Fant 453 publikasjoner. Viser side 1 av 19:
Suspect screening helps detect chemicals in environmental samples without predefined target lists which can facilitate isolation of a larger number of substances. This study shows however that no single extraction method or analytical platform (LC-HRMS or GC-HRMS) can capture all relevant pollutants—at least half are missed. The technique works best for chemically similar families, where optimized methods can target specific classes or broader families of similar substances (e.g. PFAS). Effective grouping of similar substances is therefore essential. A broad coverage of substances can however be achieved if multiple sample extractions are performed and each extract is analysed on both LC- and GC-HRMS. Strategies where comparisons can be made over time or across locations will also help to isolate pollutant-related signals from the background. Such considerations must be integrated into programme design and budgeting for retrospective analysis. This will maximize likelihood of detection for the largest diversity of substances.
Norwegian Environment Agency, M-3038|2025
NILU
2026
Transboundary particulate matter, photo-oxidants, acidifying and eutrophying components
Norwegian Meteorological Institute
2025
Årsrapport 2025. Nasjonalt referanselaboratorium for luftkvalitetsmålinger
Denne rapporten oppsummerer oppgavene til Nasjonalt referanselaboratorium for luftkvalitetsmålinger (NRL), delkontrakt 1b, for året 2025.
NILU
2026
Forbedring av klimagassregnskapet for veitrafikk. Casestudie Oslo kommune
Arbeidet i denne rapporten omfatter en gjennomgang av tilgjengelige datakilder for å forbedre kjøretøysammensetningen i Oslo spesielt og andre kommuner generelt, med mål om å gi en mer presis beregning av klimagassutslippet med modellen NERVE. Analyser viser at bompasseringsdata kan definere en representativ lokal kjøretøypark, og det er utviklet og implementert metoder for å forbedre kjøretøysammetningen i NERVE i henhold til dette.
NILU
2026
MIKRONOR 2024 Monitoring of microplastics and tyre wear particles in the Norwegian environment
The 2024 MIKRONOR campaign, coordinated by NIVA and NILU on behalf of the Norwegian Environment Agency, signifcantly expanded the national monitoring framework for microplastics (MPs) to encompass diverse environmental compartments, including surface waters (Oslofjord and Lake Mjøsa), urban runoff, marine sediments, atmospheric deposition, and coastal beach sediments. Urban stormwater runoff was identifed as a predominant source of MPs, particularly tyre wear particles (TWP). Sediment samples from stormwater traps in Oslo exhibited high TWP concentrations up to 240 mg/g, constituting approximately 25% of the total sediment mass. Corresponding runoff water samples revealed MP concentrations as high as 733 ± 142 particles/L, indicating substantial episodic fuxes of MPs into receiving aquatic or marine systems. Inner Oslofjord sediments contained 0.6–3.5 % TWP by mass, confrming the high levels found in 2023. Microplastic concentrations in surface waters were generally low, ranging from 0 to 0.6 MP/m³. However, two hydrodynamic accumulation zones within the Oslofjord exhibited anomalously high concentrations, with levels approximately two orders of magnitude greater than outside the accumulation zones. One net tow recovered >7,000 fragments of expanded polystyrene, highlighting localized retention. Atmospheric deposition peaked in urban Sofenbergparken (1514 µg/m²/d; 68 % TWP) and showed a clear urban-to-remote gradient. Beach sediments at Akerøya remained low in MPs, with most samples below detection limits. The findings highlight urban runoff, especially TWP, as a dominant source to the Oslofjord, and reveal critical hotspots in both water and air pathways.
Norsk institutt for vannforskning (NIVA)
2025
National E-waste Monitor 2025 - Norway
The National E-waste Monitor 2025 – Norway provides a detailed assessment of the current situation of e-waste statistics and legislation, and an outlook on e-waste statistics up to 2050.
Norway is the world’s leading nation in Waste Electrical and Electronic Equipment (WEEE) generation per capita, producing 27.5 kg per person in 2022, equivalent to 149 kt.
However, the country has established an efficient collection system, successfully gathering 72% of generated e-waste, with 107 kt tons collected in 2022 (approximately 19.5 kg per capita).
The country’s WEEE stock has seen significant growth over the past decade, expanding from 14 million tons in 2010 to nearly 20 million tons in 2022. However, based on the monitor’s results, the implementation of robust Circular Economy measures could help EEE Put on the Market in Norway reaching, by 2050, half of the to 2010 levels (67 kt). The big drop is explained by more repairability and improved durability of EEE products; by contrast, the projection in a Business as Usual scenario would be 5 times higher (294 kt) than in the Circular Economy scenario.
In terms of international trade, Norway reported 20 kt of used EEE exports for reuse, primarily within the European Union. Legal WEEE exports saw an increase from 27 kt in 2022 to 38 kt in 2023. Authorities intercepted 15.5 t of illegal exports due to inadequate documentation and functionality testing.
Upcoming country investments may go in the direction of recycling technologies for rare earth metals and precious materials recovery, improved small electronics collection systems, stricter labelling requirements for recyclable components and hazardous substances.
While Norway’s e-waste management system is already considered exemplary, the monitor’s results emphasize the need for more ambitious targets aligned with the WEEE Directive to create a truly sustainable and circular electronics management system. The focus is now shifting toward public awareness campaigns to encourage repair over replacement and the development of more efficient collection methods for small electronic devices.
Citation: E. D’Angelo, M. Schubert, T. Yamamoto, C.P. Baldé, E. Bourgé and G. Abbasi, United Nations Institute for Training and Research, NILU, “National E-waste monitor 2025 - Norway”, 2025, Bonn/Oslo, Germany and Norway.
NILU
2025
NILU har, på vegne av Telemarksforskning og Norsk Folkemuseum, analysert miljøgifter i støv, luft og materialprøver fra utvalgte antikvariske bygg. Målet var å kartlegge nivåer av miljøgifter brukt i tidligere konserveringsarbeid. Studien omfattet analyser av tungmetaller, PAH og pesticider i støv fra ni bygninger, screening av VOC i luft, samt materialprøver fra tre bygninger. Resultatene viste bekymringsverdige nivåer av tungmetaller, PAH og pesticider i støv, og svært høye nivåer av PCP i to av tre materialprøver, til tross for lav totalmengde VOC.
NILU
2025
NILU og Akvaplan-niva har et felles overvåkingsprosjekt rundt Hammerfest LNG på Melkøya. I perioden 2025 – 2028 skal overvåkingen omfatte bly (Pb), kvikksølv (Hg) og PAH i nedbør, vegetasjon, jord, ferskvann, ferskvannsfisk og ferskvannssediment, samt kvikksølv i luft. For de fleste komponenter og prøvemedier er verdiene lave.
NILU
2025
The report provides the annual update of the European air quality concentration maps and population and vegetation exposure estimates for human health related indicators of pollutants PM10 (annual average, 90.4 percentile of daily means), PM2.5 (annual average), ozone (93.2 percentile of maximum daily 8-hour means, peak season average of maximum daily 8-hour means, SOMO35, SOMO10), NO2 (annual average) and benzo(a)pyrene (annual average), and vegetation related ozone indicators (AOT40 for vegetation and for forests) for the year 2023. The report contains also maps of Phytotoxic ozone dose (PODY) for selected crops (wheat, potato and tomato) and trees (spruce and beech) and NOx annual average map for the same year 2023. The trends in exposure estimates in the period 2005-2023 are summarized. The analysis for 2023 is based on the interpolation of the annual statistics of the 2023 observational data reported by the EEA member and cooperating countries and other voluntary reporting countries and stored in the Air Quality e-reporting database, complemented, when needed, with measurements from additional sources. The mapping method is the Regression – Interpolation – Merging Mapping (RIMM). It combines monitoring data, chemical transport model results and other supplementary data using linear regression model followed by kriging of its residuals (residual kriging). The report presents the mapping results and gives an uncertainty analysis of the interpolated maps. It also presents concentration change in 2023 in comparison to the 5-year average 2018-2022 using the difference maps and exposure estimates.
European Topic Centre on Human Health and the Environment (ETC HE)
2025
The report presents interim 2024 maps for PM10 annual average, PM2.5 annual average, O3 indicator peak season average of maximum daily 8-hour means, and NO2 annual average. The maps have been produced based on the 2024 non-validated E2a (UTD) data of the AQ e-reporting database, the CAMS Ensemble Forecast modelling data and other supplementary data. Together with the concentration maps, the inter-annual differences between 5-year average 2019-2023 and 2024 are presented (using the 2019-2023 regular and the 2024 interim maps), as well as basic exposure estimates based on the interim maps.
European Topic Centre on Human Health and the Environment (ETC HE)
2025
EEA´s revision of the European air quality index bands
The European Air quality index has been updated and now its bands take into consideration the World Health Organization global air quality guidelines, published in 2021. A subindex per pollutant is calculated based on hourly data (including for PM, for which running 24-hours averages were considered before) and on the risk of short-term mortality. The worst pollutant subindex categorizes the index. The health messages linked to the different index categories remain unchanged.
European Topic Centre on Human Health and the Environment (ETC HE)
2025
Monitoring air quality around airports and nearby cities is crucial to understanding the role of emissions from air traffic and other airport activities. This report analyses air quality in 23 European airports, revealing limited observations in and around airport areas. Only three of the 23 airports had at least one air quality sampling point for NO2, PM2.5 and O3 inside the airport area. Concentrations in nearby cities can be up to double (NO2), 57% higher (PM2.5) and 85% higher (O3) when the wind comes from the airport. EEA air quality maps showed higher annual mean NO2 concentrations in airport areas compared to surrounding regions, with one airport above the 2030 limit value of 20 µg/m³. Annual mean PM2.5 concentrations were also higher in airport areas, with six airports exceeding the revised limit value. The limited number of sampling points makes it challenging to assess trends in NO2, PM2.5 and O3 concentrations. A final chapter of the report presents an overview of available measurements and studies of ultra fine particles (UFP) in the vicinity of airports.
European Topic Centre on Human Health and the Environment (ETC HE)
2025
Assessing the environmental burden of disease related to air pollution in Europe in 2023
This report evaluates the environmental burden of disease (EBD) linked to long-term exposure to fine particulate matter (PM2.5), nitrogen dioxide (NO2), and ozone (O3) across 41 European countries in 2023. Using the key health indicators—attributable deaths, years of life lost, years lived with disability, and disability-adjusted life years—the analysis quantifies the health impacts of air pollution above concentrations defined as the World Health Organisation’s air quality guideline levels. Approximately 206,000 deaths are attributable to PM2.5, while about 56,000 and 71,000 deaths area attributable to NO2 and O3, respectively. The disease burden from PM2.5 was highest due to its association with multiple health outcomes, with high baseline prevalence and mortality. Results highlight strong regional disparities, with South-Eastern Europe most affected by health effects from PM2.5 and NO2, and Southern Europe by those from O3. Findings underscore the need for targeted policies to reduce pollutant-specific health impacts in Europe.
European Topic Centre on Human Health and the Environment (ETC HE)
2025
2025
Skogens helsetilstand i Norge. Resultater fra skogskadeovervåkingen i 2024
Skog dekker nærmere 40 % av Norges landareal. Skogene bidrar til karbonbinding både over og under bakken, forsyner oss med råvarer, spiller en viktig rolle for friluftslivet og er leveområdet for utallige arter. Skogens viktige rolle som leverandør av slike økosystemtjenester forutsetter imidlertid et intakt skogøkosystem, en god skoghelse og en langsiktig og bærekraftig forvaltning.
Skogens helsetilstand påvirkes i stor grad av klima og værforhold, enten direkte ved tørke, frost, snø og vind, eller indirekte ved at klimaet påvirker omfanget og spredningen av soppsykdommer og insektangrep.
Klimaendringene og den forventede økningen i klimarelaterte skogskader gir store utfordringer for forvaltningen av framtidas skogressurser. Det samme gjør invaderende skadegjørere, både allerede etablerte arter og nye som kan komme til Norge i nær framtid. Uansett hvilke utfordringer skogen står overfor, er det viktig med langsiktige skogovervåkingsprogrammer for å kunne oppdage endringer og iverksette tiltak mot truslene. I denne rapporten presenteres resultater fra skogskadeovervåkingen i Norge i 2024 og trender over tid for følgende temaer:
1. Landsrepresentativ skogovervåking;
2. Intensiv skogovervåking;
3. Barkbilleovervåkingen 2024: Fortsatt høye fangster i stormrammede områder;
4. Overvåking av fremmede trelevende insekter;
5. Almesyken sprer seg til nye områder;
6. Overvåking av askas naturlige foryngelse i skog angrepet av askeskuddsyke;
7. Andre spesielle skogskader i 2024.
NIBIO
2025
Støvnedfall Miljøbriketter AS. Måling av nedfallsstøv og mangan
NILU har gjort målinger av nedfallsstøv rundt Miljøbriketter AS sitt anlegg i Skien. Det ble gjort prøvetaking ved 8 målepunkter i to perioder. Prøvene ble analysert for mengde nedfallsstøv og mangan. Bidraget fra Miljøbriketter til total mengde nedfallsstøv er lite.
NILU
2025
Monitoring of greenhouse gases and aerosols at Svalbard and Birkenes in 2024. Annual report
This annual report for 2024 summarizes the activities and results of the greenhouse gas monitoring at the Zeppelin Observatory, situated on Svalbard, during the period 2001-2024, and the greenhouse gas monitoring and aerosol observations from Birkenes for 2009-2024.
NILU
2025
Kartlegging av utslipp fra aktiviteter i Oslo Havn
Stiftelsen NILU har utarbeidet en utslippsberegning for aktiviteter på land ved Oslo Havn. Arbeidet omfatter innhenting av aktivitetsdata og utslippsfaktorer fra relevante kilder. Utslippet er beregnet for Dagens situasjon 2023 og framskrevet til 2030 og 2040. For 2040 er det også regnet på effekten av å bytte til bio-basert brensel i fabrikkene.
NILU
2025
Monitoring of environmental contaminants in air and precipitation. Annual report 2024
This report presents air monitoring data from 2024 for the Norwegian monitoring programme "Atmospheric contaminants". The results cover 16 groups comprising of 260 organic compounds (regulated and non-regulated) as well as 14 heavy metals, and a selection of organic chemicals of emerging concern.
NILU
2025
Revidert tiltaksutredning for lokal luftkvalitet i Tromsø
Stiftelsen NILU har, i samarbeid med Transportøkonomisk institutt (TØI), utarbeidet en revidert tiltaksutredning for lokal luftkvalitet i Tromsø kommune for perioden 2025 til 2030. Arbeidet omfatter en kartlegging av luftkvaliteten basert på trafikk-, utslipps- og spredningsberegninger for PM10, PM2,5 og NO2 for Dagens situasjon 2023, Referansesituasjonen 2030 og 2030 med tiltak. Det er beregnet risiko for overskridelse av dagens grenseverdier i forurensningsforskriften og for grenseverdier i nytt EU-direktiv som ennå ikke er tatt inn i norsk lovgiving.
NILU
2025
Denne rapporten beskriver en studie utført av NILU for Nordre Follo kommune, med støtte fra Folkehelseinstituttet. Målet var å prøve uhildet kartlegging som metode for å undersøke hvilke organisk-kjemiske forbindelser som finnes i nedbørfeltet til drikkevannskilden Gjersjøen. Som del av dette ønsket vi også å identifisere forbindelser som forårsaker feilaktige, store utslag i nitratsensorer. Ved bruk av høyoppløselig massespektrometri og miljøforensiske metoder ble 163 markører identifisert, inkludert aspirin, kreatin og kreatinin, knyttet til kloakkforurensning under kraftig nedbør. Funnene gir innsikt i kjemisk interferens og kan forbedre overvåkingssystemer og vannforvaltning.
NILU
2025