Publications

Environmental contaminants modulate the transcriptional activity of polar bear (Ursus maritimus) and human peroxisome proliferator-activated receptor alpha (PPARA)

Routti, Heli Anna Irmeli; Berg, Mari Katrine; Lille-Langøy, Roger; Øygarden, Lene Eidsvik; Harju, Mikael; Sonne, C.; Dietz, R.; Goksøyr, Anders

Environmental determinants of human health. Molecular and integrative toxicology

Pacyna, J.M.; Pacyna, E.G. (eds.)

Environmental dose-response functions of silk and paper exposed in museums.

Grøntoft, Terje; Hallett, Kathryn; Blades, Nigel

This paper reports 1 year of data of the environments and changes in the molecular weight of silk and the degree of polymerization of sensitive paper measured externally and indoors in 10 European museums, and the dose-response functions that were obtained by statistical analysis of this data. The measurements were performed in the EU FP5 project Master (EVK-CT-2002-00093). The work provides documentation of deterioration of silk by NO2 and O3, and alternatively in combination with UV radiation. The indoor deterioration of the silk was only observed in one location with high UV radiation. The indoor deterioration of sensitive paper correlated with the UV radiation, the concentrations of NO2 and O3, and in addition with an SO2 concentration of 4 µgm−3 and a formic acid concentration of 50 µgm−3 in two different locations. If the observed dose-response effects are linear to lower doses and longer exposure times, then the lifetime to intolerable deterioration of the paper and silk would be 6–7 times longer overall in the enclosures than in the galleries.

Environmental emissions of selected persistent organic pollutants.

Pacyna, J.

Environmental fate and bioaccumulation of cVMS in a subarctic freshwater lake

Krogseth, Ingjerd Sunde; Undeman, E.; Evenset, Anita; Christensen, G. N.; Whelan, M. J.; Breivik, Knut; Warner, Nicholas Alexander

Environmental fate of chlorinated bornanes estimated by theortical descriptors.

Heimstad, E.S.; Smalås, A.O.; Kallenborn, R.

Environmental Forensics Overview and tools for source identification

Mudge, Stephen Michael

Environmental health assessment. Respiratory disease in relation to air pollution in Kanpur, Uttar Pradesh. NILU OR

Bartonova, A.; Liu, H.-Y. (eds.)

The aim of this report is to summarize all activities of the whole period for the India¿Norwegian cooperation project: Environmental Health Assessment: Respiratory Disease in relation to Air Pollution in Kanpur, Uttar Pradesh. It includes: (1) verification of measurement methods in relationship to the European CEN/EN12341 standard on PM10 monitoring in Kanpur and Agra; (2) health effect assessment attributable to air pollution in the city of Kanpur; and (3) dissemination (workshops) and administration.

Environmental impact and risk assessment for outdoor materials.

Henriksen, J. F.

Environmental impact assessment: modelling exposure to ambient air pollution using atmospheric dispersion models.

Bartonova, A.; Clench-Aas, J.; Grønskei, K.E.

Environmental Impact Factor (EIF). Emission to air. Phase I. NILU OR

Larssen, T.; Knudsen, S.; Høgåsen, T.; Bruteig, I.

Environmental impact of amines from CO2 capture. NILU OR

Knudsen, S.; Moe, M.K.; Schlabach, M.; Schmidbauer, N.; Dye, C.

Environmental impacts of a chemical looping combustion power plant

Thorne, Rebecca Jayne; Bouman, Evert; Sundseth, Kyrre; Sanchez, Maria Asuncion Aranda; Czakiert, Tomasz; Pacyna, Jozef M; Pacyna, Elisabeth G; Krauz, Mariusz; Celińska, Agnieszka

Chemical Looping Combustion (CLC) is a promising CO2 capture option since it inherently separates CO2 from other flue components, theoretically with low energy penalty. Here, a Life Cycle Assessment model was developed of a theoretical hybrid CLC (HCLC) power plant facility utilising experimental data for CuO based oxygen carrier (OC) production and oxygen capacity. Power plant models with and without post-combustion CO2 capture, recognised as the most mature capture technology, acted as environmental performance targets. Results show that when OC is produced at lab-scale without optimisation, almost all (>99.9%) lifecycle impacts per kWh electricity from an HCLC plant derive from the specific OC material used, giving a total of ˜700 kg CO2eq/kWh. This is related to high electrical input required for OC processing, as well as high OC losses during production and from plant waste. Only when processing parameters are optimised and OC recycling from plant waste is implemented - reducing fresh OC needs – is the environmental impact lower than the conventional technologies studied (e.g. 0.2 kg CO2 eq/kWh vs. ˜0.3-1 kg CO2 eq/kWh, respectively). Further research should thus focus on identifying OCs that do not require energy intensive processing and can endure repeated cycles, allowing for recycling.