon	BAL-SE-RG-Ostersjon
Q4h - Temporal scope	Start date- End date	1962-9999	1962-9999	2016-9999	2016-9999	2016-9999	2016-9999
Q9h - Temporal resolution of sampling		Other Varies between 3 times during 12 days and 2-weekly during 3,5 months	Other Varies between 3 times during 12 days and 2-weekly during 3,5 months	3yearly	3yearly	Other Temporal frequency depends on the frequency of granted releases. Collection of data should be done yearly.	Other Temporal frequency depends on the frequency of granted releases. Collection of data should be done yearly.

Q9c - Monitoring method		Provfiske i Östersjöns kustområden – Djupstratifierat provfiske med Nordiska kustöversiktsnät https://www.havochvatten.se/download/18.64f5b3211343cffddb280005491/1348912813575/Provfiske+i+%C3%96stersj%C3%B6ns+kustomr%C3%A5den-+Djupstratifierat+provfiske+med+Nordiska+kust%C3%B6versiktsn%C3%A4t.pdf	Provfiske i Östersjöns kustområden – Djupstratifierat provfiske med Nordiska kustöversiktsnät https://www.havochvatten.se/download/18.64f5b3211343cffddb280005491/1348912813575/Provfiske+i+%C3%96stersj%C3%B6ns+kustomr%C3%A5den-+Djupstratifierat+provfiske+med+Nordiska+kust%C3%B6versiktsn%C3%A4t.pdf			Parameters to be monitored are the waters in which fish stocking has occurred, the amount of fish species and strains that have been released, dissemination opportunities in the area, genetic origin of released material, who has applied for a license and performed the release, and when and how the release was performed, and risk category for health status.	Parameters to be monitored are the waters in which fish stocking has occurred, the amount of fish species and strains that have been released, dissemination opportunities in the area, genetic origin of released material, who has applied for a license and performed the release, and when and how the release was performed, and risk category for health status.
Q9d - Description of alteration to method		See sub-programme Effekter av kylvatten, chapter Metoder	See sub-programme Effekter av kylvatten, chapter Metoder	See sub-programme Främmande arter i hamnar, farleder och utsattta områden, chapter Metoder	See sub-programme Främmande arter i hamnar, farleder och utsattta områden, chapter Metoder
Q9e - Quality assurance		Internal procedures are available at SLU in the form of a checklist for the various stages of monitoring. Further work on the quality assurance of monitoring procedures and data is currently underway as part of an overall quality program at SLU. Other	Internal procedures are available at SLU in the form of a checklist for the various stages of monitoring. Further work on the quality assurance of monitoring procedures and data is currently underway as part of an overall quality program at SLU. Other	Other See sub-programme Främmande arter i hamnar, farleder och utsattta områden, chapter Metoder	Other See sub-programme Främmande arter i hamnar, farleder och utsattta områden, chapter Metoder	Other Regular point efforts should be made in the form of training for personnel at county administrative boards and SwAM to insure correct data input into the database, as well as regular follow-ups for quality assurance and validation of data.	Other Regular point efforts should be made in the form of training for personnel at county administrative boards and SwAM to insure correct data input into the database, as well as regular follow-ups for quality assurance and validation of data.
Q9f - Quality control		OtherQC	OtherQC	Unknown	Unknown	OtherQC	OtherQC
Q9g - Spatial resolution of sampling	Q9g - Proportion of area covered %	100	100	1	1	100	100
Q9g - Spatial resolution of sampling	Q9g - No. of samples	720	720	15 samples (3 samples from 5 locations)/ every 3 years Ca. 30 samples during the 6-year reporting cycle	15 samples (3 samples from 5 locations)/ every 3 years Ca. 30 samples during the 6-year reporting cycle	In total around 1500-2000 permits per year including lakes and rivers and in the sea (the North sea and the Baltic Sea).	In total around 1500-2000 permits per year including lakes and rivers and in the sea (the North sea and the Baltic Sea).
Q9i - Description of sample representivity		See sub-programme Effekter av kylvatten, parameter table in the initial section, chapter Rumslig och tidsmässig täckning and Metoder	See sub-programme Effekter av kylvatten, parameter table in the initial section, chapter Rumslig och tidsmässig täckning and Metoder	See sub-programme Främmande arter i hamnar, farleder och utsattta områden, chapter Rumslig och tidsmässig täckning and chapter Metoder	See sub-programme Främmande arter i hamnar, farleder och utsattta områden, chapter Rumslig och tidsmässig täckning and chapter Metoder	See sub-programme Utsättning av främmande arter, chapter Rumslig och tidsmässig täckning samt metoder	See sub-programme Utsättning av främmande arter, chapter Rumslig och tidsmässig täckning samt metoder
Q10a - Scale for aggregation of data		Other See 10b	Other See 10b	Other See 10b	Other See 10b	Unknown	Unknown
Q10b - Other scale for aggregation of data		The monitoring methods is adapted to the specific pressure and to the environmental conditions in the surrounding waters of the nuclear power plants. Data could be aggregated with similar data from other countries with similar environmental preconditions.	The monitoring methods is adapted to the specific pressure and to the environmental conditions in the surrounding waters of the nuclear power plants. Data could be aggregated with similar data from other countries with similar environmental preconditions.	It will be possible to aggregate data with similar data from other countries using the online decision support tool described in HELCOM ALIENS 3 – Tests of the Harmonized Approach to Ballast Water Management Exemptions in the Baltic (chapter 5).	It will be possible to aggregate data with similar data from other countries using the online decision support tool described in HELCOM ALIENS 3 – Tests of the Harmonized Approach to Ballast Water Management Exemptions in the Baltic (chapter 5).
Q10c - Access to monitoring data	Q10c - Data type	UnprocessedData ProcessedData DataProducts	UnprocessedData ProcessedData DataProducts	ProcessedData	ProcessedData	UnprocessedData ProcessedData	UnprocessedData ProcessedData
Q10c - Access to monitoring data	Q10c - Data access mechanism	LocationNationalDC	LocationNationalDC	URLdownload	URLdownload	URLdownload	URLdownload
Q10c - Access to monitoring data	Q10c - Data access rights	Moratorium	Moratorium	Open	Open	RestrictedGeneral	RestrictedGeneral
Q10c - Access to monitoring data	Q10c - INSPIRE standard
Q10c - Access to monitoring data	Q10c Date data are available	2014-09	2014-09	2017-01	2017-01	2016-01	2016-01
Q10c - Access to monitoring data	Q10c - Data update frequency	Yearly	Yearly	3yearly	3yearly	Yearly	Yearly
Q10d - Description of data access		See sub-programme Effekter av kylvatten, chapter Var finns data	See sub-programme Effekter av kylvatten, chapter Var finns data	See sub-programme Främmande arter i hamnar, farleder och utsattta områden, chapter Var finns data	See sub-programme Främmande arter i hamnar, farleder och utsattta områden, chapter Var finns data	See sub-programme Utsättning av främmande arter, chapter Var finns data	See sub-programme Utsättning av främmande arter, chapter Var finns data

Descriptor	D2	D2	D2	D2	D2	D2	D2	D2	D2	D2	D2	D2	D2



Monitoring strategy description	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "	"IInternational co-operation within the UN Convention on Biological Diversity and the Ballast Water Management Convention is of great importance for the work in Sweden regarding monitoring and management of marine non-indigenous species (NIS). Sweden participates in this mainly through regional coordination within Helcom and Ospar for the development and application of appropriate monitoring methods for early detection of NIS as well as warning to other countries' authorities. Within a national collaboration between the Swedish Transport Agency, the Swedish University of Agricultural Sciences (SLU), the Swedish Meteorological and Hydrological Institute (SMHI) and the Swedish Agency for Marine and Water Management (SwAM) the relations and roles is well defined. Lists of alien species have been produced nationally, regionally and on an EU-level, based on their risk of adverse effects, such as the Target species list for ballast water exemptions. In Sweden, a risk list has been produced by the SLU Swedish Species Information Centre (Strand et al. 2018). The risk list provides guidance on which species are invasive in Sweden and therefore should be prioritized in monitoring and assessment, but also in measures. For aquatic NIS, SwAM has also produced a focus list with species already established, or with the risk of being introduced. The purpose of the focus list is to encourage researchers and agencies carrying out biological monitoring to report NIS to SwAM to improve the dataflow from early detection and spread of already established species and thus bring about effective measures. The list in 2020 consists of a total of 57 species, of which 24 are marine or eustarine and of these, 13 are door knocker species. Pathways of introductions of NIS have been examined both nationally and in Helcom and Ospar. This has led to measures being implemented within the Ballast Water Management Convention and International Maritime Organization to reduce the load from namely ballast water and biofouling. This has also led to a project in which hotspots for introductions of NIS were identified, based on pathways analysis. These hotspots indicates which premises the monitoring should take place in , in order to effectively detect new introductions. NIS is also monitored in areas with nuclear power plants as well as from pulp and paper industry with extensive cooling water discharge which also helps to predict risk of introduction and establishment due to climate change. "






Coverage of GES criteria	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024
Gaps and plans	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."	"In order for future assessments to be more accurate, they need to be based on data with better geographical coverage. Starting 2020 monitoring of hotspots generated using a newly developed model (Bergkvist et al. 2020) will be carried out. The model identified areas that consist of ports and marinas on the west coast, in the Sound (the Danish–Swedish border) and in the Baltic Proper. However, it turns out that the risk of hotspots is much lower in the Gulf of Bothnia. Before the station network changes, the next step will be to carry out a modelling of the risk of limnic species being introduced in the Gulf of Bothnia, to see how it affects the selection of hotspots. By further developing the ongoing citizen science where the public reports sightings of alien species, there is great potential for data of higher quality, mainly regarding accuracy and reliability. A validation system to secure data is being developed through collaboration with the Swedish EPA, the County administrative boards and the SLU Swedish Species Information Centre. In addition, technical support has been launched for validation of reports and with alarm functions that facilitate rapid measures as response to reports of introductions. Using eDNA for monitoring has been tested and are further developed in several ongoing national funded research projects and research networks, with the aim to promote cooperation between environmental monitoring and research that favours the development and use of quality-assured DNA methods for monitoring and environmental analysis. The Swedish research also collaborate with the European network DNAqua-net. At present, there is no established concept of method for monitoring the impact on native species and habitats from NIS, but in connection with the development of monitoring of introductions of NIS, Sweden is also reviewing the developments in research and monitoring projects in other countries where impacts of NIS are monitored."
Related targets	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter	ANSSE-C.1_Introduktion_främmande arter BALSE-C.1_Introduktion_främmande arter






Coverage of targets	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024



Related measures	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'	ANSSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' ANSSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' ANSSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' ANSSE-M034 - 'National environmental targets' ANSSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' ANSSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species' BALSE-M001 - 'ÅPH 1 - design a pilot project to develop methods for control and local combating of invasive non-indigenous species.' BALSE-M002 - 'ÅPH 2 - To develop technical tools to improve the availability and quality of information on alien species' BALSE-M003 - 'ÅPH 3 - To develop a national warning and response system for early detection of new invasive alien species, together with handling and emergency plans for these species' BALSE-M040 - 'Council Regulation (EC) No 708/2007 of 11 June 2007 concerning use of alien and locally absent species in aquaculture' BALSE-M041 - 'Regulation (EU) No 1143/2014 of the European Parliament and of the Council of 22 October 2014 on the prevention and management of the introduction and spread of invasive alien species'







Coverage of measures	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024	Adequate monitoring will be in place by 2024

Related monitoring programmes	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen	SE-D1D2D7-outfalls SE-D2-NIS SE-D2-citizen

Programme code	SE-D1D2D7-outfalls	SE-D1D2D7-outfalls	SE-D1D2D7-outfalls	SE-D1D2D7-outfalls	SE-D1D2D7-outfalls	SE-D1D2D7-outfalls	SE-D1D2D7-outfalls	SE-D1D2D7-outfalls	SE-D1D2D7-outfalls	SE-D2-NIS	SE-D2-NIS	SE-D2-citizen	SE-D2-citizen
Programme name	Effects of outfalls from power stations	Effects of outfalls from power stations	Effects of outfalls from power stations	Effects of outfalls from power stations	Effects of outfalls from power stations	Effects of outfalls from power stations	Effects of outfalls from power stations	Effects of outfalls from power stations	Effects of outfalls from power stations	Non-indigenous species - Input and spread	Non-indigenous species - Input and spread	Citizen science regarding NIS	Citizen science regarding NIS
Update type	Modified from 2014	Modified from 2014	Modified from 2014	Modified from 2014	Modified from 2014	Modified from 2014	Modified from 2014	Modified from 2014	Modified from 2014	Modified from 2014	Modified from 2014	New programme	New programme
Old programme codes	ANSSE-HYDRO-D72-Kylvatten BALSE-HYDRO-D72-Kylvatten	ANSSE-HYDRO-D72-Kylvatten BALSE-HYDRO-D72-Kylvatten	ANSSE-HYDRO-D72-Kylvatten BALSE-HYDRO-D72-Kylvatten	ANSSE-HYDRO-D72-Kylvatten BALSE-HYDRO-D72-Kylvatten	ANSSE-HYDRO-D72-Kylvatten BALSE-HYDRO-D72-Kylvatten	ANSSE-HYDRO-D72-Kylvatten BALSE-HYDRO-D72-Kylvatten	ANSSE-HYDRO-D72-Kylvatten BALSE-HYDRO-D72-Kylvatten	ANSSE-HYDRO-D72-Kylvatten BALSE-HYDRO-D72-Kylvatten	ANSSE-HYDRO-D72-Kylvatten BALSE-HYDRO-D72-Kylvatten	ANSSE-NIS-D2-Hamn BALSE-NIS-D2-Hamn	ANSSE-NIS-D2-Hamn BALSE-NIS-D2-Hamn
Programme description	A nuclear power plant affects the marine environment mainly through the use of large volumes of seawater for cooling. The cooling water is purified at the intake, which to some extent reduces the loss of organisms that would otherwise accompany the intake, but for those who follow, mortality occurs mechanically and thermally when the water passes through the power plant. The outgoing cooling water is 10° C warmer than the water taken in. The hot water is then spread over relatively large areas, where the organisms can be affected. The warm water can also make it easier for non-indigenous species to get established than in other areas. To control the effects of cooling water use, extensive control programmes have been established at and around the Swedish nuclear power plants since the nuclear power plants were established. In Sweden, there are nuclear power plants at one site in the North Sea (Ringhals nuclear power plant) and two in the Baltic Sea (Forsmark nuclear power plant and Oskarshamnsverket). Electricity production at the power plant in Barsebäck by the Sound ceased in 2005. Monitoring in the North sea started in 1968 and in the Baltic sea in 1969. Monitoring frequency varies from daily during spring/summer, to monthly or yearly depending on the parameter, location and purpose. Details are described in the monitoring fact sheet linked below. The nuclear power plants are undergoing a slow decommissioning, for example at Ringhals, two out of four reactors are planned to be shut down in the near future. As the monitoring is connected to the industry, it will also in the long run be phased out after the activity has ended and the effects have ceased.	A nuclear power plant affects the marine environment mainly through the use of large volumes of seawater for cooling. The cooling water is purified at the intake, which to some extent reduces the loss of organisms that would otherwise accompany the intake, but for those who follow, mortality occurs mechanically and thermally when the water passes through the power plant. The outgoing cooling water is 10° C warmer than the water taken in. The hot water is then spread over relatively large areas, where the organisms can be affected. The warm water can also make it easier for non-indigenous species to get established than in other areas. To control the effects of cooling water use, extensive control programmes have been established at and around the Swedish nuclear power plants since the nuclear power plants were established. In Sweden, there are nuclear power plants at one site in the North Sea (Ringhals nuclear power plant) and two in the Baltic Sea (Forsmark nuclear power plant and Oskarshamnsverket). Electricity production at the power plant in Barsebäck by the Sound ceased in 2005. Monitoring in the North sea started in 1968 and in the Baltic sea in 1969. Monitoring frequency varies from daily during spring/summer, to monthly or yearly depending on the parameter, location and purpose. Details are described in the monitoring fact sheet linked below. The nuclear power plants are undergoing a slow decommissioning, for example at Ringhals, two out of four reactors are planned to be shut down in the near future. As the monitoring is connected to the industry, it will also in the long run be phased out after the activity has ended and the effects have ceased.	A nuclear power plant affects the marine environment mainly through the use of large volumes of seawater for cooling. The cooling water is purified at the intake, which to some extent reduces the loss of organisms that would otherwise accompany the intake, but for those who follow, mortality occurs mechanically and thermally when the water passes through the power plant. The outgoing cooling water is 10° C warmer than the water taken in. The hot water is then spread over relatively large areas, where the organisms can be affected. The warm water can also make it easier for non-indigenous species to get established than in other areas. To control the effects of cooling water use, extensive control programmes have been established at and around the Swedish nuclear power plants since the nuclear power plants were established. In Sweden, there are nuclear power plants at one site in the North Sea (Ringhals nuclear power plant) and two in the Baltic Sea (Forsmark nuclear power plant and Oskarshamnsverket). Electricity production at the power plant in Barsebäck by the Sound ceased in 2005. Monitoring in the North sea started in 1968 and in the Baltic sea in 1969. Monitoring frequency varies from daily during spring/summer, to monthly or yearly depending on the parameter, location and purpose. Details are described in the monitoring fact sheet linked below. The nuclear power plants are undergoing a slow decommissioning, for example at Ringhals, two out of four reactors are planned to be shut down in the near future. As the monitoring is connected to the industry, it will also in the long run be phased out after the activity has ended and the effects have ceased.	A nuclear power plant affects the marine environment mainly through the use of large volumes of seawater for cooling. The cooling water is purified at the intake, which to some extent reduces the loss of organisms that would otherwise accompany the intake, but for those who follow, mortality occurs mechanically and thermally when the water passes through the power plant. The outgoing cooling water is 10° C warmer than the water taken in. The hot water is then spread over relatively large areas, where the organisms can be affected. The warm water can also make it easier for non-indigenous species to get established than in other areas. To control the effects of cooling water use, extensive control programmes have been established at and around the Swedish nuclear power plants since the nuclear power plants were established. In Sweden, there are nuclear power plants at one site in the North Sea (Ringhals nuclear power plant) and two in the Baltic Sea (Forsmark nuclear power plant and Oskarshamnsverket). Electricity production at the power plant in Barsebäck by the Sound ceased in 2005. Monitoring in the North sea started in 1968 and in the Baltic sea in 1969. Monitoring frequency varies from daily during spring/summer, to monthly or yearly depending on the parameter, location and purpose. Details are described in the monitoring fact sheet linked below. The nuclear power plants are undergoing a slow decommissioning, for example at Ringhals, two out of four reactors are planned to be shut down in the near future. As the monitoring is connected to the industry, it will also in the long run be phased out after the activity has ended and the effects have ceased.	A nuclear power plant affects the marine environment mainly through the use of large volumes of seawater for cooling. The cooling water is purified at the intake, which to some extent reduces the loss of organisms that would otherwise accompany the intake, but for those who follow, mortality occurs mechanically and thermally when the water passes through the power plant. The outgoing cooling water is 10° C warmer than the water taken in. The hot water is then spread over relatively large areas, where the organisms can be affected. The warm water can also make it easier for non-indigenous species to get established than in other areas. To control the effects of cooling water use, extensive control programmes have been established at and around the Swedish nuclear power plants since the nuclear power plants were established. In Sweden, there are nuclear power plants at one site in the North Sea (Ringhals nuclear power plant) and two in the Baltic Sea (Forsmark nuclear power plant and Oskarshamnsverket). Electricity production at the power plant in Barsebäck by the Sound ceased in 2005. Monitoring in the North sea started in 1968 and in the Baltic sea in 1969. Monitoring frequency varies from daily during spring/summer, to monthly or yearly depending on the parameter, location and purpose. Details are described in the monitoring fact sheet linked below. The nuclear power plants are undergoing a slow decommissioning, for example at Ringhals, two out of four reactors are planned to be shut down in the near future. As the monitoring is connected to the industry, it will also in the long run be phased out after the activity has ended and the effects have ceased.	A nuclear power plant affects the marine environment mainly through the use of large volumes of seawater for cooling. The cooling water is purified at the intake, which to some extent reduces the loss of organisms that would otherwise accompany the intake, but for those who follow, mortality occurs mechanically and thermally when the water passes through the power plant. The outgoing cooling water is 10° C warmer than the water taken in. The hot water is then spread over relatively large areas, where the organisms can be affected. The warm water can also make it easier for non-indigenous species to get established than in other areas. To control the effects of cooling water use, extensive control programmes have been established at and around the Swedish nuclear power plants since the nuclear power plants were established. In Sweden, there are nuclear power plants at one site in the North Sea (Ringhals nuclear power plant) and two in the Baltic Sea (Forsmark nuclear power plant and Oskarshamnsverket). Electricity production at the power plant in Barsebäck by the Sound ceased in 2005. Monitoring in the North sea started in 1968 and in the Baltic sea in 1969. Monitoring frequency varies from daily during spring/summer, to monthly or yearly depending on the parameter, location and purpose. Details are described in the monitoring fact sheet linked below. The nuclear power plants are undergoing a slow decommissioning, for example at Ringhals, two out of four reactors are planned to be shut down in the near future. As the monitoring is connected to the industry, it will also in the long run be phased out after the activity has ended and the effects have ceased.	A nuclear power plant affects the marine environment mainly through the use of large volumes of seawater for cooling. The cooling water is purified at the intake, which to some extent reduces the loss of organisms that would otherwise accompany the intake, but for those who follow, mortality occurs mechanically and thermally when the water passes through the power plant. The outgoing cooling water is 10° C warmer than the water taken in. The hot water is then spread over relatively large areas, where the organisms can be affected. The warm water can also make it easier for non-indigenous species to get established than in other areas. To control the effects of cooling water use, extensive control programmes have been established at and around the Swedish nuclear power plants since the nuclear power plants were established. In Sweden, there are nuclear power plants at one site in the North Sea (Ringhals nuclear power plant) and two in the Baltic Sea (Forsmark nuclear power plant and Oskarshamnsverket). Electricity production at the power plant in Barsebäck by the Sound ceased in 2005. Monitoring in the North sea started in 1968 and in the Baltic sea in 1969. Monitoring frequency varies from daily during spring/summer, to monthly or yearly depending on the parameter, location and purpose. Details are described in the monitoring fact sheet linked below. The nuclear power plants are undergoing a slow decommissioning, for example at Ringhals, two out of four reactors are planned to be shut down in the near future. As the monitoring is connected to the industry, it will also in the long run be phased out after the activity has ended and the effects have ceased.	A nuclear power plant affects the marine environment mainly through the use of large volumes of seawater for cooling. The cooling water is purified at the intake, which to some extent reduces the loss of organisms that would otherwise accompany the intake, but for those who follow, mortality occurs mechanically and thermally when the water passes through the power plant. The outgoing cooling water is 10° C warmer than the water taken in. The hot water is then spread over relatively large areas, where the organisms can be affected. The warm water can also make it easier for non-indigenous species to get established than in other areas. To control the effects of cooling water use, extensive control programmes have been established at and around the Swedish nuclear power plants since the nuclear power plants were established. In Sweden, there are nuclear power plants at one site in the North Sea (Ringhals nuclear power plant) and two in the Baltic Sea (Forsmark nuclear power plant and Oskarshamnsverket). Electricity production at the power plant in Barsebäck by the Sound ceased in 2005. Monitoring in the North sea started in 1968 and in the Baltic sea in 1969. Monitoring frequency varies from daily during spring/summer, to monthly or yearly depending on the parameter, location and purpose. Details are described in the monitoring fact sheet linked below. The nuclear power plants are undergoing a slow decommissioning, for example at Ringhals, two out of four reactors are planned to be shut down in the near future. As the monitoring is connected to the industry, it will also in the long run be phased out after the activity has ended and the effects have ceased.	A nuclear power plant affects the marine environment mainly through the use of large volumes of seawater for cooling. The cooling water is purified at the intake, which to some extent reduces the loss of organisms that would otherwise accompany the intake, but for those who follow, mortality occurs mechanically and thermally when the water passes through the power plant. The outgoing cooling water is 10° C warmer than the water taken in. The hot water is then spread over relatively large areas, where the organisms can be affected. The warm water can also make it easier for non-indigenous species to get established than in other areas. To control the effects of cooling water use, extensive control programmes have been established at and around the Swedish nuclear power plants since the nuclear power plants were established. In Sweden, there are nuclear power plants at one site in the North Sea (Ringhals nuclear power plant) and two in the Baltic Sea (Forsmark nuclear power plant and Oskarshamnsverket). Electricity production at the power plant in Barsebäck by the Sound ceased in 2005. Monitoring in the North sea started in 1968 and in the Baltic sea in 1969. Monitoring frequency varies from daily during spring/summer, to monthly or yearly depending on the parameter, location and purpose. Details are described in the monitoring fact sheet linked below. The nuclear power plants are undergoing a slow decommissioning, for example at Ringhals, two out of four reactors are planned to be shut down in the near future. As the monitoring is connected to the industry, it will also in the long run be phased out after the activity has ended and the effects have ceased.	New species have been introduced to Sweden with the help of humans for a long time. Shipping is identified as one of the most significant activities behind the introduction of NIS in that species accompany boats either as growth (biofouling) on the hull or in the ship's ballast water, but introductions can also take place through release or spreading through reproduction or migration. The purpose of Sweden's and the EU's work with alien species is to prevent introduction, limit spread and prevent damage due to NIS. The purpose is also to implement the Ballast Water Convention, which prevents foreign organisms from spreading with ballast water. Sweden participates in this mainly through regional coordination within the sea areas for the development and application of appropriate monitoring methods in order to be able to detect alien species and harmful organisms at an early stage and to be able to warn the authorities of other countries. In order for the damage to be effectively minimized, measures must primarily be preventive. By monitoring new introductions of alien species, early detection and rapid measures are enabled in a cost-effective manner. A total of 20 sampling stations have been selected using a risk model for the introduction of marine species. The areas that fell out with the greatest risk, so-called hotspots, are all along the west coast or in the Baltic Proper. Monitoring will be carried out through a recurring sampling at the 20 stations during a six-year management cycle. Coordination with other environmental monitoring is planned for effective implementation. Although the Gulf of Bothnia was not identified by the model as a hot spot, there are plans to add monitoring there based on risk modeling with a focus on freshwater species. Complementary genetic methods are being developed. For example, Sweden is one of the partners in the Complete project, which was launched in October 2017. The aim is to minimize the introduction of harmful aquatic organisms and pathogens by developing a consistent and adaptive management system for the Baltic Sea Region. Complete reports its results to the EU but also to HELCOM, where there is collaboration in managing alien species in shipping. Another example is the international network ARMS (Programme Europe), which aims to identify alien species and their spread to European waters through long-term monitoring of the biodiversity of the hard bottom community. Swedish experts are part of ARMS through the In	New species have been introduced to Sweden with the help of humans for a long time. Shipping is identified as one of the most significant activities behind the introduction of NIS in that species accompany boats either as growth (biofouling) on the hull or in the ship's ballast water, but introductions can also take place through release or spreading through reproduction or migration. The purpose of Sweden's and the EU's work with alien species is to prevent introduction, limit spread and prevent damage due to NIS. The purpose is also to implement the Ballast Water Convention, which prevents foreign organisms from spreading with ballast water. Sweden participates in this mainly through regional coordination within the sea areas for the development and application of appropriate monitoring methods in order to be able to detect alien species and harmful organisms at an early stage and to be able to warn the authorities of other countries. In order for the damage to be effectively minimized, measures must primarily be preventive. By monitoring new introductions of alien species, early detection and rapid measures are enabled in a cost-effective manner. A total of 20 sampling stations have been selected using a risk model for the introduction of marine species. The areas that fell out with the greatest risk, so-called hotspots, are all along the west coast or in the Baltic Proper. Monitoring will be carried out through a recurring sampling at the 20 stations during a six-year management cycle. Coordination with other environmental monitoring is planned for effective implementation. Although the Gulf of Bothnia was not identified by the model as a hot spot, there are plans to add monitoring there based on risk modeling with a focus on freshwater species. Complementary genetic methods are being developed. For example, Sweden is one of the partners in the Complete project, which was launched in October 2017. The aim is to minimize the introduction of harmful aquatic organisms and pathogens by developing a consistent and adaptive management system for the Baltic Sea Region. Complete reports its results to the EU but also to HELCOM, where there is collaboration in managing alien species in shipping. Another example is the international network ARMS (Programme Europe), which aims to identify alien species and their spread to European waters through long-term monitoring of the biodiversity of the hard bottom community. Swedish experts are part of ARMS through the In	In order to strengthen the targeted monitoring of alien species, data on new introductions and spread of alien species are also collected through citizen science, where e.g. the public, researchers and fishermen can report their findings of alien species. According to the EU Invasive Alien Species Regulation (IAS), countries should set up mechanisms for the exchange of information and data, early warning systems and programs to increase public awareness and knowledge of IAS. An early warning is a prerequisite for being able to implement effective management measures for IAS. Citizen science is gaining a stronger position as a method for data collection where traditional monitoring, surveys or research do not capture early changes in the environment or where traditional methods are too costly to have a large geographical coverage or provide too little data. One weakness, however, is that the methods can be difficult to quality assure or that the information can give a skewed geographical picture because it depends on where people usually stay. In the sea, Neogobius melanostomus, Eriocheir sinensis, Hemigrapsus sanguineus and Hemigrapsus takanoi are good examples where citizen science has been crucial for early detection and also facilitated rapid measures.	In order to strengthen the targeted monitoring of alien species, data on new introductions and spread of alien species are also collected through citizen science, where e.g. the public, researchers and fishermen can report their findings of alien species. According to the EU Invasive Alien Species Regulation (IAS), countries should set up mechanisms for the exchange of information and data, early warning systems and programs to increase public awareness and knowledge of IAS. An early warning is a prerequisite for being able to implement effective management measures for IAS. Citizen science is gaining a stronger position as a method for data collection where traditional monitoring, surveys or research do not capture early changes in the environment or where traditional methods are too costly to have a large geographical coverage or provide too little data. One weakness, however, is that the methods can be difficult to quality assure or that the information can give a skewed geographical picture because it depends on where people usually stay. In the sea, Neogobius melanostomus, Eriocheir sinensis, Hemigrapsus sanguineus and Hemigrapsus takanoi are good examples where citizen science has been crucial for early detection and also facilitated rapid measures.
Monitoring purpose	Environmental state and impacts Human activities causing the pressures Pressures at source Pressures in the marine environment	Environmental state and impacts Human activities causing the pressures Pressures at source Pressures in the marine environment	Environmental state and impacts Human activities causing the pressures Pressures at source Pressures in the marine environment	Environmental state and impacts Human activities causing the pressures Pressures at source Pressures in the marine environment	Environmental state and impacts Human activities causing the pressures Pressures at source Pressures in the marine environment	Environmental state and impacts Human activities causing the pressures Pressures at source Pressures in the marine environment	Environmental state and impacts Human activities causing the pressures Pressures at source Pressures in the marine environment	Environmental state and impacts Human activities causing the pressures Pressures at source Pressures in the marine environment	Environmental state and impacts Human activities causing the pressures Pressures at source Pressures in the marine environment	Effectiveness of measures Pressures in the marine environment	Effectiveness of measures Pressures in the marine environment	Effectiveness of measures Pressures in the marine environment	Effectiveness of measures Pressures in the marine environment
Other policies and conventions	Monitoring programme targeting at national legislation	Monitoring programme targeting at national legislation	Monitoring programme targeting at national legislation	Monitoring programme targeting at national legislation	Monitoring programme targeting at national legislation	Monitoring programme targeting at national legislation	Monitoring programme targeting at national legislation	Monitoring programme targeting at national legislation	Monitoring programme targeting at national legislation	HELCOM Monitoring programmes Invasive Alien Species Regulation Maritime Spatial Planning Directive Monitoring programme targeting at national legislation OSPAR Coordinated Environmental Monitoring Programme Water Framework Directive	HELCOM Monitoring programmes Invasive Alien Species Regulation Maritime Spatial Planning Directive Monitoring programme targeting at national legislation OSPAR Coordinated Environmental Monitoring Programme Water Framework Directive	HELCOM Monitoring programmes Invasive Alien Species Regulation Maritime Spatial Planning Directive Monitoring programme targeting at national legislation OSPAR Coordinated Environmental Monitoring Programme Water Framework Directive	HELCOM Monitoring programmes Invasive Alien Species Regulation Maritime Spatial Planning Directive Monitoring programme targeting at national legislation OSPAR Coordinated Environmental Monitoring Programme Water Framework Directive
Regional cooperation - coordinating body										HELCOM OSPAR	HELCOM OSPAR
Regional cooperation - countries involved
Regional cooperation - implementation level										Coordinated data collection	Coordinated data collection
Monitoring details
Features	Non-renewable energy generation	Extraction of, or mortality/injury to, wild species (by commercial and recreational fishing and other activities)	Coastal fish	Demersal shelf fish	Pelagic shelf fish	Newly introduced non-indigenous species	Established non-indigenous species	Hydrographical changes	Input of other forms of energy (including electromagnetic fields, light and heat)	Input or spread of non-indigenous species	Established non-indigenous species	Input or spread of non-indigenous species	Established non-indigenous species
	Non-renewable energy generation	Extraction of, or mortality/injury to, wild species (by commercial and recreational fishing and other activities)	Coastal fish	Demersal shelf fish	Pelagic shelf fish	Newly introduced non-indigenous species	Established non-indigenous species	Hydrographical changes	Input of other forms of energy (including electromagnetic fields, light and heat)	Input or spread of non-indigenous species	Established non-indigenous species	Input or spread of non-indigenous species	Established non-indigenous species
	Non-renewable energy generation	Extraction of, or mortality/injury to, wild species (by commercial and recreational fishing and other activities)	Coastal fish	Demersal shelf fish	Pelagic shelf fish	Newly introduced non-indigenous species	Established non-indigenous species	Hydrographical changes	Input of other forms of energy (including electromagnetic fields, light and heat)	Input or spread of non-indigenous species	Established non-indigenous species	Input or spread of non-indigenous species	Established non-indigenous species
	Non-renewable energy generation	Extraction of, or mortality/injury to, wild species (by commercial and recreational fishing and other activities)	Coastal fish	Demersal shelf fish	Pelagic shelf fish	Newly introduced non-indigenous species	Established non-indigenous species	Hydrographical changes	Input of other forms of energy (including electromagnetic fields, light and heat)	Input or spread of non-indigenous species	Established non-indigenous species	Input or spread of non-indigenous species	Established non-indigenous species
Elements			Abramis brama Alburnus alburnus Anguilla anguilla Blicca bjoerkna Ciliata mustela Ctenolabrus rupestris Esox lucius Gadus morhua Gasterosteus aculeatus Gobius niger Gymnocephalus cernua Labrus bergylta Leuciscus idus Neogobius melanostomus Platichthys flesus Rutilus rutilus Sander lucioperca Scardinius erythrophthalmus Symphodus melops Syngnathus acus Tinca tinca Zoarces viviparus	Myoxocephalus scorpius Perca fluviatilis Pleuronectes platessa Syngnathus typhle Taurulus bubalis	Clupea harengus	Not Applicable	Alkmaria romijni Bonnemaisonia hamifera Crassostrea gigas Dasya baillouviana Hemigrapsus sanguineus Marenzelleria spp. (neglecta & viridis) Neogobius melanostomus Oncorhynchus mykiss Potamopyrgus antipodarum Sargassum muticum Spermothamnion repens var. flagelliferum	Temperature	Not Applicable	Not Applicable	Acartia (Acanthacartia) tonsa Amphibalanus improvisus Beroe ovata Boccardiella ligerica Bonnemaisonia hamifera Caprella mutica Cordylophora caspia Crassostrea gigas Crepidula fornicata Dasysiphonia japonica Ficopomatus enigmaticus Hemigrapsus sanguineus Hemigrapsus takanoi Karenia mikimotoi Marenzelleria spp. (neglecta & viridis) Mnemiopsis leidyi Molgula manhattensis Mya arenaria Neogobius melanostomus Palaemon elegans Potamopyrgus antipodarum Rangia cuneata Rhithropanopeus harrisii	Not Applicable	Acartia (Acanthacartia) tonsa Amphibalanus improvisus Beroe ovata Boccardiella ligerica Bonnemaisonia hamifera Caprella mutica Cordylophora caspia Crassostrea gigas Crepidula fornicata Dasysiphonia japonica Ficopomatus enigmaticus Hemigrapsus sanguineus Hemigrapsus takanoi Karenia mikimotoi Marenzelleria spp. (neglecta & viridis) Mnemiopsis leidyi Molgula manhattensis Mya arenaria Neogobius melanostomus Palaemon elegans Potamopyrgus antipodarum Rangia cuneata Rhithropanopeus harrisii
GES criteria			D1C2	D1C2	D1C2	D2C1	D2C2	D7C1	D7C1	D2C1	D2C2	D2C1	D2C2

Parameters			Abundance (number of individuals) Biomass Other	Abundance (number of individuals) Biomass	Abundance (number of individuals) Biomass	Presence	Abundance (number of individuals) Biomass	Extent	Other	Presence	Abundance (number of individuals) Biomass Extent	Presence	Other











Parameter Other			Size distribution						temperature				Presence
Spatial scope	Coastal waters (WFD)	Coastal waters (WFD)	Coastal waters (WFD)	Coastal waters (WFD)	Coastal waters (WFD)	Coastal waters (WFD)	Coastal waters (WFD)	Coastal waters (WFD)	Coastal waters (WFD)	Coastal waters (WFD)	Coastal waters (WFD)	Coastal waters (WFD) EEZ (or similar) Territorial waters	Coastal waters (WFD) EEZ (or similar) Territorial waters

Marine reporting units	ANS-SE-AA-B_Kattegatt BAL-SE-AA-B_Bottenhavet BAL-SE-AA-B_V_Gotlandshavet	ANS-SE-AA-B_Kattegatt BAL-SE-AA-B_Bottenhavet BAL-SE-AA-B_V_Gotlandshavet	ANS-SE-AA-B_Kattegatt BAL-SE-AA-B_Bottenhavet BAL-SE-AA-B_V_Gotlandshavet	ANS-SE-AA-B_Kattegatt BAL-SE-AA-B_Bottenhavet BAL-SE-AA-B_V_Gotlandshavet	ANS-SE-AA-B_Kattegatt BAL-SE-AA-B_Bottenhavet BAL-SE-AA-B_V_Gotlandshavet	ANS-SE-AA-B_Kattegatt BAL-SE-AA-B_Bottenhavet BAL-SE-AA-B_V_Gotlandshavet	ANS-SE-AA-B_Kattegatt BAL-SE-AA-B_Bottenhavet BAL-SE-AA-B_V_Gotlandshavet	ANS-SE-AA-B_Kattegatt BAL-SE-AA-B_Bottenhavet BAL-SE-AA-B_V_Gotlandshavet	ANS-SE-AA-B_Kattegatt BAL-SE-AA-B_Bottenhavet BAL-SE-AA-B_V_Gotlandshavet	ANS-SE-AA-B_Kattegatt ANS-SE-AA-B_Oresund ANS-SE-AA-B_Skagerrak BAL-SE-AA-B_Arkonahavet_och_S_Oresund BAL-SE-AA-B_Bornholmshavet_och_Hanobukten BAL-SE-AA-B_Bottenhavet BAL-SE-AA-B_N_Gotlandshavet BAL-SE-AA-B_O_Gotlandshavet BAL-SE-AA-B_V_Gotlandshavet	ANS-SE-AA-B_Kattegatt ANS-SE-AA-B_Oresund ANS-SE-AA-B_Skagerrak BAL-SE-AA-B_Arkonahavet_och_S_Oresund BAL-SE-AA-B_Bornholmshavet_och_Hanobukten BAL-SE-AA-B_Bottenhavet BAL-SE-AA-B_N_Gotlandshavet BAL-SE-AA-B_O_Gotlandshavet BAL-SE-AA-B_V_Gotlandshavet	ANS-SE-AA-BG_Vasterhavet BAL-SE-AA-BG_Bottniska_Viken BAL-SE-AA-BG_Egentliga_Ostersjon	ANS-SE-AA-BG_Vasterhavet BAL-SE-AA-BG_Bottniska_Viken BAL-SE-AA-BG_Egentliga_Ostersjon
Temporal scope (start date - end date)	1968-9999	1968-9999	1968-9999	1968-9999	1968-9999	1968-9999	1968-9999	1968-9999	1968-9999	2019-9999	2019-9999	2000-9999	2000-9999
Monitoring frequency	Other	Other	Other	Other	Other	Other	Other	Other	Other	Other	Other	As needed	As needed
Monitoring type	In-situ sampling coastal	In-situ sampling coastal	In-situ sampling coastal	In-situ sampling coastal	In-situ sampling coastal	In-situ sampling coastal	In-situ sampling coastal	In-situ sampling coastal	In-situ sampling coastal	In-situ sampling coastal Visual observation	In-situ sampling coastal Visual observation	Administrative data collection Visual observation	Administrative data collection Visual observation
Monitoring method	HELCOM Guidelines for coastal fish monitoring Other monitoring method	HELCOM Guidelines for coastal fish monitoring Other monitoring method	HELCOM Guidelines for coastal fish monitoring Other monitoring method	HELCOM Guidelines for coastal fish monitoring Other monitoring method	HELCOM Guidelines for coastal fish monitoring Other monitoring method	HELCOM Guidelines for coastal fish monitoring Other monitoring method	HELCOM Guidelines for coastal fish monitoring Other monitoring method	HELCOM Guidelines for coastal fish monitoring Other monitoring method	HELCOM Guidelines for coastal fish monitoring Other monitoring method	HELCOM Guidelines for monitoring of non-indigenous species by eRAS OSPAR CEMP Guideline: Common Indicator - Changes to non-indigenous species communities (NIS3) (Agreement 2018-04) Other monitoring method	HELCOM Guidelines for monitoring of non-indigenous species by eRAS OSPAR CEMP Guideline: Common Indicator - Changes to non-indigenous species communities (NIS3) (Agreement 2018-04) Other monitoring method	Other monitoring method	Other monitoring method
Monitoring method other	"https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-i-ostersjons-kustomraden---djupstratifierat-provfiske-med-nordiska-kustoversiktsnat.html https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-med-kustoversiktsnat-natlankar-och-ryssjor-pa-kustnara-grunt-vatten.html https://www.slu.se/institutioner/akvatiska-resurser/miljoanalys/datainsamling/biologisk-recipientkontroll-vid-kusten/ https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/vegetationskladda-bottnar-ostkust.html"	"https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-i-ostersjons-kustomraden---djupstratifierat-provfiske-med-nordiska-kustoversiktsnat.html https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-med-kustoversiktsnat-natlankar-och-ryssjor-pa-kustnara-grunt-vatten.html https://www.slu.se/institutioner/akvatiska-resurser/miljoanalys/datainsamling/biologisk-recipientkontroll-vid-kusten/ https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/vegetationskladda-bottnar-ostkust.html"	"https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-i-ostersjons-kustomraden---djupstratifierat-provfiske-med-nordiska-kustoversiktsnat.html https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-med-kustoversiktsnat-natlankar-och-ryssjor-pa-kustnara-grunt-vatten.html https://www.slu.se/institutioner/akvatiska-resurser/miljoanalys/datainsamling/biologisk-recipientkontroll-vid-kusten/ https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/vegetationskladda-bottnar-ostkust.html"	"https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-i-ostersjons-kustomraden---djupstratifierat-provfiske-med-nordiska-kustoversiktsnat.html https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-med-kustoversiktsnat-natlankar-och-ryssjor-pa-kustnara-grunt-vatten.html https://www.slu.se/institutioner/akvatiska-resurser/miljoanalys/datainsamling/biologisk-recipientkontroll-vid-kusten/ https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/vegetationskladda-bottnar-ostkust.html"	"https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-i-ostersjons-kustomraden---djupstratifierat-provfiske-med-nordiska-kustoversiktsnat.html https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-med-kustoversiktsnat-natlankar-och-ryssjor-pa-kustnara-grunt-vatten.html https://www.slu.se/institutioner/akvatiska-resurser/miljoanalys/datainsamling/biologisk-recipientkontroll-vid-kusten/ https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/vegetationskladda-bottnar-ostkust.html"	"https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-i-ostersjons-kustomraden---djupstratifierat-provfiske-med-nordiska-kustoversiktsnat.html https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-med-kustoversiktsnat-natlankar-och-ryssjor-pa-kustnara-grunt-vatten.html https://www.slu.se/institutioner/akvatiska-resurser/miljoanalys/datainsamling/biologisk-recipientkontroll-vid-kusten/ https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/vegetationskladda-bottnar-ostkust.html"	"https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-i-ostersjons-kustomraden---djupstratifierat-provfiske-med-nordiska-kustoversiktsnat.html https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-med-kustoversiktsnat-natlankar-och-ryssjor-pa-kustnara-grunt-vatten.html https://www.slu.se/institutioner/akvatiska-resurser/miljoanalys/datainsamling/biologisk-recipientkontroll-vid-kusten/ https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/vegetationskladda-bottnar-ostkust.html"	"https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-i-ostersjons-kustomraden---djupstratifierat-provfiske-med-nordiska-kustoversiktsnat.html https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-med-kustoversiktsnat-natlankar-och-ryssjor-pa-kustnara-grunt-vatten.html https://www.slu.se/institutioner/akvatiska-resurser/miljoanalys/datainsamling/biologisk-recipientkontroll-vid-kusten/ https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/vegetationskladda-bottnar-ostkust.html"	"https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-i-ostersjons-kustomraden---djupstratifierat-provfiske-med-nordiska-kustoversiktsnat.html https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-med-kustoversiktsnat-natlankar-och-ryssjor-pa-kustnara-grunt-vatten.html https://www.slu.se/institutioner/akvatiska-resurser/miljoanalys/datainsamling/biologisk-recipientkontroll-vid-kusten/ https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/vegetationskladda-bottnar-ostkust.html"	For the monitoring NIS, the following Swedish method standards are used: • Growth of biofouling on PVC-panels - Upcoming method will soon be published • Growth of organisms on different types of substrates such as wood, metal and plastic, mobile epifauna crustaceans - Upcoming method will soon be published • Phytoplankton – https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/vaxtplankton.html • Zooplankton and gelatinous zooplankton – https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/djurplankton-trend--och-omradesovervakning.html and https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/geleplankton.html • Macrofauna in sediments – https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/mjukbottenlevande-makrofauna-trend--och-omradesovervakning.html • Mobile epifauna fish – https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-med-kustoversiktsnat-natlankar-och-ryssjor-pa-kustnara-grunt-vatten.html	For the monitoring NIS, the following Swedish method standards are used: • Growth of biofouling on PVC-panels - Upcoming method will soon be published • Growth of organisms on different types of substrates such as wood, metal and plastic, mobile epifauna crustaceans - Upcoming method will soon be published • Phytoplankton – https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/vaxtplankton.html • Zooplankton and gelatinous zooplankton – https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/djurplankton-trend--och-omradesovervakning.html and https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/geleplankton.html • Macrofauna in sediments – https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/mjukbottenlevande-makrofauna-trend--och-omradesovervakning.html • Mobile epifauna fish – https://www.havochvatten.se/vagledning-foreskrifter-och-lagar/vagledningar/ovriga-vagledningar/undersokningstyper-for-miljoovervakning/undersokningstyper/provfiske-med-kustoversiktsnat-natlankar-och-ryssjor-pa-kustnara-grunt-vatten.html	Whenever a NIS is discovered by a citizen, authority employee or expert, the reporter can follow a guidance how to report the sighting. The guidance is available here: https://www.havochvatten.se/arter-och-livsmiljoer/frammande-arter/sa-sprids-frammande-arter-och-vad-du-kan-gora-for-att-forhindra-det.html#h-Rapporteranyaellerframmandearter	Whenever a NIS is discovered by a citizen, authority employee or expert, the reporter can follow a guidance how to report the sighting. The guidance is available here: https://www.havochvatten.se/arter-och-livsmiljoer/frammande-arter/sa-sprids-frammande-arter-och-vad-du-kan-gora-for-att-forhindra-det.html#h-Rapporteranyaellerframmandearter

Quality control	https://internt.slu.se/stod-service/fortlopande-miljoanalys/verksamhetsstod/ingangssida/kvalitetsguide/	https://internt.slu.se/stod-service/fortlopande-miljoanalys/verksamhetsstod/ingangssida/kvalitetsguide/	https://internt.slu.se/stod-service/fortlopande-miljoanalys/verksamhetsstod/ingangssida/kvalitetsguide/	https://internt.slu.se/stod-service/fortlopande-miljoanalys/verksamhetsstod/ingangssida/kvalitetsguide/	https://internt.slu.se/stod-service/fortlopande-miljoanalys/verksamhetsstod/ingangssida/kvalitetsguide/	https://internt.slu.se/stod-service/fortlopande-miljoanalys/verksamhetsstod/ingangssida/kvalitetsguide/	https://internt.slu.se/stod-service/fortlopande-miljoanalys/verksamhetsstod/ingangssida/kvalitetsguide/	https://internt.slu.se/stod-service/fortlopande-miljoanalys/verksamhetsstod/ingangssida/kvalitetsguide/	https://internt.slu.se/stod-service/fortlopande-miljoanalys/verksamhetsstod/ingangssida/kvalitetsguide/	For species determination of alien species, taxonomic calibration must be applied both nationally and internationally. National trainings, workshops and meetings for the contracters are needed. The methodology is developed in standardization projects within HELCOM and OSPAR. Depending on a continuous change and development in the taxonomy, determining literature can constitute a quality assurance problem. Taxonomists should therefore document which determination literature has been used.	For species determination of alien species, taxonomic calibration must be applied both nationally and internationally. National trainings, workshops and meetings for the contracters are needed. The methodology is developed in standardization projects within HELCOM and OSPAR. Depending on a continuous change and development in the taxonomy, determining literature can constitute a quality assurance problem. Taxonomists should therefore document which determination literature has been used.	All information is collected in the Species Portal (Artportalen) and validated by a validation organization that also validates endangered and certain red-listed species. Proposals for a national routine for validation of IAS have been prepared by SLU. A digital support for validation is linked to Artportalen. The reporting follows the reporting forms that control the content and format of data and guarantees that the report contains at least the mandatory information. If a photograph is missing or the location is insufficient, the report can be validated by the validator contacting the reporter for more information.	All information is collected in the Species Portal (Artportalen) and validated by a validation organization that also validates endangered and certain red-listed species. Proposals for a national routine for validation of IAS have been prepared by SLU. A digital support for validation is linked to Artportalen. The reporting follows the reporting forms that control the content and format of data and guarantees that the report contains at least the mandatory information. If a photograph is missing or the location is insufficient, the report can be validated by the validator contacting the reporter for more information.




Data management	The raw data collected is stored in SLU Aqua's databases KUL (nets) and is updated annually. The results from the surveys are compiled annually in the Aqua reports by the Department of Aquatic Resources at SLU. Fish fry data and data on Non-indigenous species in Ringhals are stored in simpler databases (Excel and Access). All data is owned by the respective power company, which must give its approval for the data to be used in other contexts. For access to raw data, it is required for the time being to contact the Coastal Laboratory at SLU, which in turn must obtain approval from the data owner to disclose data. Inquiries about aggregated data can be made to datavard-fisk@slu.se	The raw data collected is stored in SLU Aqua's databases KUL (nets) and is updated annually. The results from the surveys are compiled annually in the Aqua reports by the Department of Aquatic Resources at SLU. Fish fry data and data on Non-indigenous species in Ringhals are stored in simpler databases (Excel and Access). All data is owned by the respective power company, which must give its approval for the data to be used in other contexts. For access to raw data, it is required for the time being to contact the Coastal Laboratory at SLU, which in turn must obtain approval from the data owner to disclose data. Inquiries about aggregated data can be made to datavard-fisk@slu.se	The raw data collected is stored in SLU Aqua's databases KUL (nets) and is updated annually. The results from the surveys are compiled annually in the Aqua reports by the Department of Aquatic Resources at SLU. Fish fry data and data on Non-indigenous species in Ringhals are stored in simpler databases (Excel and Access). All data is owned by the respective power company, which must give its approval for the data to be used in other contexts. For access to raw data, it is required for the time being to contact the Coastal Laboratory at SLU, which in turn must obtain approval from the data owner to disclose data. Inquiries about aggregated data can be made to datavard-fisk@slu.se	The raw data collected is stored in SLU Aqua's databases KUL (nets) and is updated annually. The results from the surveys are compiled annually in the Aqua reports by the Department of Aquatic Resources at SLU. Fish fry data and data on Non-indigenous species in Ringhals are stored in simpler databases (Excel and Access). All data is owned by the respective power company, which must give its approval for the data to be used in other contexts. For access to raw data, it is required for the time being to contact the Coastal Laboratory at SLU, which in turn must obtain approval from the data owner to disclose data. Inquiries about aggregated data can be made to datavard-fisk@slu.se	The raw data collected is stored in SLU Aqua's databases KUL (nets) and is updated annually. The results from the surveys are compiled annually in the Aqua reports by the Department of Aquatic Resources at SLU. Fish fry data and data on Non-indigenous species in Ringhals are stored in simpler databases (Excel and Access). All data is owned by the respective power company, which must give its approval for the data to be used in other contexts. For access to raw data, it is required for the time being to contact the Coastal Laboratory at SLU, which in turn must obtain approval from the data owner to disclose data. Inquiries about aggregated data can be made to datavard-fisk@slu.se	The raw data collected is stored in SLU Aqua's databases KUL (nets) and is updated annually. The results from the surveys are compiled annually in the Aqua reports by the Department of Aquatic Resources at SLU. Fish fry data and data on Non-indigenous species in Ringhals are stored in simpler databases (Excel and Access). All data is owned by the respective power company, which must give its approval for the data to be used in other contexts. For access to raw data, it is required for the time being to contact the Coastal Laboratory at SLU, which in turn must obtain approval from the data owner to disclose data. Inquiries about aggregated data can be made to datavard-fisk@slu.se	The raw data collected is stored in SLU Aqua's databases KUL (nets) and is updated annually. The results from the surveys are compiled annually in the Aqua reports by the Department of Aquatic Resources at SLU. Fish fry data and data on Non-indigenous species in Ringhals are stored in simpler databases (Excel and Access). All data is owned by the respective power company, which must give its approval for the data to be used in other contexts. For access to raw data, it is required for the time being to contact the Coastal Laboratory at SLU, which in turn must obtain approval from the data owner to disclose data. Inquiries about aggregated data can be made to datavard-fisk@slu.se	The raw data collected is stored in SLU Aqua's databases KUL (nets) and is updated annually. The results from the surveys are compiled annually in the Aqua reports by the Department of Aquatic Resources at SLU. Fish fry data and data on Non-indigenous species in Ringhals are stored in simpler databases (Excel and Access). All data is owned by the respective power company, which must give its approval for the data to be used in other contexts. For access to raw data, it is required for the time being to contact the Coastal Laboratory at SLU, which in turn must obtain approval from the data owner to disclose data. Inquiries about aggregated data can be made to datavard-fisk@slu.se	The raw data collected is stored in SLU Aqua's databases KUL (nets) and is updated annually. The results from the surveys are compiled annually in the Aqua reports by the Department of Aquatic Resources at SLU. Fish fry data and data on Non-indigenous species in Ringhals are stored in simpler databases (Excel and Access). All data is owned by the respective power company, which must give its approval for the data to be used in other contexts. For access to raw data, it is required for the time being to contact the Coastal Laboratory at SLU, which in turn must obtain approval from the data owner to disclose data. Inquiries about aggregated data can be made to datavard-fisk@slu.se	Data are reported for all species to the national data hosts. For biological and oceanographic data it´s SMHI and for fish, it´s SLU. Both contain quality-assured data that can be downloaded free of charge from the data hosts' websites. In addition, data on newly introduced species for the country or a new distribution area for already established species are also reported to the Species Portal at SLU, where data is also generally available. Data are also reported to HELCOM's database for risk assessment when examining exemptions for handling ballast water.	Data are reported for all species to the national data hosts. For biological and oceanographic data it´s SMHI and for fish, it´s SLU. Both contain quality-assured data that can be downloaded free of charge from the data hosts' websites. In addition, data on newly introduced species for the country or a new distribution area for already established species are also reported to the Species Portal at SLU, where data is also generally available. Data are also reported to HELCOM's database for risk assessment when examining exemptions for handling ballast water.
Data access	https://www.havochvatten.se/marin-miljoovervakning-kylvatten-data	https://www.havochvatten.se/marin-miljoovervakning-kylvatten-data	https://www.havochvatten.se/marin-miljoovervakning-kylvatten-data	https://www.havochvatten.se/marin-miljoovervakning-kylvatten-data	https://www.havochvatten.se/marin-miljoovervakning-kylvatten-data	https://www.havochvatten.se/marin-miljoovervakning-kylvatten-data	https://www.havochvatten.se/marin-miljoovervakning-kylvatten-data	https://www.havochvatten.se/marin-miljoovervakning-kylvatten-data	https://www.havochvatten.se/marin-miljoovervakning-kylvatten-data	https://www.havochvatten.se/marin-miljoovervakning-frammande-arter-data	https://www.havochvatten.se/marin-miljoovervakning-frammande-arter-data	https://artportalen.se/	https://artportalen.se/






Related indicator/name	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art BALSE-C.1.1_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art BALSE-C.1.1_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art BALSE-C.1.1_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art BALSE-C.1.1_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art BALSE-C.1.1_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art BALSE-C.1.1_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art BALSE-C.1.1_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art BALSE-C.1.1_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art BALSE-C.1.1_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art BALSE-C.1.1_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art BALSE-C.1.1_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art	ANSSE-2.1A_Intro_fr�mmande_art ANSSE-C.1.1_Intro_fr�mmande_art BALSE-2.1A_Intro_fr�mmande_art
Contact	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se	miljoovervakning@havochvatten.se
References	https://www.havochvatten.se/marin-miljoovervakning-kylvatten	https://www.havochvatten.se/marin-miljoovervakning-kylvatten	https://www.havochvatten.se/marin-miljoovervakning-kylvatten	https://www.havochvatten.se/marin-miljoovervakning-kylvatten	https://www.havochvatten.se/marin-miljoovervakning-kylvatten	https://www.havochvatten.se/marin-miljoovervakning-kylvatten	https://www.havochvatten.se/marin-miljoovervakning-kylvatten	https://www.havochvatten.se/marin-miljoovervakning-kylvatten	https://www.havochvatten.se/marin-miljoovervakning-kylvatten	https://www.havochvatten.se/marin-miljoovervakning-frammande-arter	https://www.havochvatten.se/marin-miljoovervakning-frammande-arter	https://www.havochvatten.se/marin-miljoovervakning-medborgarforskning	https://www.havochvatten.se/marin-miljoovervakning-medborgarforskning