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Radon variability due to floor level in two typical residential buildings in Serbia

Treść / Zawartość
Identyfikatory
Warianty tytułu
Konferencja
III International Conference „Radon in the Environment” (3 ; 27-31 May 2019 ; Krakow, Poland)
Języki publikacji
EN
Abstrakty
EN
It is well known that one of the factors that influence the indoor radon variability is the floor level of the buildings. Considering the fact that the main source of indoor radon is radon in soil gas, it is expected that the radon concentration decreases at higher floors. Thus at higher floors the dominant source of radon is originating from building materials, and in some cases there may be deviations from the generally established regularity. In such sense, we chose one freestanding single-family house with loft and other 16-floor high-rise residential building for this study. The indoor radon measurements were performed by two methods: passive and active. We used passive devices based on track-etched detectors: Radtrak2 Radonova. For the short-term indoor radon measurements, we used two active devices: SN1029 and SN1030 (manufactured by Sun Nuclear Corporation). The first device was fixed in the living room at the ground level and the second was moved through the floors of the residential building. Every measuring cycle at the specified floor lasted seven days with the sampling time of 2 h. The results show two different indoor radon behaviours regarding radon variability due to floor level. In the single-family house with loft we registered intense difference between radon concentration in the ground level and loft, while in the high-rise residential building the radon level was almost the same at all floors, and hence we may conclude that radon originated mainly from building materials.
Słowa kluczowe
Czasopismo
Rocznik
Strony
121--125
Opis fizyczny
Bibliogr. 19 poz., rys.
Twórcy
  • Institute of Physics Belgrade University of Belgrade Pregrevica 118 St., 11080 Belgrade, Serbia
  • Institute of Physics Belgrade University of Belgrade Pregrevica 118 St., 11080 Belgrade, Serbia
  • Institute of Physics Belgrade University of Belgrade Pregrevica 118 St., 11080 Belgrade, Serbia
  • Institute of Physics Belgrade University of Belgrade Pregrevica 118 St., 11080 Belgrade, Serbia
  • Institute of Physics Belgrade University of Belgrade Pregrevica 118 St., 11080 Belgrade, Serbia
  • Institute of Physics Belgrade University of Belgrade Pregrevica 118 St., 11080 Belgrade, Serbia
  • Institute of Physics Belgrade University of Belgrade Pregrevica 118 St., 11080 Belgrade, Serbia
  • Institute of Physics Belgrade University of Belgrade Pregrevica 118 St., 11080 Belgrade, Serbia
  • Serbian Radiation and Nuclear Safety and Security Directorate Masarikova 5 St., 11000 Belgrade, Serbia
Bibliografia
  • 1. Bochicchio, F., Campos-Venuti, G., Piermattei, S., Nuccetelli, C., Risica, S., Tommasino, L., Torri, G., Magnoni, M., Agnesod, G., Sgorbati, G., Bonomi, M., Minach,L., Trotti, F., Malisan, M. R., Maggiolo, S., Gaidolfi , L.,Giannardi, C., Rongoni, A., Lombardi, M., Cherubini,G., D’Ostilio, S., Cristofaro, C., Pugliese, M., Martucci,V., Crispino, A., Cuzzocrea, P., Sansone Santamaria,A., & Cappai, M. (2005). Annual average and seasonal variations of residential radon concentration for all the Italian Regions. Radiat. Meas., 40, 686–694.
  • 2. Friedmann, H. (2005). Final results of the Austrian Radon Project. Health Phys., 89(4), 339–348.
  • 3. Du, L., Prasauskas, T., Leivo, V., Turunen, M., Pekkonen, M., Kiviste, M., Aaltonen, A., Martuzevicius,D., & Haverinen-Shaughnessy, U. (2015). Assessment of indoor environmental quality in existing multifamily buildings in North-East Europe. Environ. Int.,79, 74–84.
  • 4. Cucoş (Dinu), A., Cosma, C., Dicu, T., Begy, R.,Moldovan, M., Papp, B., Niţă, D., Burghele, B., & Sainz, C. (2012). Thorough investigations on indoor radon in Băiţa radon-prone area (Romania). Sci. Total Environ., 431, 78–83.
  • 5. Yarmoshenko, I., Vasilyev, A., Malinovsky, G., Bossew, P., Žunić, Z. S., Onischenko, A., & Zhukovsky,M. (2016). Variance of indoor radon concentration: Major influencing factors. Sci. Total Environ., 541, 155–160.
  • 6. Kropat, G., Bochud, F., Jaboyedoff, M., Laedermann, J. P., Murith, C., Palacios, M., & Baechler, S. (2014).Major influencing factors of indoor radon concentrations in Switzerland. J. Environ. Radioact., 129, 7–22.
  • 7. Borgoni, R., De Francesco, D., De Bartolo, D., & Tzavidis, N. (2014). Hierarchical modeling of indoor radon concentration: how much do geology and building factors matter? J. Environ. Radioact., 138, 227–237.
  • 8. Xie, D., Liao, M., & Kearfott, K. J. (2015). Influence of environmental factors on indoor radon concentration levels in the basement and ground floor of a building – A case study. Radiat. Meas., 82, 52–58.
  • 9. Man, C. K., & Yeung, H. S. (1999). Modeling and measuring the indoor radon concentrations in highrise buildings in Hong Kong. Appl. Radiat. Isot., 50,1131–1135.
  • 10. Vukotić, P., Zekić, R., Antović, N. M., & Andjelić, T.(2019). Radon concentrations in multi-story buildings in Montenegro. Nucl. Technol. Radiat. Prot., 34,165–174.
  • 11. Lorenzo-González, M., Ruano-Ravina, A., Peón, J.,Piñeiro, M., & Barros-Dios, J. M. (2017). Residential radon in Galicia: a cross-sectional study in a radonprone area. J. Radiol. Prot., 37(3), 728–741.
  • 12. Elío, J., Cinelli, G., Bossew, P., Gutiérrez-Villanueva, J. L., Tollefsen, T., De Cort, M., Nogarotto, A., & Braga, R. (2019). The first version of the Pan-European Indoor Radon Map. Nat. Hazards Earth Syst. Sci., 19,2451–2464.
  • 13. Jovanović Popović, M., Ignjatović, D., Radivojević, A., Rajčić, A., Ćuković Ignjatović, N., Đukanović, Lj.,& Nedić, M. (2013). National typology of residential buildings in Serbia. Belgrade: Faculty of Architecture University of Belgrade.
  • 14. Udovičić, V., Maletić, D., Banjanac, R., Joković, D.,Dragić, A., Veselinović, N., Živanović, J., Savić, M., & Forkapić, S. (2018). Multiyear indoor radon variability in a family house–A case study in Serbia. Nucl. Technol. Radiat. Prot., 33(2), 174–179.
  • 15. Maletić, D., Udovičić, V., Banjanac, R., Joković, D., Dragić, A., Veselinović, N., & Filipović, J. (2014). Comparison of multivariate classification and regression methods for indoor radon measurements. Nucl. Technol. Radiat. Prot., 29, 17–23.
  • 16. Filipović, J., Maletić, D., Udovičić, V., Banjanac, R., Joković, D., Savić, M., & Veselinović, N. (2016). The use of multivariate analysis of the radon variability in the underground laboratory and indoor environment. Nukleonika, 61(3), 357–360. DOI: 10.1515/nuka-2016-0059.
  • 17. Udovičić, V., Aničin, I., Joković, D., Dragić, A., Banjanac, R., Grabež, B., & Veselinović, N. (2011). Radon time-series analysis in the Underground Low-level Laboratory in Belgrade, Serbia. Radiat. Prot. Dosim.,145(2/3), 155–158.
  • 18. Udovičić, V., Filipović, J., Dragić, A., Banjanac, R.,Joković, D., Maletić, D., Grabež, B., & Veselinović,N. (2014). Daily and seasonal radon variability in the underground low-background laboratory in Belgrade, Serbia. Radiat. Prot. Dosim., 160(1/3), 62–64.
  • 19. Ujić, P., Čeliković, I., Kandić, A., Vukanac, I.,Đurašević, M., Dragosavac, D., & Žunić, Z. S. (2010).Internal exposure from building materials exhaling 222Rn and 220Rn as compared to external exposure due to their natural radioactivity content. Appl. Radiat. Isot., 68, 201–206.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-542b28ed-fc96-4cc2-a472-a14bcd160bc2
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