Free Access
Issue
Radioprotection
Volume 52, Number 1, January-March 2017
Page(s) 37 - 43
DOI https://doi.org/10.1051/radiopro/2017001
Published online 05 April 2017

© EDP Sciences 2017

1 Introduction

Taking into account the half-lives of the main radionuclides of the Chernobyl origin, i.e. 137Cs (Т1/2 = 30 years) and 90Sr (Т1/2 = 28.5 years), the challenging issues start to emerge concerning resuming the use of former agricultural lands characterized by the finest natural soil fertility though excluded from farm production in the aftermath of the Chernobyl accident. In addressing such issues special concerns relate to the alpha-emitting transuranium elements (TUE) 241Am and 238,239+240Pu which may be present in these lands alongside with the other dispersed radioactive contaminants. Thus, additional efforts have to be provided in order to estimate yet more precisely the committed effective doses received by agricultural workers via inhalation intake of radioactive airborne dust in the process of intensive grain harvesting operations. Affecting soil surface, such operations result in radionuclides, otherwise fixed in soil, to rise up in the air together with dust particulates and therefore contribute in developing internal exposure of harvest workers through inhalation pathway.

This research paper presents the results of comparative analysis of external exposure and committed effective doses of internal exposure received by agricultural workers due to inhalation intake of 241Am, 238,239+240Pu, 137Cs and 90Sr in the process of harvesting grain crops from the backyard located in a populated area and from the experimental plot of land located in the resettled area of the Chernobyl evacuation zone in Gomel region, Belarus. Two categories of agricultural workers involved in grain harvesting operations were subject to the analysis: (1) operators of combine harvesters and (2) agrarians or members of the general public employed in agricultural works directly on the field.

2 Materials and methods

The first experimental field, with a total area of 3.6 ha, was the one located close to the former inhabited area named Rafalov (Bragin district, Gomel region, Belarus) 42 km from the Chernobyl NPP within the boundaries of the State Polessye Radiation-Ecological Reserve (PRER) (Fig. 1), characterized by sod-podzolic sandy loam soils and high levels of radioactive contamination densities: 137Cs 993 kBq m−2 (26.8 Ci km−2), 90Sr 91.2 kBq m−2 (2.5 Ci km−2), 241Am 5.0 kBq m−2 (0.14 Ci km−2), 238Pu 1.0 kBq m−2 (0.03 Ci km−2), 239+240Pu 2.6 kBq m−2 (0.07 Ci km−2). Since this field is located in the resettlement zone, implementation of economic activities in this area is subject to special national regulations. According to the legislation of the Republic of Belarus, the presence and implementation of any economic activities by the members of general public in the resettlement zone is prohibited. Only personnel members or individuals designated as personnel are eligible to implement any such activities in the resettlement zone.

The second experimental field was selected to be in the PRER neighborhood, attached to Kovali and Burki villages of the same district, and located about 50 km from the Chernobyl NPP (Fig. 1). This private backyard, with a total area of 2.8 ha, is continuously used by the local residents for growing grain crops. Characterized by the same type of soil as that of the first experimental field, its radioactive contamination densities were as follows: 137Cs 243 kBq m−2 (6.6 Ci km−2), 90Sr 29 kBq m−2 (0.8 Ci km−2), 241Am 2.0 kBq m−2 (0.06 Ci km−2), 238Pu 0.4 kBq m−2 (0.01Ci km−2), 239+240Pu 1.0 kBq m−2 (0.03 Ci km−2).

Grain crops (i.e. wheat, triticale, and barley) from Kovali/Burki experimental field and winter rape from Rafalov field were harvested with a “Polessye 10K” combine harvester with an operator's cabin equipped with an air conditioning system. It should be mentioned however, that, while harvesting in Kovali/Burki, the operator of a “Polessye 10K” combine harvester often preferred to leave the door open, rather than use air conditioning in a sealed cabin. For gathering winter triticale from the field of Rafalov a “Lida 1300” combine harvester was used, with no air conditioning system inside the cabin.

The experiment took place within a harvesting period starting from the late July till the early August. During this whole period, the weather in both experimental fields was dry and sunny, with no precipitation. The air temperature was in the range of 28–30 °C, and relative humidity did not exceed 30%.

Assessment of activity concentrations of 137Cs, 90Sr and TUE isotopes (241Am and 238,239+240Pu) in the air was done based on air sampling. Samples were collected both in the air of grain harvesting area (workplace), i.e.on the field”, and inside the operator's cabin of a combine harvester, i.e.in the cab”, by means of air pumping through sampling filters of portable aspirator pumps. Air sampling “in the cab” was done with the use of a Portable Sampling Unit model 04А. Sampling “on the field” was done by four H-810 model Filter/Fan Units placed along the windward side of the field and used simultaneously. For filtering materials, Petryanov's filtering cloth was used, an ultra-thin synthetic fabrics with an average fiber diameter of 1.5 microns. In order to obtain a detectable (i.e. >MDA, Minimum Detectable Activity) value of radionuclide activity, the filters labeling “on the field” workplace were combined into a single sample. Mass concentrations of dust were measured in a gravimetric procedure by having each of the four filters weighed before and after sampling.

The external dose rates of gamma-radiation were determined with the use of a MKS-AT 1125 dosimeter/radiometer. Concentrations of 137Cs, 241Am in soil samples, and 137Cs air concentrations in air samples were measured by a Canberra Gamma Analyst spectrometer of extended energy range, equipped with a GX3020 detector with a beryllium window. The method of radiochemical purification (IAEA, 1999) was used to determine activity concentrations of 90Sr and TUE in air samples. The same procedure was used to measure specific activities of 238Pu, 239+240Pu and 90Sr in soil samples. The radiochemical procedure included (a) ashing of air filters, (b) acid digestion, (c) concentration and purification from alkali and alkaline earth metals, (d) Pu stabilization in its quadrivalent state, (e) Am purification from Pu (IV) with anion exchange resin, (f) Am purification from Sr (II) and Fe (II) with TRU-Spec extraction chromatography resin, (g) Am purification from rare earth elements (lanthanides) with TEVA-Spec extraction chromatography resin, and (h) electrodeposition of Pu and Am on a polished, stainless steel plate with an active spot of 25 mm in diameter.

Detection of TUE was performed using a Canberra Alpha Analyst spectrometer equipped with a silicon semiconductor PIPS detector, with energy resolution of <15 keV, detector efficiency of no less than 18% (for detector-source spacing of less than 5 mm), background <1 count h−1, counting time per sample 1–4 days. The count rate of beta particles from 90Sr source was measured using an in situ Canberra model 5SE low background gas proportional counter. The chemical yield varied in the range of 80–95%. The minimum detectable activities (MDA) in air samples varied depending on sample volumes amounting to 0.001 Bq per sample for 241Am, 238,239+240Pu, 0.1 Bq per sample for 90Sr, and 0.9 Bq per sample for 137Cs. Considering that the area of experimental fields was only 2–4 ha, each dust sampling was done in a matter of several hours, which, in its turn, was the main restricting factor for the volumes of air samples which varied between 3.7 m3 (“in the cab” sampling) and 230 m3 (“on the field” sampling).

Assessment of committed effective doses received by harvest workers due to inhalation intake of radionuclides during dusty harvesting operations was carried out in full correspondence with the national and international radiation safety standards as recommended by the International Atomic Energy Agency (IAEA, 2000; NRB, 2000; IAEA, 2011; CRIA, 2012; RSR, 2012).

thumbnail Fig. 1

Location of both experimental fields with respect to the PRER borders (as shown on the satellite image).

3 Results and discussion

The results of 137Cs, 90Sr and TUE concentrations measured in air samples collected during grain harvesting operations from the two experimental fields are shown in Table 1. The air concentrations of each analyzed radionuclide (241Am, 238Pu, 239+240Pu, 137Cs, 90Sr) were compared against the average annual Permissible Activity Concentration levels for the population (PACpop) specified in the national NRB-2000 Basic Radiation Safety Standards (NRB, 2000). However, the current regulations in force (CRIA, 2012; RSR, 2012) do not establish the unified PACpop values and instead recommend to calculate these values with reference to the basic dose limit established for “personnel” (20 mSv y−1) and “general public” (1 mSv y−1), and set them as independent sanitary standards for different types of work under the authority of the Ministry of Health. According to the major requirement under these regulations, in cases when an individual is simultaneously exposed both to external and internal sources of radiation, the total effective dose must not exceed the basic dose limits.

According to the results, the highest dust concentration (36.5 mg m−3) was found in the operator's cabin of a Polessye 10K combine harvester kept in the open state during the whole harvesting period in Kovali/Burki backyard. By contrast to this, during winter rape harvesting from the field in the resettled area near the former village Rafalov, the air in an isolated and well-conditioned cabin of the same combine harvester was found to be characterized by the lowest dust concentration (0.2 mg m3). This important condition was the reason why the concentration values of all analyzed radionuclides (i.e. 241Am, 238Pu, 239+240Pu, 137Cs) in the air were less than the MDA.

Thus, when harvesting in the open Polessye 10K combine cabin, the dust burden on the operator's respiratory system was more than 100 times higher than the dust burden to which an operator in a closed, conditioned cabin was exposed. Such significant difference in dust exposure therefore resulted in noticeable difference between the values of activity concentrations of the target radionuclides (Tab. 1).

Despite the fact that the levels of contamination densities of 137Cs, 90Sr, 241Am and 238,239+240Pu radionuclides in soil of the field in the resettled area were up to 3 times higher than those found in the private backyard of the residential area, harvesting grains in the Kovali/Burki field happened to be attended by significantly greater amounts of airborne dust when compared with harvesting winter triticale and winter rape from the field of Rafalov, making it possible to obtain detectable values of activity concentrations of the analyzed radionuclides. The same phenomenon was described by Konoplya et al. (2009). According to their observations held in Bragin areas during 1990–2006, the values of TUE concentrations in the air during harvesting operations in spring and autumn, despite their lesser contamination densities in soil, were equal and in some cases above the similar values found in the resettlement area.

Comparing the above results with the NRB-2000 reference levels, the activity concentrations of 137Cs, 90Sr, 241Am and 239+240Pu in the most dusty workplace (“in the cab” harvesting on Kovali/Burki field) made up respectively 0.4%, 0.4%, 7.0% and 3.5% of the annual average permissible activity concentrations in the inhaled air established for the population (PACpop). At the same time, based on the results of the first post-accident aerosol sampling of 26 May 1986 carried out in Bragin town (located in ∼50 km area of ChNPP, same as Kovali and Burki villages), the values of 239+240Pu contents in the air were 6.2 pCi m3 (Lebedev et al., 1992), or 230 mBq m−3, which was significantly, by two orders of magnitude, higher than the PACpop.

In the case of the Lida 1300 combine harvester, the series with no fitted conditioner, the operator's cabin required continuous airing through the open window apertures during the whole working period, causing the upraised radioactive particles to freely enter in. On the other hand, the cabin of the Polessye 10K combine harvester is a model equipped with a conditioner. Besides, during winter rape harvesting from the field of Rafalov it was kept closed, therefore providing for the lowest measurement results as far as the activity concentrations in the workplace air are concerned. Yet, the highest levels of activity concentrations of all target radionuclides were found “in the cab” of the Polessye 10K combine harvester due to its permanent open state and increased dust release during grain harvesting from the field of Kovali/Burki.

Thus, the maximum levels of radionuclide activity concentrations in the air of operator workplace can be potentially observed in the cabins lacking appropriate sealing conditions. Hence, maintaining sealing integrity of the operator's cabin should be also deemed an essential requirement of radiation protection of machinery operators involved in agricultural operations on the territories of radioactive contamination.

The values of radionuclide concentration in the air of working areas as shown in Table 1 were then used for estimating committed effective doses of internal exposure received by harvest workers per 1 h via inhalation intake of 241Am, 238,239+240Pu, 137Cs, and 90Sr (Tab. 2).

Internal exposure dose rates in Table 2 were calculated based on the dose coefficients corresponding to all available types of lung absorption (F, M, S), particle sizes of 1 μm and 5 μm) for all estimated radionuclides, both for personnel and for general public (IAEA, 2011).

Both international and national standards require different dose coefficients to be used in relation to workers and members of the public. In the present study, doses were calculated using dose coefficients for members of the public with regard to Kovali/Burki site being a residential area, because harvesting operations engaged individuals from among local population. At the same time, with regard to Rafalov site being a resettlement area, dose coefficients for workers were used, because the works there can only engage individuals who are officially assigned as personnel members. However, the local specifics is such that the same agricultural workers can be engaged in farm operations in a resettlement area as ‘personnel’ and also be the ones who work in the adjacent residential area as mere ‘agricultural workers’. Therefore, this study is purposefully dedicated to assessing radiation doses to agricultural workers as a whole, without focusing much on making distinctions between these two categories.

Additionally, the values of internal exposure due to inhalation of radionuclides were calculated taking into account the breathing rates derived from the national regulatory standards (CRIA, 2012) established for personnel (V = 2400 m3 year−1, t = 1700 h year−1) and the general public (V = 8100 m3 year−1, t = 8800 h year−1).

According to the results, the highest effective dose rate due to inhalation intake of 137Cs, 90Sr and total TUE isotopes (241Am + 238,239+240Pu) was registered in the cabin of the Polessye 10K combine's operator when harvesting grain crops from the private field of Kovali/Burki under conditions of hot and dry weather and increased dust generation.

From the obtained measurement results it can be inferred that during implementation of grain dust operations in either the operator's cabin or directly on the field the prevailing contribution to the total effective doses received by farm workers would be made by external exposures. Even in the increased dust conditions, during “in the cab” harvesting on the field of Kovali/Burki, the committed effective dose of internal exposure due to 137Cs, 90Sr and TUE total inhalation exposure made the range of 4.9 × 10−6 to 3.3 × 10−5 mSv h−1, that is 5–34 times lower than the measured dose of external exposure “on the field” of Kovali/Burki (1.7 × 10−4 mSv h−1). At the same time, the value of internal dose rate “in the cab” was 40 times lower than the value of external dose rate “in the cab”. Retrospectively, the results of internal dose estimates performed in the first days after the Chernobyl accident for the residents of contaminated areas in Gomel region (Kut'kov et al., 1996), also show that inhalation intake of airborne particles of nuclear fuel was not significant and had little impact on the doses of internal and external exposure associated with I, Cs and Sr isotopes.

Moreover, the committed effective doses of internal exposure of the field harvest workers due to inhalation intake of radionuclides were up to one order of magnitude lower when compared to the respective doses received by an operator in the unconditioned cabin.

Figure 2 graphically shows the structure of the committed effective dose rates due to inhalation intake of 241Am, 238,239+240Pu, 137Cs and 90Sr by the grain harvest workers on both experimental fields.

According to the results, the radionuclides prevailing in the structure of the committed effective dose rates due to inhalation were 241Am and 238,239+240Pu with the contribution of 82–97% against only 3–18% from 137Cs and 90Sr.

The average time spent by fieldsmen and machinery operators on grain harvesting operations was 14 days, or 140 h given that the working activity during the harvest period commonly lasts up to 10 h. Considering this, the total annual effective doses (total effective dose of external exposure and committed dose of internal exposure) to these two categories of agricultural workers involved in grain dust operations on the experimental fields were calculated to constitute respectively 6 × 10−2 mSv year−1 and 2–3 × 10−2 mSv year−1, or respectively 6% and 2–3% of the regulatory limit for permissible public exposure of 1 mSv year−1.

Table 1

The concentrations of 137Cs, 90Sr and TUE (241Am, 238,239+240Pu) in the workplace air during grain harvesting operations.

Table 2

Effective dose rates of agricultural persons involved in grain harvesting operations.

thumbnail Fig. 2

Inhalation intake of 238,239+240Pu, 241Am, 90Sr and 137Cs in the structure of the committed effective dose rates.

4 Conclusion

This study is focused on assessing the inhalation impact of dusty grain harvesting operations implemented on the backyard of a populated area and on the field in the resettled area of the Chernobyl evacuation zone, both located in Gomel region of Belarus. According to the results, the dust factor is a prevailing contributor in developing internal radiation doses of grain harvest workers (i.e. in a populated area with a lower contamination density the doses may be higher than those received in harvesting operations with smaller dust amounts in the resettled area). Committed effective doses of internal exposure due to inhalation intake of all analyzed radionuclides in all “on the field” harvesting operations are up to one order of magnitude lower when compared to the respective doses of internal exposure received “in the cab”, given that an operator's cabin has no air conditioning system. Importantly, the highest committed effective doses of internal exposure due to 137Cs, 90Sr and TUE total inhalation exposure (3.3 × 10−5 mSv h−1) is up to 5 times lower when compared to the lowest dose of external exposure (0.15 × 10−3 mSv h−1). In terms of the structure of the committed effective dose rates, 241Am and 238,239+240Pu are the dominant contributors to doses constituting 82–97% of the total inhalation exposure in harvesting operations on both fields.

Given that the working activity during the harvest period on the average lasts 140 h, the total doses of external and internal exposure received by harvest workers on both fields are significantly below 1 mSv year−1, the universally accepted limit for public exposure. The highest committed effective doses of internal exposure due to inhalation intake of 241Am, 238,239+240Pu, 137Cs and 90Sr are developed in case an operator's cabin is continuously left open, or if it has no air conditioning system. To protect harvest workers from receiving high doses of internal exposure, the present study recommends to employ agricultural machinery with operator cabins safely sealed and equipped with air conditioning systems, as well as to minimize the working time of field workers involved in harvest operations in the open air. To protect harvest workers against external exposure, it is considered highly efficient to implement combined technological operations (e.g. simultaneous application of fertilizers and herbicides) in order to reduce the time spent by workers in the areas of increased radiation background and minimize dust exposure.

Acknowledgement

The authors would like to express their immense gratitude to Aliona A. Mikhailova (RIR) for her tremendous translation, editing and proofreading work and her overall assistance in production of this manuscript.

References

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Cite this article as: Podolyak A, Tagai S, Nilova E, Averin V. 2017. Assessment of committed doses received by agricultural workers in grain harvesting operations in the areas of radioactive contamination. Radioprotection 52(1): 37–43.

All Tables

Table 1

The concentrations of 137Cs, 90Sr and TUE (241Am, 238,239+240Pu) in the workplace air during grain harvesting operations.

Table 2

Effective dose rates of agricultural persons involved in grain harvesting operations.

All Figures

thumbnail Fig. 1

Location of both experimental fields with respect to the PRER borders (as shown on the satellite image).

In the text
thumbnail Fig. 2

Inhalation intake of 238,239+240Pu, 241Am, 90Sr and 137Cs in the structure of the committed effective dose rates.

In the text

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