Natural radioactivity of groundwater from the Przerzeczyn-Zdrój Spa

• Autorzy: Walencik A. , Kozłowska B. , Przylibski T. A. , Dorda J. , Zipper W.
• Języki publikacji: EN

Abstrakty

EN

The present authors performed investigations of natural radioactivity in groundwater from the Przerzeczyn- -Zdrój Spa. Some of the waters are regarded as medical and are used for balneological purposes. Samples from seven groundwater intakes were collected 5 times over a period of 8 years (1999–2007). In order to obtain necessary data, two different nuclear spectrometry techniques were applied: α spectrometry and liquid scintillation spectrometry. The activity concentrations of 222Rn varied in the range from 15±2 Bq/l to 154±22 Bq/l. The results of activity concentrations of 226,228Ra varied from below 10 mBq/l to 30±1.5 mBq/l and from below 30 mBq/l to 60±4 mBq/l, respectively. Activity concentration lower than minimum detectable activity (MDA) was obtained for 3 samples for 226Ra and 4 for 228Ra determinations out of 7 investigated samples. The uranium content in the studied samples was determined once and the value ranged from 4.5±0.6 mBq/l to 13.6±1.2 mBq/l for 238U and from 17.1±0.9 mBq/l to 52.2±2.8 mBq/l for 234U. All obtained values for uranium isotopes showed activity concentrations above MDA. The activity ratios 234U/238U, 222Rn/226Ra and 226Ra/238U and the correlations between different isotopes concentrations were evaluated.

Słowa kluczowe

EN

radon; radium; uranium; groundwater; medicinal water

• Wydawca: Institute of Nuclear Chemistry and Technology
• Czasopismo: Nukleonika
• Rocznik: 2010
• Tom: Vol. 55, No. 2
• Strony: 169--175
• Opis fizyczny: Bibliogr. 36 poz., rys.

Twórcy

autor

Walencik A.

autor

Kozłowska B.

autor

Przylibski T. A.

autor

Dorda J.

autor

Zipper W.

• Department of Nuclear Physics and Its Applications, Institute of Physics, University of Silesia, 4 Uniwersytecka Str., 40-007 Katowice, Poland, Tel.: +48 32 359 1308, Fax: +48 32 258 8431,

Bibliografia

• 1. Bateman H (1910) Solution of a system of differential equations occurring in the theory of radioactive transformations. Proceedings of the Cambridge Philosophical Society. Math Phys Sci 15:423–427
• 2. Botezatu E, Iacob O, Elisei G, Capitanu O (2005) Exposure of the population through mineral water consumption. Radioactiv Environ 7:1099–1107
• 3. Chau ND, Michalec B (2009) Natural radioactivity in bottled natural spring, mineral and therapeutic waters in Poland. J Radioanal Nucl Chem 278;1:121–129
• 4. Currie LA (1968) Limits for qualitative detection and quantitative determination. Anal Chem 40;3:586–592
• 5. Fistek J (1995) Hydrogeological conditions of Przerzeczyn-Zdrój Spa medicinal waters. In: Fistek J, Staśko S, Zieliński W. Groundwaters from the Fore-Sudetic block. Annales Societatis Geologorum Poloniae. Special issue. Przewodnik LXVI Zjazdu Polskiego Towarzystwa Geologicznego. Przewodnik do wycieczek, Wycieczka K: 266–271 (in Polish)
• 6. Hem JD (1985) Study and interpretation of the chemical characteristics of natural water. US Geological Survey Water-Supply Paper 2254
• 7. Hetman A, Dorda J, Zipper W (1998) Determination of radium isotopes concentrations in mineral waters by liquid scintillation method. Nukleonika 43;4:481–488
• 8. IAEA (2008) The world-wide open proficiency test IAEACU-2009-03 on the determination of natural and artificial radionuclides in moss-soil and spiked water. http://www.iaea.org./programmes/aqcs/interlab_studies.shtml
• 9. Jagielak J, Biernacka M, Henschke J, Sosińska A (1998) Radiological atlas of Poland 1997. Biblioteka Monitoringu Środowiska. Państwowa Inspekcja Ochrony Środowiska, CLOR, PAA, Warszawa (in Polish)
• 10. Kozłowska B (2009) Natural radioactivity of spring waters in spas of southern Poland. Wydawnictwo Uniwersytetu Śląskiego, Katowice (in Polish)
• 11. Kozłowska B, Morelli D, Walencik A et al. (2009) Radioactivity in waters of Mt. Etna (Italy). Radiat Meas, doi:10.1016/j.radmeas.2009.05.002
• 12. Kozłowska B, Walencik A, Dorda J (2008) Natural radioactivity and dose estimation in underground water from the Sudety Mountains in Poland. Radiat Prot Dosim 128;3:331–335
• 13. Kozłowska B, Walencik A, Dorda J, Przylibski TA (2007) Uranium, radium and 40K isotopes in bottled mineral
• waters from Outer Carpathians, Poland. Radiat Meas 42:1380–1386
• 14. Luo S, Ku TL, Roback R, Murrell M, McLing TL (2000) In-situ radionuclide transport and preferential groundwater flows at INEEL (Idaho): decay-series disequilibrium studies. Geochim Cosmochim Acta 64;5:867–881
• 15. Macioszczyk A, Dobrzyński D (2002) Hydrogeochemistry of the groundwaters active exchange zone. Wydawnictwo Naukowe PWN, Warszawa (in Polish)
• 16. Martin Sanchez A, Rubio Montero MP, Gomez Escobar V, Jurado Vargas M (1999) Radioactivity in bottled mineral waters. Appl Radiat Isot 50:1049–1055
• 17. Möbius S, Salonen L (2002) Pilot intercomparison and Workshop for Radon and Radium in Natural Water. In: Möbius S, Noakes J, Schönchofer F (eds) LSC 2001 Advances in liquid scintillation spectrometry. Radiocarbon, Tucson, Arizona, USA, pp 327–324
• 18. National Research Council (1999) Risk assessment of radon in drinking water. National Academy Press, Washington, DC
• 19. Osmond JK, Cowart JB, Ivanovitch M (2001) Uranium isotopic disequilibrium in ground water as an indicator of anomalies. Appl Radiat Isot 34;1:283–308
• 20. Pietrzak-Flis Z, Suplińska MM, Rosiak L (1997) The dietary intake of 238U, 234U, 232Th and 226Ra from food and drinking water by inhabitants of Wałbrzych region. J Radioanal Nucl Chem 222;1/2:189–193
• 21. Polish Norm (1989) Radium isotopes determination in water with LSC method. PN-89/ZN-70072. Wydawnictwa Normalizacyjne „Alfa”, Warsaw (in Polish)
• 22. Przylibski TA (2004) Concentration of 226Ra in rock of southern part of Lower Silesia (SW Poland). J Environ Radioactiv 75:171–191
• 23. Przylibski TA (2005) Radon. Specific component of medicinal waters in the Sudety Mountains. Oficyna Wydawnicza Politechniki Wrocławskiej, Wrocław (in Polish) Natural radioactivity of groundwater from the Przerzeczyn-Zdrój Spa 175
• 24. Przylibski TA, Dorda J, Kozłowska B (2002) The occurence of 226Ra and 228Ra in groundwaters of the Polish Sudety Mountains. Nukleonika 47;2:59–64 25. Przylibski TA, Mamont-Cieśla K, Kusyk M, Dorda J, Kozłowska B (2004) Radon concentrations in groundwaters of the Polish part of the Sudety Mountains (SW Poland). J Environ Radioactiv 75;2:193–209
• 26. Sill CW (1987) Precipitation of actinides as fluorides or hydroxides for high resolution alpha spectrometry. Nucl Chem Waste Management 7:201–215
• 27. Skwarzec B, Strumińska DI, Boryło A (2003) Radionuclides of 210Po, 234U and 238U in drinking bottled mineral water in Poland. J Radioanal Nucl Chem 256;2:361–364
• 28. Suksi J (2001) Natural uranium as a tracer in radionuclide geosphere transport studies. Academic dissertation. University of Helsinki
• 29. Suomela J (1993) Method for determination of radon-222 in water by liquid scintillation counting. SSI rapport 93-13, ISO Norm: ISO/TC147/SC3/WG6 Work. Swedish Radiation Protection Institute, Stockholm
• 30. Suomela J (1993) Method for determination of U-isotopes in water. Swedish Radiation Protection Institute, Stockholm
• 31. Vesterbacka P, Makelainen I, Arvela H (2005) Natural radioactivity in drinking water in private wells in Finland. Radiat Prot Dosim 113:223–232
• 32. Walencik A, Kozłowska B, Dorda J, Zipper W (2009) Natural radioactivity in underground water from the Outer Carpathians in Poland with the use of nuclear spectrometry techniques. Appl Radiat Isot, doi:10.1016/j. apradiso.2009.09.056
• 33. Walencik A, Kozłowska B, Wojtecki Ł (2006) Preliminary study of natural radioactivity in underground waters in the Silesia Voivodeship. Polish J Environ Studies 15;4A:210–213
• 34. Wallac (1995) Instrument manual 1414 WinspectralTM. Wallac, Turku, Finland
• 35. WHO (2008) Guidelines for drinking-water quality,radiological aspects. Chapter 9
• 36.Wood WW, Kraemer TF, Shapiro A (2004) Radon (222Rn)in ground water of fractured rocks: a diffusion/ion exchange model. Ground Water 42;4:552–567