Multibarrier system preventing migration of radionuclides from radioactive waste repository

Olszewska, W.; Miśkiewicz, A.; Zakrzewska-Kołtuniewicz, G.; Lankof, L.; Pająk, L.

doi:10.1515/nuka-2015-0103

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Tytuł artykułu

Multibarrier system preventing migration of radionuclides from radioactive waste repository

Autorzy

Olszewska W. , Miśkiewicz A. , Zakrzewska-Kołtuniewicz G. , Lankof L. , Pająk L.

Treść / Zawartość

Pełne teksty:

olszewska_Multibarrier system preventing.pdf

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Identyfikatory

DOI

10.1515/nuka-2015-0103

Warianty tytułu

Konferencja

International Conference on Development and Applications of Nuclear Technologies NUTECH 2014 (21-24.09.2014, Warsaw, Poland)

Języki publikacji

Abstrakty

Safety of radioactive waste repositories operation is associated with a multibarrier system designed and constructed to isolate and contain the waste from the biosphere. Each of radioactive waste repositories is equipped with system of barriers, which reduces the possibility of release of radionuclides from the storage site. Safety systems may differ from each other depending on the type of repository. They consist of the natural geological barrier provided by host rocks of the repository and its surroundings, and an engineered barrier system (EBS). The EBS may itself comprise a variety of sub-systems or components, such as waste forms, canisters, buffers, backfi lls, seals and plugs. The EBS plays a major role in providing the required disposal system performance. It is assumed that the metal canisters and system of barriers adequately isolate waste from the biosphere. The evaluation of the multibarrier system is carried out after detailed tests to determine its parameters, and after analysis including mathematical modeling of migration of contaminants. To provide an assurance of safety of radioactive waste repository multibarrier system, detailed long term safety assessments are developed. Usually they comprise modeling of EBS stability, corrosion rate and radionuclide migration in near fi eld in geosphere and biosphere. The principal goal of radionuclide migration modeling is assessment of the radionuclides release paths and rate from the repository, radionuclides concentration in geosphere in time and human exposure to ionizing radiation.

Słowa kluczowe

engineered barrier migration radionuclides repository radioactive waste

Wydawca

Institute of Nuclear Chemistry and Technology

Czasopismo

Nukleonika

Rocznik

2015

Tom

Vol. 60, No. 3, part 2

Strony

557--563

Opis fizyczny

Bibliogr. 19 poz., rys.

Twórcy

autor

Olszewska W.

Institute of Nuclear Chemistry and Technology, 16 Dorodna Str., 03-195 Warsaw, Poland, Tel.: +48 22 504 1270, Fax: +48 22 811 1917

autor

Miśkiewicz A.

a.miskiewicz@ichtj.waw.pl

Institute of Nuclear Chemistry and Technology, 16 Dorodna Str., 03-195 Warsaw, Poland, Tel.: +48 22 504 1270, Fax: +48 22 811 1917

autor

Zakrzewska-Kołtuniewicz G.

Institute of Nuclear Chemistry and Technology, 16 Dorodna Str., 03-195 Warsaw, Poland, Tel.: +48 22 504 1270, Fax: +48 22 811 1917

autor

Lankof L.

The Mineral and Energy Economy Research Institute of the Polish Academy of Sciences, 7 Wybickiego Str., 31-261 Krakow, Poland

autor

Pająk L.

The Mineral and Energy Economy Research Institute of the Polish Academy of Sciences, 7 Wybickiego Str., 31-261 Krakow, Poland

Bibliografia

1. CEA. (2012). Report on sustainable radioactive waste management. (2012). CEA Nuclear Energy Division, Saclay Center.
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3. Chapman, N., & Hooper, A. (2011). The disposal of radioactive wastes underground. In Proceedings of the Geologists’ Association, 123, (pp. 46–63).
4. Engineered Barrier Systems (EBS): Design Requirements and Constraints. (2004). Workshop Proceedings, Turku, Finland, 26–29 August 2003, in co-operation with the European Commission and hosted by Posiva Oy, Finland.
5. Zakrzewska-Trznadel, G., Harasimowicz, M., & Chmielewski, A. G. (2001). Membrane processes in nuclear technology-application for liquid radioactive waste treatment. Sep. Purif. Technol., 22/23, 617–625.
6. Tomaszewska, B., & Bodzek, M. (2013). The removal of radionuclides during desalination of geothermal waters containing boron using the BWRO system. Desalination, 309, 284–290.
7. Wdowin, M., Franus, M., Panek, R., Bandura, L., & Franus, W. (2014). The conversion technology of fly ash into zeolites. Clean Technologies and Environmental Policy, 16, 1217–1223. DOI: 10.1007/s10098-014-0719-6, http://wbia.pollub.pl/fi les/102/attachment/2382_clean.pdf.
8. IAEA. (2001). Performance of engineered barrier materials in near surface disposal facilities for radioactive waste, results of a coordinated research project. Vienna: International Atomic Energy Agency. (IAEA-TECDOC-1255).
9. IPPA Report from I Workshop in Poland IPPA FP7-269849 Project Deliverable 6.3, date of issue 08.03.2012; Project co-funded by the European Commission under the Seventh Euratom Framework Programme for Nuclear Research and Training Activities (2007–2011).
10. Lankof, L., & Pająk, L. (2014). Założenia metodyczne w zakresie modelowania migracji radionuklidów w środowisku geologicznym w sąsiedztwie składowisk nisko i średnioaktywnych odpadów promieniotwórczych. Technika Poszukiwań Geologicznych Geotermia, Zrównoważony Rozwój nr 2/2014. Wyd. IGSMiE PAN.
11.IAEA. (2004). Safety Assessment Methodologies for Near Surface Disposal Facilities Vol. 1 – Review and enhancement of safety assessment approaches and tools. Vienna: International Atomic Energy Agency.
12.Crăciun, C. (1997). Mineralogical, physical and chemical research of clay deposits from Saligny area. Economical Contract no. 37.1/1997, Romanian Academy for Science in Agriculture and Forestry ‘Gheorghe Ionescu-Siseşti’. Bucharest Institute for Research in Pedology and Agro-chemistry.
13.Bondietti, E. A. (1982). Mobile species of Pu, Am,Cm, Np and Tc in the environment. Environmental Migration of Long-Lived Radionuclides. Vienna: International Atomic Energy Agency. (SM257/42).
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15.Curtis, M., Oldenburg, C., & Pruess, K. (1995). EOS7R: Radionuclide Transport for TOUGH2, Berkeley: Lawrence Berkeley National Laboratory. (Report LBL-34868).
16. Pruess, K., Oldenburg, C., & Moridis, G. (2012). TOUGH2 User’s Guide, Version 2. (p. 197). Berkeley: Earth Sciences Division, Lawrence Berkeley National Laboratory, University of California.
17. Dendys, M., Tomaszewska, B., & Pająk, L. (2014). Modelowanie numeryczne jako narzędzie wspomagające badania systemów geotermalnych. In A. Krawiec & I. Jamroska (Eds.), Modele matematyczne w hydrogeologii (pp. 199–206). Toruń: Wydawnictwo Naukowe Uniwersytetu Mikołaja Kopernika.
18. Bujakowski, W., & Tomaszewska, B. (Eds.). (2014). Atlas wykorzystania wód termalnych do skojarzonej produkcji energii elektrycznej i cieplnej w układach binarnych w Polsce (Atlas of the possible use of geothermal waters for combiner production of electricity and heat using binary systems in Poland). Kraków: Wydawnictwo “Jak”.
19. Śliwa, T., Gonet, A., Złotkowski, A., Pająk, L., Sapińska-Śliwa, A., & Jezuit, Z. (2012). Zintegrowany system otworowych wymienników ciepła i kolektorów słonecznych. Monografie Wydawnictw Akademii Górniczo-Hutniczej im. Stanisława Staszica w Krakowie 0474 (pp. 161–165, abstract). Kraków: AGH

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Bibliografia

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