Sedimentation rates and dating of bottom sediments in the Southern Baltic Sea region

• Autorzy: Suplińska M. M. , Pietrzak-Flis Z.
• Konferencja: International Conference on Recent Developments and Applications of Nuclear Technologies (15-17.09 2008 ; Białowieża, Poland)
• Języki publikacji: EN

Abstrakty

EN

Sedimentation rates and dating of bottom sediments were estimated in two sampling stations of the Gulf of Gdańsk and in four stations in the open sea area. Estimations were based on vertical distributions of 210Pb, 137Cs and 239,240Pu activity concentrations in sediment core samples taken in 1998–2007. Two dating models based on changes of activity concentrations of 210Pbunsup were used: 1) CF:CS (Constant Flux Constant Sedimentation rate-model) and 2) CRS (Constant Rate of Supply-model). 137Cs and 239,240Pu were applied as time markers. 137Cs originates mostly from the Chernobyl accident in 1986, whereas 239,240Pu comes from the global fallout in 1963. The validation of the 210Pb methods was performed by activity peak of 137Cs and 239,240Pu. Sediment accumulation rate (g·cm–2·y–1) was constant along sediment core. Annually accumulated layer, (mm·y–1) decreased with sediment depth in all the locations. In the Gulf of Gdańsk sedimentation rate in the upper layer was about 3.6 mm·y–1, and it decreased in the deeper layers to about 1.1 mm·y–1. Sedimentation rates in the open sea area were lower than in the gulf region and the lowest was observed in the Bornholm Deep, being about 0.95 mm·y–1 in the upper layer and 0.35 mm·y–1 in the deeper layer. The growth of a 5 cm thick layer took 27–37 years in the Gulf of Gdańsk, and 61–105 years in the open sea area. It is suggested that the mean values obtained from the models would give a most reliable estimation of the sedimentation rates.

Słowa kluczowe

EN

sedimentation rate; 210Pb; 137Cs; 239,240Pu; Southern Baltic; bottom sediment

• Wydawca: Institute of Nuclear Chemistry and Technology
• Czasopismo: Nukleonika
• Rocznik: 2008
• Tom: Vol. 53, suppl. 2
• Strony: 105--111
• Opis fizyczny: Bibliogr. 14 poz., rys.

Twórcy

autor

Suplińska M. M.

• Department of Radiation Hygiene, Central Laboratory for Radiological Protection, 7 Konwaliowa Str., 03-195 Warsaw, Poland, Tel.: +48 22 8110011 ext. 227, Fax: +48 22 811

autor

Pietrzak-Flis Z.

• Department of Radiation Hygiene, Central Laboratory for Radiological Protection, 7 Konwaliowa Str., 03-195 Warsaw, Poland, Tel.: +48 22 8110011 ext. 227, Fax: +48 22 811

Bibliografia

• 1. Alvarez-Iglesias P, Quintana B, Rubio B, Perez-Arlucea M (2007) Sedimentation rates and trace metal input history in intertidal sediments from San Simon Bay (Ria de Vigo, NW Spain) derived from 210Pb and 137Cs chronology. J Environ Radioact 98:229–250
• 2. Appleby PG (1997) Dating of sediments by 210Pb: problems and solutions. In: Proc of a Seminar Dating of Sediments and Determination of Sedimentation Rate, Helsinki, Finland. STUK A145:7–24
• 3. Hille S, Leipe T, Seifert T (2006) Spatial variability of recent sedimentation rates in the Eastern Gotland Basin (Baltic Sea). Oceanologia 48:297–317
• 4. Ilus E, Mattila J, Klemola S, Ikaheimonen K (1997) Evaluation of sedimentation rate at two sampling stations in the Gulf of Finland based on Pb-210, Cs-137 and Pu-239,240 profiles in sediment. In: Proc of a Seminar Dating of Sediments and Determination of Sedimentation Rate, Helsinki, Finland. STUK A145:136–147
• 5. Ilus E, Niemisto L, Bojanowski R (1995) Radionuclides in sediment and suspended particulate matter. In: HELCOM 1995. Radioactivity in the Baltic Sea 1992–1998. Balt Sea Environ Proc 61:69–87
• 6. Jaworowski Z (1969) Radioactive lead in the environment and in the human body. At Energ Rev 7:3–45
• 7. Jaworowski Z, Bilkiewicz J, Kownacka W, Włodek S (1972) Artificial sources of natural radionuclides in environment. In: Natural radiation environment II 2:809–818
• 8. Krishnaswami S, Lal D (1978) Radionuclide limnochronology. In: Lerman A (ed) Lakes: chemistry, geology, physics. Springer, New Jork, pp 157–177
• 9. Mattila J, Kankaanpaa H, Ilus E (2006) Estimation of recent sediment accumulation rates in the Baltic Sea using artificial radionuclides 137Cs and 239,240Pu as time markers. Boreal Env Res 11:95–107
• 10. Niemisto L, Voipio A (1981) Notes on the sediment studies in the Finnish pollution research in the Baltic Sea. Rapp P-v Reun Cons Inst Explor Mer 181:87–92
• 11. Pempkowiak J, Widrowski H (1988) Pollution of upper layer of bottom sediments of Southern Baltic Sea with heavy metals. Arch of Environ Protect 1/2:55–66
• 12. Robbins JA (1978) Geochemical and geophysical applications of radioactive lead. In: Nriagu JO (ed) Biogeochemistry of lead in the environment. Elsevier, Amsterdam, pp 285–393
• 13. Rushing D, Garcia WJ, Clark DA (1964) The analysis of effluents and environmental samples from uranium mills and to biological samples for radium, polonium and uranium. In: Radiological health and safety in mining and milling of nuclear materials. Vol. II. IAEA, Vienna, pp 187–230
• 14. Taipale TK, Tuomainen K (1985) Radiochemical determination of plutonium and americium from sea-water, sediment and biota samples., Helsinki, Finland. STUK- -B-Valo 26, pp 1–29