Atmospheric 210Pb activity concentrations in Stepnogorsk city, North Kazakhstan uranium province area.

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Bibliographic Details
Title: Atmospheric 210Pb activity concentrations in Stepnogorsk city, North Kazakhstan uranium province area.
Authors: Bagramova, A.1 (AUTHOR) assel.yaf.enu@gmail.com, Sakaguchi, A.2,3 (AUTHOR), Sakata, K.4 (AUTHOR), Takahashi, J.3 (AUTHOR), Kajimoto, T.5 (AUTHOR), Endo, S.5 (AUTHOR), Toekin, M.1 (AUTHOR), Zhumalina, A.1 (AUTHOR), Ibraeva, D.6 (AUTHOR), Stepanenko, V.7 (AUTHOR), Hoshi, M.8 (AUTHOR), Zhumadilov, K.1 (AUTHOR)
Source: Atmospheric Environment. May2026, Vol. 372, pN.PAG-N.PAG. 1p.
Subject Terms: *Radioactive aerosols, *Emissions (Air pollution), *Aerosols, Radiation dosimetry, Statistical correlation
Geographic Terms: Kazakhstan
Abstract: Lead-210 (210Pb), a decay product of 222Rn in the 238U decay series, is associated with aerosol particles in the atmosphere and is therefore widely used as a tracer of atmospheric processes and aerosol dynamics. This study focused on airborne 210Pb levels to evaluate the radiological influence of nearby uranium processing and waste storage facilities in North Kazakhstan uranium province. Collection of aerosol particles was conducted in Stepnogorsk city during 2020–2022 with the exception of the winter months. Activity of 210Pb and major ion concentrations in seven size-fractionated aerosol particles were determined by high-purity germanium (HPGe) detector and ion chromatography, respectively. The observed 210Pb activity concentrations in aerosol samples varied between 0.46 ± 0.01 mBq/m3 and 2.60 ± 0.03 mBq/m3, with an arithmetic mean of 0.86 mBq/m3. The radiation dosimetry of daily inhalation of 210Pb through exposure to outdoor air was estimated to be from 0.9 to 2.5 μSv/y. Although this level is low compared to global mean exposures, the long term presence of inhaled 210Pb in the body constitutes a persistent radiation risk. The negative correlation (r = −0.60) was observed between total activity and average temperature indicating an increase in concentration with decreasing temperature. The dominant fraction of atmospheric 210Pb predominantly was found in fine aerosol particles smaller than 2.1 μm, and accounted for 95.3 ± 12.0% of the total. The linear correlation of 210Pb with sulfate, nitrate, and chloride suggests that human activities, including coal combustion, are possible contributors to atmospheric 210Pb in this study area. This highlights the importance of considering local anthropogenic emissions when interpreting the atmospheric 210Pb levels. • Atmospheric size-fractionated 210Pb measured in North Kazakhstan uranium region. • Higher 210Pb levels were observed under lower ambient temperatures. • Fine aerosol particles were the dominant carriers of atmospheric 210Pb. • 210Pb levels correlate with S O 4 2 − , N O 3 − , a n d C l − , suggesting human activity sources. [ABSTRACT FROM AUTHOR]
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Abstract:Lead-210 (210Pb), a decay product of 222Rn in the 238U decay series, is associated with aerosol particles in the atmosphere and is therefore widely used as a tracer of atmospheric processes and aerosol dynamics. This study focused on airborne 210Pb levels to evaluate the radiological influence of nearby uranium processing and waste storage facilities in North Kazakhstan uranium province. Collection of aerosol particles was conducted in Stepnogorsk city during 2020–2022 with the exception of the winter months. Activity of 210Pb and major ion concentrations in seven size-fractionated aerosol particles were determined by high-purity germanium (HPGe) detector and ion chromatography, respectively. The observed 210Pb activity concentrations in aerosol samples varied between 0.46 ± 0.01 mBq/m3 and 2.60 ± 0.03 mBq/m3, with an arithmetic mean of 0.86 mBq/m3. The radiation dosimetry of daily inhalation of 210Pb through exposure to outdoor air was estimated to be from 0.9 to 2.5 μSv/y. Although this level is low compared to global mean exposures, the long term presence of inhaled 210Pb in the body constitutes a persistent radiation risk. The negative correlation (r = −0.60) was observed between total activity and average temperature indicating an increase in concentration with decreasing temperature. The dominant fraction of atmospheric 210Pb predominantly was found in fine aerosol particles smaller than 2.1 μm, and accounted for 95.3 ± 12.0% of the total. The linear correlation of 210Pb with sulfate, nitrate, and chloride suggests that human activities, including coal combustion, are possible contributors to atmospheric 210Pb in this study area. This highlights the importance of considering local anthropogenic emissions when interpreting the atmospheric 210Pb levels. • Atmospheric size-fractionated 210Pb measured in North Kazakhstan uranium region. • Higher 210Pb levels were observed under lower ambient temperatures. • Fine aerosol particles were the dominant carriers of atmospheric 210Pb. • 210Pb levels correlate with S O 4 2 − , N O 3 − , a n d C l − , suggesting human activity sources. [ABSTRACT FROM AUTHOR]
ISSN:13522310
DOI:10.1016/j.atmosenv.2026.121836