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Fant 10000 publikasjoner. Viser side 228 av 400:

Publikasjon  
År  
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Influence of La Nina on high impact weather over Eurasia in summer 2010.

Peters, D.; Schneidereit, A.; Fraedrich, K.; Orsolini, Y.J.; Zhang, L.; Zhu, X.

2015

Influence of emissions from ships and local power plants on air quality in Longyearbyen, Ny-Ålesund and Barentsburg

Dekhtyareva, Alena; Hermansen, Ove; Nikulina, Anna; Chernov, Dmitry; Drotikova, Tatiana; Gregorič, Asta

2019

Influence of clouds on the spectral actinic flux density in the lower troposphere (INSPECTRO): overview of the field campaigns.

Thiel, S.; Ammannato, L.; Bais, A.; Bandy, B.; Blumthaler, M.; Bohn, B.; Engelsen, O.; Gobbi, G.P.; Gröbner, J.; Jäkel, E.; Junkermann, W.; Kazadzis, S.; Kift, R.; Kjeldstad, B.; Kouremeti, N.; Kylling, A.; Mayer, B.; Monks, P.S.; Reeves, C.E.; Schallhart, B.; Scheirer, R.; Schmidt, S.; Schmitt, R.; Schreder, J.; Silbernagl, R.; Topaloglou, C.; Thorseth, T.M.; Webb, A.R.; Wendisch, M.; Werle, P.

2008

Influence of climate change on contaminant distribution and effects in Arctic marine food webs - Summary of the IPY project COPOL.

Evenset, A.; Borgå, K.; Warner, N.; Bustnes, J.O.; Ruus, A.; Christensen, G.; Heimstad, E.S.; Overjord, J.; Hallanger, I.G.; Gabrielsen, G.W.

2012

Influence of climate and biomagnification in species of Arctic zooplankton. NILU F

Hallanger, I.; Ruus, A.; Warner, N.; Evenseth, A.; Gabrielsen, G.W.; Borgå, K.

2011

Influence of biomass burning and anthropogenic emissions on ozone, carbon monoxide and black carbon at the Mt. Cimone GAW-WMO global station (Italy, 2165 m a.s.l.).

Cristofanelli, P.; Fierli, F.; Marinoni, A.; Calzolari, F.; Duchi, R.; Burkhart, J.; Stohl, A.; Maione, M.; Arduini, J.; Bonasoni, P.

2013

Influence of aerosol-radiation interactions on air pollution in East Asia

Hodnebrog, Øivind; Stjern, Camilla Weum; Marelle, Louis; Myhre, Gunnar; Pisso, Ignacio; Wang, Shuxiao

2022

Inferring surface energy fluxes using drone data assimilation in large eddy simulations

Pirk, Norbert; Aalstad, Kristoffer; Westermann, Sebastian; Vatne, Astrid; Hove, Alouette van; Tallaksen, Lena Merete; Cassiani, Massimo; Katul, Gabriel G.

Spatially representative estimates of surface energy exchange from field measurements are required for improving and validating Earth system models and satellite remote sensing algorithms. The scarcity of flux measurements can limit understanding of ecohydrological responses to climate warming, especially in remote regions with limited infrastructure. Direct field measurements often apply the eddy covariance method on stationary towers, but recently, drone-based measurements of temperature, humidity, and wind speed have been suggested as a viable alternative to quantify the turbulent fluxes of sensible (H) and latent heat (LE). A data assimilation framework to infer uncertainty-aware surface flux estimates from sparse and noisy drone-based observations is developed and tested using a turbulence-resolving large eddy simulation (LES) as a forward model to connect surface fluxes to drone observations. The proposed framework explicitly represents the sequential collection of drone data, accounts for sensor noise, includes uncertainty in boundary and initial conditions, and jointly estimates the posterior distribution of a multivariate parameter space. Assuming typical flight times and observational errors of light-weight, multi-rotor drone systems, we first evaluate the information gain and performance of different ensemble-based data assimilation schemes in experiments with synthetically generated observations. It is shown that an iterative ensemble smoother outperforms both the non-iterative ensemble smoother and the particle batch smoother in the given problem, yielding well-calibrated posterior uncertainty with continuous ranked probability scores of 12 W m−2 for both H and LE, with standard deviations of 37 W m−2 (H) and 46 W m−2 (LE) for a 12 min vertical step profile by a single drone. Increasing flight times, using observations from multiple drones, and further narrowing the prior distributions of the initial conditions are viable for reducing the posterior spread. Sampling strategies prioritizing space–time exploration without temporal averaging, instead of hovering at fixed locations while averaging, enhance the non-linearities in the forward model and can lead to biased flux results with ensemble-based assimilation schemes. In a set of 18 real-world field experiments at two wetland sites in Norway, drone data assimilation estimates agree with independent eddy covariance estimates, with root mean square error values of 37 W m−2 (H), 52 W m−2 (LE), and 58 W m−2 (H+LE) and correlation coefficients of 0.90 (H), 0.40 (LE), and 0.83 (H+LE). While this comparison uses the simplifying assumptions of flux homogeneity, stationarity, and flat terrain, it is emphasized that the drone data assimilation framework is not confined to these assumptions and can thus readily be extended to more complex cases and other scalar fluxes, such as for trace gases in future studies.

2022

Industrial and public infrastructure as local sources of organic contaminants in the Arctic

Kallenborn, Roland Peter; Gabrielsen, Geir W.; Katrin Vorkamp, ; Reiersen, Lars Otto; Evenset, Anita; Pedersen, Kristine B.; Simonetta Corsolini, ; Nicoletta Ademollo, ; Yi-Fan Li, ; Zifeng Zhang, ; Langberg, Håkon Austad; Hartz, William Frederik; Hippel, Frank von; C.G. Muir, Derek; Wit, Cynthia de; J Gunnarsdottir, Maria; Erland Jensen, Pernille; M Kirkelund, Gunvor; Breedveld, Gijs D.; Nash, Susan Bengtson; Lyche, Jan Ludvig; Elena Barbaro,

Arctic pollution has been a focal point in environmental research over the past five decades. Recently, the number of pollutants identified as relevant to the Arctic has significantly increased. Consequently, the expert group on Persistent Organic Pollutants (POPs) and Chemicals of Emerging Arctic Concern (CEACs) of the Arctic Monitoring and Assessment Programme (AMAP) has prepared a series of assessments of contaminants in the Arctic, including influences of climate change. This review addresses local sources of Arctic organic pollutants associated with infrastructure in the Arctic. Industrial, military, and public infrastructures, including domestic installations, sewage treatment, solid waste management, and airports, were identified as significant local pollution sources. Additionally, operational emissions (e.g., from shipping, transportation, heating, and power production) contribute to the overall local pollution profile. Based on currently available scientific information, elevated POP and CEAC levels are mostly found in close proximity to identified local pollution sources. To date, hazardous effects have only been confirmed for a few selected chemicals, such as polycyclic aromatic compounds (PAC) and certain pharmaceutical residues. However, studies are biased in the sense that they often focus on well-known contaminants, at a risk of overlooking CEAC and their effects. The review identifies several measures to reduce human impacts on local Arctic environments, including (i) using local indicator pollutants in ongoing national monitoring schemes, (ii) harmonizing emission reduction policies and licensing of industrial activities in the region to minimize exposure risks and environmental pollution, (iii) encouraging local municipalities, industries, and related stakeholders to coordinate their activities to minimize pollutant emissions.

2025

Indoor/outdoor particulate matter number and mass concentration in modern offices.

Chatoutsidou, S.E.; Ondracek, J.; Tesar, O.; Tørseth, K.; Zdimal, V.; Lazaridis, M.

2015

Indoor/outdoor particulate matter measurements in two residential houses in Oslo, Norway.

Lazaridis, M.; Dahlin, E.; Hanssen, J.E.; Smolik, J.; Schmidbauer, N.; Moravec, P.; Zdimal, V.; Hermansen, O.; Glytsos, T.; Svendby, T.; Dye, C.

2003

Indoor organic films and dust as reservoirs of polychlorinated alkanes: Enrichment patterns and exposure implications

Ezker, Idoia Beloki; Yuan, Bo; Bohlin-Nizzetto, Pernilla; Li, Li; Borgen, Anders; Wang, Thanh

Indoor environments have shown to be a major source of human exposure of polychlorinated alkanes (PCAs), yet information on their distribution across indoor matrices and associated exposure pathways remains limited. PCAs, the main components in chlorinated paraffin mixtures, are widely used as flame retardants and plastic additives in numerous indoor consumer products and materials. This study quantified PCAs in paired indoor dust and indoor organic films (IOFs) from homes, offices, schools and gym sports halls (n = 41) in Sweden and assess their contribution to human exposure. Mean PCA concentrations in indoor dust were 7.3, 43.2, and 14.6 μg g−1 for ∑PCAs-C10–13, ∑PCAs-C14–17, and ∑PCAs-C18–30, respectively, while corresponding concentrations in IOFs were 38.2, 312, and 123 ng m−2. PCAs-C14–17 dominated both matrices, but IOFs showed an enrichment tendency towards longer-chain, higher-KOA PCAs, reflecting the less frequent cleaning and longer-term PCA accumulation in IOFs. IOF concentrations were particularly elevated in schools, and PCA variation across sites was influenced by differences in ventilation practices and building age. Dermal uptake was the dominant exposure pathway for children, with substantially estimated doses from IOFs, while adults show comparable dust dermal and dust ingestion exposures. PCA transformation products formed through hydroxylation, hydrolysis, and sulfation were also tentatively detected in both matrices. These findings highlight the importance of jointly assessing dust and IOFs to better characterize multipathway exposure to the diverse PCA mixture in indoor environments.

2026

Indoor contamination with hexabromocyclododecanes, polybrominated diphenyl ethers, and perfluoroalkyl compounds: An important exposure pathway for people?

Harrad, S.; de Wit, C.A.; Abdallah, M.A.E.; Bergh, C.; Bjorklund, J.A.; Covaci, A.; Darnerud, P.O.; de Boer, J.; Diamond, M.; Huber, S.; Leonards, P.; Mandalakis, M.; Oestman, C.; Haug, L.S.; Thomsen, C.; Webster, T.F.

2010

Indoor and outdoor particle number and mass concentrations in Athens. Sources, sinks and variability of aerosol parameters.

Diapouli, E.; Eleftheriadis, K.; Karanasiou, A.A.; Vratolis, S.; Hermansen, O.; Colbeck, I.; Lazaridis, M.

2011

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