Abstract
The background levels of uranium content in the soil cover of different regions of Belarus are determined. Experimental data on the uranium content in the samples of (0–20)-cm layers of different varieties of sod-podzolic, sod, and peat-bog soils are presented. From analysis of the experimental data obtained, it follows that the uranium content increases in the series of soils “sandy-sandy loamy-loamy-clayey” as the content of fraction with the size of soil particles less than 10 μm increases. Natural background concentrations of uranium in the environment differ between various regions of the country. In accordance with the structure of the soil cover, there is an increased content of uranium in the northern region of Belarus with a higher proportion of loamy and clayey soils than in the southern region where sandy and sandy loam soils occupy a significant part of the territory. Experimental data on the uranium content in the soil interstitial (pore) water extracted from water-saturated soil samples by the method of high-speed centrifugation are presented. A close direct relationship was found between the portions of uranium and organic components in the soil interstitial solutions of their total content in mineral soil samples. The coefficients of uranium distribution between a solid phase and interstitial solution of soils of different types were estimated. For individual varieties of soils, it has been established how the uranium reserve in a mobile (conditionally biologically available) form changes with a change in the temperature and humidity of the soil.
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Aleksahin RM, Arkhipov NP, Barkhudarov RМ (1990) Heavy natural radionuclides in the biosphere: Migration and biological effect on populations and biogeocenoses. Nauka, Мoscow, pp 368. (In Russian)
Anisova ZM, Yakushev BI (2008) Natural isotopes of uranium in soils and plants of pine forests of the Minsk Upland, Minsk. Belorusskaya Nauka, pp 162
Bocharov MV (1995) Global radioactive contamination of the natural environment of the Northern Hemisphere and the contribution to it of Soviet nuclear tests. Atom Energ 78:50–53. (In Russian)
Borovoy AA, Galkin AP, Krinitsyn AP, Markushev VM, Pazukhin EM, Cherubov AN, Checherov KP (1990) Newly formed products of fuel interaction with structural materials of the 4th block of the Chernobyl NPP. Radiokhimiya 32:103–113. (In Russian)
Chernykh NA, Prasanna J (2000) Transformation of lead and cadmium compounds in different types of soils. Vestnik RUDN. Ser. Ekologiya i Bezopasnost’ Zhiznedeyatel’nosti 4:82–88. (In Russian)
Diemann C (2012) Uran in Boden und Wasser. In: Diemann C, Utermann J (eds) Dessau-Roßlau. Umweltbundesamt, pp 24
Fedorov AA (2002) Evaluation of the content in the soil of elements of mineral nutrition available to plants. Agrokhimiya 3:15–22. (In Russian)
Frid AS (1996) Migratory concept of the availability of soil substances to plant roots. Agrokhimiya 3:29–37. (In Russian)
GN 2.6.1.8—27-2000 Radiation safety standards (NRB-2000) (2002) Мinsk: Ministry of Health of the Republic of Belarus (In Russian).
Gorbilyova FI (2007) Soil of Belarus. IVTS Minfinab, Minsk, pp 184. (In Russian)
Greenwood NN, Earnshaw A (1997) Chemistry of the elements. Butterworth, Oxford, pp 1600
Grodzinsky DM (1989) Radiobiology of plants. Naukova Dumka, Kyiv, pp 282. (In Russian)
Gurskiy GV, Loseva YI (1989) Natural radioactivity of the cover sediments and soils of Belarus. Geochemical studies of the landscapes of Belarus and the Baltic States. Nauka i Tekhnika, Minsk, pp 53–58. (In Russian)
Hanson US (1985) Transuranic elements in the environment. Energoatomizdat, Moscow, pp 345. (In Russian)
Hirose K, Takatani S, Aogama M (1994) Deposition of 90Sr and plutonium isotopes derived from Chernobyl accident in Japan. J Radioanal Nucl Chem 182:349–358
IAEA (1988) Final report on the causes of the consequences of the Chernobyl accident: Report of the International Advisory Group on Nuclear Safety. IAEA: Safety Ser. No 75. Vienna
IAEA (1989) Measurement of radionuclides in food and the environment: а guidebook, Vienna, 1989. Technical Reports Series, No 295. Vienna
IAEA (2004) Radiation, People and the Environment. IAEA-PI--A75. Vienna, pp 86
Ionizing Radiation: Sources and Biological Effects (1982) Report of the United Nations Scientific Committee on the effects of atomic radiation. New York, pp 890
Iskra AA, Bakhurov VG (1981) Natural radionuclides in the biosphere. Energoizdat, Moscow, pp 123. (In Russian)
Ivanovich M, Harmon RS (1982) Uranium series disequilibrium: applications to environmental problems. Clarendon Press, Oxford, pp 40
Kabata-Pendias A, Pendias H (1989) Microelements in soils and plants. Mir, Moscow, pp 439. (In Russian)
Kashparov VA, Priester BS, Zvarych SI, Protsak VP, Khomutinin YV, Polyakov VD, Gudkov AN, Kurepin AD, Pazukhin EM (1995) Simulation of “hot” particles during the Chernobyl accident: problems of Chernobyl exclusion zone, vol 2. Naukova Dumka, Kiev, pp 120–127. (In Russian)
Kashparov VA, Lundin SM, Zvarych SI, Yoshchenko VI, Levchuk SE, Khomutinin YV, Maloshtan IM, Protsak VP (2003) Territory contamination with the radionuclides representing the fuel component of Chernobyl fallout. Sci Total Environ 317:105–119
Katz J, Seaborg G, Morse L (1991) Chemistry of actinides, vol 1. Mir, Moscow, pp 525
Konoplya YF, Kudrjashov VP, Mironov VP (2007) Radiation and Chernobyl: trans uranium elements on the territory of Belarus. RNIUP Institut Radiologii, Gomel, pp 128. (In Russian)
Kovacheva P, Mitsiev S, Djingova R (2014) Physicochemical fractionation of americium, thorium, and uranium in Chernozem soil after sharp temperature change and soil drought. Chem Paper 68:336–341
Kudrjashov VP, Mironov VP, Konoplya EF (2000) Formation of contamination in main components of ecosystems with transuranium elements on the territory of Belarus as a result of nuclear weapons tests and Chernobyl NPP accident. 5th International Conference on Nuclear and Radiochemistry, Pontresina, Switzerland, September 3–8, pp 545
Kudrjashov VP, Mironov VP, Ananich PI, Zhuravkov VV (2001) Plutonium, americium and other actinides in Belarus: sources, levels, risks. IAEA, INIS Publication, pp 103–132. (In Russian)
Kudrjashov VP, Mironov VP, Matusevich JL, Boulyga SF (2002) Determination of irradiated reactor uranium in soil samples in Belarus as irradiated uranium tracer. J Environ Monit 4:12–14
Kulakovsky TN, Rogovoy PP, Smeyan NI (1974) Soil of the Byelorussian SSR. Urozhay, Minsk, pp 328. (In Russian)
Kuznetsov VA (1997) Radiogeochemistry of river valleys. Institute of Geological Sciences of the National Academy of Sciences of Belarus, Minsk, pp 332. (In Russian)
Loginov VF (2013) Climate change and their impact on various economic sectors. Analytical report of the National Academy of Sciences of Belarus. Department of Chemistry of Earth Sciences. GNU, Institut Prirodopol’Zovaniya, Minsk, pp 46. (In Russian)
Loginov VF, Volchek AA, Shpoka IN (2010) Dangerous hydrometeorological phenomena on the territory of Belarus. Belorusskaya Nauka, Minsk, pp 170. (In Russian)
Loshchilov NA, Kashparov VA, Yudin EB, Protsak VP (1992) Fractionation of radionuclides in Chernobyl fuel “hot” particles. Radiokhimiya 5:125–134. (In Russian)
Lukashov KI (2002) Geochemical provinces of the cover sediments of the USSR. IGN NAN Belarus, Minsk, pp 256 (In Russian)
Luo W, Gu B (2009) Dissolution and mobilization of uranium in reduced sediment by natural humic substances under anaerobic condition. Environ Sci Technol 43:152–156
Mansurov VV, Meleshin AA (2000) The weather effect on the harvest. Kartofel’ i Ovoshchi. 5:21–24. (In Russian)
Methods for determination of uranium in soils and aerosol filters: MN 1497–2001. Minsk, BelGIM (In Russian)
Milićević T, Relić S, Škrivanj S, Tešić Z, Popović A (2017) Assessment of major and trace element bioavailability in vineyard soil applying different single extraction procedures and pseudo-total digestion. Chemosphere 171:284–293
Morton LS, Evans CV, Estes GO (2002) Natural uranium and thorium distributions in podzolized soils and native blueberry. J Environ Qual 31:155–162
Mortvedt JJ (1994) Plant and soil relationships of uranium and thorium decay series radionuclides—a review. J Environ Qual 31:155–162
Nikolayeva SA, Yeremina AM (2001) Transformation of iron compounds in chernozems under conditions of high soil moisture. Pochvovedeniye 8:963–969. (In Russian)
Orlov DS (1990) Humus acids of soils and general theory of humification. Izd-vo MGU, Moscow, pp 325. (In Russian)
Ovcharenko MM (1996) Mobility of heavy metals in soil and their accessibility to plants. Agrarnaya Nauka 3:39–40. (In Russian)
Ovsiannikova SV, Sokolik GA, Eismont EA, Kilchitskaya SL, Kimlenko IM, Zhukovich NV, Rubinchik SY (2000) Soil pore solutions in the processes of migration of 137Сs, 90Sr, 239,240Pu and 241Am. Geokhimiya 2:222–234. (In Russian)
Perkins RU, Tomas KU (1985) Global radioactive fallout. In: Hanson US (ed) Transuranic elements in the environment. Energoatomizdat, Moscow, pp 48–65. (In Russian)
Poludin AL, Deryagin VV, Levina SG (2013) Content and distribution of natural uranium in the soil component of the lakeshores of Itcul and Sinara (Southern Ural). Radioactivity and radioactive elements in the human environment. Materials of the IV International Conference, Tomsk, June 4–8, pp 411–414 (In Russian)
Ponomareva VV, Plotnikova TA (1980) Humus and soil formation. Nauka, Leningrad, pp 222. (In Russian)
Rachkova NG, Shuktumova II, Taskaev AI (2010) Condition in soils of natural radionuclides of uranium, radium and thorium (review). Pochvovedeniye 6:698–705. (In Russian)
Reponen A, Jantunen M (1993) Plutonium fallout in Southern Finland after Chernobyl accident. J Environ Rad 23:119–130
Shagalova ED (1986) Uranium content in soils of Belarus. Pochvovedenie 2:140–145. (In Russian)
Sheppard IC, Campbell MJ (1980) Retention of radionuclides by mobile humic components and soil particles. Environ Sci Technol 14:1349–1353
Sheppard SC, Evenden WG (1988) Critical compilation and review of plant/soil concentration ratios for uranium, thorium and lead. J Environ Radioact 8:255–285
Sokolik G, Ovsiannikova S, Kimlenka I (2002) Soil organic matter and migration properties of 239,240Pu and 241Am. Radioprotection 37:283–288
Sokolik GA, Ovsyannikova SV, Voynikova EV, Rakhmanko EM, Popenya MV (2010) Migratory-active forms of radium and uranium in the soils of the Republic of Belarus. Litosfera, Minsk 32:128–134. (In Russian)
Sokolik GA, Ovsiannikova SV, Voinikava KV, Popenia MV, Ivanova TG (2012) Soil as a geochemical barrier of migration of uranium and radium in terrestrial ecosystems in Belarus. Vestsi Natsyyanal’nay akademiy navuk Belarusi. Serp. Khim Navuk 2:101–109 (In Russian)
Sparovek R, Fleckenstein J, Schnug E (2002) Issues of uranium and radioactivity in natural mineral waters. Lanbauforschung Volkenrode 51:149–157.
The Second Congress of the Soil Science Society. Abstracts of the reports St. Petersburg, June 27–30 (1996) In: Vol. 2/ Ros. acad. Sciences, Soil Science Society. St. Petersburg: Publishing house of St. Petersburg State University. pp 453.
Titayeva NA (2005) Geochemistry of natural radioactive decay series. GEOS, Moscow, pp 226. (In Russian)
Titayeva NA, Taskayev AI (1983) Migration of heavy natural radionuclides in soils of the humid zone. Nauka, Leningrad, pp 232. (In Russian)
Vandenhove H, Olyslaegers G, Sanzarova N, Shubina O, Shang Z, Velasco H (2009) Proposal for new best estimates of the soil-to-plant transfer factor of U, Th, Ra, Pb and Po. J Environ Radioact 100:721–732
Vandenhove H, Vanhoudt N, Dunguéne L, Antunes K (2014) Comparison of two procedures for uranium fractionation in contaminated soils. J Environ Radioact 137:1–9
Vasilenko IY (2001) Radiation: sources, rationing of radiation. Priroda 4:11–16. (In Russian)
Vinogradov AV (1950) Radioactive elements in soils. In: Geochemistry of rare and dispersed chemical elements in soils. Publishing House of the USSR AS, Moscow, pp 229–237. (In Russian)
Vodyanitskiy YN (2011) Chemical aspects of uranium behavior in soils (literature review). Khimiya Pochv 8:940–952. (In Russian)
Vodyanitskiy YN, Bol’shakov VA (1998) Identification of the technogenicity of chemical elements in soils. Anthropogenic degradation of the soil covers and measures to prevent it. Tez. doc. All-Russian Conference. Moscow: June 16–18, 1998. 2:116–119
Vorobyova LA (2006) Theory and practice of chemical analysis of soils. GEOS, Moscow, pp 400. (In Russian)
Zhang YJ, Bryan ND, Livens FR, Jones MN (1997) Selectivity in the complexation of actinides by humic substances. Environ Pollut 96:361–367
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Sokolik, G.A., Ovsiannikova, S.V., Papenia, M.V. (2020). Uranium and Its Distribution in Typical Belarusian Soils. In: Gupta, D., Walther, C. (eds) Uranium in Plants and the Environment. Radionuclides and Heavy Metals in the Environment. Springer, Cham. https://doi.org/10.1007/978-3-030-14961-1_2
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