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Annual Variations of 14C Concentration in the Tree Rings in the Vicinity of Ignalina Nuclear Power Plant

Published online by Cambridge University Press:  02 July 2018

Žilvinas Ežerinskis*
Affiliation:
Center for Physical Sciences and Technology, Savanorių ave. 231, LT-02300 Vilnius, Lithuania
Justina Šapolaitė
Affiliation:
Center for Physical Sciences and Technology, Savanorių ave. 231, LT-02300 Vilnius, Lithuania
Algirdas Pabedinskas
Affiliation:
Center for Physical Sciences and Technology, Savanorių ave. 231, LT-02300 Vilnius, Lithuania
Laurynas Juodis
Affiliation:
Center for Physical Sciences and Technology, Savanorių ave. 231, LT-02300 Vilnius, Lithuania
Andrius Garbaras
Affiliation:
Center for Physical Sciences and Technology, Savanorių ave. 231, LT-02300 Vilnius, Lithuania
Evaldas Maceika
Affiliation:
Center for Physical Sciences and Technology, Savanorių ave. 231, LT-02300 Vilnius, Lithuania
Rūta Druteikienė
Affiliation:
Center for Physical Sciences and Technology, Savanorių ave. 231, LT-02300 Vilnius, Lithuania
Darius Lukauskas
Affiliation:
State Nuclear Power Safety Inspectorate, A. Goštauto str. 12, LT-01108 Vilnius, Lithuania
Vidmantas Remeikis
Affiliation:
Center for Physical Sciences and Technology, Savanorių ave. 231, LT-02300 Vilnius, Lithuania
*
*Corresponding author. Email: [email protected].

Abstract

In this paper we analyze the radiocarbon (14C) concentration changes over the whole operational period of the Ignalina Nuclear Power Plant (INPP) including the post-shutdown decommissioning. Environmental samples from the vicinity of the INPP and a rural area as background of pine tree rings were analyzed with the single stage accelerator mass spectrometer (SSAMS). The analysis shows the local influence of the INPP from 3 to 7 pMC. The whole time span from 1983 to 2015 is divided into three periods representing the early and late operational and post-shutdown stages of the INPP with different 14C profiles in analyzed samples. The influence of the maintenance of the INPP and radioactive waste management activities are indicated and discussed.

Type
Trees
Copyright
© 2018 by the Arizona Board of Regents on behalf of the University of Arizona 

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References

REFERENCES

Almenas, K, Kalietka, A, Ushpuras, E. 1994. Ignalina RBMK-1500.Google Scholar
Gaiko, VB, Korablev, NA, Solov’ev, EN, Trosheva, TI, Shamov, VP, Umanets, MP, Shcherbina, VG. 1985. Discharge of 14C by nuclear power stations with RBMK-1000 reactors. Soviet Atomic Energy 59:703–5.Google Scholar
Graven, HD, Gruber, N. 2011. Continental-scale enrichment of atmospheric 14CO2 from the nuclear power industry: potential impact on the estimation of fossil fuel-derived CO2 . Atmospheric Chemistry and Physics 11:12339–49.Google Scholar
Ignalina NPP (Ignalina Nuclear Power Plant). 1999. Nuclear safety reports.Google Scholar
Isogai, K, Cook, G, Anderson, R. 2002. Reconstructing the history of 14C discharges from Sellafield: Part 1—atmospheric discharges. Journal of Environmental Radioactivity 59:207222.Google Scholar
Janovics, R, Kern, Z, Güttler, D, Wacker, L, Barnabás, I, Molnár, M. 2013. Radiocarbon Impact on a Nearby Tree of a Light-Water VVER-Type Nuclear Power Plant, Paks, Hungary. Radiocarbon 55(2):826832.Google Scholar
Ješkovský, M, Povinec, PP, Steier, P, Šivo, A, Richtáriková, M, Golser, R. 2015. Retrospective study of 14C concentration in the vicinity of NPP Jaslovské Bohunice using tree rings and the AMS technique. Nuclear Instruments and Methods in Physics Research B 361:129132.Google Scholar
Koarashi, J, Fujita, H, Nagaoka, M. 2016. Atmospheric discharge of 14C from the Tokai reprocessing plant: comprehensive chronology and environmental impact assessment. Journal of Nuclear Science and Technology 53:546553.Google Scholar
Konstantinov, EA, Korablev, NA, Solov’ev, EN, Shamov, VP, Fedorov, VL, Litvinov, AM, Olariu, A, Zakaria, M, Rääf, C, Mattsson, S. 1989. 14C emission from RBMK-1500 reactors and features determining it. Soviet Atomic Energy 66:77–9.Google Scholar
Kunz, C. 1985. Carbon-14 discharge at three light-water reactors. Health Physics 49:2535.Google Scholar
Levin, I, Kromer, B, Barabas, M, Munnich, KO. 1988. Environmental distribution and long-term dispersion of reactor 14CO2 around two German nuclear power plants. Health Physics 54:149156.Google Scholar
Magnusson, Å, Stenström, K, Skog, G, Adliene, D, Adlys, G, Hellborg, R, Olariu, A, Zakaria, M, Rääf, C, Mattsson, S. 2004. Levels of 14C in the terrestrial environment in the vicinity of two European nuclear power plants. Radiocarbon 46(2):863868.Google Scholar
Magnusson, Å, Stenström, K, Skog, G, Adliene, D, Adlys, G, Dias, C, Rääf, C, Zakaria, M, Mattsson, S. 2007. Carbon-14 levels in the vicinity of the Lithuanian nuclear power plant Ignalina. Nuclear Instruments and Methods in Physics Research B 259:530555.Google Scholar
Mazeika, J, Petrosius, R, Pukiene, R. 2007. Carbon-14 in tree rings in the vicinity of Ignalina Nuclear Power Plant, Lithuania. Geochronometria 28:3137.Google Scholar
Mazeika, J, Petrosius, R, Pukiene, R. 2008. Carbon-14 in tree rings and other terrestrial samples in the vicinity of Ignalina Nuclear Power Plant, Lithuania. Journal of Environmental Radioactivity 99:238247.Google Scholar
Mazeika, J. 2010. Carbon-14 in terrestrial and aquatic environment of Ignalina nuclear power plant: sources of production, releases and dose estimates. In: Tsvetjov P, editor. Nuclear Power. Intech.Google Scholar
Němec, M, Wacker, L, Hajdas, I, Gäggeler, H. 2010. Alternative methods for cellulose preparation for AMS measurement. Radiocarbon 52(3):1358–70.Google Scholar
Plukis, A, Remeikis, V, Juodis, L, Plukienė, R, Lukauskas, D, Gudelis, A. 2008. Analysis of nuclide content in Ignalina NPP radioactive waste streams. Lithuanian Journal of Physics 48.Google Scholar
Povinec, P, Chudý, M, Šivo, A. 1986. Anthropogenic radiocarbon: past, present and future. Radiocarbon 28(2A):668672.Google Scholar
Povinec, P, Šivo, A, Ješkovský, M, Svetlik, I, Richtáriková, M, Kaizer, J. 2015. Radiocarbon in the atmosphere of the Žlkovce monitoring station of the Bohunice NPP: 25 years of continuous monthly measurements. Radiocarbon 57(3):355362.Google Scholar
Ramsey, C. 1995. Radiocarbon calibration and analysis of stratigraphy: the OxCal program. Radiocarbon 37(2):425430.Google Scholar
Remeikis, V, Juodis, L, Plukis, A, Vycinas, L, Rozkov, A, Jasiulionis, R. 2012. Indirect assessment of 135Cs activity in the ventilation system of the Ignalina NPP RBMK-1500 reactor. Nuclear Engineering and Design 242:420424.Google Scholar
Stenström, K, Erlandsson, B, Mattsson, S, Thornberg, C, Hellborg, R, Kiisk, M. 2000. 14 C Emission from Swedish Nuclear Power Plants and its Effect on the 14 C Levels in the Environment. Report.Google Scholar
Stenstrom, K, Skog, G, Thornberg, C, Erlandsson, B, Hellborg, R, Mattsson, S, Persson, P. 1997. 14C levels in the vicinity of two Swedish nuclear power plants and at two “clean-air” sites in southernmost Sweden. Radiocarbon 40(1):433–8.Google Scholar
Stuiver, M. 1983. International agreements and the use of the new oxalic acid standard. Radiocarbon 25(2):793–5.Google Scholar
Stuiver, M, Polach, HA. 1977. Reporting of 14C data. Radiocarbon 19(3):355363.Google Scholar
Svetlik, I, Fejgl, M, Tomaskova, L, Turek, K, Michalek, V. 2012. 14C studies in the vicinity of the Czech NPPs. Journal of Radioanalytical and Nuclear Chemistry 291:689695.Google Scholar
UNSCEAR (United Nations Scientific Committee on the Effects of Atomic Radiation). 2000. Sources and effects of ionizing radiation. UNSCEAR 2000 Report to the General Assembly. United Nations.Google Scholar
Veres, M, Hertelendi, E, Uchrin, G, Csaba, E, Barnabás, I, Ormai, P, Volent, G, Futó, I. 1995. Concentration of radiocarbon and its chemical forms in gaseous effluents, environmental air, nuclear waste and primary water of a pressurized water reactor power plant in Hungary. Radiocarbon 37(2):497504.Google Scholar
Wacker, L, Němec, M, Bourquin, J. 2010. A revolutionary graphitisation system: fully automated, compact and simple. Nuclear Instruments and Methods in Physics Research B 268:931–4.Google Scholar
Wang, Z, Xiang, Y, Guo, Q. 2012. 14C levels in tree rings located near Qinshan nuclear power plant, China. Radiocarbon 54(2):195202.Google Scholar
Xu, S, Cook, GT, Cresswell, AJ, Dunbar, E, Freeman, SPHT, Hastie, H, Hou, X, Jacobsson, P, Naysmith, P, Sanderson, DCW, Tripney, BG, Yamaguchi, K. 2016. 14C levels in the vicinity of the Fukushima Dai-ichi Nuclear Power Plant prior to the 2011 accident. Journal of Environmental Radioactivity 157:9096.Google Scholar
Yim, M-S, Caron, F. 2006. Life cycle and management of carbon-14 from nuclear power generation. Progress in Nuclear Energy 48:236.Google Scholar