Your search keyword '"Stenström K. E."' showing total 3 results

1. A compact accelerator driven neutron source at the Applied Nuclear Physics Laboratory, Lund University

Author

Frost, R. J. W., Elfman, M., Fissum, K., Kristiansson, P., Mauritzson, N., Pallon, J., Pédehontaa-Hiaa, G., Perrey, H., Stenström, K. E., and Sjöland, A.

Published

2023

2. Primary and secondary biomass burning aerosols determined by proton nuclear magnetic resonance (H-1-NMR) spectroscopy during the 2008 EUCAARI campaign in the Po Valley (Italy)

Author

Paglione M., Saarikoski S, Carbone S, Hillamo R, Facchini M. C., Finessi E., Giulianelli L., Carbone C., Fuzzi S., Swietlicki E., Stenström K. E., Prévôt A. S. H., Massoli P., Canaragatna M., Worsnop D., Decesari S., MORETTI, FABIO, TAGLIAVINI, EMILIO, Paglione M., Saarikoski S, Carbone S, Hillamo R, Facchini M.C., Finessi E., Giulianelli L., Carbone C., Fuzzi S., Moretti F., Tagliavini E., Swietlicki E., Stenström K.E., Prévôt A.S.H., Massoli P., Canaragatna M., Worsnop D., and Decesari S.

Subjects

NON-FOSSIL CARBON, MASS-SPECTROMETER, PARTICULATE MATTER, PO VALLEY, complex mixtures, NMR

Abstract

Atmospheric organic aerosols are generally classified as primary and secondary (POA and SOA) according to their formation processes. An actual separation, however, is challenging when the timescales of emission and gas-to-particle formation overlap. The presence of SOA formation in biomass burning plumes leads to scientific questions about whether the oxidized fraction of biomass burning aerosol is rather of secondary or primary origin, as some studies would suggest, and about the chemical compositions of oxidized biomass burning POA and SOA. In this study, we apply nuclear magnetic resonance (NMR) spectroscopy to investigate the functional group composition of fresh and aged biomass burning aerosols during an intensive field campaign in the Po Valley, Italy. The campaign was part of the EUCAARI project and was held at the rural station of San Pietro Capofiume in spring 2008. Factor analysis applied to the set of NMR spectra was used to apportion the wood burning contribution and other organic carbon (OC) source contributions, including aliphatic amines. Our NMR results, referred to the polar, water-soluble fraction of OC, show that fresh wood burning particles are composed of polyols and aromatic compounds, with a sharp resemblance to wood burning POA produced in wood stoves, while aged samples are clearly depleted of alcohols and are enriched in aliphatic acids with a smaller contribution of aromatic compounds. The comparison with biomass burning organic aerosols (BBOA) determined by high-resolution aerosol mass spectrometry (HR-TOF-AMS) at the site shows only a partial overlap between NMR BB-POA and AMS BBOA, which can be explained by either the inability of BBOA to capture all BB-POA composition, especially the alcohol fraction, or the fact that BBOA account for insoluble organic compounds unmeasured by the NMR. Therefore, an unambiguous composition for biomass burning POA could not be derived from this study, with NMR analysis indicating a higher O/C ratio compared to that measured for AMS BBOA. The comparison between the two techniques substantially improves when adding factors tracing possible contributions from biomass burning SOA, showing that the operational definitions of biomass burning organic aerosols are more consistent between techniques when including more factors tracing chemical classes over a range of oxidation levels. Overall, the non-fossil total carbon fraction was 50-57%, depending on the assumptions about the 14C content of non-fossil carbon, and the fraction of organic carbon estimated to be oxidized organic aerosol (OOA) from HR-TOF-AMS measurements was 73-100% modern

Published

2014

3. Tritium in urine from members of the general public and occupationally exposed workers in Lund, Sweden, prior to operation of the European Spallation Source.

Author

Pédehontaa-Hiaa G, Holstein H, Mattsson S, Rääf CL, and Stenström KE

Subjects

Humans, Mass Spectrometry, Occupational Exposure, Particle Accelerators, Sweden, Tritium, Radiation Monitoring

Abstract

A powerful neutron source, the European Spallation Source (ESS), is currently under construction in Lund, Sweden (~90 000 inhabitants). Levels of tritium ( 3 H) in urine were estimated in members of the public in Lund and employees at the ESS using liquid scintillation counting, to obtain baseline levels before the start of operation of the ESS. These were compared with levels in other occupationally exposed radiation workers. Both the spallation reaction in the ESS tungsten target and the activation of various materials by the protons produced by the 5 MW linear accelerator will generate tritium, which will be released into the atmosphere mainly as tritiated water (HTO). Urinary HTO activity concentrations were determined in a total of 55 individuals belonging to four different categories: ESS employees, neighbours of the ESS, members of the general public in Lund and exposed workers from other facilities. The participants were asked to provide information on their beverage intake the day before urine sampling. The urine samples were filtered on activated charcoal and distilled before analysis. The effect of sample preparation on the isotope fractionation of urine samples was investigated by isotope ratio mass spectrometry (IRMS) of 2 H/ 1 H, which showed no influence. IRMS was also used to investigate if the ratio between the stable hydrogen isotopes ( 2 H/ 1 H) could provide useful data of the origin, and hence the tritium concentration, of various types of drinking water. Urinary HTO activity concentrations determined using liquid scintillation counting (LSC) were found to be below the minimum detectable activity (MDA) of 2.1 Bq⋅L -1 for most of the participants. Five of the workers actively handling organic tritiated material were found to have activity concentrations between 3.5 and 11 Bq⋅L -1 , which were higher than the average value in local tap water of 1.5 ± 0.6 Bq⋅L -1 . The results will be used to evaluate the radiological impact on the population from future releases of tritium resulting from the operation of the ESS., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2019 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2020