Soil-to-plant transfer factors of trace and major elements in rice plant (Oryza Sativa) at Kalpakkam

International Nuclear Information System (INIS)

Sreedevi, K.R.; Rajaram, S.; Thulasi Brindha, J.; Venkataraman, S.; Hegde, A.G.

2011-01-01

The objective of this study was to evaluate the distribution of trace and major elements in rice plant (Oryza Sativa) which is the staple diet of the public at Kalpakkam. The transfer factor from soil to various parts of plant was also studied. Trace and major elements such as Fe, Mn, Zn, Co, Cu, Ni, Cr, Cd, Pb , Sr, K, Ca and Mg were selected based on their role in nutrition and also to study the behaviour of their radioactive counterparts. Among the trace elements Fe concentration was observed to be maximum in soil, the mean value of which was 18394 mg/kg dry wt. Cadmium concentration was observed to be minimum with the mean value of 2 mg/kg dry wt. The maximum and minimum concentration observed in the rice grain were due to Zn and Cd and the values were found to be 9 and 0.044 mg/kg dry wt, respectively. In the stem and leaves part the maximum and minimum concentration was due to Fe and Cd and the values were found to be 26.8 and 0.12 mg/kg dry wt. Similarly in the root part Fe and Cd concentrations were found to be maximum and minimum, respectively. Among the different parts of the rice plant, trace elements concentration in root was maximum and in stem and leaves major elements concentration was maximum. Transfer factor from soil to plant parts was computed. In general, the transfer factor was maximum in root, followed by stem and leaves and grain for trace elements. The transfer factor computed for whole rice plant was maximum for Zn and minimum for Sr which is a significant observation from radiological point of view. (author)

137Cs Transfer Factor from Latosol Soil to Swamp Gabbages (Ipomea Reptans Poir)

International Nuclear Information System (INIS)

Leli-Nirwani; Yurfida; Buchori

2001-01-01

A study of 137 Cs transfer factor from Latosol soil to swamp cabbages plant has been conducted using pot treatment system with complete random design. The aim of the research is to determine transfer factor of 137 Cs from latosol soil to swamp cabbages plant. Cs-137 concentration administered was 7.5287 kBq/pot. The number of swamp cabbages planted in 137 Cs treated soil and in cannot soil respectively was 12 pots filled with 1 kg soil/pot. After harvest, the weight of dried plant was measured. Transfer factor was determined according to the accumulation of 137 Cs concentration in swamp cabbages and soil and counted using Spectrometer Gamma. It was found that is a significant difference between 137 Cs concentration in swamp cabbages planted inthe treated soil and that of control soil. Transfer factor ranges between 0.02 and 0.13 with the averageof 0.08. (author)

Variability of the soil-to-plant radiocaesium transfer factor for Japanese soils predicted with soil and plant properties.

Science.gov (United States)

Uematsu, Shinichiro; Vandenhove, Hildegarde; Sweeck, Lieve; Van Hees, May; Wannijn, Jean; Smolders, Erik

2016-03-01

Food chain contamination with radiocaesium (RCs) in the aftermath of the Fukushima accident calls for an analysis of the specific factors that control the RCs transfer. Here, soil-to-plant transfer factors (TF) of RCs for grass were predicted from the potassium concentration in soil solution (mK) and the Radiocaesium Interception Potential (RIP) of the soil using existing mechanistic models. The mK and RIP were (a) either measured for 37 topsoils collected from the Fukushima accident affected area or (b) predicted from the soil clay content and the soil exchangeable potassium content using the models that had been calibrated for European soils. An average ammonium concentration was used throughout in the prediction. The measured RIP ranged 14-fold and measured mK varied 37-fold among the soils. The measured RIP was lower than the RIP predicted from the soil clay content likely due to the lower content of weathered micas in the clay fraction of Japanese soils. Also the measured mK was lower than that predicted. As a result, the predicted TFs relying on the measured RIP and mK were, on average, about 22-fold larger than the TFs predicted using the European calibrated models. The geometric mean of the measured TFs for grass in the affected area (N = 82) was in the middle of both. The TFs were poorly related to soil classification classes, likely because soil fertility (mK) was obscuring the effects of the soil classification related to the soil mineralogy (RIP). This study suggests that, on average, Japanese soils are more vulnerable than European soils at equal soil clay and exchangeable K content. The affected regions will be targeted for refined model validation. Copyright © 2015 Elsevier Ltd. All rights reserved.

Soil to plant transfer factor in the vicinity of coal fired power plants

International Nuclear Information System (INIS)

Nikolic, J.; Todorovic, D.; Jankovic, M.; Radenkovic, M.; Joksic, J.

2009-01-01

In this paper, the monitoring of working and living environment results in 5 coal fired powered plants, for the period from 2004. to 2009. are presented. Soil-plant transfer factor, suitable for estimation of possible contamination of food chain was chosen, as a measure of influence of power plants on the environment. The results gathered over the years of monitoring of working and living environment in the vicinity of the coal fired power plant were analyzed, and it was determined that no significant discrepancy exists comparing to the results reported in world literature. Also, the basic mathematical analysis was conducted, in order to assess the model of the behavior of the results in respect to the frequency count. (author) [sr

3rd Report of the workgroup on soil-to-plant transfer factors

International Nuclear Information System (INIS)

1984-01-01

This report presents about 2000 soil-to-plant transfer factors obtained in different countries. They are included in a data bank compiled by the different IUR working groups. Some remarks on organisation and present status of the data bank, are followed up with 11 contributions presented at the conference, of which 5 are included in Atomindex separately. (Auth.)

Proposal for new best estimates of the soil-to-plant transfer factor of U, Th, Ra, Pb and Po

Energy Technology Data Exchange (ETDEWEB)

Vandenhove, H. [Belgian Nuclear Research Centre, Biosphere Impact Studies, Mol (Belgium)], E-mail: hvandenh@sckcen.be; Olyslaegers, G. [Belgian Nuclear Research Centre, Biosphere Impact Studies, Mol (Belgium); Sanzharova, N.; Shubina, O. [RIAREA, Russian Institute of Agricultural Radiology and Agroecology, Obninsk (Russian Federation); Reed, E. [SENES Oak Ridge Inc., Center for Risk Analysis, Oak Ridge, TN (United States); Shang, Z. [Nuclear Safety Center of SEPA, Beijing (China); Velasco, H. [GEA- IMASL, Universidad Nacional de San Luis, Consejo Nacional de Investigaciones Cientificas y Tecnicas (Argentina)

2009-09-15

There is increasing interest in radiological assessment of discharges of naturally occurring radionuclides into the terrestrial environment. Such assessments require parameter values for the pathways considered in predictive models. An important pathway for human exposure is via ingestion of food crops and animal products. One of the key parameters in environmental assessment is therefore the soil-to-plant transfer factor to food and fodder crops. The objective of this study was to compile data, based on an extensive literature survey, concerning soil-to-plant transfer factors for uranium, thorium, radium, lead, and polonium. Transfer factor estimates were presented for major crop groups (Cereals, Leafy vegetables, Non-leafy vegetables, Root crops, Tubers, Fruits, Herbs, Pastures/grasses, Fodder), and also for some compartments within crop groups. Transfer factors were also calculated per soil group, as defined by their texture and organic matter content (Sand, Loam, Clay and Organic), and evaluation of transfer factors' dependency on specific soil characteristics was performed following regression analysis. The derived estimates were compared with estimates currently in use.

Radionuclide soil-to-plant transfer - experiences from the Chernobyl accident in Austria

International Nuclear Information System (INIS)

Gerzabek, M.H.

1994-03-01

In field studies after the Chernobyl fallout in Austria distinct differences in soil-to-plant transfer of 137 Cs and 90 Sr between crops were observed. However, within single plant species transfer values varied over one to three orders of magnitude. The main influencing factors are the soil properties, the soil adhesion phenomenon and probably the unhomogeneous vertical distribution of the radionuclides after plowing. On the basis of the presented results we should be aware of the uncertainties of the simple soil-to-plant transfer model, which partly mask the influence of soil parameters on root uptake and translocation. (author)

Bioavailability and soil-to-plant transfer factors as indicators of potentially toxic element contamination in agricultural soils

Energy Technology Data Exchange (ETDEWEB)

Adamo, Paola, E-mail: paola.adamo@unina.it [Dipartimento di Agraria, Università di Napoli Federico II, via Università 100, 80055 Portici (Italy); Iavazzo, Pietro [Dipartimento di Agraria, Università di Napoli Federico II, via Università 100, 80055 Portici (Italy); Albanese, Stefano [Dipartimento di Scienze della Terra, dell' Ambiente e delle Risorse, Università di Napoli Federico II, Via Mezzocannone 8, 80134 Napoli (Italy); Agrelli, Diana [Dipartimento di Agraria, Università di Napoli Federico II, via Università 100, 80055 Portici (Italy); De Vivo, Benedetto; Lima, Annamaria [Dipartimento di Scienze della Terra, dell' Ambiente e delle Risorse, Università di Napoli Federico II, Via Mezzocannone 8, 80134 Napoli (Italy)

2014-12-01

Soil pollution in agricultural lands poses a serious threat to food safety, and suggests the need for consolidated methods providing advisory indications for soil management and crop production. In this work, the three-step extraction procedure developed by the EU Measurement and Testing Programme and two soil-to-plant transfer factors (relative to total and bioavailable concentration of elements in soil) were applied on polluted agricultural soils from southern Italy to obtain information on the retention mechanisms of metals in soils and on their level of translocation to edible vegetables. The study was carried out in the Sarno river plain of Campania, an area affected by severe environmental degradation potentially impacting the health of those consuming locally produced vegetables. Soil samples were collected in 36 locations along the two main rivers flowing into the plain. In 11 sites, lettuce plants were collected at the normal stage of consumption. According to Italian environmental law governing residential soils, and on the basis of soil background reference values for the study area, we found diffuse pollution by Be, Sn and Tl, of geogenic origin, Cr and Cu from anthropogenic sources such as tanneries and intensive agriculture, and more limited pollution by Pb, Zn and V. It was found that metals polluting soils as a result of human activities were mainly associated to residual, oxidizable and reducible phases, relatively immobile and only potentially bioavailable to plants. By contrast, the essential elements Zn and Cu showed a tendency to become more readily mobile and bioavailable as their total content in soil increased and were more easily transported to the edible parts of lettuce than other pollutants. According to our results, current soil pollution in the studied area does not affect the proportion of metals taken up by lettuce plants and there is a limited health risk incurred. - Highlights: • Soil pollution in an intensively farmed area of

Bioavailability and soil-to-plant transfer factors as indicators of potentially toxic element contamination in agricultural soils

International Nuclear Information System (INIS)

Adamo, Paola; Iavazzo, Pietro; Albanese, Stefano; Agrelli, Diana; De Vivo, Benedetto; Lima, Annamaria

2014-01-01

Soil pollution in agricultural lands poses a serious threat to food safety, and suggests the need for consolidated methods providing advisory indications for soil management and crop production. In this work, the three-step extraction procedure developed by the EU Measurement and Testing Programme and two soil-to-plant transfer factors (relative to total and bioavailable concentration of elements in soil) were applied on polluted agricultural soils from southern Italy to obtain information on the retention mechanisms of metals in soils and on their level of translocation to edible vegetables. The study was carried out in the Sarno river plain of Campania, an area affected by severe environmental degradation potentially impacting the health of those consuming locally produced vegetables. Soil samples were collected in 36 locations along the two main rivers flowing into the plain. In 11 sites, lettuce plants were collected at the normal stage of consumption. According to Italian environmental law governing residential soils, and on the basis of soil background reference values for the study area, we found diffuse pollution by Be, Sn and Tl, of geogenic origin, Cr and Cu from anthropogenic sources such as tanneries and intensive agriculture, and more limited pollution by Pb, Zn and V. It was found that metals polluting soils as a result of human activities were mainly associated to residual, oxidizable and reducible phases, relatively immobile and only potentially bioavailable to plants. By contrast, the essential elements Zn and Cu showed a tendency to become more readily mobile and bioavailable as their total content in soil increased and were more easily transported to the edible parts of lettuce than other pollutants. According to our results, current soil pollution in the studied area does not affect the proportion of metals taken up by lettuce plants and there is a limited health risk incurred. - Highlights: • Soil pollution in an intensively farmed area of

Interpretation of soil-to-plant transfer on the basis of soil solution chemical composition

International Nuclear Information System (INIS)

Lembrechts, J.F.; Van Loon, L.R.; Van Ginkel, J.H.; Desmet, G.M.

1988-01-01

Soil-to-plant translocation of a radionuclide depends on its availability on the one hand and on the efficiency of the uptake process on the other. Criticism on the use of transfer coefficients for the description of translocation mainly concerns the fact that the complex variety of processes, a.o. dependent on plant characteristics and soil type and treatment, is integrated in a single ratio. For the interpretation of the effect of counter-measures the static transfer coefficient proved to be hard to handle and knowledge of the separate underlying processes and their time dependence showed to be indispensible. Based upon translocation experiments with technetium, cobalt, strontium and zinc transfer was shown to be primarily related to the concentration of the plant available fraction in the soil solution as well as to the soil solution chemistry in general. The transfer factor of the first three elements expressed in the basis of soil solution activity (ml/g), was observed to decrease when the nutrient content of the soil solution -- reflected by its conductivity -- increased. The characteristics of the soil matrix (solid phase) furthermore showed to be of secondary importance for the explanation of the observed accumulation. Since the interstitial soil liquid phase mediates between solid phase and plant root, reliable interpretations of soil-to-plant transfer might as a rule be based on a separate study of the effect of soil properties on availability on the one hand of the uptake from nutrient solutions on the other

CS-137 transfer factors soil-plant and density of hyphae in soil of spruce forests

International Nuclear Information System (INIS)

Klemt, E.; Deuss, H.; Drissner, J.; Krapf, M.; Miller, R.; Zibold, G.

1999-01-01

Samples of soil and plants were taken at spruce stand sites in southern Baden-Wuerttemberg. Fern always had the highest aggregated Cs-137 transfer factor (T ag ) varying between 0.01 and 0.27 m 2 kg -1 . There is a tendency for higher T ag s in soils with thicker raw humus layers, lower pH, lower cation exchange capacity (CEC) in the O h horizon, and lower clay content below the organic deposit. The density of hyphae is determined by the season and its weather conditions and it usually decreases continuously from O f to top B horizon. In analyzing our data no correlation between aggregated or horizon-specific transfer factors of different plants and density of hyphae could be found. Refs. 5 (author)

A new approach for soil-plant transfer calculations

International Nuclear Information System (INIS)

Dorp, F. van; Eleveld, R.; Frissel, M.J.

1979-01-01

Models to calculate radiation doses to man caused by normal or accidental release of radionuclides from nuclear industries often include the transfer of these nuclides from soil to plant. This soil-plant transfer is mostly described with a black box approach by using concentration factors. This approach has several disadvantages, the most important being the lack of physical meaning of a concentration factor. We propose to describe the soil-plant transfer of radionuclides as a function of plant and soil parameters all having a physical meaning. The separate parameters are open to experimental determination but a realistic estimation of the parameters is also possible, or the use of a combination of both. Depending on the purpose of the calculation, realistic or conservative values of the parameters can be used and the degree of conservatism can be indicated. (author)

Soil-to-plant transfer factors for natural radionuclides in the Brazilian cerrado region

International Nuclear Information System (INIS)

Jacomino, Vanusa M.F.; Oliveira, Kerley A.; Menezes, Maria Angela de B.; Mello, Jaime de; Silva, David F. da

2009-01-01

Large amounts of phosphogypsum produced have been attracting attention of Radiological Protection institutions and Environmental Protection agencies worldwide, given its high potential for environmental contamination. In Brazil, this material has been used for several decades, especially for agricultural purposes. Due to the presence of radionuclides in its composition, it is necessary to understand the mechanisms for natural radionuclide transfer in the soil/plant system and to evaluate if the use of phosphogypsum in soil contributes to increased exposition of humans to natural radioactivity. Experiments were accomplished in a greenhouse with lettuce cultivation in two types of soil (sandy and clayey) fertilized with four different amounts of phosphogypsum. Samples of phosphogypsum, soil, lettuce and drainage water were then analyzed for key radionuclides. 238 U and 232 Th analyses were carried out by Neutron Activation Analysis; 226 Ra, 228 Ra, and 210 Pb by analyzed by Gamma Spectrometry; and 210 Po by Alpha Spectrometry Technique. Finally, Transfer Factors of soil-plant were calculated as well as annual contribution to the effective dose due to the ingestion of lettuces. 22 '6Ra average specific activity in phosphogypsum samples (252 Bq kg -1 ) was below the maximum level recommended by USEPA, which is 370 Bq.kg -1 for agricultural use. Although most of the results for mean specific activity of radionuclides in lettuce presented values below the Minimum Detectable Activity (MDA), Transfer Factors were estimated for those conditions in which the mean specific activity proved to be superior to MDA. Values ranged from 1.8 10 -3 to 2.3 10 -2 for 232 Th; 3.5 10 - '2 to 4.1 10 -2 for 226 Ra, 2.4 10 -1 to 3.2 10 - '1 for 228 Ra, and 3.5 10 -2 to 8.5 10 -2 for 210 Po, depending on the type of soil used for planting vegetables. In general, results obtained in the present study indicated that mobility of radionuclides was low in both soils studied. Calculated effective

Soil-to-plant transfer factors for natural radionuclides in the Brazilian cerrado region

Energy Technology Data Exchange (ETDEWEB)

Jacomino, Vanusa M.F.; Oliveira, Kerley A.; Menezes, Maria Angela de B., E-mail: vmfj@cdtn.b [Centro de Desenvolvimento da Tecnologia Nuclear (CDTN/CNEN-MG), Belo Horizonte, MG (Brazil); Mello, Jaime de; Silva, David F. da, E-mail: jwvmello@ufv.b [Universidade Federal de Vicosa (UFV), MG (Brazil). Dept. de Solos; Siqueira, Maria C.; Taddei, Maria H.; Dias, Fabiana F., E-mail: mc_quimica@hotmail.co, E-mail: mhtaddei@cnen.gov.b, E-mail: fdias@cnen.gov.b [Comissao Nacional de Energia Nuclear (CNEN-MG), Pocos de Caldas, MG (Brazil). Lab. de Pocos de Caldas (LAPOC)

2009-07-01

Large amounts of phosphogypsum produced have been attracting attention of Radiological Protection institutions and Environmental Protection agencies worldwide, given its high potential for environmental contamination. In Brazil, this material has been used for several decades, especially for agricultural purposes. Due to the presence of radionuclides in its composition, it is necessary to understand the mechanisms for natural radionuclide transfer in the soil/plant system and to evaluate if the use of phosphogypsum in soil contributes to increased exposition of humans to natural radioactivity. Experiments were accomplished in a greenhouse with lettuce cultivation in two types of soil (sandy and clayey) fertilized with four different amounts of phosphogypsum. Samples of phosphogypsum, soil, lettuce and drainage water were then analyzed for key radionuclides. {sup 238}U and {sup 232}Th analyses were carried out by Neutron Activation Analysis; {sup 226}Ra, {sup 228}Ra, and {sup 210}Pb by analyzed by Gamma Spectrometry; and {sup 210}Po by Alpha Spectrometry Technique. Finally, Transfer Factors of soil-plant were calculated as well as annual contribution to the effective dose due to the ingestion of lettuces. {sup 22}'6Ra average specific activity in phosphogypsum samples (252 Bq kg{sup -1}) was below the maximum level recommended by USEPA, which is 370 Bq.kg{sup -1} for agricultural use. Although most of the results for mean specific activity of radionuclides in lettuce presented values below the Minimum Detectable Activity (MDA), Transfer Factors were estimated for those conditions in which the mean specific activity proved to be superior to MDA. Values ranged from 1.8 10{sup -3} to 2.3 10{sup -2} for {sup 232}Th; 3.5 10{sup -}'2 to 4.1 10{sup -2} for {sup 226}Ra, 2.4 10{sup -1} to 3.2 10{sup -}'1 for {sup 228}Ra, and 3.5 10{sup -2} to 8.5 10{sup -2} for {sup 210}Po, depending on the type of soil used for planting vegetables. In general, results

60Co, 63Ni and 94Nb soil-to-plant transfer in pot experiments

International Nuclear Information System (INIS)

Gerzabek, M.H.; Mohamad, S.A.; Mueck, K.; Horak, O.

1995-01-01

Soil-to-plant transfer factors for 60 Co, 63 Ni and 94 Nb were obtained via pot experiments with a Dystric Cambisol and a Calcic Chernozem, both from Lower Austria. Investigated plants were greenrape (Brassica napus oleifera L.), bean (Phaseolus vulgaris L.) and winter wheat (Triticum aestivum L.). The soil-to-plant transfer factors decreased from 63 Ni to 60 Co and 94 Nb. Mean values from all experiments ranged from 1.12 ( 63 Ni) to 0.0045 ( 94 Nb). The transfer values obtained for 60 Co and 63 Ni are comparable to literature values, but 94 Nb-transfer seems to be lower than previous estimates. All radionuclides showed differences between plant species and plant organs. Transfer values were also dependent on the soil type. (author)

60Co Transfer Factor From Lutosol Soil To Leafy Vegetable (Ipomea reptans poir)

International Nuclear Information System (INIS)

Leli-Nirwani; Jumaher; Wahyudi

2003-01-01

It has been conducted 60 Co transfer study from Lutosol soil to leafy vegetable plant by using pot treatment system. The aim of the research is to obtain data of the transfer factor of 60 Co from lutosol soil to leafy vegetable plant. Pot experiment was carried out by using the complete random design to evaluate two treatment, namely soil with 60 Co and without 60 Co (as a control). 60 Co concentration was with 6.1371 kBq/pot. Tested plant and control plant amount to 12 pots. Each pot contains 1 kg of soil. After harvesting, the weight of dry plant was determined and was conducted with Spectrometer Gamma to 60 Co concentration in dry plant and dry soil. Transfer factor was found to between 0.02 and 0.68 and the average is 0.2068. (author)

Soil Plant and plant mammal transfer factors

NARCIS (Netherlands)

de Nijs ACM; Vermeire TG

1990-01-01

In order to assess the lifetime hazard of ingestion exposure of man to new substances, the RIVM Assessment System for New Substances links environmental concentrations in water and soil to human exposure applying transfer factors. This report discusses indirect human exposure to new substances via

Screening plant species native to Taiwan for remediation of 137Cs-contaminated soil and the effects of K addition and soil amendment on the transfer of 137Cs from soil to plants

International Nuclear Information System (INIS)

Chou, F.-I.; Chung, H.-P.; Teng, S.-P.; Sheu, S.-T.

2005-01-01

This study aims to screen plant species native to Taiwan that could be used to eliminate 137 Cs radionuclides from contaminated soil. Four kinds of vegetables and two kinds of plants known as green manures were used for the screening. The test plants were cultivated in 137 Cs-contaminated soil and amended soil which is a mixture of the contaminated one with a horticultural soil. The plant with the highest 137 Cs transfer factor was used for further examination on the effects of K addition on the transfer of 137 Cs from the soils to the plant. Experimental results revealed that plants cultivated in the amended soil produced more biomass than those in the contaminated soil. Rape exhibited the highest production of aboveground parts, and had the highest 137 Cs transfer factor among all the tested plants. The transfer of 137 Cs to the rape grown in the soil to which 100 ppm KCl commonly used in local fertilizers had been added, were restrained. Results of this study indicated that rape, a popular green manure in Taiwan, could remedy 137 Cs-contaminated soil

Cesium-137 in soil texture fractions and its impact on Cesium-137 soil-to-plant transfer

International Nuclear Information System (INIS)

Gerzabek, M.H.; Mohamad, S.A.; Mueck, K.

1992-06-01

Field studies at two sites contaminated by the Chernobyl fallout showed 137 Cesium (Cs) soil-to-plant transfer factors in wheat, rye and potato. Transfer values ranged from 0.0017 (potato tuber) to 0.07 (wheat straw). Generally transfer coefficients in cereal grains and potato tubers were significantly below the values of the shoots. A comparison of the two sites led to the conclusion that for all plants investigated 137 Cs transfer factors were higher in Lower Austria (Calcic Chernozem) than in Upper Austria (Eutric Cambisol). The specific activities of the texture fractions of the two soil types increased from sand to silt and clay. In the Calcic Chernozem the ratio of the 137 Cs activity in the silt fraction to the total activity in the soil was considerably higher than in the Eutric Cambisol. At the same time extractability of 137 Cs from the silt fraction of the latter soil was clearly lower. Both results mainly were attributed to the differences between the soils according to the organic matter content of the silt fractions, the Calcic Chernozem being seven times higher. Therefore, the differences in the 137 Cs-soil-to-plant transfer can be attributed partly to these soil characteristics. (authors)

Transfer Factor of Co-60 and Cs-137 from Agricultural Soil to Agricultural Plant of Rice and Beans

International Nuclear Information System (INIS)

Suzie, D; Cerdas, T; Susilah, S; Umbara, H

1996-01-01

A study to estimate transfer factor of Co-60 and Cs-137 radionuclides from agricultural soil to agricultural plant of beans and rice in Serpong Nuclear Research Center Complex has been carried out. The soil used was that from off site Serpong Nuclear Research Center Complex, the agricultural plant samples were rice with variety of Cisadane, Situgintung, Seratus Malam, and Atomita 4, and for beans were peanut with variety of AH 1781 SI (parent) and A 20 psj (daughter), soybean with variety of Kerinci (parent) and Camar (daughter), and greenbean with variety of Manyar (parent) and Camar (daughter), which obtained from PAIR-BATAN Pasar Jumat. 10 kg of soil was put on the container which layered with plastic. The soil was contaminated with Co-60 and Cs-137 with activity concentration of 10 Bq/kg. Samples were counted with gamma spectrometer. The value of transfer factor was obtained by comparing activity concentration of agricultural plant with that of agricultural soil. The results of transfer factor of Co-60 for rice and beans were 0.12 x 10-2 and 1.05 x 10-2, respectively and the transfer factor of Cs-137 for rice and beans were 0.83 x 10-2 and 2.09 x 10-2, respectively. The gamma emmitter radionuclides counted from the soil of Serpong Nuclear Research Center Complex were Th-228, U-235, Ra-226, Ac-228 and K-40, with activities concentration as background were 35.39 - 101.60; 32.14 - 74.50; 23.37 - 28.57; 20.90 - 31.28 and 5.97 - 8.13 Bq/kg, respectively

Element interactions and soil properties affecting the soil-to-plant transfer of six elements relevant to radioactive waste in boreal forest

International Nuclear Information System (INIS)

Roivainen, Paeivi; Makkonen, Sari; Holopainen, Toini; Juutilainen, Jukka

2012-01-01

Cobalt (Co), lead (Pb), molybdenum (Mo), nickel (Ni), uranium (U), and zinc (Zn) are among the elements that have radioactive isotopes in radioactive waste. Soil-to-plant transfer is a key process for possible adverse effects if these radionuclides are accidentally released into the environment. The present study aimed at investigating factors affecting such transfer in boreal forest. The plant species studied were blueberry (Vaccinium myrtillus), May lily (Maianthemum bifolium), narrow buckler fern (Dryopteris carthusiana), rowan (Sorbus aucuparia) and Norway spruce (Picea abies). Regression analyses were carried out to investigate the effects of the chemical composition and physical properties of soil on the soil-to-leaf/needle concentration ratios of Co, Mo, Ni, Pb, U and Zn. Soil potassium (K), magnesium (Mg), manganese (Mn), phosphorus (P) and sulphur (S) concentrations were the most important factors affecting the soil-to-plant transfer of the elements studied. Soil clay and organic matter contents were found to significantly affect plant uptake of Mo, Pb and U. Knowledge of the effects of these factors is helpful for interpretation of the predictions of radioecological models describing soil-to-plant transfer and for improving such models. (orig.)

Element interactions and soil properties affecting the soil-to-plant transfer of six elements relevant to radioactive waste in boreal forest

Energy Technology Data Exchange (ETDEWEB)

Roivainen, Paeivi; Makkonen, Sari; Holopainen, Toini; Juutilainen, Jukka [University of Eastern Finland, Department of Environmental Science, Kuopio (Finland)

2012-03-15

Cobalt (Co), lead (Pb), molybdenum (Mo), nickel (Ni), uranium (U), and zinc (Zn) are among the elements that have radioactive isotopes in radioactive waste. Soil-to-plant transfer is a key process for possible adverse effects if these radionuclides are accidentally released into the environment. The present study aimed at investigating factors affecting such transfer in boreal forest. The plant species studied were blueberry (Vaccinium myrtillus), May lily (Maianthemum bifolium), narrow buckler fern (Dryopteris carthusiana), rowan (Sorbus aucuparia) and Norway spruce (Picea abies). Regression analyses were carried out to investigate the effects of the chemical composition and physical properties of soil on the soil-to-leaf/needle concentration ratios of Co, Mo, Ni, Pb, U and Zn. Soil potassium (K), magnesium (Mg), manganese (Mn), phosphorus (P) and sulphur (S) concentrations were the most important factors affecting the soil-to-plant transfer of the elements studied. Soil clay and organic matter contents were found to significantly affect plant uptake of Mo, Pb and U. Knowledge of the effects of these factors is helpful for interpretation of the predictions of radioecological models describing soil-to-plant transfer and for improving such models. (orig.)

Soil-to-plant transfer factors of technetium-99 for various plants collected in the Chernobyl area

International Nuclear Information System (INIS)

Tagami, Keiko; Uchida, Shigeo

2005-01-01

Technetium-99 is thought to be highly soluble and rarely adsorbed onto soil, however, its mobility under natural environment is not well known because its scarcity and low levels in environmental samples has limited the available data. In this study, we determined 99 Tc contents in 27 plant samples collected in three forest sites in 1994 and 1995 around the Chernobyl area to obtain transfer factors (TFs) of Tc in the soil-plant system under environmental conditions. The samples were leaves of raspberry, strawberry and pink plants, black alder, birch, cowberry and oak trees, and ferns. After chemical separation, 99 Tc in the sample was measured by ICP-MS. Tc-95m was used as a yield tracer and the total recovery ranged from 0.48 to 0.92 with an average of 0.76. The determined 99 Tc concentrations in plants ranged from -1 (dry weight basis). TF values ranged from 99 Tc contents of the soil organic layers. The highest TF was found in the leaves of raspberry plants. The observed TFs were much lower than the values of 8.1 - 2600 compiled by IAEA for grass, fodder and leafy vegetables. (author)

Transfer of radioactive cesium from soil to rape plants, rape blossoms and rape honey

International Nuclear Information System (INIS)

Molzahn, D.; Klepsch, A.; Assmann-Wertmueller, U.

1989-01-01

Due to the test of atomic weapons and the accident in the nuclear power plant at Chernobyl, the vegetation in Germany has been exposed to cesium contamination in the soil. It was to be expected that activity would migrate from soil to plants and to food products. In this work, the transfer of radioactive cesium from soil to rape plants (Brassica napus var. oleifera), rape blossoms and further to rape honey was investigated. By measuring the gamma activity of cesium using germanium detectors with measuring capacity up to 30 h per sample (limit of detection about 0.14 Bq/kg to 0.19 Bq/kg), we determined a mean transfer factor f cs = 0,116 ± 0,080 for the system soil-rape plant, f cs = 0.065 + 0.075 for the system soil-rape blossom and F!S = 0.098 + 0.044 for the system soil-rape honey (plants and honey wet mass, soil dry mass) (Table IV). Additionally, for the transfer of cesium from rape plants to rape honey, a factor of f cs = 2.04 ± 7.23 (both wet mass) was determined. Due to some environmental circumstances, which can hardly ever be taken into account, the results obtained sometimes differ considerably. Nevertheless, the mean transfer factors are within the range of values found in literature (Table V) [de

Soil-to-plant transfer factors for radiocaesium measured in different soil types in the Czech Republic

International Nuclear Information System (INIS)

Tecl, J.; Mirchi, R.; Malatova, I.; Peskova, I.; Schlesingerova, E.

2001-01-01

This study was perform in frame of the SAVEC project (SAVEC = Spatial Analysis of Vulnerable Ecosystems in Central Europe; European Union project). The aim of the SAVEC project was to develop a user-friendly software package that will allow the identification of areas vulnerable or resilient to radiocesium deposition in the Central European countries: Poland, Hungary and the Czech Republic. The software package will incorporate a semi- mechanistic soil-to-plant transfer model which uses commonly measured soil properties to estimate the dynamic behaviour of deposited radiocesium. This model was developed for the European Commission IV th Framework programme Spatial Analysis of Vulnerable Ecosystems (SAVE) project. In the SAVEC software package, spatially variable data (including 137 CS deposition, soil property , agricultural production and dietary data) can be used to assess the consequences of the deposition in the three Central European countries following nuclear accidents. The SAVEC project collates data of sufficient resolution specific to Poland, Hungary and the Czech Republic for integration within the SAVE-IT software package to allow the identification of areas and population groups that may be vulnerable to radiocesium deposition. From this viewpoint the samples of soil and vegetation were collected (1999 and 2000; the locations of the sampling places are in Fig. 1.) in which the content of 137 CS by semiconductor gamma spectrometry were determined. The mass activity of 137 CS were used for calculation of soil-to-plant transfer factors. (authors)

Soil-to-plant transfer factors for natural radionuclides in grass in the vicinity of a former uranium mine

Energy Technology Data Exchange (ETDEWEB)

Štrok, Marko, E-mail: Marko.Strok@ijs.si; Smodiš, Borut, E-mail: Borut.Smodis@ijs.si

2013-08-15

Highlights: • Soil and grass samples were collected from sites at the uranium mill tailings pile. • {sup 238}U, {sup 230}Th, {sup 226}Ra and {sup 210}Pb activity concentrations were determined. • Soil-to-plant transfer factors were determined and are comparable with literature. • Potential use of grass as a monitor of radionuclide migration was evaluated. • Grass has potential in predicting {sup 238}U and {sup 226}Ra migration. -- Abstract: The activity concentrations of {sup 238}U, {sup 230}Th, {sup 226}Ra and {sup 210}Pb were determined in soil and grass samples collected from sites at the uranium mill tailings waste pile, which lies near the former uranium mine at Žirovski vrh in Slovenia. Soil-to-plant transfer factors were determined and the potential use of grass as a monitor of radionuclide migration from the waste pile was evaluated. It was found that grass was not suitable for monitoring {sup 230}Th and {sup 210}Pb migration (no linear correlation between soil and grass activity concentrations) but has potential in predicting {sup 238}U and {sup 226}Ra migration (linear correlation between soil and grass activity concentrations). Soil-to-plant transfer factors for grass were in the range from 0.0014 to 0.015 kg/kg DM for {sup 238}U, 0.0039 to 0.012 kg/kg DM for {sup 230}Th, 0.035 to 0.46 kg/kg DM for {sup 226}Ra and 0.098 to 1.5 kg/kg DM for {sup 210}Pb.

Cs-137 soil to plant transfer factors derived from pot experiments and field studies

International Nuclear Information System (INIS)

Horak, O.; Gerzabek, M.H.; Mueck, K.

1989-11-01

Soil to plant transfer factors (TF) of 137 Cs for different crop plants were determined in pot experiments, in outdoor experiments with plastic containers of 50 l volume, and in field studies. In all cases the soil contamination with 137 Cs resulted from fallout after the Chernobyl reactor accident. Mean TF derived for outdoor plants on a fresh weight basis, ranged from 0,0017 (leaf vegetables) to 0,059 (rye straw) and showed characteristic differences depending on plant part and species. Generally, for fruits and potato tubers a lower TF was found than for vegetative plant parts. Moreover, the data were compared with those from former experiments, carried out before the Chernobyl accident. There is a good agreement for cereals (with exception of rye) fruit vegetables and fodder crops, while actual TF are substantially lower for potatoes, leaf and root vegetables, but higher for rye. A significant negative correlation was observed between the TF and the soil activity concentrations for 137 Cs. In container experiments the TF were found to be influenced mainly by the clay content of the soil. 11 refs., 2 figs., 2 tabs. (Authors)

The effects of plant traits and phylogeny on soil-to-plant transfer of 99Tc

International Nuclear Information System (INIS)

Willey, N.J.; Tang, S.; McEwen, A.; Hicks, S.

2010-01-01

Assessments of the behaviour of 99 Tc in terrestrial environments necessitate predicting soil-to-plant transfer. An experiment with 116 plant taxa showed that 99 Tc transfer to plants was positively related to plant dry weight but negatively related to % dry matter and age at exposure. Activities of 99 Tc analysed by hierarchical ANOVA coded with an angiosperm phylogeny revealed significant effects, with 55% of the variance between species explained at the Ordinal level and above. Monocots had significantly lower transfer of 99 Tc than Eudicots, within which Caryophyllales > Solanales > Malvales > Brassicales > Asterales > Fabales. There was a significant phylogenetic signal in soil-to-plant transfer of 99 Tc. This phylogenetic signal is used to suggest that, for example, a nominal Tc Transfer Factor of 5 could be adjusted to 2.3 for Monocots and 5.3 for Eudicots.

Soil-to-Plant Transfer Factors of {sup 99}Tc for Korean Major Upland Crops

Energy Technology Data Exchange (ETDEWEB)

Choi, Yong Ho; Lim, Kwang Muk; Jun, In; Keum, Dong Kwon [Korea Atomic Energy Reserach Institute, Daejeon (Korea, Republic of)

2011-12-15

In order to investigate the soil-to-plant transfer factor (TF) of {sup 99}Tc for Korean major upland crops (soybean, radish and Chinese cabbage), pot experiments were performed in a greenhouse. Soils were collected from four upland fields (two for soybean and two for radish and Chinese cabbage) around Gyeongju radioactive-waste disposal site. Three to four weeks before sowing, dried soils were mixed with a {sup 99}Tc solution and the mixtures were put into pots and irrigated. TF values were expressed as the ratios of the {sup 99}Tc concentrations in plants (Bq kg{sup -1}-dry or fresh) to those in soils (Bq kg{sup -1}-dry). There was no great difference in the TF value between soils. The TF values for soybean seeds were extremely lower than those for the straws, indicating a very low mobility of {sup 99}Tc to seeds. As representative TF values of{sup 99}Tc,1.8 X 10{sup -1}, 1.2 X 10{sup 1}, 3.2 X 10{sup 2} and 1.3 X 10{sup 2} (for dry plants), arithmetic means for two soils, were proposed for soybean seeds, radish roots, radish leaves and Chinese cabbage leaves, respectively. In the case of the vegetables, proposals for fresh plants were also made. The proposed values are not sufficiently representative so successive updates are needed.

Transfer of 137Cs, essential and trace elements from soil to potato plants in an agricultural field

International Nuclear Information System (INIS)

Tsukada, H.; Hasegawa, H.

2000-01-01

The concentrations of 137 Cs, essential and trace elements were measured in soils and potato tubers collected from 26 agricultural fields in Aomori, Japan, and soil-to-potato transfer factors were determined. The elements were divided into two groups. The first group (Cl, K, Ca, etc.) showed an inverse correlation between the transfer factors and the concentrations of the elements in the soils, while for the second group (Sc, Co, etc.) the transfer factors were independent of the soil concentrations of the elements. The transfer factors of 137 Cs (0.0037-0.16), derived from global fallout, were well correlated with those of naturally stable Cs (0.00052-0.080). These transfer factors showed a negative correlation with the soil concentrations of K and Cs, but they were independent of the organic material contents in the soils. These results suggest that the transfer of stable Cs could serve as a natural analog to predict the behavior of radiocesium in the soil-plant pathway. The distributions of these elements were determined for the entire potato plant. The concentrations of the elements were lower in the tubers than in leaves, petioles and stems. During the harvesting of potatoes the elements in the non-edible portions of the potato plants are returned to the soil, where they may again be utilized in the soil-potato pathways. Therefore, the distributions of elements in plant components can provide useful information for understanding the transfer of radionuclides and elements from the soil to plants in agricultural fields. The concentration ratios for Sr/Ca in potato plant components showed relatively constant values while those for Cs/K varied. These findings suggest that the translocation rates of both Ca and Sr were similar within a potato plant, whereas those of K and Cs were different. Consequently, the transfers of both Ca and Sr may predict the behavior of radiostrontium. The transfer of Cs could be used to predict the behavior of radiocesium, whereas the

Application of of artificial neural networks for estimation of soil-plant transfer factor for "1"3"7Cs

International Nuclear Information System (INIS)

Santos, Anna Karla Gomes dos

2016-01-01

The knowledge of radionuclide behavior in soils is fundamental to calculate the dose due to food ingestion and to evaluate the risks of radioactive exposure of the population. This knowledge associated to the socio-economic characteristics of the affected region will set the radio protective measures to be taken in case of radioactive contamination of rural areas. The soil-plant transfer factor (TF) is the specific parameter value of radiological models to numerically integrate the dynamic processes that occur within the radionuclides in the soil plant system. This measurement, specific to each radionuclide and soil type, is defined ratio between a specific radionuclide activity in the edible part of the plant and its soil activity. However, the absence of linearity between soil concentrations and the measurements in plants indicate the complexity of the transfer process of radionuclide from soil to a plant, making it difficult to forecast the TF ratio in a specific scenario. One of the main radionuclides associated to nuclear accidents impacting rural areas is "1"3"7Cs. This is one of the most worrisome radionuclides because of its physiochemical properties and its chemical similarity with potassium (K) and its extended physical mid-life (t1/2 = 30,17 years) that allows great environmental dispersion, ecological mobility and environmental endurance. Radiological studies related to "1"3"7Cs transfer factor show that pedological parameters that considerably explain the behavior of "1"3"7Cs in soil-plant system are: exchangeable K, clayed minerals, organic matter content and pH in soils. In this work, the computational method of artificial neural network (ANN) was applied to evaluate the possibility to forecast the TF of "1"3"7Cs in cereals, associated to pedological parameters considered potential indicators of its phyto availability: cationic exchange capacity (CEC), exchangeable K and pH. This study demonstrated that the ANN, having only as entry data the

Soil-to-plant concentration factors for radiological assessments

International Nuclear Information System (INIS)

Ng, Y.C.; Thompson, S.E.; Colsher, C.S.

1982-09-01

This report presents the results of a literature review to derive soil-to-plant concentration factors to predict the concentration of a radionuclide in plants from that in soil. The concentration factor, B/sub v/ is defined as the ratio of the concentration of a nuclide in the edible plant part to that in dry soil. CR (the concentration ratio) is similarly defined to denote the concentration factor for dry feed consumed by livestock. B/sub v/ and CR values are used to assess the dose from radionuclides deposited onto soil and transferred into crop plants via roots. Approaches for deriving B/sub v/ and CR values are described, and values for food and feed are tabulated for individual elements. The sources of uncertainty are described, and the factors that contribute to the inherent variability of the B/sub v/ and CR values are discussed. Summary tables of elemental B/sub v/ and CR values and statistical parameters that characterize their distributions provide a basis for a systematic updating of many of the B/sub v/ values in Regulatory Guide 1.109. They also provide a basis for selecting B/sub v/ and CR values for other applications that involve the use of equilibrium models to predict the concentration of radionuclides in plants from that in soil

Hg transfer from contaminated soils to plants and animals

NARCIS (Netherlands)

Rodrigues, S.M.; Henriques, B.; Reis, A.T.; Duarte, A.C.; Pereira, E.; Romkens, P.F.A.M.

2012-01-01

Understanding the transfer of mercury (Hg) from soil to crops is crucial due to Hg toxicity and Hg occurrence in terrestrial systems. Previous research has shown that available Hg in soils contributes to plant Hg levels. Plant Hg concentrations are related to soil conditions and plant

Results of field studies on 90SR and stable SR soil-to-plant transfer

International Nuclear Information System (INIS)

Gerzabek, M.H.; Artner, C.; Horak, O.; Mueck, K.

1992-01-01

In 1987 and 1988 at 35 sites plants ready to harvest and the corresponding soils (0 - 20 cm) were collected for 90 Sr and stable strontium analyses. Sample preparation and measurement led to a detection limit of 0.008 Bq 90 Sr kg -1 . The 90 Sr-contamination of Austrian soils ranged from 396 to 1998 Bq m -2 . Known from literature the contribution of the Chernobyl fallout amounted to app. 25 % of the total contamination. Stable strontium contents of the soils were between 6 and 62.5 mg kg -1 . Bariumtriethanolamine extracted 17.7 to 62.3 % of the total stable Sr in soil. 90 Sr-concentrations in cereal grains ranged from 0.03 to 0.67 Bq kg -1 (fresh wight) for maize and barley, respectively. The values for other foodstuff were between 0.15 (white cabbage) and 0.91 Bq kg -1 (spinach). Stable strontium contents were between 0.079 mg kg -1 (maize) and 72.5 mg kg -1 (celery shoot). The following mean 90 Sr soil-to-plant transfer factors for cereal grains were obtained: 0.010 (maize), 0.097 (rye), 0.049 (wheat), 0.095 (barley). Transfer factors for straw were up to 50 times higher (maize). The transfer of 90 Sr into vegetables and potatoes reached the same order of magnitude compared to the cereals. In all cases soil-to-plant transfer of stable Sr was clearly lower up to 60 % of the respective values for 90 Sr. Thus natural stable strontium is less plant available than 90 Sr. The influence of soil parameters on the 90 Sr transfer into plants was examinated by correlation analyses. Increasing exchangeable calcium contents of the soils resulted in a significant reduction of Sr soil-to-barley straw transfer. (authors)

Effects of soil's properties on transfer of 137Cs to rice plants through plant uptake after soil deposition

International Nuclear Information System (INIS)

Keum, Dong-Kwon; Lee, Hansoo; Kang, Hee-Seok; Jun, In; Choi, Yong-Ho; Lee, Chang-Woo

2007-01-01

This paper presents a dynamic compartment model to appraise the concentration of 137 Cs in agricultural plants as a result of a soil deposition. The present model used the Absalom model as a module to account for the effects of a soil's properties (pH, soil clay content, organic matter content, and exchangeable potassium) on a plant uptake, and the leaching and fixation process of 137 Cs in a soil. The model was tested by comparing the model predictions of the 137 Cs aggregated transfer factors for rice plants with those obtained as results of simulated 137 Cs soil deposition experiments with seventeen paddy soils of different properties, all of which were performed before a transplanting of the rice. Predicted 137 Cs TF a values of the rice plants were found to be comparable with those observed. (author)

Characteristics of soil-to-plant transfer of elements relevant to radioactive waste in boreal forest

Energy Technology Data Exchange (ETDEWEB)

Roivainen, P.

2011-07-01

The use of nuclear energy generates large amounts of different types of radioactive wastes that can be accidentally released into the environment. Soil-to-plant transfer is a key process for the dispersion of radionuclides in the biosphere and is usually described by a concentration ratio (CR) between plant and soil concentrations in radioecological models. Our knowledge of the soil-to-plant transfer of many radionuclides is currently limited and concerns mainly agricultural species and temperate environments. The validity of radioecological modelling is affected by the accuracy of the assumptions and parameters used to describe soil-to-plant transfer. This study investigated the soil-to-plant transfer of six elements (cobalt (Co), molybdenum (Mo), nickel (Ni), lead (Pb), uranium (U) and zinc (Zn)) relevant to radioactive waste at two boreal forest sites and assessed the factors affecting the CR values. May lily (Maianthemum bifolium), narrow buckler fern (Dryopteris carthusiana) and blueberry (Vaccinium myrtillus) were selected as representatives of understory species, while rowan (Sorbus aucuparia) and Norway spruce (Picea abies) represented trees in this study. All the elements studied were found to accumulate in plant roots, indicating that separate CR values for root and aboveground plant parts are needed. The between-species variation in CR values was not clearly higher than the within-species variation, suggesting that the use of generic CR values for understory species and trees is justified. No linear relationship was found between soil and plant concentrations for the elements studied and a non-linear equation was found to be the best for describing the dependence of CR values on soil concentration. Thus, the commonly used assumption of a linear relationship between plant and soil concentrations may lead to underestimation of plant root uptake at low soil concentrations. Plant nutrients potassium, magnesium, manganese, phosphorus and sulphur were found to

Characteristics of soil-to-plant transfer of elements relevant to radioactive waste in boreal forest

International Nuclear Information System (INIS)

Roivainen, P.

2011-01-01

The use of nuclear energy generates large amounts of different types of radioactive wastes that can be accidentally released into the environment. Soil-to-plant transfer is a key process for the dispersion of radionuclides in the biosphere and is usually described by a concentration ratio (CR) between plant and soil concentrations in radioecological models. Our knowledge of the soil-to-plant transfer of many radionuclides is currently limited and concerns mainly agricultural species and temperate environments. The validity of radioecological modelling is affected by the accuracy of the assumptions and parameters used to describe soil-to-plant transfer. This study investigated the soil-to-plant transfer of six elements (cobalt (Co), molybdenum (Mo), nickel (Ni), lead (Pb), uranium (U) and zinc (Zn)) relevant to radioactive waste at two boreal forest sites and assessed the factors affecting the CR values. May lily (Maianthemum bifolium), narrow buckler fern (Dryopteris carthusiana) and blueberry (Vaccinium myrtillus) were selected as representatives of understory species, while rowan (Sorbus aucuparia) and Norway spruce (Picea abies) represented trees in this study. All the elements studied were found to accumulate in plant roots, indicating that separate CR values for root and aboveground plant parts are needed. The between-species variation in CR values was not clearly higher than the within-species variation, suggesting that the use of generic CR values for understory species and trees is justified. No linear relationship was found between soil and plant concentrations for the elements studied and a non-linear equation was found to be the best for describing the dependence of CR values on soil concentration. Thus, the commonly used assumption of a linear relationship between plant and soil concentrations may lead to underestimation of plant root uptake at low soil concentrations. Plant nutrients potassium, magnesium, manganese, phosphorus and sulphur were found to

Transfer of 137Cs from soil to plants in different types of soils

International Nuclear Information System (INIS)

Todorovic, D.; Radenkovic, M.; Popovic, D.; Djuric, G.

1998-01-01

The investigations were carried out in two mountainous regions in the West and South region of the country). Three main types of soils were examined: shale, limestone and the mixed type, and several plants: grass, meadow flora, pinewood, blueberries, an endemic species of Mt. Sara and the bioindicators: moss and lichen. The transfer factors lay in the range of 0.1 - 2.0 in dependence on the type of soil and plant (3.0 - 10.0 for the bioindicator plants). The vertical distribution of 13' 7Cs in the first 15 cm layer of the soil indicates a slow migration of Chernobyl cesium through soil, except on riversides where the wash-out effect plays a role. Generally, the concentration of 137 Cs in soils strongly depends on the configuration of the ground

Activity concentration and transfer factor of 40K, from soil to plant and grass to milk/meat in Rajasthan Rawatbhata Site Environment

International Nuclear Information System (INIS)

Menaria, Tejpal; Tiwari, S.N.; Ravi, P.M.; Tripathi, R.M.

2018-01-01

Radionuclide uptake by plants is evaluated by transfer factor (TF) defined as the ratio between plant specific activity (Bqkg -1 fr.wt) and soil specific activity (Bqkg -1 fr.wt). It is widely used for calculating radiological human dose via the ingestion pathway. TF is regarded as one of the most important parameters in environmental safety assessment for nuclear facilities. The absorbance of radioactive substances by plants, man and animals can be direct and indirect. In the direct absorbance the plant, man and animals are directly incorporating the radioactive substances. Indirect presupposes the absorbance of radionuclides through the pathway soil - roots - plant -animal - man. The indirect way of intake is the most important and influences the food for greater period of time. Soil to plant transfer of various radionuclides are known to be affected by soil properties, organic matter content, variety of plant species, climatic condition and cultural practices. Study showed that absorption of 40 K by Cereals and Pulses are higher than vegetable because of smaller contiguity of 40 K with the carriers of the cellular membranes of the plant roots

[sup 60]Co, [sup 63]Ni and [sup 94]Nb soil-to-plant transfer in pot experiments

Energy Technology Data Exchange (ETDEWEB)

Gerzabek, M.H.; Mohamad, S.A.; Mueck, K.; Horak, O. (Austrian Research Centre Seibersdorf (Austria). Div. of Life Sciences)

1994-01-01

Soil-to-plant transfer factors for [sup 60]Co, [sup 63]Ni and [sup 94]Nb were obtained via pot experiments with a Dystric Cambisol and a Calcic Chernozem, both from Lower Austria. Investigated plants were greenrape (Brassica napus oleifera L.), bean (Phaseolus vulgaris L.) and winter wheat (Triticum aestivum L.). The soil-to-plant transfer factors decreased from [sup 63]Ni to [sup 60]Co and [sup 94]Nb. Mean values from all experiments ranged from 1.12 ([sup 63]Ni) to 0.0045 ([sup 94]Nb). The transfer values obtained for [sup 60]Co and [sup 63]Ni are comparable to literature values, but [sup 94]Nb-transfer seems to be lower than previous estimates. All radionuclides showed differences between plant species and plant organs. Transfer values were also dependent on the soil type. (author).

Factors affecting the transfer of radionuclides from the environment to plants

International Nuclear Information System (INIS)

Golmakani, S.; Moghaddam, V.M.; Hosseini, T.

2008-01-01

Much of our food directly or indirectly originates from plant material; thus, detailed studies on plant contamination processes are an essential part of international environmental research. This overview attempts to identify and describe the most important parameters and processes affecting the behaviour of radionuclide transfer to plants. Many parameters influence these processes. These parameters are related to: (1) plant, (2) soil, (3) radionuclide, (4) climate and (5) time. Often there is no boundary between the factors and they are linked to each other. Knowledge of important factors in radionuclide transfer to plants can help to assess and prevent radiological exposure of humans. This knowledge can also help to guide researches and modelling related to transfer of radionuclides to food chain. (authors)

Soil-to-plant, plant-to-milk and plant-to-meat transfers for the Oxi-sols in Tahiti, French Polynesia

International Nuclear Information System (INIS)

Descamps, B.

2006-01-01

French Polynesia is included in the latitude band 10 -30 degrees S.. In this band the total deposition of 137 Cs is about 1000 Bq.m -2; the French tests represent 13 % of this total deposition. The radiological survey of the French Polynesia environment exists since the beginning of the French nuclear program in 1966.It concerns 7 islands: Hiva Oa in the north (10 degrees S), Tubuai in the south (25 degrees S) and, from east to west, Mangareva, Hao, Rangiroa, Tahiti and Maupiti. Tahiti is a recent, high and volcanic island;it is the largest of the French Polynesia as a whole.Under tropical humid climate with heavy rainfalls, high summer temperatures, and excessive air humidity, the strong relief has been considerably eroded with the formation of particular soils, the oxi-sols.On these soils, in the Taravao peninsula, a cattle breeding farm of about 400 hectares has been studied since more than 30 years. Local milk is an important contributor to the ingestion dose in Tahiti and also an excellent item for the determination of the effective decrease of long -lived radionuclides in the environment. During the 1974 -1994 period the long term decrease for milk shows an effective half-live of 14.8 years and an environmental half-live of 24.8 years.In west european zones the effective half-live is about 5 years. To explain this difference we must mainly consider that the pasture zone in Taravao peninsula is a natural area whereas it is semi-natural in Europe. Moreover we assume that a 137 Cs stocking zone exists with very humic soils in some higher summits; a progressive lixiviation of 137 Cs could take place then. For the 1974 -1994 period the effective half live for the beef meat is about 11.5 years against 18.5 years for the environmental half-live. The difference between effective half-live for milk and meat can be explain by a greater collection zone for meat than for milk. The soil-to-plant transfer factor (F.T.) is about 10 (reporting dry matter) for the genus

Soil availability, plant uptake and soil to plant transfer of 99Tc-- A review

International Nuclear Information System (INIS)

Bennett, Roy; Willey, Neil

2003-01-01

The fission yield of 99 Tc from 239 Pu and 235 U is similar to that of 137 Cs or 90 Sr and it is therefore an important component of nuclear weapons fall-out, nuclear waste and releases from nuclear facilities. There is particular current interest in 99 Tc transfer from soil to plants for: (a) environmental impact assessments for terrestrial nuclear waste repositories, and (b) assessments of the potential for phytoextraction of radionuclides from contaminated effluent and soil. Vascular plants have high 99 Tc uptake capacity, a strong tendency to transport it to shoot material and accumulate it in vegetative rather than reproductive structures. The mechanisms that control 99 Tc entry to plants have not been identified and there has been little discussion of the potential for phytoextraction of 99 Tc contaminated effluents or soil. Here we review soil availability, plant uptake mechanisms and soil to plant transfer of 99 Tc in the light of recent advances in soil science, plant molecular biology and phytoextraction technologies. We conclude that 99 Tc might not be highly available in the long term from up to 50% of soils worldwide, and that no single mechanism that might be easily targeted by recombinant DNA technologies controls 99 Tc uptake by plants. Overall, we suggest that Tc might be less available in terrestrial ecosystems than is often assumed but that nevertheless the potential of phytoextraction as a decontamination strategy is probably greater for 99 Tc than for any other nuclide of radioecological interest

Effect of AFCF on the soil-plant transfer of Cs-134

Energy Technology Data Exchange (ETDEWEB)

Vandenhove, H; Van Hees, M; Vandecasteele, C

1996-09-18

The possible use of ammonium-ferric-hexaCynano-Ferrate (AFCF) as a countermeasure for radiocaesium soil-to-plant transfer is evaluated. On a sandy agricultural soil, an AFCF application dose of 10 and 100 g of AFCF m{sup -2} reduced the radiocaesium transfer to ryegrass with a factor of respectively 25 and 225 without affecting plant growth. Even additions of one gram of AFCF m{sup -2} resulted in a fourfold reduction of the radiocaesium transfer factor. Additions of less than one gram of AFCF m{sup -2} are hardly effective in reducing radiocaesium transfer to ryegrass. Depending on the soil radiocaesium contamination level, the cost of AFCF application can be out-leveled by the benefits due to the decrease averted dose. The decrease in averted dose when man is consuming less contaminated food due to the AFCF application was assessed using a simple cost-benefit model. For a loamy soil with an intrinsically higher radiocaesium fixation capacity than a sandy soil, AFCF additions of 10 g m{sup -2} only reduced transfer with a factor of 3, which is on this soil type only as effective as ploughing in reducing transfer to ryegrass. It is concluded that AFCF application is not recommended as countermeasure for contaminated loamy soils.

Soil Microbial Communities and Gas Dynamics Contribute to Arbuscular Mycorrhizal Nitrogen Uptake and Transfer to Plants

Science.gov (United States)

Hestrin, R.; Harrison, M. J.; Lehmann, J.

2016-12-01

Arbuscular mycorrhizal fungi (AMF) associate with most terrestrial plants and influence ecosystem ecology and biogeochemistry. There is evidence that AMF play a role in soil nitrogen cycling, in part by taking up nitrogen and transferring it to plants. However, many aspects of this process are poorly understood, including the factors that control fungal access to nitrogen stored in soil organic matter. In this study, we used stable isotopes and root exclusion to track nitrogen movement from organic matter into AMF and host plants. AMF significantly increased total plant biomass and nitrogen content, but both AMF and other soil microbes seemed to compete with plants for nitrogen. Surprisingly, gaseous nitrogen species also contributed significantly to plant nitrogen content under alkaline soil conditions. Our current experiments investigate whether free-living microbial communities that have evolved under a soil nitrogen gradient influence AMF access to soil organic nitrogen and subsequent nitrogen transfer to plants. This research links interactions between plants, mycorrhizal symbionts, and free-living microbes with terrestrial carbon and nitrogen dynamics.

Will global warming affect soil-to-plant transfer of radionuclides?

International Nuclear Information System (INIS)

Dowdall, M.; Standring, W.; Shaw, G.; Strand, P.

2008-01-01

Recent assessments of global climate/environmental change are reaching a consensus that global climate change is occurring but there is significant uncertainty over the likely magnitude of this change and its impacts. There is little doubt that all aspects of the natural environment will be impacted to some degree. Soil-to-plant transfer of radionuclides has long been a significant topic in radioecology, both for the protection of humans and the environment from the effects of ionising radiation. Even after five decades of research considerable uncertainty exists as to the interplay of key environmental processes in controlling soil-plant transfer. As many of these processes are, to a lesser or greater extent, climate-dependent, it can be argued that climate/environmental change will impact soil-to-plant transfer of radionuclides and subsequent transfers in specific environments. This discussion attempts to highlight the possible role of climatic and climate-dependent variables in soil-to-plant transfer processes within the overall predictions of climate/environmental change. The work is speculative, and intended to stimulate debate on a theme that radioecology has either ignored or avoided in recent years

Soil to plant transfer factors for Cs-137 and Pu-239+240 determined by field and glasshouse measurements in Great Britain

International Nuclear Information System (INIS)

Cawse, P.A.; Baker, S.J.

1984-01-01

Further data on soil to plant transfer factors is provided for Cs-137 and Pu-239+240, as an extension of results presented at the previous IUR Workshop at Wageningen in December 1982. Field crops of grass, barley and oats produced in 1982 at 11 locations in Britain were analysed for radionuclides. Analysis of soils that produced these crops showed that they contained 'background' nuclear weapons fallout concentrations of Cs-137 and plutonium which were elevated in regions with high rainfall. Analysis of basic soil properties was also made. In separate experiments, transfer factors were derived for 10 crop plants grown in pot trials under glasshouse conditions. In one trial the soil used contained low concentrations of radionuclides derived from nuclear weapons fallout. In a second trial a brown earth was used, which contained additional radionuclides from long-term deposition by nuclear fuel reprocessing. (orig.)

Direct determination of tellurium in soil and plant samples by sector-field ICP-MS for the study of soil-plant transfer of radioactive tellurium subsequent to the Fukushima Daiichi Nuclear Power Plant accident

International Nuclear Information System (INIS)

Yang, Guosheng; Zheng, Jian; Tagami, Keiko; Uchida, Shigeo

2013-01-01

The Fukushima Daiichi Nuclear Power Plant (FDNPP) accident caused the release of large amounts of radioactive Te into the environment. Stable Te, as an analogue, is considered to be useful for the estimation of the soil-plant transfer of radioactive Te. It is necessary to estimate the radiation dose of Te that would result from food ingestion. However, due to the extremely low concentrations of Te in the environment, reported transfer factor values for Te are considerably limited. We report a sensitive analytical method for direct determination of trace Te in soil and plant samples using a sector-field inductively coupled plasma mass spectrometry (SF-ICP-MS). The developed analytical method is characterized by a very low detection limit at the sub-parts per billion (ng g"-"1) level in soil and plant samples, and it has been applied to the study of soil-plant transfer to collect transfer factor data in Japan. (author)

Caesium Radionuclide Uptake from Wet Soil to Kangkung Plant (Ipomoea sp)

International Nuclear Information System (INIS)

Putu Sukmabuana; Poppy Intan Tjahaja

2009-01-01

Caesium radionuclide transfer from soil to kangkung plant (Ipomoea sp) generally consumed by people had been examined to obtain transfer factor value for internal radiation dose assessment via soil-plant-human pathway. The kangkung plants were cultivated on watered soil medium containing 134 Cs with concentration of about 80 Bq/g, and the 134 Cs uptake by plants, i.e root, stem, and leaves, were measured using gamma spectrometer. The 134 Cs plant uptake was expressed as transfer factor, i.e. ratio of plant 134 Cs concentration to 134 Cs concentration on soil medium. From this research it was obtained transfer factor value of 134 C from soil to plant is 0.07, and the transfer factor for root, stem, and leaves are 0.34 ; 0.05 ; 0,03 respectively, after 45 days cultivation. The transfer factor values are less than one, indicate that kangkung plant do not accumulate Cs radionuclide from soil. (author)

Evaluation and development of soil values for the pathway 'soil to plant'. Transfer factors soil to plant; Ueberpruefung und Fortentwicklung der Bodenwerte fuer den Boden-Pflanze-Pfad. Teilbericht 1: Transferfaktoren Boden-Pflanze

Energy Technology Data Exchange (ETDEWEB)

Trapp, S.; Matthies, M.; Reiter, B.; Gaeth, S.

2001-10-01

Within the research project 'Ueberpruefung und Fortentwicklung der Bodenwerte fuer den Boden-Pflanzen-Pfad', transfer factors soil to plant were calculated for compounds of the substance classes PCB and PAH. Literature studies, experiments undertaken by the LUA/Essen at the lysimeter research station Waldfeucht, and model simulations were used. The transfer differs for the plant species. For kale and wheat straw, the dominant uptake is from air. For lettuce and spinach, a significant uptake from soil was found. The main transport seems to occur via soil resuspension and volatilization, followed by sorption to leaf surfaces. These processes act mainly on low growing harvest products. Uptake from the soil solution and translocation within the plant do not seem to play a role except for phenanthren. The carrots and potatoes investigated showed only a contamination of the peel. The transfer factors of the PCB were throughout higher than that of the PAH. We assume that photolytic processes of PAH on plant surfaces are responsible. Furthermore, there are hints in literature that the metabolism of PAH in plants is faster than that of the PCB. (orig.) [German] Im Rahmen des Forschungsvorhabens 'Ueberpruefung und Fortentwicklung der Bodenwerte fuer den Boden-Pflanze-Pfad' wurden fuer organische Schadstoffe aus den Stoffklassen PCB und PAK Transferfaktoren Boden-Pflanze errechnet. Hierzu wurden Literaturstudien, Experimente der LUA von der Lysimeteranlage Waldfeucht sowie Modellsimulationen eingesetzt. Der Transfer ist fuer die untersuchten Pflanzen nicht einheitlich. Fuer Gruenkohl und Weizenstroh wurde eine Dominanz des Eintrags aus der Luft festgestellt. Demgegenueber zeigte sich fuer Salatpflanzen und Spinat deutliche Aufnahme aus dem Boden. Als Haupttransportweg werden Resuspension von Bodenpartikeln und Ausgasung aus dem Boden mit nachfolgender Sorption an Blattflaechen vermutet. Diese Prozesse wirken vorwiegend auf niedrig wirkende Ernteprodukte

Study of the possibility of attenuating soil-plant transfer after an accident, by application of manure to the soil and by foliar spraying

International Nuclear Information System (INIS)

Grauby, Andre; Jouve, Andre; Legrand, Bernard

1990-01-01

This study focuses on the possibility of attenuating soil to plant transfer factor of cesium and strontium by fertilisation. It is based on the correlation analysis of the transfer factor and stable element levels in soils. Results for potassium and cesium show that in most of the soils studied a supply of 5000 Kg of K2S04 per hectare allows a division of the transfer factor to beans by a factor of 10. In the soils with a low cationic exchange capacity, an excess addition of potassium produces an increase in the transfer factor. The ammonium phosphate supply in all soils produces an increase of the transfer factor of cesium to grass. The calcium and potassium supply which affect the transfer factor of cesium do not affect that of strontium. The foliar supply of potassium to bean leaves leads to a reduction of pod contamination by a factor 2. (author)

Transfer of technetium from soil to paddy and upland rice

International Nuclear Information System (INIS)

Yanagisawa, Kei; Muramatsu, Yasuyuki

1995-01-01

Soil-plant transfer factors (concentration ratio between the plant and soil) of technetium in paddy and upland rice plants were obtained from laboratory experiments. The transfer factor is one of the most important parameters for environmental radiation dose assessment. Technetium tracer ( 95m TcO 4 - ) was added to the soil prior to rice cultivation. The transfer factor of technetium for the hulled grains (brown rice) of paddy rice (≤0.0002) was much lower than for that of upland rice (0.021). The transfer factors for both types of hulled grains were much lower than in the leaves. The technetium decontamination rate from hulled grains by polishing was 34%, the percentage of the weight decrease being 12%. The concentration of technetium in the soil solution collected from the paddy rice soil (flooded conditions) decreased rapidly with time due to its adsorption on the soil. In the upland rice soil (non-flooded) solution, the decrease in the technetium concentration was fairly slow. The low transfer factors for the paddy rice plants could be explained by the immobilization of technetium in the flooded soil. The oxidation-reduction potentials (Eh) in the flooded soil decreased rapidly with time. We conclude that technetium tracer added as TcO 4 - to flooded soil is readily transformed to an insoluble form (e.g.TcO 2 ) under the reducing conditions provided by flooding. (author)

Soil-plant transfer factors of radionuclides in mangroves in the State of Pernambuco, Brazil

International Nuclear Information System (INIS)

Paiva, J.D.S.; França, E.J. de

2017-01-01

Mangroves are the main inputs of chemical substances, considering the Brazilian estuarine environments. Natural radionuclides such as 40 K and 228 Ra can be transferred to vegetation. The objective of this work is to determine the transfer factors (TF) and aggregate transfer (TF ag ) of radionuclides 40 K and 228 Ra in the soil-plant system of mangroves in the State of Pernambuco , Brazil. Concentrations of 40 K and 228 Ra activity in the soil of mangroves and in samples composed of leaves of individuals of the native plant species Rhizophora mangle, Laguncularia racemosa and Aviccenia Schaueriana were determined from Gamma Spectrometry with hyper-pure germanium detector (HPGe). The transfer and aggregate transfer factors were calculated according to the methodology proposed in the literature. The respective TF and TF ag values for the 40 K radionuclide were 0.384 and 2.13 x 10 -3 for R. mangle; 0.394 and 2.05 x 10 -3 for L. racemosa and 1.348 and 3.44 x 10 -3 for Avicennia sp. For the radionuclide 228 Ra, the results were lower for R. mangle (TF = 0.089; TF ag = 1.95 x 10 -4 ) and L. race-mosa (TF = 0.142; TF ag = 3.46 x 10 -4 ). For Avicennia schaueriana, the concentrations of 228 Ra activity in the leaves were below the detection limit. The TF values found demonstrated a greater 40 K transfer in Avicennia and 228 Ra dominated mangroves for mangroves where the L. racemosa distribution predominates

Transfer factors of 137Cs and 9Sr from soil to trees in arid regions

International Nuclear Information System (INIS)

Al-Oudat, M.; Asfary, A.F.; Mukhalallti, H.; Al-Hamwi, A.; Kanakri, S.

2006-01-01

Transfer factors of 137 Cs and 9 Sr from contaminated soil (Aridisol) to olive, apricot trees and grape vines were determined under irrigated field conditions for four successive years. The transfer factors (calculated as Bq kg -1 dry plant material per Bq kg -1 dry soil) of both radionuclides varied among tree parts and were highest in olive and apricot fruits. However, the values for 9 Sr were much higher than those for 137 Cs in all plant parts. The geometric mean of the transfer factors in olives, apricots and grapes were 0.007, 0.095 and 0.0023 for 137 Cs and 0.093, 0.13 and 0.08 for 9 Sr, respectively, and were negligible in olive oil for both radionuclides. The transfer factors of both radionuclides were similar to, or in the lower limits of, those obtained in other areas of the world. This could be attributed to differences in soil characteristics: higher pH, lower organic matter, high clay content, and higher exchangeable potassium and calcium

An analysis of domestic experimental results for soil-to-crops transfer factors of radionuclides

Energy Technology Data Exchange (ETDEWEB)

Jun, In; Choi, Young Ho; Keum, Dong Kwon; Kang, Hee Seok; Lee, Han Soo; Lee, Chang Woo [KAERI, Daejeon (Korea, Republic of)

2006-12-15

For more realistic assessment of Korean food chain radiation doses due to the operation of nuclear facilities, it is required to use domestically produced data for radionuclide transfer parameters in crop plants. This paper analyzed results of last about 10 year's studies on radionuclide transfer parameters in major crop plants by the Korean Atomic Energy Research Institute, comparing with the published international data, and consequently suggested the proper parameters to use. The trends of transfer parameter shows normal distributions if we have a lot of experimental data, but some radionuclides showed enormous variations with the environment of experimental, crops and soils. These transfer factors can be used to assess realistic radiation doses or to predict the doses in crops for normal operation or accidental release. Some kinds of parameter can be produced as conservatives or fragmentary results because soil-to-plant transfer factors were measured through greenhouse experiments which sometimes showed improper field situations. But these parameters mentioned in this paper can be representative of the status of Korean food chain than that of foreign country.

An analysis of domestic experimental results for soil-to-crops transfer factors of radionuclides

International Nuclear Information System (INIS)

Jun, In; Choi, Young Ho; Keum, Dong Kwon; Kang, Hee Seok; Lee, Han Soo; Lee, Chang Woo

2006-01-01

For more realistic assessment of Korean food chain radiation doses due to the operation of nuclear facilities, it is required to use domestically produced data for radionuclide transfer parameters in crop plants. This paper analyzed results of last about 10 year's studies on radionuclide transfer parameters in major crop plants by the Korean Atomic Energy Research Institute, comparing with the published international data, and consequently suggested the proper parameters to use. The trends of transfer parameter shows normal distributions if we have a lot of experimental data, but some radionuclides showed enormous variations with the environment of experimental, crops and soils. These transfer factors can be used to assess realistic radiation doses or to predict the doses in crops for normal operation or accidental release. Some kinds of parameter can be produced as conservatives or fragmentary results because soil-to-plant transfer factors were measured through greenhouse experiments which sometimes showed improper field situations. But these parameters mentioned in this paper can be representative of the status of Korean food chain than that of foreign country

Prediction of Radionuclide transfer based on soil parameters: application to vulnerability studies

International Nuclear Information System (INIS)

Roig, M.; Vidal, M.; Rauret, G.

1998-01-01

The multi factorial character of the radiocaesium and radiostrontium soil-to-plan transfer, which depends on the radionuclide level in the soil solution amplified by a plant factor, prevents from establishing univariate relationships between transfer factors and soil and/or plant parameters. The plant factor is inversely proportional to the level of competitive species in the soil solution (Ca and Mg, for radiostrontium, and K and NH 4 for radiocaesium). Radionuclide level in soil solution depends on the radionuclide available fraction and its distribution coefficient. For radiostrontium, this may be obtained from the Cationic Exchange Capacity (CEC), whereas for radiocaesium the Specific Interception Potential should be calculate, both corrected by the concentrations of the competitive species and selectivity coefficients. Therefore, the transfer factor eventually depends on soil solution composition, the available fraction and the number of sorption sites, as well as on the plant factor. For a given plant, a relative sequence of transfer can be set up based solely on soil parameters, since the plant factor is cancelled. This prediction model has been compared with transfer data from experiments with Mediterranean, mineral soils, contaminated with a thermo generated aerosol, and with podzolic and organic soils, contaminated by the Chernobyl fallout. These studies revealed that it was possible to predict a relative scale of transfer for any type of soil, also allowing a scale of soil vulnerability to radiostrontium and radiocaesium contamination to be set up. (Author)

A versatile model for tritium transfer from atmosphere to plant and soil

International Nuclear Information System (INIS)

Melintescu, A.; Galeriu, D.

2004-01-01

The need to increase the predictive power of risk assessment for large tritium releases implies a process level approach for model development. Tritium transfer for atmosphere to plant and the conversion in organically bound tritium depend strongly on plant characteristics, season, and meteorological conditions.In order to cope with this large variability and to avoid also, expensive calibration experiments, we developed a model using knowledge of plant physiology, agro-meteorology, soil sciences, hydrology, and climatology. The transfer of tritiated water to plant is modelled with resistance approach including sparse canopy. The canopy resistance is modelled using Jarvis-Calvet approach modified in order to directly use the canopy photosynthesis rate.The crop growth model WOFOST is used for photosynthesis rate both for canopy resistance and formation of organically bound tritium, also. Using this formalism, the tritium transfer parameters are directly linked to known processes and parameters from agricultural sciences. The model predictions for tritium in wheat are closed to a factor two to experimental data without any calibration. The model also is tested for rice and soya bean and can be applied for various plants and environmental conditions. For sparse canopy the model uses coupled equations between soil and plants. (author)

Transfer factors of some selected radionuclides (radioactive Cs, Sr, Mn, Co and Zn) from soil to leaf vegetables

International Nuclear Information System (INIS)

Ban-nai, Tadaaki; Muramatsu, Yasuyuki; Yanagisawa, Kei

1995-01-01

Transfer factors of radionuclides from soil to leaf vegetables (cabbage, Chinese cabbage, komatsuna, spinach and lettuce) have been studied by radiotracer experiments using Andosol as a representative of Japanese soils. The transfer factors of radioactive Cs, Sr, Mn, Co and Zn for edible parts of vegetables (average of five vegetables) were 0.11, 0.24, 0.61, 0.05 and 0.52, respectively. These values should be used in safety assessment for Japanese agricultural environment. The transfer factors of Mn, Co and Zn for spinach were higher than those for the other vegetables. The transfer factors of Cs for different organs of the leaf vegetables were rather homogeneous. The transfer factors of Sr and Mn were higher for older (outer) leaves than younger (inner) ones. In contrast to Sr and Mn, transfer factors of Zn for younger leaves were higher than those for older ones. The distribution ratios of the elements between soil-solution and soil were in the order Sr>Mn>Cs>Co>Zn, whereas the distribution ratios of the elements between plant and soil-solution were in the order Zn>Cs>Mn>Co>Sr. These results indicate that the selectivity for Sr by plants from the soil-solution was low and that for Zn was very high. (author)

Radionuclide transfer from soil to plants

International Nuclear Information System (INIS)

Teufel, D.; Steinhilber-Schwab, B.; Hoepfner, U.; Ratka, R.; Sand, H. van de; Franke, B.

1979-01-01

The planned nuclear reprocessing plant (NEZ) Gorleben will fundamentally differ from actually operating nuclear power plants with regard to its radioactive emissions because relatively long-life isotopes will play a greater role in the emissions. The longevity of the radionuclides emitted in the planned NEZ implies that there will be an accumulation of radionuclides in the surroundings of the plant and long-term effects of the plant on the environment will get higher significance. As radionuclides mainly reach milk and meat via the food of farm animals the transfer of cesium and strontium from the ground into plants was amply investigated. The results show that the correlation calculations are suitable to describe the effect of different parameters on the transfer factor. They are not suited for a forecast of the transfer conditions on a certain location for the reasons explained before. Location-specific measurements seem to be indispensable for these purposes. Besides the greenhouse tests open air measurements of fall-out nuclides with and without elimination of external contamination seem to represent a realistic possibility for the determination of transfer factors. Great attention has to be paid in this kind of tests to the growth conditions (especially fertilization) which have to be accurately registered. (orig./MG) [de

Soil to rice transfer factors for 210Pb: a study on rice grown in India

International Nuclear Information System (INIS)

Karunakara, N.; Rao, Chetan; Ujwal, P.; Yashodhara, I.; Sudeep Kumara; Somashekarappa, H.M.; Bhaskara Shenoy, K.; Ravi, P.M.

2013-01-01

India is the second largest producer of rice (Oryza sativa L.) in the world and rice is the essential component of the diet for the majority of the population of India. However, detailed studies aimed at evaluation of radionuclide transfer factors (F v ) for rice grown in India are almost non-existent. This paper presents soil to rice transfer factors for 210 Pb for rice grown in natural field conditions on the West Coast of India. A rice field was developed very close to the Kaiga nuclear power plant for the field studies. For a comparative study of radionuclide transfer factors, rice samples were also collected from the rice fields of nearby villages. The soil to un-hulled rice grain 210 Pb varied in the range <1.2 x10 -2 to 8.1 x 10 -1 with a mean of 1.4 x 10 -1 . The mean values of un-hulled grain to white rice processing retention factors (F r ) was 0.03 for 210 Pb. Using the processing retention factors the soil to white rice transfer factor was estimated and found to have the mean value of 4.2 x 10 -3 . The study has shown that the transfer of 210 Pb was retained in the root and its transfer to above ground organs of rice plant is significantly lower. (author)

A literature review on radioactivity transfer to plants and soil

International Nuclear Information System (INIS)

Nielsen, O.J.

1981-07-01

The literature on transfer of radioactivity to plants and soil have been reviewed. Main emphasis has been placed on the transfer to plants. A general plant transfer model has been set up. Root uptake, dry deposition, wet deposition, weathering, resuspension, and translocation are the transfer processes discussed. Theory and experimental data for evaluating the different pathways are reported. Only iodine-131, strontium-90 and caecium-137 have been considered in the report. Recommendations of specific transfer parameters have been given as realistic as possible. Suggestions for further research have also been given. (author)

Radiocesium storage in soil microbial biomass of undisturbed alpine meadow soils and its relation to 137Cs soil-plant transfer

International Nuclear Information System (INIS)

Stemmer, Michael; Hromatka, Angelika; Lettner, Herbert; Strebl, Friederike

2005-01-01

This study focuses on radiocesium storage in soil microbial biomass of undisturbed alpine meadow sites and its relation to the soil-to-plant transfer. Soil and plant samples were taken in August 1999 from an altitude transect (800-1600 m.a.s.l.) at Gastein valley, Austria. Soil samples were subdivided into 3-cm layers for analyses of total, K 2 SO 4 -extractable and microbially stored 137 Cs. Microbial biomass was measured by the fumigation extraction method, and fungal biomass was quantified using ergosterol as biomarker molecule. In general, the quantity of 137 Cs stored in the living soil microbial biomass was relatively small. At the high-altitude meadows, showing high amounts of fungal biomass, microbially stored 137 Cs amounted to 0.64 ± 0.14 kBq m -2 which corresponds to about 1.2-2.7% of the total 137 Cs soil inventory. At lower altitudes, microbial 137 Cs content was distinctly smaller and in most cases not measurable at all using the fumigation extraction method. However, a positive correlation between the observed soil-to-plant aggregated transfer factor, microbially stored 137 Cs and fungal biomass was found, which indicates a possible role of fungal biomass in the storage and turnover of 137 Cs in soils and in the 137 Cs uptake by plants

Soil-to-plant halogens transfer studies

Energy Technology Data Exchange (ETDEWEB)

Kashparov, V. [Ukrainian Institute of Agricultural Radiology (UIAR), Mashinostroiteley Str.7, Chabany, Kiev Region 08162 (Ukraine); Colle, C. [Institute for Radioprotection and Nuclear Safety (IRSN/DEI/SECRE), Cadarache bat 159, BP 3, 13115 Saint Paul-lez-Durance (France)]. E-mail: claude.colle@irsn.fr; Zvarich, S. [Ukrainian Institute of Agricultural Radiology (UIAR), Mashinostroiteley Str.7, Chabany, Kiev Region 08162 (Ukraine); Yoschenko, V. [Ukrainian Institute of Agricultural Radiology (UIAR), Mashinostroiteley Str.7, Chabany, Kiev Region 08162 (Ukraine); Levchuk, S. [Ukrainian Institute of Agricultural Radiology (UIAR), Mashinostroiteley Str.7, Chabany, Kiev Region 08162 (Ukraine); Lundin, S. [Ukrainian Institute of Agricultural Radiology (UIAR), Mashinostroiteley Str.7, Chabany, Kiev Region 08162 (Ukraine)

2005-07-01

Long-term controlled experiments under natural conditions in the field have been carried out in the Chernobyl Exclusion zone in order to determine the parameters governing radioiodine transfer to plants from four types of soils (podzoluvisol, greyzem and typical and meadow chernozem) homogeneously contaminated in the 20-cm upper layer with an addition of {sup 125}I. An absence of {sup 125}I depletion in arable soil layers due to volatilization was noted up to one year after contamination. During one year, depletion due to the vertical migration of radioiodine from the arable layer of each of the soils did not exceed 4% of the total {sup 125}I content. Radioiodine concentration ratios (CR) were obtained in radish roots, lettuce leaves, bean pods, and wheat grain and straw. The highest CR values were observed in podzoluvisol: 0.01-0.03 for radish roots and lettuce leaves, 0.003-0.004 for bean pods and 0.001 for wheat grains. In the other three soils, these values were one order of magnitude lower. The parameters relating to changes in radioiodine bioavailability were determined, based on the contamination dynamics of plants in field conditions.

Transfer of technetium in the soil-rice plant system

International Nuclear Information System (INIS)

Yanagisawa, K.; Muramatsu, Y.

1995-01-01

In order to assess the behavior of Tc in flooded soil-plant systems, laboratory experiments have been done using 95m Tc as a tracer. Two common soil types in Japan, Andosol and Gray lowland soils, were used. Soil-plant transfer factors of Tc in rice grain were very low, i.e. 5 x 10 -5 for Andosol and 6 x 10 -4 for Gray lowland soil. It was found that the Tc concentrations in rice plants were influenced by those in soil solutions. Concentrations of 95m Tc in both soil solutions decreased rapidly in the early period of cultivation. It was observed that redox-potential (Eh) also decreased markedly following flooding. A relationship was found between the decrease of the 95m Tc concentrations in soil solutions and the drop of Eh in the soils. The Tc (VII) added to soil was transformed to insoluble Tc (IV) under the reduced conditions existing in flooded soil. (author). 10 refs., 2 figs., 4 tabs

Transfer factors of 134Cs for olive and orange trees grown on different soils

International Nuclear Information System (INIS)

Skarlou, V.; Nobeli, C.; Anoussis, J.; Haidouti, C.; Papanicolaou, E.

1999-01-01

Transfer factors (TF) of 134 Cs to olive and citrus trees grown on two different soils, were determined for a 3-year greenhouse experiment. Two-year-old trees were transplanted with their entire rootball into large pots containing the contaminated soil (110 kg pot -1 ). The soil was transferred to each pot in layers on the top of which 134 Cs as CsCl was dripped (18.5 MBq pot -1 ). For both evergreen trees, soil type significantly influenced radiocaesium transfer. 134 Cs concentration was lower for the calcareous-heavy soil than for the acid-light soil. Transfer factors of orange trees were higher than those of olive trees in the acid-light soil. Although a significant amount of 134 Cs was measured in olives grown on the acid-light soil, no 134 Cs was detected in the unprocessed olive oil when an oil fraction (5% f.w.) was extracted. On the contrary the edible part of the oranges showed the highest 134 Cs concentration of all plant parts. The relationship between 134 Cs uptake and potassium content in the different plant compartments was also studied when selected trees were cut down. The potassium concentration in the plants was not significantly different between the trees growing in the two types of soil in spite of the big differences in the 134 Cs uptake in the two soils. TF values and potassium content in the different plant compartments of each tree were highly correlated. For both crops transfer factors as well as potassium content were the highest in the developing plant parts (new leaves and branches, flowers). The transfer factors of 134 Cs for the studied trees are in the same order of magnitude as the values of annual crops grown under similar conditions. (Copyright (c) 1999 Elsevier Science B.V., Amsterdam. All rights reserved.)

Investigation of the soil-to-plant transfer of Np-237, Pu-238, Am-241 and Cm-244

International Nuclear Information System (INIS)

Pimpl, M.

1988-08-01

Inside a greenhouse for radioecological studies the root uptake of Np, Pu, Am, and Cm from 5 different soils into 19 crop plants have been measured. The soils have been artificially contaminated with the 4 nuclides in range from 1-20 Bq/g dry soil. Within 7 vegetation periods about 380 transfer measurements have been performed. The obtained results show that the soil-to-plant transfer is mainly influenced by the following parameters: physical and chemical properties of the different radionuclides, plant species and variety, soil type, time of soil utilization and soil management. The transfer factors measured are compared with those data which are proposed for the calculation of the long term radiation burden of the population by ingestion of contaminated food inside the Federal Republic of Germany. The experiments have been performed from the beginning of 1983 to the end of 1986. The results summarized within this report have already been published in annual reports or as contributions to scientific meetings. (orig.) [de

Cesium-137 in soils and its soil-to-plant transfer rate

International Nuclear Information System (INIS)

Papastefanou, C.; Manolopoulou, M.; Charalambous, S.

1988-01-01

Measurements of fallout-derived 137 Cs in soils were made in the Valley of Ptolemais, North Greece after the Chernobyl nuclear reactor accident. The 137 Cs concentrations ranged between 290 Bq kg -1 and 7670 Bq kg -1 . It was found that the 137 Cs concentration is inversely proportional to 40 K concentration or potassium content of soils. Cesium-137 transfer coefficients from soil to plants (grass) ranged from 0.02 to 0.2

Final report on a field study of soil-to-plant transfer radioactive caesium, strontium and zinc in Tropical Northern Australia

International Nuclear Information System (INIS)

Twining, J.; Payne, T.; Russell, R.; Wilde, K; McOrist, G.; Wong, H.; Shotton, P.; Tagami, K.; Itakura, T.

2003-01-01

Soil-to-plant radionuclide transfer factors for cesium ( 134 Cs), strontium ( 85 Sr) and zinc ( 65 Zn) into sorghum and mung plants grown in tropical Australia have been determined over a four-year study period. The crops were grown on two types of red earth soils. Transfer factors for Cs and Sr are not substantially different from the expected values based on previous studies, reported in the general literature and compiled in the IUR database, mainly performed within temperate climates. In contrast, the values for zinc (Zn) are more than an order of magnitude greater than anticipated. Most of the radioactivity added to the soils has been retained in the top 5 cm of both soils. There has been a general decline in soil-to-plant transfer of Cs and Zn as time has increased

Analytic of elements for the determination of soil->plant transfer factors

International Nuclear Information System (INIS)

Liese, T.

1985-02-01

This article describes a part of the conventional analytical work, which was done to determine soil to plant transfer factors. The analytical methods, the experiments to find out the best way of sample digestion and the resulting analytical procedures are described. Analytical methods are graphite furnace atomic absorption spectrometry (GFAAS) and inductively coupled plasma atomic emission spectrometry (ICP-AES). In case of ICP-AES the necessity of right background correction and correction of the spectral interferences is shown. The reliability of the analytical procedure is demonstrated by measuring different kinds of standard reference materials and by comparison of AAS and AES. (orig./HP) [de

Study of solution speciation, soil retention and soil-plant transfer of zirconium

International Nuclear Information System (INIS)

Ferrand, E.

2005-12-01

Within the framework of the risks prevention policy of Andra, the radioactive zirconium introduction ( 93 Zr and 95 Zr) into the environment could be carried out starting from the nuclear waste whose storage is envisaged in deep geological layers. Thus, the goal of this study was to evaluate the parameters and phenomena influencing speciation (various chemical forms) and the soil-plant transfer of zirconium. Experiments of adsorption/desorption of zirconium with different ligands likely to be present in soils (goethite and humic acid) and with two soils, with contrasted characteristics, close to the underground research laboratory of Andra (Meuse) were carried out. These results of adsorption were then confronted with those obtained by the MUSIC and NICA-DONNAN models carried out using the computer code ECOSAT. Zr presents a strong affinity for the two types of soils and the soils constituents. Specific interactions of internal sphere type with the goethite were highlighted using the model. Soil-solution partition coefficients, or K d , values increase with pH and contact time. Various types of edible plants, pea (Pisum sativum L.) and tomato (Lycopersicon esculentum L cv. St Pierre) were cultivated in hydroponic conditions and in soils spiked with various sources of Zirconium. The maximum zirconium contents are mainly measured in the roots of the plants. The soil-plant transfer factors measured during these experiments show a weak bioavailability of zirconium. An influence of speciation on Zr bioavailability is however highlighted. Some chemical forms, such as oxychloride or acetate, are more easily mobilized than others by the plant. (author)

Linearity assumption in soil-to-plant transfer factors of natural uranium and radium in Helianthus annuus L

International Nuclear Information System (INIS)

Rodriguez, P. Blanco; Tome, F. Vera; Fernandez, M. Perez; Lozano, J.C.

2006-01-01

The linearity assumption of the validation of soil-to-plant transfer factors of natural uranium and 226 Ra was tested using Helianthus annuus L. (sunflower) grown in a hydroponic medium. Transfer of natural uranium and 226 Ra was tested in both the aerial fraction of plants and in the overall seedlings (roots and shoots). The results show that the linearity assumption can be considered valid in the hydroponic growth of sunflowers for the radionuclides studied. The ability of sunflowers to translocate uranium and 226 Ra was also investigated, as well as the feasibility of using sunflower plants to remove uranium and radium from contaminated water, and by extension, their potential for phytoextraction. In this sense, the removal percentages obtained for natural uranium and 226 Ra were 24% and 42%, respectively. Practically all the uranium is accumulated in the roots. However, 86% of the 226 Ra activity concentration in roots was translocated to the aerial part

Linearity assumption in soil-to-plant transfer factors of natural uranium and radium in Helianthus annuus L

Energy Technology Data Exchange (ETDEWEB)

Rodriguez, P. Blanco [Departamento de Fisica, Facultad de Ciencias, Universidad de Extremadura, 06071 Badajoz (Spain); Tome, F. Vera [Departamento de Fisica, Facultad de Ciencias, Universidad de Extremadura, 06071 Badajoz (Spain)]. E-mail: fvt@unex.es; Fernandez, M. Perez [Area de Ecologia, Departamento de Fisica, Facultad de Ciencias, Universidad de Extremadura, 06071 Badajoz (Spain); Lozano, J.C. [Laboratorio de Radiactividad Ambiental, Facultad de Ciencias, Universidad de Salamanca, 37008 Salamanca (Spain)

2006-05-15

The linearity assumption of the validation of soil-to-plant transfer factors of natural uranium and {sup 226}Ra was tested using Helianthus annuus L. (sunflower) grown in a hydroponic medium. Transfer of natural uranium and {sup 226}Ra was tested in both the aerial fraction of plants and in the overall seedlings (roots and shoots). The results show that the linearity assumption can be considered valid in the hydroponic growth of sunflowers for the radionuclides studied. The ability of sunflowers to translocate uranium and {sup 226}Ra was also investigated, as well as the feasibility of using sunflower plants to remove uranium and radium from contaminated water, and by extension, their potential for phytoextraction. In this sense, the removal percentages obtained for natural uranium and {sup 226}Ra were 24% and 42%, respectively. Practically all the uranium is accumulated in the roots. However, 86% of the {sup 226}Ra activity concentration in roots was translocated to the aerial part.

The soil-to-plant transfer of radionuclides. Feasibilities and limits of the transfer concept

International Nuclear Information System (INIS)

Gerzabek, M.H.

1993-01-01

The present paper discusses the simple transfer model. After the Chernobyl fallout in Austria field investigations dealt with the behaviour of radionuclides in the soil-plant system. They led to the following conclusions: (1) A single plowing does not result in a homogeneous radionuclide distribution in the A p horizon. (2) Low plant availability of radionuclides (e.g. 137 Cs) led to a higher contribution of outer contamination (resuspension) to concentrations in plants in the first years after the fallout. Differences arose between high and low contamination areas. This was not true for 90 Sr, which exhibited three to ten times higher transfer factors as compared to 137 Cs. (3) The contamination source has a distinct impact on the plant availability of radionuclides. (4) In semi-natural environments radiocaesium can be bound to the biomass to a great extent, which results in significantly higher biological half-lives as compared to agricultural ecosystems. (author)

Soil plant transfer coefficient of 14C-carbofuran in brassica sp. vegetable agroecosystem

International Nuclear Information System (INIS)

Nashriyah Mat; Mazleha Maskin; Kubiak, R.

2006-01-01

The soil plant transfer coefficient or f factor of 14 C-carbofuran pesticide was studied in outdoor lysimeter experiment consisting of Brassica sp. vegetable crop, riverine alluvial clayey soil and Bungor series sandy loam soil. Soil transfer coefficients at 0-10 cm soil depth were 4.38 ± 0.30, 5.76 ± 1.04, 0.99 ± 0.25 and 2.66 ± 0.71; from IX recommended application rate in alluvial soil, 2X recommended application rate in alluvial soil, IX recommended application rate in Bungor soil and 2X recommended application rate in Bungor soil, respectively. At 0-25 cm soil depth, soil plant transfer coefficients were 8.96 ± 0.91, 10.40 ± 2.63, 2.34 ± 0.68 and 619 ±1.40, from IX recommended application rate in alluvial soil, 2X recommended application rate in alluvial soil, IX recommended application rate in Bungor soil and 2X recommended application rate in Bungor soil, respectively. At 77 days after treatment (DAT), the soil plant transfer coefficient was significantly higher in riverine alluvial soil than Bungor soil whereas shoot and root growth was significantly higher in Bungor soil than in riverine alluvial soil. At both 0-10 cm Brassica sp. rooting depth and 0-25 cm soil depth, the soil plant transfer coefficient was significantly higher in 2X recommended application rate of 14 C-carbofuran as compared to IX recommended application rate, in both Bungor and riverine alluvial soils. (Author)

Transfer-factors for radionuclides in the coal-fired power plants environments in Serbia

International Nuclear Information System (INIS)

Todorovic, Dragana; Jankovic, Marija; Joksic, Jasminka; Radenkovic, Mirjana

2008-01-01

Full text: During the coal combustion in power plants, radionuclides are distributed in solid and gaseous combustion products and discharged into environment. Radioactivity monitoring of coal-fired power-plants environments (PP Nikola Tesla, PP Kolubara, PP Morava and PP Kostolac) in Serbia was carried out during 2003-2006. Here are presented results concerning the soil-plant and ash-plant systems. Plant samples growing at the soil and ash disposals are analyzed by gamma spectrometry (HPGe detector, relative efficiency 23%) and corresponding transfer factors (TF) for natural isotopes 226 Ra, 232 Th and 40 K were calculated and discussed. Obtained concentrations values of naturally occurring radionuclides are in following ranges: (0.4 - 29) Bq/kg 226 Ra, (0.16 - 23) Bq/kg 232 Th, (245 - 1274) Bq/kg 40 K, (1.7 - 30) Bq/kg 238 U, (0.08 - 4.7) Bq/kg 235 U, (5.6 - 95) Bq/kg 210 Pb; (28 - 288) Bq/kg 7 Be and man-made 137 Cs in range 0.06 - 2.8 Bq/kg. Ash-to-plant and soil-to-plant transfer factors for 226 Ra, 232 Th and 40 K are calculated for several sampling points. Values for both ash-to-plant and soil-to-plant transfer factors are much higher for 40 K than 226 Ra and 232 Th probably due to different assimilation mechanisms of these elements by plants. Analyzed radionuclides have higher concentrations in the ash disposal than soil, and corresponding transfer-factors values obtained for ash-plant systems (ranged from 0,007 to 0,179 for 226 Ra, from 0,015 to 0,174 for 232 Th and from 0,418 to 2,230 for 40 K) are higher, indicating that there is no limit value for absorption in plants. (author)

Soil-to-plant transfer of radiocaesium for selected tropical plant species in Bangladesh

International Nuclear Information System (INIS)

Rahman, M.M.; Rahman, M.M.; Koddus, A.; Ahmad, G.U.; Voigt, G.

2005-01-01

Soil-to-plant transfer factors (TF) of radiocaesium ( 137 Cs) were determined under field condition for grassy vegetation grown in Bangladesh at contaminated land in the Atomic Energy Research Establishment (AERE) campus. TF values for rice, grass and grassy/root vegetations grown in the same type of soil were also measured under pot condition. TF values of 137 Cs for grassy vegetation (2.4 x 10 -2 -4.2 x 10 -2 with an average of 3.1 x 10 -2 ± 0.005) obtained under field condition were slightly lower than the values for grass and grassy/root vegetations (2.9 x 10 -2 -6.6 x 10 -2 with an average of 4.8 x 10 -2 ± 0.01 for grass and grassy vegetations and 2.3 x 10 -2 -5.6 x 10 -2 with an average of 4.0 x 10 -2 ± 0.009 for root vegetations, respectively) obtained under pot condition. However, TF values (9.0 x 10 -3 -2.6 x 10 -2 with an average of 1.9 x 10 -2 ± 0.004) obtained for rice were about a factor of 4 lower than the values obtained for grass and grassy/root vegetations. When the properties of the AERE soils as input parameters were used in the soil-plant transfer model of Absalom, the estimated TF values (4.5 x 10 -2 -6.7 x 10 -2 with an average of 5.3 x 10 -2 ± 0.006) were consistent with the measured values obtained for grass and grassy vegetations under pot condition, however, the model overestimates the TF values for rice

Interrelationships of metal transfer factor under wastewater reuse and soil pollution.

Science.gov (United States)

Papaioannou, D; Kalavrouziotis, I K; Koukoulakis, P H; Papadopoulos, F; Psoma, P

2018-06-15

The transfer of heavy metals under soil pollution wastewater reuse was studied in a Greenhouse experiment using a randomized block design, including 6 treatments of heavy metals mixtures composed of Zn, Mn, Cd, Co, Cu, Cr, Ni, and Pb, where each metal was taking part in the mixture with 0, 10, 20, 30, 40, 50 mg/kg respectively, in four replications. The Beta vulgaris L (beet) was used as a test plant. It was found that the metal transfer factors were statistically significantly related to the: (i) DTPA extractable soil metals, (ii) the soil pollution level as assessed by the pollution indices, (iii) the soil pH, (iv) the beet dry matter yield and (v) the interactions between the heavy metals in the soil. It was concluded that the Transfer Factor is subjected to multifactor effects and its real nature is complex, and there is a strong need for further study for the understanding of its role in metal-plant relationships. Copyright © 2017 Elsevier Ltd. All rights reserved.

Soil to plant transfer of 134Cs for olive and orange trees: preliminary results

International Nuclear Information System (INIS)

Skarlou, V.; Nobeli, C.; Anoussis, J.; Papanicolaou, E.; Haidouti, C.

1995-01-01

The objective of this research programme was to calculate values of transfer parameters of 134 Cs from soil to tree crops (olive and orange trees) in a long term glasshouse pot experiment, started in 1994. Radiocaesium contamination in the different tree parts as well as the importance of the storage or cycling of 134 Cs will also be examined. The experiment was conducted in large pots filled with a calcareous, heavy soil (115 kg/pot) where olive and orange trees, two years after grafting were transplanted. The soil was added to the pot in layers ca. 2 cm thick on the top of which the radioactive solution was added in small drops. Caesium-134 as CsCl (0.5 mCi) was added to each pot. The soil in the pots was watered to field capacity and left to stand for eight weeks for the 134 Cs to reach equilibrium. Plant samples were taken at fruit maturity, eight months after transplanting. It is noticed that the length of experimentation is rather short for tree crops and the data should be considered as preliminary ones with indicative tendencies. Under these conditions plant contamination was generally very low in both plant species studied. The concentration ratios (CR) of 134 Cs for the studied crops did not differ much and they ranged from 0.0007 to 0.002 for olive trees and from 0.0006 to 0.001 for orange trees. Leaves compared to other plant parts showed the highest CR value in both crops. Furthermore new leaves and branches of the olive trees showed higher CR values than the old ones by approximately a factor of two. Potassium content of the different plant parts showed significant differences and they were higher in leaves and fruits. There is no correlation between K content and transfer factors of Cs in the different plant parts of both crops. To study the effect of soil type on CRs of 134 Cs for olive and orange trees a similar experiment was established two months later, using a sandy and acid soil. Based on first results, higher values of transfer factors of 134

Transfer of 137Cs to plants from two types of soil

International Nuclear Information System (INIS)

Skowronska-Smolak, M.; Pietrzak-Flis, S.

1994-01-01

Transfer of 137 Cs from soil to plants was studied in two types of soil: sandy soil (I) and sandy loam soil (II). The study was performed on an experimental field for of 1991 (soil I) and for 1992-93 (soil II). Transfer of 137 Cs from soil I was examined for spring barley, spring wheat, red beet, lettuce and kale; transfer from soil II was examined for winter barley, grass, alfalfa, potato tubers, red beet, radish, bean, spinach and lettuce. 137 Cs and potassium in plants and soil were determined using gamma spectrometry. The soils were characterized by particle size distribution and such chemical properties as pH H 2 O , pH KCl , content of organic matter, Ca, Mg and exchangeable K. The concentration of 137 Cs in the soil I was over five times lower than in soil II, being equal to 8.84±0.32 Bq kg -1 and 50.38±2.21 Bq kg -1 , respectively. The soils differ in their chemical characteristics and texture. Soil I contains 6.47±0.21 g kg -1 potassium, 0.147±0.015 g kg -1 exchangeable potassium, 2.21±0.32 g kg -1 Ca, 0.055±0.013 g kg -1 Mg and 1.733% organic matter. Soil II contains 10.87±0.22 g kg -1 potassium, 0.082±0.007 g kg -1 exchangeable potassium, 1.62±0.16 g kg -1 Ca, 0.097±0.009 g kg -1 Mg and 2.307% organic matter; pH H2O of soil I was equal to 7.40 and of soil II - 6.56. The lowest concentrations of 137 Cs for both soils were observed in cereals (spring wheat - 0.67±0.06 Bq kg -1 dw and spring barley - 0.33± Bq kg -1 dw for soil I and winter barley - 0.79±0.20 Bq kg -1 dw for soil II). The highest concentrations of this isotope were found in red beet leaves (9.11±1.38 Bq kg -1 dw for soil I and 16.44±1.14 Bq kg -1 dw for soil II). Transfer of 137 Cs to plants from the sandy loam soil was from about 2 up to about 7 times lower than from the sandy soil. The lower transfer of 137 Cs from soil II to plants in comparison to soil I might be associated with the presence of clay which binds Cs strongly. The strong binding of Cs in soil II can also be

Studies on the Cs 137-transfer in the foodchain soil - plant - milk under the ecological conditions in a given environment

International Nuclear Information System (INIS)

Heine, K.; Wiechen, A.

1979-01-01

Transfer factors of Cs 137 were determined by low-levels measurements of soil, plants and milk in the surroundings of the site of the planned nuclear reprocessing plant near Gorleben. The evaluated transfer factors for the transition soil - plant range between 0.018 and 0.115 (pCi/kg plant wet weight: pCi/kg soil dry weight). Higher values were generally found for sandy soils than for the loamy soils of the lowland near the river Elbe. Because of a possible direct contamination of the plants by fall out or wash out the determined values can be considered as the higher limits of the transfer factors. The determined Cs 137-transfer factors of the transition plant - milk range between 0.0023 and 0.057 (pCi/l: pCi/daily intake). The highest transfer factors are determined for farms the pastures of which have sandy soils. More than 2/3 of all transfer factors determined for the transition plant - milk are lower than the value 0.012 (pCi/l: pCi/daily intake) published by the Strahlenschutzkommission in 1977. As for two farms the mean values of the factors during the outdoor season are higher than this value, it probably has to be raised in the evaluation of the radiation exposure for this part of the surroundings of the nuclear plant. (orig./MG) 891 MG/orig. 892 MB [de

Transfer factor of Radium -226, lead-210 and Polonium-210 from Norm contaminated soil to Atriplex, Afelfa and Bermuda grasses

International Nuclear Information System (INIS)

Al-Masri, M.S.; Mukhallati, H.; Al-Hamwi, A.

2011-10-01

transfer factors of Radium -226, lead-210 and Polonium-210 from contaminated soil with oil coproduced water to grazing plants in the north eastern region of Syria have been determined. contaminated soil was collected from one of the AL-Furat Petroleum Oil company oil fields;soil was distributed into several pots where the studied plants were planted in order to study the transfer factors of radioisotopes to them. Results have shown that the mean transfer factors of radium to green parts have reached has reached 0.0016 in Atriplex halimus L.,0.0021 in Atriplex canescens Nutt, 0.0025 in Atriplex Leucoclada Bioss,0.0082 in Bermuda grass and 0.0167 in Medicago Sativ L,which was the highest,while the transfer factors of polonium and lead were ten times higher than those for radium and reacted 0.012 in Atriplex Leucoclada Bioss, 0.011 in Atriplex canescens Nutt, 0.007 in Atriplex halimus L.0.32 in bermuda grass and 0.025 in Afelfa.(author)

Accumulation of 137Cs in Brazilian soils and its transfer to plants under different climatic conditions

International Nuclear Information System (INIS)

Handl, J.; Sachse, R.; Jakob, D.; Michel, R.; Evangelista, H.; Goncalves, A.C.; Freitas, A.C. de

2008-01-01

The spatial distribution and behaviour of the global fallout 137 Cs in the tropical, subtropical and equatorial soil-plant systems were investigated at several upland sites in Brazil selected according to their climate characteristics, and to the agricultural importance. To determine the 137 Cs deposition density, undisturbed soil profiles were taken from 23 environments situated between the latitudes of 02 o N and 30 o S. Sampling sites located along to the equator exhibited 137 Cs deposition densities with an average value of 219 Bq m -2 . Extremely low deposition densities of 1.3 Bq m -2 were found in the Amazon region. In contrast, the southern part of Brazil, located between latitudes of 20 o S and 34 o S, exhibited considerably higher deposition densities ranging from 140 Bq m -2 to 1620 Bq m -2 . To examine the 137 Cs soil-to-plant transfer in the Brazilian agricultural products, 29 mainly tropical plant species, and corresponding soil samples were collected at 43 sampling locations in nine federal states of Brazil. Values of the 137 Cs concentration factor plant/soil exhibited a large range from 0.020 (beans) to 6.2 (cassava). Samples of some plant species originated from different collecting areas showed different concentration factors. The 137 Cs content of some plants collected was not measurable due to a very low 137 Cs concentration level found in the upper layers of the incremental soils. Globally, the soil-to-plant transfer of 137 Cs can be described by a logarithmic normal distribution with a geometric mean of 0.3 and a geometric standard deviation of 3.9

Soil-to-plant halogens transfer studies 2. Root uptake of radiochlorine by plants

International Nuclear Information System (INIS)

Kashparov, V.; Colle, C.; Zvarich, S.; Yoschenko, V.; Levchuk, S.; Lundin, S.

2005-01-01

Long-term field experiments have been carried out in the Chernobyl exclusion zone in order to determine the parameters governing radiochlorine ( 36 Cl) transfer to plants from four types of soil, namely, podzoluvisol, greyzem, and typical and meadow chernozem. Radiochlorine concentration ratios (CR) in radish roots (15 ± 10), lettuce leaves (30 ± 15), bean pods (15 ± 11) and wheat seed (23 ± 11) and straw (210 ± 110) for fresh weight of plants were obtained. These values correlate well with stable chlorine values for the same plants. One year after injection, 36 Cl reached a quasi-equilibrium with stable chlorine in the agricultural soils and its behavior in the soil-plant system mimicked the behavior of stable chlorine (this behavior was determined by soil moisture transport in the investigated soils). In the absence of intensive vertical migration, more than half of 36 Cl activity in arable layer of soil passes into the radish, lettuce and the aboveground parts of wheat during a single vegetation period

Soil-to-plant halogens transfer studies 2. Root uptake of radiochlorine by plants

Energy Technology Data Exchange (ETDEWEB)

Kashparov, V. [Ukrainian Institute of Agricultural Radiology (UIAR), Mashinostroiteley Str.7, Chabany, Kiev Region 08162 (Ukraine); Colle, C. [Institute for Radioprotection and Nuclear Safety (IRSN/DEI/SECRE), Cadarache bat 159, BP 3, 13115 Saint Paul-lez-Durance (France)]. E-mail: claude.colle@irsn.fr; Zvarich, S. [Ukrainian Institute of Agricultural Radiology (UIAR), Mashinostroiteley Str.7, Chabany, Kiev Region 08162 (Ukraine); Yoschenko, V. [Ukrainian Institute of Agricultural Radiology (UIAR), Mashinostroiteley Str.7, Chabany, Kiev Region 08162 (Ukraine); Levchuk, S. [Ukrainian Institute of Agricultural Radiology (UIAR), Mashinostroiteley Str.7, Chabany, Kiev Region 08162 (Ukraine); Lundin, S. [Ukrainian Institute of Agricultural Radiology (UIAR), Mashinostroiteley Str.7, Chabany, Kiev Region 08162 (Ukraine)

2005-07-01

Long-term field experiments have been carried out in the Chernobyl exclusion zone in order to determine the parameters governing radiochlorine ({sup 36}Cl) transfer to plants from four types of soil, namely, podzoluvisol, greyzem, and typical and meadow chernozem. Radiochlorine concentration ratios (CR) in radish roots (15 {+-} 10), lettuce leaves (30 {+-} 15), bean pods (15 {+-} 11) and wheat seed (23 {+-} 11) and straw (210 {+-} 110) for fresh weight of plants were obtained. These values correlate well with stable chlorine values for the same plants. One year after injection, {sup 36}Cl reached a quasi-equilibrium with stable chlorine in the agricultural soils and its behavior in the soil-plant system mimicked the behavior of stable chlorine (this behavior was determined by soil moisture transport in the investigated soils). In the absence of intensive vertical migration, more than half of {sup 36}Cl activity in arable layer of soil passes into the radish, lettuce and the aboveground parts of wheat during a single vegetation period.

Transfer of technetium from soil to plant as a function of the type of soil, mode of contamination and vegetative cover

International Nuclear Information System (INIS)

Mousny, J.M.

1982-01-01

Study of the soil plant transfer of technetium-99 was made for two plant species (Trifolium pratense and Lolium multiflorum) either as a mixed or pure culture. The experiment was carried out in three European soils contaminated at the beginning of the test either on the surface or homogeneously, with recycling of the percolates. The work is aimed at studying changes in the transfer factors over time. Their gradual decrease is correlated with change in the physico-chemical form of TcO 4 - . (author)

Influence of soil parameters on the linearity of the soil-to-plant transfer process of {sup 238}U and {sup 226}Ra

Energy Technology Data Exchange (ETDEWEB)

Blanco Rodriguez, P.; Vera Tome, F. [Natural Radioactivity Group. Universidad de Extremadura, 06071 Badajoz (Spain); Lozano, J.C. [Laboratorio de Radiactividad Ambiental. Universidad de Salamanca, 37008 Salamanca (Spain)

2014-07-01

Transfer from soil to plant is an important input of radionuclides into the food chain. Also, the mobility of radionuclides in soils is enhanced through their passage into the plant compartment. Thus, the soil-to-plant transfer of radionuclides raises the potential human dose. In radiological risk assessment models, this process is usually considered to be an equilibrium process such that the activity concentration in plants is linearly related to the soil concentration through a constant transfer factor (TF). However, the large variability present by measured TF values leads to major uncertainties in the assessment of risks. One possible way to reduce this variability in TF values is to parametrize their determination. This paper presents correlations of TF with the major element concentrations in soils. The findings confirm the major influence of the chemical environment of a soil on the assimilation process. The variability of TF might be greatly reduced if only the labile fraction were considered. Experiments performed with plants (Helianthus annuus L.) growing in a hydroponic medium appear to confirm this suggestion, showing a linear correlation between the plant and the soil solution activity concentrations. Extracting the labile fraction of a real soil is no trivial task, however. A possible operationally definable method is to consider the water-soluble together with the exchangeable fractions of the soil. Studies performed in granitic soils showed that the labile concentration of uranium and radium strongly depended on the soil's textural characteristics. In this sense, a parametrization is proposed of the labile uranium and radium concentration as a function of the soil's granulometric parameters. (authors)

Evaluation of soil-plant transfer factors of iodine. Estimation of annual ingestion for iodine from the diet

International Nuclear Information System (INIS)

Saas, Arsene.

1980-11-01

The author presents the iodine middle contents of the soils and vegetables. A synthesis on the iodine evolution in the soils and vegetables allows to conclude that the vegetable absorption of this isotope is correlated with the isotopiquely exchangeable iodine of the soil. The soil-plant transfer-factors are calculated for the vegetables, cereals, fruits from the stable iodine quantitative analysis. The annual iodine ingestion has been estimated from the dietary of the European Communites areas. This one is a little different of the quantity estimated by CRESTA-LACOURLY-R 2979, yet the contribution by consummation unity is different [fr

Soil-to-Plant Transfer of Radiocesium in Ipomoea aquatica

International Nuclear Information System (INIS)

Salmah Moosa; Anis Nadia Mohd Faisol Mahadeven; Mohd Noor Hidayat Adenan

2016-01-01

The effectiveness of the bio fertilizer regarding the growth promotion and radiocaesium ("1"3"7Cs) uptake was evaluated in Ipomoea aquatica. The growth of Ipomoea aquatica was enhanced with the application of bio fertilizer. The practice of bio fertilizer resulted in significant increase of "1"3"7Cs concentration in all plant parts and higher "1"3"7Cs transfer from soil to plants. TF values of "1"3"7Cs ranged from 0.555 to 6.726 for the species. The plant roots possessed the lightest weight after being harvest, and show a highest "1"3"7Cs concentration in plant roots. Ipomoea aquatica could be utilized for agricultural countermeasures and phyto remediation, to diminish the allocation of radiocaesium from soil to human. (author)

Soil-to-plant transfer of elements is not linear: Results for five elements relevant to radioactive waste in five boreal forest species

Energy Technology Data Exchange (ETDEWEB)

Tuovinen, Tiina S.; Roivainen, Paeivi, E-mail: paivi.roivainen@uef.fi; Makkonen, Sari; Kolehmainen, Mikko; Holopainen, Toini; Juutilainen, Jukka

2011-12-01

Element-specific concentration ratios (CRs) assuming that plant uptake of elements is linear are commonly used in radioecological modelling to describe the soil-to-plant transfer of elements. The goal of this study was to investigate the validity of the linearity assumption in boreal forest plants, for which only limited relevant data are available. The soil-to-plant transfer of three essential (Mo, Ni, Zn) and two non-essential (Pb, U) elements relevant to the safety of radioactive waste disposal was studied. Three understory species (blueberry, narrow buckler fern and May lily) and two tree species (Norway spruce and rowan) were included. Examining CRs as a function of soil concentration showed that CR was not constant but decreased with increasing soil concentrations for all elements and plant species. A non-linear equation fitted fairly well with the empirical data; the R{sup 2}-values for this equation were constantly higher than those for the linear fit. The difference between the two fits was most evident at low soil concentrations where the use of constant CRs underestimated transfer from soil to plants. Site-specific factors affected the transfer of Mo and Ni. The results suggested that systematic variation with soil concentrations explains a part of the large variation of empirically determined CRs, and the accuracy of modelling the soil-to-plant transfer might be improved by using non-linear methods. Non-linearity of soil-to-plant transfer has been previously reported for a few different species, elements and environments. The present study systematically tested the linearity assumption for five elements (both essential and non-essential) and in five boreal forest species representing different growth traits and phylogenies. The data supported non-linearity in all cases.

Soil-to-plant transfer of elements is not linear: Results for five elements relevant to radioactive waste in five boreal forest species

International Nuclear Information System (INIS)

Tuovinen, Tiina S.; Roivainen, Päivi; Makkonen, Sari; Kolehmainen, Mikko; Holopainen, Toini; Juutilainen, Jukka

2011-01-01

Element-specific concentration ratios (CRs) assuming that plant uptake of elements is linear are commonly used in radioecological modelling to describe the soil-to-plant transfer of elements. The goal of this study was to investigate the validity of the linearity assumption in boreal forest plants, for which only limited relevant data are available. The soil-to-plant transfer of three essential (Mo, Ni, Zn) and two non-essential (Pb, U) elements relevant to the safety of radioactive waste disposal was studied. Three understory species (blueberry, narrow buckler fern and May lily) and two tree species (Norway spruce and rowan) were included. Examining CRs as a function of soil concentration showed that CR was not constant but decreased with increasing soil concentrations for all elements and plant species. A non-linear equation fitted fairly well with the empirical data; the R 2 -values for this equation were constantly higher than those for the linear fit. The difference between the two fits was most evident at low soil concentrations where the use of constant CRs underestimated transfer from soil to plants. Site-specific factors affected the transfer of Mo and Ni. The results suggested that systematic variation with soil concentrations explains a part of the large variation of empirically determined CRs, and the accuracy of modelling the soil-to-plant transfer might be improved by using non-linear methods. Non-linearity of soil-to-plant transfer has been previously reported for a few different species, elements and environments. The present study systematically tested the linearity assumption for five elements (both essential and non-essential) and in five boreal forest species representing different growth traits and phylogenies. The data supported non-linearity in all cases.

Plant-induced changes in soil chemistry do not explain differences in uranium transfer

International Nuclear Information System (INIS)

Duquene, L.; Vandenhove, H.; Tack, F.; Avoort, E. van der; Hees, M. van; Wannijn, J.

2006-01-01

A greenhouse experiment was set up with maize, ryegrass, Indian mustard, wheat and pea to evaluate to what extent differences in uranium (U) transfer factors can be explained by root-mediated changes in selected soil properties. The experiment involved an acid and an alkaline soil contaminated with 238 U. U soil-to-shoot transfer factors (TFs) ranged between 0.0005 and 0.021 on the acid soil and between 0.007 and 0.179 on the alkaline soil. Indian mustard showed the highest U uptake in shoots and maize the lowest. The root TFs, only available for the acid soil, ranged from 0.58 for maize and Indian mustard to 1.38 for ryegrass. The difference in U uptake between the two soils and the five plants was only partially explained by the different initial U concentrations in soil solution or differences in soil properties in the two soils. However, we obtained a significant relation for differences in shoot TFs observed between the two soils when relating shoot TFs with concentration of UO 2 2+ and uranyl carbonate complexes in soil solution (R 2 = 0.88). The physiological mechanisms by which root-to-shoot U transfer is inhibited or promoted seemed at least as important as the plant-induced changes in soil characteristics in determining soil-to-shoot TFs

The transfer of 137Cs through the soil-plant-sheep food chain in different pasture ecosystems

Directory of Open Access Journals (Sweden)

A. PAASIKALLIO

2008-12-01

Full Text Available A grazing experiment with sheep was carried out in 1990-1993 on natural, semi-natural and cultivated pasture on clay soil. The pastures were located in Southern Finland and were moderately contaminated with 137 Cs by Chernobyl fallout. Natural pasture refers to forest pasture and semi-natural pasture to set-aside field pasture, the latter having been under cultivation about 15 years ago. The transfer of 137 Cs to sheep was clearly higher from forest pasture than from the other two pastures and it was lowest from cultivated pasture. The transfer was higher to muscle and kidney than to liver and heart. The transfer of 137 Cs to plants and to meat varied with years. Seasonal variation in the plant 137 Cs was followed-up on forest and set-aside field pasturerespect to 137 Cs transfer to plants, the mean soil-plant transfer factors of 137 Cs for forest, set-aside field and cultivated pastures were 1.78, 0.36 and 0.09, and soil-meat aggregated transfer factors 11.0, 0.28 and 0.03, respectively.;

The transfer of 137Cs through the soil-plant-sheep food chain in different pasture ecosystems

International Nuclear Information System (INIS)

Paasikallio, Arja; Sormunen-Cristian, Riitta

1996-01-01

A grazing experiment with sheep was carried out in 1990-1993 on natural, semi-natural and cultivated pasture on clay soil. The pastures were located in Southern Finland and were moderately contaminated with 137 Cs by Chernobyl fallout. Natural pasture refers to forest pasture and semi-natural pasture to set-aside field pasture, the latter having been under cultivation about 15 years ago. The transfer of 137 Cs to sheep was clearly higher from forest pasture than from the other two pastures and it was lowest from cultivated pasture. The transfer was higher to muscle and kidney than to liver and heart. The transfer of 137 Cs to plants and to meat varied with years. Seasonal variation in the plant 137 Cs was followed-up on forest and set-aside field pasturerespect to 137 Cs transfer to plants, the mean soil-plant transfer factors of 137 Cs for forest, set-aside field and cultivated pastures were 1.78, 0.36 and 0.09, and soil-meat aggregated transfer factors 11.0, 0.28 and 0.03, respectively

Predicting soil-to-plant transfer of radionuclides with a mechanistic model (BioRUR)

Energy Technology Data Exchange (ETDEWEB)

Casadesus, J. [Servei de Camps Experimentals, Universitat de Barcelona, Avda Diagonal 645, 08028 Barcelona (Spain); Sauras-Yera, T. [Departament de Biologia Vegetal, Facultat de Biologia, Universitat de Barcelona, Avda Diagonal 645, 08028 Barcelona (Spain)], E-mail: msauras@ub.edu; Vallejo, V.R. [Departament de Biologia Vegetal, Facultat de Biologia, Universitat de Barcelona, Avda Diagonal 645, 08028 Barcelona (Spain); Centro de Estudios Ambientales del Mediterraneo, Charles Darwin 14, Parc Tecnologic, 46980 Paterna, Valencia (Spain)

2008-05-15

BioRUR model has been developed for the simulation of radionuclide (RN) transfer through physical and biological compartments, based on the available information on the transfer of their nutrient analogues. The model assumes that radionuclides are transferred from soil to plant through the same pathways as their nutrient analogues, where K and Ca are the analogues of Cs and Sr, respectively. Basically, the transfer of radionuclide between two compartments is calculated as the transfer of nutrient multiplied by the ratio of concentrations of RN to nutrient, corrected by a selectivity coefficient. Hydroponic experiments showed the validity of this assumption for root uptake of Cs and Sr and reported a selectivity coefficient around 1.0 for both. However, the application of this approach to soil-to-plant transfer raises some questions on which are the effective concentrations of RN and nutrient detected by the plant uptake mechanism. This paper describes the evaluation of two configurations of BioRUR, one which simplifies the soil as an homogeneous pool, and the other which considers that some concentration gradients develop around roots and therefore ion concentrations at the root surface are different from those of the bulk soil. The results show a good fit between the observed Sr transfer and the mechanistic simulations, even when a homogeneous soil is considered. On the other hand, Cs transfer is overestimated by two orders of magnitude if the development of a decreasing K profile around roots is not taken into account.

Predicting soil-to-plant transfer of radionuclides with a mechanistic model (BioRUR)

International Nuclear Information System (INIS)

Casadesus, J.; Sauras-Yera, T.; Vallejo, V.R.

2008-01-01

BioRUR model has been developed for the simulation of radionuclide (RN) transfer through physical and biological compartments, based on the available information on the transfer of their nutrient analogues. The model assumes that radionuclides are transferred from soil to plant through the same pathways as their nutrient analogues, where K and Ca are the analogues of Cs and Sr, respectively. Basically, the transfer of radionuclide between two compartments is calculated as the transfer of nutrient multiplied by the ratio of concentrations of RN to nutrient, corrected by a selectivity coefficient. Hydroponic experiments showed the validity of this assumption for root uptake of Cs and Sr and reported a selectivity coefficient around 1.0 for both. However, the application of this approach to soil-to-plant transfer raises some questions on which are the effective concentrations of RN and nutrient detected by the plant uptake mechanism. This paper describes the evaluation of two configurations of BioRUR, one which simplifies the soil as an homogeneous pool, and the other which considers that some concentration gradients develop around roots and therefore ion concentrations at the root surface are different from those of the bulk soil. The results show a good fit between the observed Sr transfer and the mechanistic simulations, even when a homogeneous soil is considered. On the other hand, Cs transfer is overestimated by two orders of magnitude if the development of a decreasing K profile around roots is not taken into account

Soil-to-plant transfer factors of natural radionuclides (226Ra and 40K) in selected Thai medicinal plants.

Science.gov (United States)

Saenboonruang, Kiadtisak; Phonchanthuek, Endu; Prasandee, Kamonkhuan

2018-04-01

A soil-to-plant transfer factor (TF) is an important parameter that could be used to estimate radionuclides levels in medicinal plants. This work reports concentrations of natural radionuclides ( 226 Ra and 40 K) and TFs in six Thai medicinal plants grown in central Thailand using an HPGe gamma ray spectrometer. Either root, leaf, or flower parts of each medicinal plant were selected for use in the investigation according to their practical uses in traditional medicine. The results showed that due to K being essential in plants, 40 K had higher arithmetic means of activity concentrations and geometric means of TFs (geometric standard deviations in parentheses) of 610 ± 260 Bq kg -1 dry weight (DW) and 2.0 (1.4), respectively, than 226 Ra, which had the activity concentrations and TFs of 4.8 ± 2.6 Bq kg -1 DW and 0.17 (1.8), respectively. The results also showed that the leaves of medicinal plants had higher activity concentrations and TFs than root and flower parts, probably due to higher metabolic activities in leaves. Furthermore, there was good agreement between the results from the current work and other similar reports on medicinal plants. The information obtained from this work could strengthen knowledge of natural radionuclides in plants and particularly increase available TF data on Thai medicinal plants. Copyright © 2018 Elsevier Ltd. All rights reserved.

Estimation of soil-to-plant transfer factors of radiocesium in 99 wild plant species grown in arable lands 1 year after the Fukushima 1 Nuclear Power Plant accident.

Science.gov (United States)

Yamashita, Jun; Enomoto, Takashi; Yamada, Masao; Ono, Toshiro; Hanafusa, Tadashi; Nagamatsu, Tomohiro; Sonoda, Shoji; Yamamoto, Yoko

2014-01-01

One year after the deposition of radionuclides from the Fukushima 1 Nuclear Power Plant (A formal name is Fukushima Daiichi Nuclear Power Station) in March 2011, radiocesium (¹³⁴Cs, ¹³⁷Cs) concentrations ([Cs]) were comprehensively investigated in the wild plants of 99 species most of which were annual or summer green perennial herbs and started to grow from April 2012 at the heavily contaminated fields of paddy (three study sites) and upland (one study site) in Fukushima Prefecture. The survey was conducted three times (April, July and October) in the year. In each site, soils (soil cores of 5-cm depth) and plants (aerial shoots) were collected for determination of [Cs] on a dry weight basis, and then the transfer factor (TF) of radiocesium from soil to plant ([Cs]plant/[Cs]soil) was estimated in each species. The [Cs] values of both soils and plants largely varied. However, some species exhibited relatively high TF values (more than 0.4) (e.g., Athyrium yokoscense, Dryopteris tokyoensis, and Cyperus brevifolius), while others exhibited almost negligible values (less than 0.01) (e.g., Salix miyabeana, Humulus scandens, and Elymus tsukushiensis). In addition, judging from the 11 species grown in both paddy and upland fields, TF values were generally higher in the paddy fields. The estimation of phytoextraction efficiency of soil radiocesium by weed communities in the paddy fields suggests that the weed community is not a practical candidate for phytoremediation technique.

A soil-based model to predict radionuclide transfer in a soil-plant system

International Nuclear Information System (INIS)

Roig, M.; Vidal, M.; Tent, J.; Rauret, G.; Roca, M.C.; Vallejo, V.R.

1998-01-01

The aim of this work was to check if the main soil parameters predefined as ruling soil-plant transfer were sufficient to predict a relative scale of radionuclide mobility in mineral soils. Two agricultural soils, two radionuclides ( 85 Sr and 134 Cs), and two crops (lettuce and pea) were used in these experiments following radioactive aerosol deposition simulating the conditions of a site some distance far away from the center of a nuclear accident, for which condensed deposition would be the more significant contribution. The available fraction of these radionuclides was estimated in these soils from experiments in which various reagents were tested and several experimental conditions were compared. As a general conclusion, the soil parameters seemed to be sufficient for prediction purposes, although the model should be improved through the consideration of physiological aspects, especially those depending of the plant selectivity according to the composition of the soil solution

Transfer factors of radioiodine from volcanic-ash soil (Andosol) to crops

Energy Technology Data Exchange (ETDEWEB)

Ban-Nai, Tadaaki; Muramatsu, Yasuyuki [National Inst. of Radiological Sciences, Chiba (Japan). Environmental and Toxicological Sciences Research Group

2003-03-01

In order to obtain soil-to-plant transfer factors (TFs) of radioiodine from volcanic-ash soil to agricultural crops, we carried out radiotracer experiments. The mean values of TFs (on a wet weight basis) of radioiodine from Andosol to edible parts of crops were as follows: water dropwort, 0.24; lettuce, 0.00098; onion, 0.0011; radish, 0.0044; turnip, 0.0013 and eggplant, 0.00010. The mean value of the TFs of radioiodine for edible parts of wheat (on a dry weight basis) was 0.00015. We also studied the distributions of iodine in crops. There was a tendency for the TFs of leaves to be higher than those of tubers, fruits and grains. A very high TF was found for water dropwort, because this plant was cultivated under a waterlogged condition, in which iodine desorbed from soil into soil solution with a drop in the Eh value. The data obtained in this study should be helpful to assess the long-lived {sup 129}I (half life: 1.57 x l0{sup 7} yr) pathway related to the fuel cycle. (author)

Transfer factors of radioiodine from volcanic-ash soil (Andosol) to crops

International Nuclear Information System (INIS)

Ban-Nai, Tadaaki; Muramatsu, Yasuyuki

2003-01-01

In order to obtain soil-to-plant transfer factors (TFs) of radioiodine from volcanic-ash soil to agricultural crops, we carried out radiotracer experiments. The mean values of TFs (on a wet weight basis) of radioiodine from Andosol to edible parts of crops were as follows: water dropwort, 0.24; lettuce, 0.00098; onion, 0.0011; radish, 0.0044; turnip, 0.0013 and eggplant, 0.00010. The mean value of the TFs of radioiodine for edible parts of wheat (on a dry weight basis) was 0.00015. We also studied the distributions of iodine in crops. There was a tendency for the TFs of leaves to be higher than those of tubers, fruits and grains. A very high TF was found for water dropwort, because this plant was cultivated under a waterlogged condition, in which iodine desorbed from soil into soil solution with a drop in the Eh value. The data obtained in this study should be helpful to assess the long-lived 129 I (half life: 1.57 x l0 7 yr) pathway related to the fuel cycle. (author)

Transfer factor for 210Pb from soil to vegetables in the surrounding environment of Kaiga nuclear power station

International Nuclear Information System (INIS)

Rao, Chetan; Karunakara, N.; Yashodhara, I.; Ravi, P.M.

2013-01-01

The paper presents a detailed study on site specific soil to vegetable (leafy, fruit and root) transfer factors for 210 Pb for Kaiga region, India where a PHWR, nuclear power plant is in operation. An experimental vegetable field was developed at about 500 m aerial distance from the Nuclear Power Plant (NPP) site at Kaiga to study the site-specific soil to plant transfer factors. Different types of vegetables were grown in the experimental field, during different seasons of the year, using the discharge water from the Kaiga nuclear power plant. The development of the experimental vegetable fields helped in evaluating accurate site-specific data. For a comparative study of the transfer factors obtained for the experimental field, samples cultivated using normal water resources by the local farmers of nearby villages, were also collected and analysed. The soil to leafy vegetable transfer factor of 210 Pb varied in the range of < 1.5 x 10 -2 - 1.6 x 10 -1 with a mean value of 6.0 x 10 -2 . Similarly the soil to fruit vegetable varied in the range of < 1.0 x 10 -2 - 3.4 x 10 -1 and the soil to root vegetable varied in the range of < 1.0 x 10 -2 - 4.0 x 10 -2 with corresponding mean values of 6.0 x 10 -2 and 3.0 x 10 -2 respectively. The annual effective dose due to intake of 210 Pb through leafy vegetables varied in the range of 7.9 - 76.0 μSv a -1 with a mean value of 35.2 ìSv a -1 . And through fruit and root vegetables, it varied in the range of 34.9 - 207 μSv a -1 with a mean value of 119 ìSv a -1 . It was found that radionuclide concentration in plants was not linearly related to soil concentration. (author)

Values of soil-plant transfer factor of 226Ra and 228Ra: agricultural areas versus areas of high natural radioactivity

International Nuclear Information System (INIS)

Wasserman, Maria Angelica; Lauria, Dejanira; Perez, Daniel Vidal; Schuch, Luiz Alexandre; Zago, Ari

2000-01-01

In this work, soil to plant transfer factor of 226 Ra and 228 Ra obtained in areas of traditional agricultural practices varied as a function of the considered cultivated species but little variation was observed as a function of the soil type. Beans and soybeans presented more important absorption than cereals (corn, rice and wheat). In our work legumes (bean and soybean) presented transfer factors up to one order of magnitude higher than average values for regions where natural radioactivity is high. On the other hand, the results for cereals did not presented such clear differences. It can be concluded that cultural inputs of 226 Ra and 228 Ra are occurring in agricultural areas, but few species can concentrate it. The transfer factor values obtained in this work for 226 Ra and 228 Ra can be applied in risk assessment models. (author)

Soil to plant transfer of {sup 137}Cs and {sup 60}Co in Ferralsol, Nitisol and Acrisol

Energy Technology Data Exchange (ETDEWEB)

Wasserman, M.A. [Instituto de Radioprotecao e Dosimetria, CNEN, Av. Salvador Allende s/no, Recreio, CEP: 22780-160, Rio de Janeiro, RJ (Brazil)], E-mail: angelica@ird.gov.br; Bartoly, F.; Viana, A.G.; Silva, M.M.; Rochedo, E.R.R. [Instituto de Radioprotecao e Dosimetria, CNEN, Av. Salvador Allende s/no, Recreio, CEP: 22780-160, Rio de Janeiro, RJ (Brazil); Perez, D.V. [Centro Nacional de Pesquisa de Solos, EMBRAPA, R. Jardim Botanico 1024, CEP: 22460-000, Rio de Janeiro, RJ (Brazil); Conti, C.C. [Instituto de Radioprotecao e Dosimetria, CNEN, Av. Salvador Allende s/no, Recreio, CEP: 22780-160, Rio de Janeiro, RJ (Brazil)

2008-03-15

In this study, soil to plant transfer factor values were determined for {sup 137}Cs and {sup 60}Co in radish (Raphanus sativus), maize (Zea mays L.) and cabbage (Brassica oleracea L. var. capitata) growing in gibbsite-, kaolinite- and iron-oxide-rich soils. After 3 years of experiment in lysimeters it was possible to identify the main soil properties able to modify the soil to plant transfer processes, e.g. exchangeable K and pH, for {sup 137}Cs, and organic matter for {sup 60}Co. Results of sequential chemical extraction were coherent with root uptake and allowed the recognition of the role of iron oxides on {sup 137}Cs behaviour and of Mn oxides on {sup 60}Co behaviour. This information should provide support for adequate choices of countermeasures to be applied on tropical soils in case of accident or for remediation purposes.

The transfer of 137Cs through the soil-plant-sheep food chain in different pasture ecosystems

Directory of Open Access Journals (Sweden)

Arja Paasikallio

1996-12-01

Full Text Available A grazing experiment with sheep was carried out in 1990-1993 on natural, semi-natural and cultivated pasture on clay soil. The pastures were located in Southern Finland and were moderately contaminated with 137 Cs by Chernobyl fallout. Natural pasture refers to forest pasture and serai-natural pasture to set-aside field pasture, the latter having been under cultivation about 15 years ago. The transfer of 137Cs to sheep was clearly higher from forest pasture than from the other two pastures and it was lowest from cultivated pasture. The transfer was higher to muscle and kidney than to liver and heart. The transfer of 137Cs to plants and to meat varied with years. Seasonal variation in the plant 137 Cs was followed-up on forest and set-aside field pasture; the activity concentration of plants reached a maximum in June, a lesser increase occurred later in the autumn. In 1993, which was considered an average year with respect to 137Cs transfer to plants, the mean soil-plant transfer factors of 137Cs for forest, set-aside field and cultivated pastures were 1.78, 0.36 and 0.09, and soil-meat aggregated transfer factors 11.0, 0.28 and 0.03, respectively.

Nonlinear transfer of elements from soil to plants: impact on radioecological modeling

Energy Technology Data Exchange (ETDEWEB)

Tuovinen, Tiina S.; Kolehmainen, Mikko; Roivainen, Paeivi; Kumlin, Timo; Makkonen, Sari; Holopainen, Toini; Juutilainen, Jukka [University of Eastern Finland, Department of Environmental and Biological Sciences, P.O. Box 1627, Kuopio (Finland)

2016-08-15

In radioecology, transfer of radionuclides from soil to plants is typically described by a concentration ratio (CR), which assumes linearity of transfer with soil concentration. Nonlinear uptake is evidenced in many studies, but it is unclear how it should be taken into account in radioecological modeling. In this study, a conventional CR-based linear model, a nonlinear model derived from observed uptake into plants, and a new simple model based on the observation that nonlinear uptake leads to a practically constant concentration in plant tissues are compared. The three models were used to predict transfer of {sup 234}U, {sup 59}Ni and {sup 210}Pb into spruce needles. The predictions of the nonlinear and the new model were essentially similar. In contrast, plant radionuclide concentration was underestimated by the linear model when the total element concentration in soil was relatively low, but within the range commonly observed in nature. It is concluded that the linear modeling could easily be replaced by a new approach that more realistically reflects the true processes involved in the uptake of elements into plants. The new modeling approach does not increase the complexity of modeling in comparison with CR-based linear models, and data needed for model parameters (element concentrations) are widely available. (orig.)

Plant uptake of radiocaesium from artificially contaminated soil monoliths covering major European soil types

International Nuclear Information System (INIS)

Waegeneers, Nadia; Sauras-Yera, Teresa; Thiry, Yves; Vallejo, V. Ramon; Smolders, Erik; Madoz-Escande, Chantal; Brechignac, Francois

2009-01-01

Uptake of 137 Cs was measured in different agricultural plant species (beans, lettuce, barley and ryegrass) grown in 5 undisturbed soil monoliths covering major European soil types. The first cultivation was made three years after soil contamination and plants were grown during 3 successive years. The plant-soil 137 Cs transfer factors varied maximally 12-fold among soils and 35-fold among species when grown on the same soil. Single correlations between transfer factors and soil properties were found, but they varied widely with plant type and can hardly be used as a predictive tool because of the few soils used. The variation of 137 Cs concentrations in plants among soils was related to differences in soil solution 137 Cs and K concentrations, consistent with previous observations in hydroponics and pot trials. Absolute values of transfer factors could not be predicted based on a model validated for pot trials. The 137 Cs activity concentration in soil solution decreased significantly (11- to 250-fold) for most soils in the 1997-1999 period and is partly explained by decreasing K in soil solution. Transfer factors of lettuce showed both increasing and decreasing trends between 2 consecutive years depending on soil type. The trends could be explained by the variation in 137 Cs and K concentrations in soil solution. It is concluded that differences in 137 Cs transfer factors among soils and trends in transfer factors as a function of time can be explained from soil solution composition, as shown previously for pot trials, although absolute values of transfer factors could not be predicted.

Radionuclide transfer to meadow plants

International Nuclear Information System (INIS)

Sanzharova, N.; Fesenko, S.; Belli, M.; Arkhipov, A.; Ivanova, T.; Perepelyatnikov, G.; Tsvetnova, O.

1996-01-01

Experimental data on 90 Sr and 137 Cs transfer to plants of natural and semi-natural meadows selected in the main CIS region contaminated due to the ChNPP accident are discussed. The highest TF's in grass stand are obtained for peatlands, and minimal ones - for dry meadows. 137 Cs content in plants decreased after the accident, on average, by a factor of 2-4. The dynamics of 137 Cs uptake by plants depends on meadow and soil properties. The first half life of 137 Cs transfer to plants change from 2,0 to 2,2 years and the second (slower) period half life change from 4,0 to 12 years for different meadow types. 90 Sr TF's are higher than those obtained for 137 Cs. The correlation between soil parameters and TP's are shown. 137 Cs TF's in grass stand depend on meadow type and decrease in the following order: peatlands> flood plain and wet (lowland) meadows> dry meadows

Soil to plant 137Cs transfer factors in Zea mays and Phaseolus vulgaris in a semi-arid ecosystem from a radioactive waste site

International Nuclear Information System (INIS)

Cervantes, M.L.; Segovia, N.; Gaso, M.I.; Palacios, J.C.

2002-01-01

A study of 137 Cs in soil, maize plants, (Zea mays) and beans (Phaseolus vulgaris) has been performed at the confined Storage Centre for Radioactive Waste from Mexico. Under field conditions the site was divided in four zones with different soil contamination characteristics. The plants were grown 'in situ' reproducing the local agricultural practices without fertilizers, pesticides or artificial irrigation.The 137 Cs determinations were performed using a low background gamma spectrometry system with an HPGe detector. The results indicate that one of the zones had a striking 137 Cs contamination in the soil and the uptake by the grown plants showed the highest specific activities at the root. For the edible parts of the plants the amount of 137 Cs in the maize grains was one order of magnitude lower than for the beans. The transfer factors ranges for the different parts of the maize plants was from 0.001 in the grain to 0.6 in the root. (author)

Soil to plant transfer of radionuclides: predicting the fate of multiple radioisotopes in plants

International Nuclear Information System (INIS)

Willey, Neil J.

2014-01-01

Predicting soil-to-plant transfer of radionuclides is restricted by the range of species for which concentration ratios (CRs) have been measured. Here the radioecological utility of meta-analyses of phylogenetic effects on alkali earth metals will be explored for applications such as ‘gap-filling’ of CRs, the identification of sentinel biomonitor plants and the selection of taxa for phytoremediation of radionuclide contaminated soils. REML modelling of extensive CR/concentration datasets shows that the concentrations in plants of Ca, Mg and Sr are significantly influenced by phylogeny. Phylogenetic effects of these elements are shown here to be similar. Ratios of Ca/Mg and Ca/Sr are known to be quite stable in plants so, assuming that Sr/Ra ratios are stable, phylogenetic effects and estimated mean CRs are used to predict Ra CRs for groups of plants with few measured data. Overall, there are well quantified plant variables that could contribute significantly to improving predictions of the fate radioisotopes in the soil-plant system

Investigation of the transfer of 90Sr, 137Cs, 60Co, and 54Mn from soil to plant, and of the main soil parameters that have influence on the transfer process

International Nuclear Information System (INIS)

Steffens, W.; Fuehr, F.; Mittelstaedt, W.; Klaes, J.; Foerstel, H.

1988-12-01

In lysimetric field experiments with 2 soil types most common in the Federal Republic of Germany the effects of a continuous contamination as well as of a temporary contamination of the soil caused by a possible accident were simulated to allow forecastings on the resorption of radionuclides by farm plants. Parallel pot experiments (8 kg of soil) in greenhouses and in the field and small pot experiments under reproducible climatic chamber conditions were to examine wether or not transfer data from laboratory and pot experiments can be applied to field conditions. In addition to this, soil types representative according to soil mapping were taken from the locations of the nuclear power plants Biblis and Stade, and their properties were determined. In large-scale comparative pot experiments the relative transfer factors were determined. (orig./DG) [de

Soil-plant transfer of radiocaesium in slightly contaminated forest ecosystems

International Nuclear Information System (INIS)

Lamarque, S.; Lucot, E.; Badot, P.M.

2004-01-01

During Chernobyl's accident, large areas of Western European countries, particularly forests, were contaminated with radiocaesium fallouts. Soil-plant transfer is often the first step by which 137 Cs enters the food chains and flows through the biogeochemical cycle. The present work is devoted to document the soil-plant transfer of radiocaesium in slightly contaminated forest areas. Twelve sites, representative of the various functional features and great diversity of ecological contexts of Franche-Comte region (France), were selected to sample soils and forest trees: three species (Picea abies, Fagus sylvatica, Corylus avellana) and two organs (leaves or needles and young branches) were measured. Radiocaesium activities in soils have been observed to vary in range of 61 to 280 Bq.kg -1 DW at 0-5 cm depth (8500 to 14280 Bq.m -2 ). A great correlation exists between organic carbon content and soil total radiocaesium concentration (r 2 = 0,60). The studied soils have large organic carbon contents (2,7 to 28%) and large water pH values (3,1 to 6,1). Radiocaesium activities in leaves, needles and branches varied in range of 0 to 128 Bq.kg -1 DW, 0 to 163 Bq.kg -1 DW and 0 to 180 Bq.kg -1 DW respectively. We reported a large variability of Transfer Factors, TFs (0.02 to 0.58) with respect to vegetation type, organ type and soil features. The activity concentration in the leaves and needles were generally found to be greater than those measured in the branches. No correlation was found between soil radiocaesium activity and vegetation radiocaesium activity. TFs values could be related to variations in the radiocaesium bioavailability function of the soil features. (author)

Soil-to-plant transfer of 137Cs and 40K in an Atlantic blanket bog ecosystem

International Nuclear Information System (INIS)

Moran-Hunter, C.; O'Dea, J.

2008-01-01

The transfer of 137 Cs and 40 K from soil to vegetation was studied in an Atlantic blanket bog ecosystem along the Atlantic coast of Ireland where the dominant vegetation is a mixture of Calluna vulgaris, Eriophorum vaginatum and Sphagnum mosses. The impact of soil chemistry and nutritional status of vegetation on the uptake of both radionuclides was also examined. Cesium-137 transfer factors values ranged from 1.9 to 9.6 and accumulation of 137 Cs was higher in the leaves of C. vulgaris than in the stems. Transfer factors values for 137 Cs in both C. vulgaris and E. vaginatum were similar indicating that for the vegetation studied, uptake is not dependent on plant species. The uptake of 137 Cs in bog vegetation was found to be positively correlated with the nutrient status of vegetation, in particular the secondary nutrients, calcium and magnesium. Potassium-40 transfer factors ranged from 0.9 to 13.8 and uptake was higher in E. vaginatum than in C. vulgaris, however, unlike 137 Cs, the concentrations of 40 K within the leaves and stems of C. vulgaris were similar. The concentration of both 137 Cs and 40 K found in moss samples were in general lower than those found in vascular plants. (author)

Compilation and evaluation of radioecological data on soil/plant transfer in consideration of local variabilities in Germany

International Nuclear Information System (INIS)

Cierjacks, A.; Albers, B.

2004-01-01

Publications on soil-to-plant transfer factors (TFs) for radiocesium, radiostrontium, plutonium and iodine-129 in Germany were evaluated. Over 100 publications with relevant TFs were identified, whereof 54 were intensively analyzed and rated according to quality criteria. A database was created which gives a comprehensive survey of the transfer factors, important related soil and plant parameters and peculiarities of sampling and analyses. For better comparability, TFs were standardized and expressed in units of [Bq kg -1 plant dry matter / Bq kg -1 soil dry matter]. To enable statistical analyses, soil and plant parameters were standardized, too. Standardization also prepares data as input for modelling. The database contains 4800 records which represent singular and aggregated values of more than 7300 samples taken in Germany. Mean values of individual combinations radionuclide/crop can be queried easily using a special software module. Additional information about the experimental design, nuclide contents in plants and soil, important parameters and detailed remarks allow a classification of each record

Plant uptake of radiocaesium from artificially contaminated soil monoliths covering major European soil types

Energy Technology Data Exchange (ETDEWEB)

Waegeneers, Nadia [Laboratory for Soil and Water Management, Katholieke Universiteit Leuven, Kasteelpark Arenberg 20, B-3001 Heverlee (Belgium)], E-mail: nadia.waegeneers@agr.kuleuven.ac.be; Sauras-Yera, Teresa [Departament de Biologia Vegetal, Universitat de Barcelona, Av. Diagonal 645, 08028 Barcelona (Spain); Thiry, Yves [SCK.CEN, Radioecology Laboratory, Boeretang 200, B-2400 Mol (Belgium); Vallejo, V. Ramon [Departament de Biologia Vegetal, Universitat de Barcelona, Av. Diagonal 645, 08028 Barcelona (Spain); CEAM, Parque Tecnologico, Charles Darwin 14, 46980 Parterna (Spain); Smolders, Erik [Laboratory for Soil and Water Management, Katholieke Universiteit Leuven, Kasteelpark Arenberg 20, B-3001 Heverlee (Belgium); Madoz-Escande, Chantal; Brechignac, Francois [SERLAB, ISPN, Department for Environmental Protection, CE-Cadarache Batiment 159, Saint-Paul-lez-Durance Cedex 13108 (France)

2009-06-15

Uptake of {sup 137}Cs was measured in different agricultural plant species (beans, lettuce, barley and ryegrass) grown in 5 undisturbed soil monoliths covering major European soil types. The first cultivation was made three years after soil contamination and plants were grown during 3 successive years. The plant-soil {sup 137}Cs transfer factors varied maximally 12-fold among soils and 35-fold among species when grown on the same soil. Single correlations between transfer factors and soil properties were found, but they varied widely with plant type and can hardly be used as a predictive tool because of the few soils used. The variation of {sup 137}Cs concentrations in plants among soils was related to differences in soil solution {sup 137}Cs and K concentrations, consistent with previous observations in hydroponics and pot trials. Absolute values of transfer factors could not be predicted based on a model validated for pot trials. The {sup 137}Cs activity concentration in soil solution decreased significantly (11- to 250-fold) for most soils in the 1997-1999 period and is partly explained by decreasing K in soil solution. Transfer factors of lettuce showed both increasing and decreasing trends between 2 consecutive years depending on soil type. The trends could be explained by the variation in {sup 137}Cs and K concentrations in soil solution. It is concluded that differences in {sup 137}Cs transfer factors among soils and trends in transfer factors as a function of time can be explained from soil solution composition, as shown previously for pot trials, although absolute values of transfer factors could not be predicted.

Transfer of radionuclides in soil-plant systems following aerosol simulation of accidental release: design and first results

International Nuclear Information System (INIS)

Rauret, G.; Real, J.

1995-01-01

The behaviour of 134 Cs, 110m Ag and 85 Sr was studied in different soil-plant systems, using two types of Mediterranean soil with contrasting properties (sandy and sandy-loam soils). The plant species used was lettuce (Lactuca sativa). Contamination was induced at different stages of plant growth, using a synthetic aerosol which simulated a distant contamination source. Characterisation of aerosol and soils, interception factors in the various growth stages, foliar and root uptake, leaching from leaves by irrigation and distribution and migration of radionuclides of soils were studied, in an attempt to understand the key factors involving radionuclide soil-to-plant transferance. (author)

Transfer of radionuclides in soil-plant systems following aerosol simulation of accidental release: design and first results

Energy Technology Data Exchange (ETDEWEB)

Rauret, G. [Universitat de Barcelona (Spain). Dept. of Quimica Analitica; Vallejo, V.R. [Universitat de barcelona (Spain). Dept. of Biologia Vegetal; Cancio, D. [Centro de Investigaciones Energeticas, Medioambientales y Tecnologicas (CIEMAT), Madrid (Spain); Real, J. [CEA Centre d`Etudes de Fontenay-aux-Roses, 92 (France). Inst. de Protection et de Surete Nucleaire

1995-12-31

The behaviour of {sup 134}Cs, {sup 110m}Ag and {sup 85}Sr was studied in different soil-plant systems, using two types of Mediterranean soil with contrasting properties (sandy and sandy-loam soils). The plant species used was lettuce (Lactuca sativa). Contamination was induced at different stages of plant growth, using a synthetic aerosol which simulated a distant contamination source. Characterisation of aerosol and soils, interception factors in the various growth stages, foliar and root uptake, leaching from leaves by irrigation and distribution and migration of radionuclides of soils were studied, in an attempt to understand the key factors involving radionuclide soil-to-plant transferance. (author).

Soil-water distribution coefficients and plant transfer factors for {sup 134}Cs, {sup 85}Sr and {sup 65}Zn under field conditions in tropical Australia

Energy Technology Data Exchange (ETDEWEB)

Twining, J.R. E-mail: jrt@ansto.gov.au; Payne, T.E.; Itakura, T

2004-07-01

Measurements of soil-to-plant transfer of {sup 134}Cs, {sup 85}Sr and {sup 65}Zn from two tropical red earth soils ('Blain' and 'Tippera') to sorghum and mung crops have been undertaken in the north of Australia. The aim of the study was to identify factors that control bioaccumulation of these radionuclides in tropical regions, for which few previous data are available. Batch sorption experiments were conducted to determine the distribution coefficient (K{sub d}) of the selected radionuclides at pH values similar to natural pH values, which ranged from about 5.5 to 6.7. In addition, K{sub d} values were obtained at one pH unit above and below the soil-water equilibrium pH values to determine the effect of pH. The adsorption of Cs showed no pH dependence, but the K{sub d} values for the Tippera soils (2300-4100 ml/g) exceeded those for the Blain soils (800-1200 ml/g) at equilibrium pH. This was related to the greater clay content of the Tippera soil. Both Sr and Zn were more strongly adsorbed at higher pH values, but the K{sub d} values showed less dependence on the soil type. Strontium K{sub d}s were 30-60 ml/g whilst Zn ranged from 160 to 1630 ml/g for the two soils at equilibrium pH. With the possible exception of Sr, there was no evidence for downward movement of radionuclides through the soils during the course of the growing season. There was some evidence of surface movement of labelled soil particles. Soil-to-plant transfer factors varied slightly between the soils. The average results for sorghum were 0.1-0.3 g/g for Cs, 0.4-0.8 g/g for Sr and 18-26 g/g for Zn (dry weight) with the initial values relating to Blain and the following values to Tippera. Similar values were observed for the mung bean samples. The transfer factors for Cs and Sr were not substantially different from the typical values observed in temperate studies. However, Zn transfer factors for plants grown on both these tropical soils were greater than for soils in

Transfer of 226Ra to plants from two types of soil

International Nuclear Information System (INIS)

Rosiak, L.; Pietrzak-Flis, Z.

1998-01-01

The transfer of 226 Ra to plants used as food (carrot, parsley, wheat) and as fodder (grass, maize) was studied. The plants were grown on two types of soil: sandy soil (l) and sandy loam soil (II) in an open field (exposure to dry and wet deposition, resuspension and soil adhesion) and in polyethylene tent with an underground irrigation system (isolation from wet deposition and from water splash on soil). The plants were grown simultaneously on the open and sheltered fields. The average concentrations of total 226 Ra and of exchangeable 226 Ra were 8.48 ± 0.50 Bq/kg dw was 0.62 ± 0.07 Bq/kg dw , respectively, in Soil I and 12.2 ± 0.56 Bq/kg dw and 0.66 ± 0.05 Bq/kg dw , respectively, in Soil II. 226 Ra was determined in the above-ground parts of the plants after washing in distilled water, in the rinse obtained from washing, in the insoluble residue separated from the rinse, and in the roots. The data obtained allowed us to determine the incorporated radionuclide in the plants and on their surface. Statistical analysis of the data indicates that there is no difference in the incorporated 226 Ra for plants grown on the open field and in the tent. This indicates that Ra enter the plants mainly through the root system, while the pathway via leaves and stems is negligible

Development of a method for analyzing traces of ruthenium in plant materials and determination of the transfer factors soil/plant for ruthenium compounds from reprocessing plants

International Nuclear Information System (INIS)

Blasius, E.; Huth, R.; Neumann, W.

1988-01-01

In an artificial humous and sandy soil spiked with 106 Ru as RuO 2 and RuCl 3 , pasture grass was grown under artificial illumination in our laboratory. The amounts of ruthenium taken up by the plants were determined by γ-spectrometry. For open-air investigations with pasture grass, wheat and potatoes inactive ruthenium(III) chloride and ruthenium nitrosylchloride were used. Ruthenium was determined by electrothermal atomic absorption spectrometry (ETAAS) after destroying the organic material and concentrating the solution. The concentration and chemical form of the ruthenium exert an unimportant influence on the transfer factor. For the pasture-grass, the stems of wheat and the weed of potatoes it amounts to 0.00005 to 0.0015, for the ear of wheat to about 0.00005. In peeled potatoes there was no ruthenium detectable, therefore the limit of detection leads to a transfer factor ≤ 0.00001. So it is evident that ruthenium is little available for the roots of the plants. In the event of an accident in a nuclear plant the uptake of radioactive ruthenium by roots has only negligible radioecological consequences. This applies even if 50 years of ruthenium enrichment in the soil are assumed. (orig./RB)

The effect of soil pH and the fungicide 'Captan' on 134Cs transfer factors for cucumber and radish plants

International Nuclear Information System (INIS)

Skarlou, V.; Massas, I.; Anoussis, J.; Haidouti, C.; Arapis, G.

1999-01-01

The effect of soil pH and the fungicide 'Captan' on 134 Cs transfer factors (TFs) was studied in a greenhouse pot experiment with cucumber and radish plants. A soil with a low pH (4.2) was selected and its pH value has increased to 5.7, 6.5 and 7.6 by the addition of different amounts of Ca(OH) 2 . Liming of the soil and the subsequent increase in pH values resulted in a reduction of 134 Cs TFs which was not always significant. TFs were the highest in the very acid soil (pH 4.2) and were practically the same above the pH 5.7 although they were the lowest in the calcareous soil. The ratio highest / lowest TF of each crop or plant part ranged between ∼ 2.0 for radish and 4.5 for cucumber plants and it was much lower than that previously reported and attributed to pH differences. Edible to other plant material TF ratio indicates that cucumber plant accumulates considerably more of the totally absorbed 134 CS in the edible part than radish crops. When biomass production was used for excluding dilution effects, 134 CS total activity (Bq/pot) was higher for both plants when grown in the intermediate soil pH (5.7 - 6.5), due to the higher yield at these pH values. The application of the fungicide 'Captan' gave no significant differences in 134 Cs TFs for both plant species and in all studied soil pH. Refs. 4 (author)

Time-dependent transfer of 54Mn, 60Co, 85Sr and 137Cs from a sandy soil to soybean plants

International Nuclear Information System (INIS)

Choi, Yong-Ho; Lim, Kwang-Muk; Jun, In; Keum, Dong-Kwon; Han, Moon-Hee

2011-01-01

Greenhouse experiments were performed to investigate the dependence of 54 Mn, 60 Co, 85 Sr and 137 Cs transfer from sandy soil to soybean plants on the growth stage when a radioactive deposition occurs. A solution containing 54 Mn, 60 Co, 85 Sr and 137 Cs was applied onto the soil surfaces in the lysimeters at six different times -2 d before sowing and 13, 40, 61, 82 and 96 d after sowing. Soil-to-plant transfer was quantified with a transfer factor (m 2 kg -1 -dry) specified for the deposition time. The transfer factor values of 54 Mn, 60 Co, 85 Sr and 137 Cs for the seeds were in the range of 1.5×10 -3 -1.0×10 -2 , 4.7×10 -4 -3.2×10 -3 , 5.7×10 -4 -1.0×10 -2 and 3.0×10 -5 -2.7×10 -4 , respectively, for different deposition times. The corresponding values for the leaves were 6.4×10 -3 -3.2×10 -2 , 4.3×10 -4 -2.0×10 -3 , 5.1×10 -3 -5.3×10 -2 and 9.2×10 -5 -1.9×10 -4 , respectively. The values for the seeds were on the whole highest following the middle-growth-stage deposition. After the pre-sowing deposition, the transfer factor values of 54 Mn, 60 Co and 137 Cs for the seeds decreased annually so those in the fourth year were 53%, 75% and 34% of those in the first year, respectively. The present results may be useful for predicting the radionuclide concentrations in soybean plants due to their root uptake following an acute soil-deposition during the vegetation period, and for validating a relevant model. (author)

Non-linearity in radiocaesium soil to plant transfer: fact or fiction?

International Nuclear Information System (INIS)

Beresford, N.A.; Scott, W.A.; Wright, S.M.

2004-01-01

The basis premise of many radiological assessments is the assumption that the transfer of many radionuclides from soil to herbage and hence animal derived food products is a positive linear relationship for a given set of ecological conditions. However, a number of authors have published results which they conclude demonstrate non-linear transfer of radiocaesium to plants and animals with transfer being highest when soil concentrations are lowest. Whilst we may expect non-linear transfer of radionuclides under homeostatic control or present in comparatively large chemical quantities there appears no credible hypothesis to support such an observation for radiocaesium. In this paper we review those articles which have reported non-linear radiocaesium transfer and also analyse novel data. Mechanisms for the observation as presented in the original works are critically assessed. For instance, some authors have speculated that radiocaesium root uptake is saturated. We suggest that this is unlikely as whilst saturation of root uptake of radiocaesium has been observed above 1.37 mg Cs + L -1 in growth solutions, concentrations of Cs + in soil solutions are typically -1 , and 1 MBq m -2 of 137 Cs will add only 0.3 mg Cs + m -2 . We discuss alternative hypotheses to explain the reported observations and suggest that sampling bias, countermeasure application and statistical chance all contribute to the reported non-linearity in radiocaesium transfer. (author)

Transfer factors for the „soil-cereals” system in the region of Pcinja, Serbia

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Marković Jelena S.

2016-01-01

Full Text Available The aim of the paper was to estimate the values of transfer factors for natural radionuclides (40K, 226Ra, 232Th, 235U, and 238U and 137Cs from soil to plants (cereals: wheat, corn and barley as important parameters for the agricultures in the selection of the location and the sort of cereals to be planted on. The results presented in this paper refer to the „soil-cereals” system in the region of Pcinja, Serbia. Total of 9 samples of soil and 7 samples of cereals were measured in the Department of Radiation and Environmental Protection, Vinca Institute of Nuclear Sciences, using three high-purity germanium detectors for gamma spectrometry measurements. In all the samples, transfer factors for 226Ra are significantly lower than for 40K, but they are all in good agreement with the literature data. On the three investigated locations, the calculated values of transfer factors for 40K were in the range of 0.144 to 0.392, while in the case of 226Ra, the transfer factors ranged from 0.008 to 0.074. Only one value (0.051 was obtained for transfer factor of 232Th. Specific activities of 137Cs, as well as uranium isotopes, in all the investigated cereal samples, were below minimal detectable activity concentrations. Also, the absorbed dose rate and the annual absorbed dose from the natural radionuclides in the soil, were calculated. The absorbed dose rate ranged from 49-86 nSv/h, while the annual absorbed dose ranged from 0.061-0.105 mSv. The measurements presented in this manuscript are the first to be conducted in the region of Pcinja, thus providing the results that can be used as a baseline for future measurements and monitoring.

Using DTPA-extractable soil fraction to assess the bioconcentration factor of plants in phytoremediation of urban soils

Science.gov (United States)

Rodríguez-Bocanegra, Javier; Roca, Núria; Tume, Pedro; Bech, Jaume

2017-04-01

Urban soils may be highly contaminated with potentially toxic metals, as a result of intensive anthropogenic activities. Developing cities are increasing the number of lands where is practiced the urban agriculture. In this way, it is necessary to assess the part of heavy metals that is transferred to plants in order to a) know the potential health risk that represent soils and b) know the relation soil-plant to assess the ability of these plants to remove heavy metals from soil. Nowadays, to assess the bioconcentration factor (BF) of plants in phytoremediation, the pseudototal o total concentration has been used by many authors. Two different urban soils with similar pH and carbonates content but with different pollution degree were phytoremediated with different plant species. Urban soil from one Barcelona district (Spain), the most contaminated soil, showed an extractability of Cu, Pb and Zn of 9.6, 6.7 and 5.8% of the total fraction respectively. The soil from Talcahuano city (Chile), with contents of heavy metals slightly above the background upper limit, present values of 15.5, 13.5 and 12% of the total fraction of studied heavy metals. Furthermore, a peri-urban analysed soil from Azul (Argentina) also showed an elevated extractability with values of 24, 13.5 and 14% of the Cu, Pb and Zn contents respectively. These soils presented more extractability than other disturbed soils, like for example, soils from mine areas. The urban soils present more developed soil with an interaction between solution and solid phase in polluted systems. The most important soil surface functional groups include the basal plane of phyllosilicates and metal hydroxyls at edge sites of clay minerals, iron oxyhydroxides, manganese oxyhydroxides and organic matter. The interaction between solution and solid phase in polluted urban systems tends to form labile associations and pollutants are more readily mobilized because their bonds with soil particles are weaker. Clay and organic

Transfer characteristics of cadmium and lead from soil to the edible parts of six vegetable species in southeastern China

International Nuclear Information System (INIS)

Wang Guo; Su Miaoyu; Chen Yanhui; Lin Fenfang; Luo Dan; Gao Shufang

2006-01-01

The transfer characteristics of Cd and Pb from soils to the edible parts of six vegetable species were calculated from plant and corresponding surface soil samples collected from the fields in Fujian Province, southeastern China. The soil-to-plant transfer factors (TF) calculated from both total and DTPA-extractable Cd and Pb in the soils decreased with increasing total or DTPA-extractable Cd and Pb, indicating that the TF values of Cd and Pb depend on the soil metal content. For most plants studied, there was a significant relation between the TF values and the corresponding soil metal concentrations (total or DTPA-extractable) that was best described by an exponential equation (y = ax b ). We recommend that the representative TF value for a given crop-metal system should be estimated from the regression models between the transfer factors and the corresponding soil metal concentrations and at a given soil metal concentration. - Soil-to-plant transfer factors of Cd and Pb decreased with increasing soil contents of Cd and Pb

Soil-to-plant transfer factors of stable elements and naturally occurring radionuclides. (2) Rice collected in Japan

International Nuclear Information System (INIS)

Uchida, Shigeo; Tagami, Keiko; Hirai, Ikuko

2007-01-01

The critical paths of radionuclides and the critical foods in Japan are different from those in European and North American countries because agricultural products and food customs are different. Consequently, safety assessment in Japan is required to consider rice and vegetables as the critical foods. In this study, we measured soil-to-plant transfer factors (TFs) for rice using naturally existing elements as analogues of radionuclides under equilibrium conditions. Rice and associated soil samples were collected from 50 sampling sites throughout Japan and TFs of 36 and 34 elements for brown rice and white rice, respectively, were calculated on dry weight basis. Probability distributions of TFs of elements for brown rice and white rice were a log normal type. Except for As and Mo, the TFs for brown rice were usually lower than those for wheat and barley especially for K, Fe, Sr (t-test: p 90 Sr and 137 Cs observed in field experiments. Thus, the TFs of naturally existing elements can be used as TFs of those radionuclides which have been in contact with the environment for a long time and have reached equilibrium conditions. (author)

Soil to rice transfer factors for 226Ra, 228Ra, 210Pb, 40K and 137Cs: a study on rice grown in India

International Nuclear Information System (INIS)

Karunakara, N.; Rao, Chetan; Ujwal, P.; Yashodhara, I.; Kumara, Sudeep; Ravi, P.M.

2013-01-01

India is the second largest producer of rice (Oryza sativa L.) in the world and rice is an essential component of the diet for a majority of the population in India. However, detailed studies aimed at the evaluation of radionuclide transfer factors (F v ) for the rice grown in India are almost non-existent. This paper presents the soil to rice transfer factors for natural ( 226 Ra, 228 Ra, 40 K, and 210 Pb) and artificial ( 137 Cs) radionuclides for rice grown in natural field conditions on the West Coast of India. A rice field was developed very close to the Kaiga nuclear power plant and the water required for this field was drawn from the cooling water discharge canal of the power plant. For a comparative study of the radionuclide transfer factors, rice samples were also collected from the rice fields of nearby villages. The study showed that the 226 Ra and 228 Ra activity concentrations were below detection levels in different organs of the rice plant. The soil to un-hulled rice grain 40 K transfer factor varied in the range of 6.5 × 10 −1 to 2.9 with a mean of 0.15 × 10 1 , and of 210 Pb varied in the range of −2 to 8.1 × 10 −1 with a mean of 1.4 × 10 −1 , and of 137 Cs varied in the range of 6.6 × 10 −2 to 3.4 × 10 −1 with a mean of 2.1 × 10 −1 . The mean values of un-hulled grain to white rice processing retention factors (F r ) were 0.12 for 40 K, 0.03 for 210 Pb, and 0.14 for 137 Cs. Using these processing retention factors, the soil to white rice transfer factors were estimated and these were found to have mean values of 1.8 × 10 −1 , 4.2 × 10 −3 , and 3.0 × 10 −2 for 40 K, 210 Pb, and 137 Cs, respectively. The study has shown that the transfer of 40 K was higher for above the ground organs than for the root, but 210 Pb and 137 Cs were retained in the root and their transfer to above the ground organs of the rice plant is significantly lower. -- Highlights: ► Soil to rice (Oryza sativa L.) transfer factors for radionuclides

Concentration and measuring Platinum Group Elements (PGE) Transfer Factor in soil and vegetations

International Nuclear Information System (INIS)

Adibah Sakinah Oyub

2012-01-01

This study was conducted to determine the concentration and to measure platinum group elements (PGE) transfer factor in environmental samples of roadside soil and vegetation. The use of vehicle catalytic converter has released platinum group elements (PGE) and other gases into the environment. Thus, roadside soil and plants were exposed to this element and has become the medium for the movement of this elements. Samples of roadside soil and vegetation were taken at various locations in UKM Bangi Toll and the concentration of platinum group elements (PGE) is determined using mass spectrometry-inductively coupled plasma (ICP-MS). Overall, the concentrations of platinum group elements (PGE), which is the element platinum (Pt) in soil was 0.016 ± 0.036 μgg -1 . While the concentration of the elements palladium (Pd) was 0.079 ± 0.019 μgg -1 and element rhodium (Rh) is at a concentration of 0.013 ± 0.020 μgg -1 . Overall, the transfer factor for the element platinum (Pt) is 1. While the transfer factor of the element palladium (Pd) is 0.96 and the element rhodium (Rh) is 1.11. In conclusion, the concentration of platinum group elements (PGE) in soils have increased. (author)

The transfer of radionuclides from soil to animal feed

Energy Technology Data Exchange (ETDEWEB)

Frissel, M J; Ginkel, J.H. van; Stoutjesdijk, J F; Koester, H W [Lab. of Radiation Research, Nat. Inst. of Public Health and Environmental Hygiene, Bilthoven (Netherlands)

1986-07-01

Non volatile radioactive compounds which become released into the atmosphere will finally accumulate in the top layer of soils. The soil-to-plant transfer is therefore a key process for the contamination of food and animal feed. The spread of the uptake factors is large; even so large that a worst case approach for estimating the contamination may lead to very unrealistic conclusions. The Int. Union of Radioecologists (IUR) has established a working group to approach this problem. By means of a joint programme of many institutions sufficient transfer data are being collected to allow a sophisticated statistical evaluation resulting in predictions of transfer factor values and confidence levels. Possible counter measures against the uptake of radionuclides are discussed. (author)

The transfer of radionuclides from soil to animal feed

International Nuclear Information System (INIS)

Frissel, M.J.; Ginkel, J.H. van; Stoutjesdijk, J.F.; Koester, H.W.

1986-01-01

Non volatile radioactive compounds which become released into the atmosphere will finally accumulate in the top layer of soils. The soil-to-plant transfer is therefore a key process for the contamination of food and animal feed. The spread of the uptake factors is large; even so large that a worst case approach for estimating the contamination may lead to very unrealistic conclusions. The Int. Union of Radioecologists (IUR) has established a working group to approach this problem. By means of a joint programme of many institutions sufficient transfer data are being collected to allow a sophisticated statistical evaluation resulting in predictions of transfer factor values and confidence levels. Possible counter measures against the uptake of radionuclides are discussed. (author)

Soil to plant transfer of 134Cs for olive and orange trees after four years' experimentation

International Nuclear Information System (INIS)

Skarlou, V.; Nobeli, C.; Anoussis, J.; Haidouti, C.

1998-01-01

The transfer parameters of 134 Cs from soil to tree crops (olive and orange trees) were calculated within a long-term glass-house pot experiment which was started in 1994. The effect of the soil characteristics on 134 Cs uptake was also studied using two soils with different physical and chemical properties. Both evergreen trees exhibited a similar behavior in the two soils, showing that a higher or lower uptake is not crop specific. The capacity of the trees for 134 Cs absorption through the roots seems to be significantly influenced by the soil type. The transfer factors were very low in the calcareous heavy soil and much higher in the acid light soil (up to 10 times for olives and 40 for the edible part of oranges). The difference in the TFs is higher between the two soils than between the two tree species. 134 Cs concentration kept increasing in the orange trees up to the 4th year of growth, while it seems to reach an equilibrium, with no further increase, in the olive trees. Although the behavior of the two tree species is similar, the difference in the final processed product is extreme. A significant amount of 134 Cs was observed in olives grown in the light-acid soil whereas no transfer to the olive oil was detected. On the other hand, the edible part of the oranges showed the highest 134 Cs of nearly all the plant parts

Soil-to-soybean transfer of 99Tc and its underground distribution in differently contaminated upland soils

International Nuclear Information System (INIS)

Choi, Yong-Ho; Lim, Kwang-Muk; Jun, In; Kim, Byung-Ho; Keum, Dong-Kwon; Kim, In-Gyu

2014-01-01

Pot experiments were performed in a greenhouse to investigate the soil-to-soybean transfer of 99 Tc in two different upland soils labeled with 99 TcO 4 − in two contrasting ways. One was to mix the soil with a 99 TcO 4 − solution 26 d before sowing (pre-sowing deposition: PSD), and the other was to apply the solution onto the soil surface 44 d after sowing (growing-period deposition: GPD). The soil-to-plant transfer was quantified with the transfer factor (TF, ratio of the plant concentration to the average of at-planting and at-harvest soil concentrations) or the aggregated transfer factor (TF ag , ratio of the plant concentration to the deposition density). For both the depositions, the transfer of 99 Tc to aerial parts decreased in the order of leaf > stem > pod > seed. TF values (dimensionless) from the PSD were 0.22 and 0.27 (no statistically significant difference) for mature dry seeds in the respective soils, whereas a 600-fold higher value occurred for dry leaves. The post-harvest concentrations of the PSD 99 Tc in the top 20 cm soils as a whole were about half the initial concentrations. Around 25% of the total applied activity remained in the GPD soils after the harvest. The post-harvest depth profiles of the GPD 99 Tc in the two soils showed similar patterns of logarithmic activity decrease with increasing soil depths. Only 1.5–4.3% of the total applied activity was removed through the harvested biomass (seeds, pods and stems), and it was estimated that a great part of the total pant uptake returned to the soil through the fallen leaves. TF ag values (m 2 kg −1 ) were about 2–4 times higher for the GPD than for the PSD. This finding and generally high root uptake of Tc may indicate that the use of empirical deposition time-dependent TF ag data is particularly important for predicting the plant concentrations of Tc after its growing-period deposition. - Highlights: • Soybean TF values of 99 Tc were markedly lower for the seed than for the

Chemical speciation of technetium in soil and plants: Impact on soil-plant-animal transfer

International Nuclear Information System (INIS)

Vandecasteele, C.M.; Garten, C.T. Jr.; Van Bruwaene, R.; Janssens, J.; Kirchmann, R.; Myttenaere, C.

1985-01-01

Considerable uncertainties are associated with the environmental behaviour of technetium-99 and its transfer from soil to plants and then to animals and man. For this reason, most of the mathematical models built to simulate the environmental transport of Tc and to calculate the dose to man are associated with conservative simplifications and produce overestimates of the calculated dose. In order to follow the new ICRP recommendations, transfer models are needed that estimate as accurately as possible the dose to the population; this implies a better knowledge of the behaviour of Tc in the environment, especially concerning its long-term behaviour. At this time, most of the available data deals with the short-term and only scanty results have been obtained regarding the plant-animal transfer, especially in the case of polygastric mammals

Chemical speciation of technetium in soil and plants: impact on soil-plant-animal transfer

International Nuclear Information System (INIS)

Vandecasteele, C.M.; Bruwaene, R. van; Janssens, J.; Kirchmann, R.; Myttenaere, C.

1986-01-01

Considerable uncertainties are associated with the environmental behaviour of technetium-99 and its transfer from soil to plants and then to animals and man. For this reason, most of the mathematical models built to simulate the environmental transport of Tc and to calculate the dose to man are associated with conservative simplifications and produce overestimates of the calculated dose. In order to follow the new ICRP recommendations, transfer models are needed that estimate as accurately as possible the dose to the population; this implies a better knowledge of the behaviour of Tc in the environment, especially concerning its long-term behaviour. At this time, most of the available data deal with the short-term and only scanty results have been obtained regarding the plant-animal transfer, especially in the case of polygastric mammals. (author)

Determination of soil-to-plant transfer factors of {sup 137}Cs and {sup 90}Sr in the tropical environment of Bangladesh

Energy Technology Data Exchange (ETDEWEB)

Mollah, A.S.; Begum, A. [Atomic Energy Research Establishment (AERE), Savar, Dacca (Bangladesh); Ullah, S.M. [University of Dhaka (Bangladesh). Department of Soil Science

1998-07-01

Soil-to-plant transfer factors (TF) of {sup 137}Cs and {sup 90}Sr have been determined for different plants/crops, such as rice, beans, peanuts, pineapple, cabbage, tomato, spinach and grass. They were obtained from radioisotope experiments on plants grown in pots under outdoor ambient tropical conditions for three growing seasons (1994-1996). In the case of {sup 137}Cs and concerning the above mentioned plants/crops, the average TFs were found to be 0.28, 0.25, 0.77, 0.19, 0.23, 0.28, 0.59 and 0.18, respectively. In the case of {sup 90}Sr, the average TFs were found to be 0.82, 0.51, 0.20, 0.82, 0.69, 0.59, 0.91 and 0.84, respectively. A minor seasonal variation was observed. This study provides a database of TFs for tropical environments to be used, e.g., for radiological safety assessment models. (orig.) With 1 fig., 3 tabs., 12 refs.

Soil-leaf transfer of chemical elements for the Atlantic Forest

International Nuclear Information System (INIS)

Joacir De Franca, E.; De Nadai Fernandes, E.A.; Bacchi, M.A.; Tagliaferro, F.S.

2007-01-01

Soil analysis could improve environmental studies since soil is the main source of chemical elements for plants. In this study, soil samples collected at 0-10 cm depth under tree crown projection were analyzed by INAA. Using the chemical composition of the leaf previously determined, the leaf-soil transfer factors of chemical elements could be estimated for the Atlantic Forest. Despite the variability of the intra-species, the transfer factors were specific for some plant species due to their element accumulation in the leaves. Similar Br-Zn combined transfer factors were obtained for the species grouped according to habitats in relation to their position (understory or dominant species) in the forest canopy. (author)

Uranium transfer in the food chain from soil to plants, animals and man

International Nuclear Information System (INIS)

Mueller, R.; Betz, I.; Anke, M.; Witte, H.; Schilling, C.; Knoth, E.

2010-01-01

Our investigations aimed at following up the scientific basis of uranium transfer from the soils of different geological origins and from the immediate vicinity of uranium waste dumps in the vegetation, in waters (drinking water, mineral water and medicinal water), vegetable and animal foodstuffs and beverages; the regional human uranium intake, excretion, apparent absorption and balance in Germany and Mexico. Another aim of the investigations was to draw conclusions from the rules of transfer of this element from the rocks and soils to plants, animals and man. (authors)

Study on the radioactivity and soil-to-plant transfer factor of 226Ra, 234U and 238U radionuclides in irrigated farms from the northwestern Saudi Arabia

International Nuclear Information System (INIS)

Al-Hamarneh, Ibrahim F.; Alkhomashi, N.; Almasoud, Fahad I.

2016-01-01

The present study addresses the soil-to-plant transfer factors (TFs) of 226 Ra, 234 U and 238 U for 13 types of vegetables and agricultural crops planted under semi-arid environment in the northwestern part of Saudi Arabia. Crop plants along with plant-growing soils were collected from selected farms, which are irrigated from the non-renewable Saq aquifer, and investigated for their radioactivity content by means of alpha spectrometry after applying a radiochemical separation procedure. Hence, TF data for plant roots, green parts (stem and leaves) and fruits were calculated and contrasted to those reported in the literature. Substantial differences were observed in the TFs of Ra and U radioisotopes among plant species. In crop fruits, eggplant exhibited the highest uptake of 226 Ra (TF value of 0.11), while beans (0.16) have the highest TF for 234 U and 238 U. The geometric mean TF values indicated that the crop roots tend to accumulate Ra and U about four to six-folds higher than fruits. The relation between TF values and soil concentrations showed a weak correlation. Activity ratios between radionuclides in crop plants indicated the preferential translocation of U in fruits than Ra even though Ra is more available for root uptake. The fruit/root (F/R) ratios obtained for the investigated plants shown that pepper had the smallest F/R ratios (0.07 ± 0.01, 0.12 ± 0.02 and 0.11 ± 0.02 for 226 Ra, 234 U and 238 U, respectively), while the highest F/R ratios were observed in potatoes (0.71 ± 0.15, 0.44 ± 0.10 and 0.40 ± 0.08 for 226 Ra, 234 U and 238 U, respectively). The TF and F/R ratios data of natural radionuclides in the study region can hopefully improve the scientific knowledge for future studies. - Highlights: • Ra and U isotopes were measured in soils and plant crops in farms in Saudi Arabia. • Ra and U activities in plant roots (R) slightly exceeded that in their fruits (F). • Ra/U activity ratios showed preferential translocation of U

Analysis, method and techniques for the studying of Cesium-137 transfer from soil to plants (maize and beans) (continuation of the technical report GSR-91-20)

International Nuclear Information System (INIS)

Cervantes N, M.L.

1992-12-01

In this report the complete results of transfer of corn and bean whose objective is to determine the transfer of Cs-137 via: soil → root → plant, which is determined by the transfer factors or concentration factors (FC), which indicates the incorporation from Cs-137 to soil and plant starting from two models of compartments which were already described in the technical report GSR-91-20-1 that precedes to this are presented. These results correspond to that carried out during the agricultural cycle of 1991, as well as the first results corresponding to 1992 in the radioactive wastes storage center (CADER) in Mexico. (Author)

Transfer soil-wood of radionuclides of uranium decay series

International Nuclear Information System (INIS)

Deus, P.; Petschat, U.; Schmidt, P.

1998-01-01

The radionuclide transfer soil-plant is an essential feature for radioecological characterisation of the biosphere. Beside of plants used only for nutrition purposes also plants have to be investigated which are used otherwise intensively or over long periods by humans. This e.g. comes true in the case of wood which as timber or furniture in buildings could be the reason of radiation expositions of inhabitants. In this work by means of experimental investigations for 226 Ra, 210 Pb, 210 Po, 238 U and 227 Ac transfer factors of wood grown on areas used formerly by uranium mining are estimated. The dependence of transfer factors on specific activity in soil is determined. It is shown that in the case of higher soil activities transfer factors of wood are comparable with factors published for other vegetation. As a rule no linear dependence of plant activity on soil activity has been found. As known from other radionuclides saturations take place which result in an upper level of activity in the plants. An effective dose estimation in the case of typical applications shows as a rule no remarkable radioecological risk due to wood grown on mining areas with the exception of processes including radionuclide enrichment. In latter cases and for wood grown on areas with soil activities >1 000 Bq/kg with respect to a general radiation protection precaution duty and aspects of licence problems, however, a case-to-case decision is recommended. (orig.) [de

Kinetic and dynamic aspects of soil-plant-snail transfer of cadmium in the field

International Nuclear Information System (INIS)

Gimbert, Frederic; Mench, Michel; Coeurdassier, Michael; Badot, Pierre-Marie; Vaufleury, Annette de

2008-01-01

The proper use of bioaccumulation in the assessment of environmental quality involves accounting for chemical fluxes in organisms. Cadmium (Cd) accumulation kinetics in a soil-plant-snail food chain were therefore investigated in the field under different soil contamination (from 0 to 40 mg kg -1 ), soil pH (6 and 7) and season. Allowing for an accurate and sensitive assessment of Cd transfer to snails, toxicokinetics appears an interesting tool in the improvement of risk assessment procedures and a way to quantify metal bioavailability for a defined target. On the basis of uptake fluxes, snails proved to be sensitive enough to distinguish moderate soil contaminations. The soil pH did not appear, in the range studied, as a modulating parameter of the Cd transfer from soil to snail whereas the season, by influencing the snail mass, may modify the internal concentrations. The present data specifying a time integrated assessment of environmental factors on metal bioavailability and transfer to terrestrial snails should ensure their rational use in environmental biomonitoring. - Toxicokinetics and uptake fluxes can be used to describe the environment contamination by Cd, its bioavailability and transfer to Helix aspersa snails in the field

The transport of natural radionuclides from soil to plants

International Nuclear Information System (INIS)

Bikit, I.; Conkic, Lj.; Slivka, J.; Krmar, M.

1995-01-01

The transport and accumulation processes of Ra-226, U-238, Th-232 and K-40 from soil to plants have been studied. Plant samples with consumable parts grown below surface have been bred in natural conditions on soil with enhanced levels of natural radioactivity (barren soil of the uranium mine Gabrovnica-Kalna). An intensive transport of heavy natural radionuclides from soil to the roots was established. The transfer factors for U-238 and Ra-226 have been much bigger than for Th-232. The most intensive uptake was registered for beet root. (author)

Transfer of 40K, 238U, 210Pb, and 210Po from soil to plant in various locations in south of Syria

International Nuclear Information System (INIS)

Al-Masri, M.S.; Al-Akel, B.; Nashawani, A.; Amin, Y.; Khalifa, K.H.; Al-Ain, F.

2008-01-01

Transfer factors of 40 K, 238 U, 210 Pb, and 210 Po from soil to some agriculture crops in various locations in south of Syria (Dara'a and Assuwaydaa districts) have been determined. Soil and vegetable crops (green pepper, cucumber, tomato, and eggplant), legumes crops (lentil, chickpea, and broad bean), fruit trees (apple, grape, and olives) and cereals (barley and wheat) were collected and analyzed for 238 U, 210 Pb, and 210 Po. The results have shown that higher transfer factors (calculated as Bq kg -1 dry wt. plant material per Bq kg -1 dry wt. soil) for 210 Po, 210 Pb and 238 U were observed in vegetable leaves than fruits and cereals leaves; the highest values of transfer factor (TF) for 238 U were found to be 0.1 for straw of chickpea. Transfer factors for 210 Po varied between 2.8 x 10 -2 and 2 in fruits of eggplant and grain of barley, respectively. In addition, several parameters affecting transfer factors of the radionuclides were evaluated. The results can be considered as base values for TF of natural radionuclides in the region

Soil-to-potato transfer factors of elements

International Nuclear Information System (INIS)

Tsukada, Hirofumi; Watabe, Teruhisa.

1996-01-01

Transfer factors (TFs) of stable elements from soil to potato were determined for 26 pairs of samples which were collected at different sites in Aomori prefecture, Japan. The concentrations of 31 elements in both soil and potato samples were determined by neutron activation analysis. Several of these elements were divided into two groups, each having different TF characteristics. In the first group of elements, such as Cl, K, Ca, etc., an inverse correlation was seen between the TFs for each element and their concentrations in the soil. The relatively constant concentrations of these elements in potato were independent of the concentrations of the same elements in soil. However, in the second group, the TFs for other elements, such as Sc, Co and so on, in potato were independent of their concentrations in the soil. The fluctuation of TF observed in this study was smaller than that previously reported. It may be attributed to the fact that the experiment was done in a relatively narrow geographic area. In addition, the TFs for stable elements in this study were generally one to three orders of magnitude lower than those compiled for radioactive isotopes in IAEA publications. These differences should be precisely examined hereafter. (author)

Transport of plutonium, americium, and curium from soils into plants by roots

International Nuclear Information System (INIS)

Pimpl, M.; Schuettelkopf, H.

1979-12-01

For assessing the dose from radionuclides in agricultural products by ingestion it is necessary to know the soil to plant transfer factors. The literature was entirely investigated, in order to judge the size of the soil to plant transfer factors. In total, 92 publications - from 1948 to 1978 -have been evaluated. As result, transfer factors from 10 -9 to 10 -3 have been found for Plutonium, and from 10 -6 to 1 for Americium. For Curium only few data are available in literature. The considerable variation of the measured transfer factors is based on the dependence of these transfer factors from the ion exchange capacity of soils, from the amount of organic materials, from the pH-value, and from the mode of contamination. There are, in any case, contradictory data, although there has been detected a dependence of the transfer factors from these parameters. Chelating agenst increase the transfer factors to approximately 1300. As well, fertilizers have an influence on the size of the transfer factors - however, the relationships have been scarcely investigated. The distribution of actinides within the individual parts of plants has been investigated. The highest concentrations are in the roots; in the plant parts above ground the concentration of actinides decreases considerably. The most inferior transfer factors were measured for the respective seed or fruits. The soil to plant transfer factors of actinides are more dependend on the age of the plants within one growing period. At the beginning of the period, the transfer factor is considerably higher than at the end of this period. With respect to plants with a growing period of several years, correlations are unknown. (orig.) [de

Transfer factors of radionuclides 137Cs and 65Zn from soil to pearl millet and sorghum

International Nuclear Information System (INIS)

Sachdev, P.; Sachdev, M.S.; Deb, D.L.

1996-01-01

The soil to plant transfer factors (TF) of 137 Cs and 65 Zn were determined for two crops, sorghum and pearl millet, under irrigated conditions in greenhouse and under rain fed conditions in field. In the greenhouse experiment, the accumulation of 137 Cs was almost doubled when the soil contamination level was doubled. Under field conditions, 137 Cs concentration in both pearl millet and sorghum grains as well as straw was nearly four times more at 148 kBq Kg -1 level of soil contamination as compared to lower level of 74 kBq kg -1 soil. The TF values for 65 Zn determined under greenhouse conditions for both the crops were nearly a hundred-fold higher as compared to 137 Cs. (author). 7 refs., 2 tabs

The transfer factors of I, Ba, Sr, Y and Zr from soil to leafy vegetables

International Nuclear Information System (INIS)

Luo Daling; Li Mianfeng; Weng Senhan; Wen Guanghao; Liu Xiaowei; Zhang Cunxiang; Zhang Zeng; Yu Junyue

1996-01-01

The transfer factors of I, Ba, Sr, Y and Zr from soil to leafy vegetables have been determined using method of radioisotope tracers and element content analysis. The effects of growth period, size of the vegetables, contents of the isotopes in the soil and other climatic factors on the transfer factors have also been studied

Transfer factors of 226Ra, 210Pb and 210Po from NORM-contaminated oil field soil to some Atriplex species, Alfalfa and Bermuda grass

International Nuclear Information System (INIS)

Al-Masria, M.S.; Mukalallati, H.; Al-Hamwi, A.

2014-01-01

Transfer factors of 226 Ra, 210 Pb and 210 Po from soil contaminated with naturally occurring radioactive materials (NORM) in oil fields to some grazing plants were determined using pot experiments. Contaminated soil was collected from a dry surface evaporation pit from a Syrian oil field in the Der Ezzor area. Five types of plants (Atriplex halimus L., Atriplex canescens, Atriplex Leucoclada Bioss, Alfalfa and Bermuda grass) were grown and harvested three times over two years. The results show that the mean transfer factors of 226 Ra from the contaminated soil to the studied plant species were 1.6 x 10 -3 for Atriplex halimus L., 2.1 x 10 -3 for Atriplex canescens, 2.5 x 10 -3 for Atriplex Leucoclada Bioss, 8.2 x 10 -3 for Bermuda grass, and the highest value was 1.7 x 10 -2 for Alfalfa. Transfer factors of 210 Pb and 210 Po were higher than 226 Ra TFs by one order of magnitude and reached 7 x 10 -3 , 1.1 x 10 -2 , 1.2 x 10 -2 , 3.2 x 10 -2 and 2.5 x 10 -2 for Atriplex halimus, Atriplex canescens, Atriplex Leucoclada Bioss, Bermuda grass and Alfalfa, respectively. The results can be considered as base values for transfer factors of 226 Ra, 210 Pb and 210 Po in semiarid regions. (authors)

Influence of fertilizing on the 137Cs soil-plant transfer in a spruce forest of Southern Germany

International Nuclear Information System (INIS)

Zibold, G.; Klemt, E.; Konopleva, I.; Konoplev, A.

2009-01-01

Fertilization with 2.5 t/ha limestone: (83% CaCO 3 , 8% MgO, 6% K 2 O, 3% P 2 O 5 ) reduces the 137 Cs transfer from spruce forest soil into plants like fern (Dryopteris carthusiana) and blackberry (Rubus fruticosus) by a factor of 2-5 during at least 11 years as measured by the aggregated transfer factor T ag . In 1997 and 2006 these results were confirmed by additional measurements of the 137 Cs transfer factor TF, related to the root zone (O h horizon), which were explained by the selective sorption of 137 Cs in the root zone by measurements of the Radiocaesium Interception Potential (RIP) in fertilized (RIP > 179 meq/kg) and non-fertilized soils (RIP < 74 meq/kg).

Study on transfer of cadmium in soil-plant systems with the isotopic dilution method

International Nuclear Information System (INIS)

Wu Qitang; Morel, J.L.; Guckert, A.

1993-01-01

Experiments were conducted to determine the transfer rate from endogenous and exogenous cadmium in soil to plants. Soils were labelled with 109 Cd and amended with soluble cadmium salt or Cd containing sewage sludge. Ryegrass (Lolium perenne L.) were grown in pots and the effective transfer of cadmium from different sources to shoot of the plant were measured. The soils were also extracted with 0.1 M CaCl 2 , DTPA and 0.1 N HCl. The results showed that the addition of soluble cadmium salt substantially increased the plant cadmium content. Plant absorbed mainly the cadmium from exogenous sources in the soils treated with cadmium. The effective transfer rate of exogenous cadmium was higher than that of endogenous ones, and the soluble salt form was 2 to 3 times higher than that in the sewage sludge. 0.1 M CaCl 2 extracted Cd was significantly correlated with the plant cadmium content. The specific radioactivity of cadmium extracted by this reagent was nearer to the plant cadmium than that extracted by others. 0.1 N HCl extracted cadmium could not be absorbed by plants

Study of soil-plant transfer of 226Ra under greenhouse conditions

International Nuclear Information System (INIS)

Soudek, Petr; Petrova, Sarka; Benesova, Dagmar; Kotyza, Jan; Vagner, Martin; Vankova, Radomira; Vanek, Tomas

2010-01-01

A soil-plant transfer study was performed using soil from a former uranium ore processing factory in South Bohemia. We present the results from greenhouse experiments which include estimates of the time required for phytoremediation. The accumulation of 226 Ra by different plant species from a mixture of garden soil and contaminated substrate was extremely variable, ranging from 0.03 to 2.20 Bq 226 Ra/g DW. We found differences in accumulation of 226 Ra between plants from the same genus and between cultivars of the same plant species. The results of 226 Ra accumulation showed a linear relation between concentration of 226 Ra in plants and concentration of 226 Ra in soil mixtures. On the basis of these results we estimated the time required for phytoremediation, but this appears to be too long for practical purposes.

Migration of 137Cs in soils and its transfer to mushrooms and vascular plants in mixed forest

International Nuclear Information System (INIS)

Pietrzak-Flis, Z.; Radwan, I.; Rosiak, L.; Wirth, E.

1996-01-01

Migration of 137 Cs in the podzol soil and transfer of 137 Cs, 134 Cs and potassium from the soil to mushrooms and vascular plants in the mixed forest at the Kampinos National Park near Warsaw, Poland, was studied in 1994 at locations lying about 6 km apart. In the soil at both locations, up to about 40% of 137 Cs was present in the Of horizon and slightly less in the mixed organic/mineral OhAh horizon. The data indicate a slow vertical migration of radiocesium. Total content of 137 Cs in the soils was 3000 Bq m -2 . The enrichment of the Of horizon in 137 Cs from the decomposing mushroom fruitbodies was evaluated and it was shown that it can significantly contribute to the horizontal displacement of radiocesium. Transfer factors (TF) for mushrooms and Calluna were calculated using the concentrations of 137 Cs in the Of horizons, whereas for grass, Vaccinium myrtillus and Polypodium vulgare TF were calculated using a weighted mean concentration of 137 Cs in the nutritive horizons with organic matter as a weight

Application of of artificial neural networks for estimation of soil-plant transfer factor for {sup 137}Cs; Aplicacao de redes neurais artificiais para a previsao de valores do fator de transferencia solo-planta para {sup 137}Cs

Energy Technology Data Exchange (ETDEWEB)

Santos, Anna Karla Gomes dos

2016-07-01

The knowledge of radionuclide behavior in soils is fundamental to calculate the dose due to food ingestion and to evaluate the risks of radioactive exposure of the population. This knowledge associated to the socio-economic characteristics of the affected region will set the radio protective measures to be taken in case of radioactive contamination of rural areas. The soil-plant transfer factor (TF) is the specific parameter value of radiological models to numerically integrate the dynamic processes that occur within the radionuclides in the soil plant system. This measurement, specific to each radionuclide and soil type, is defined ratio between a specific radionuclide activity in the edible part of the plant and its soil activity. However, the absence of linearity between soil concentrations and the measurements in plants indicate the complexity of the transfer process of radionuclide from soil to a plant, making it difficult to forecast the TF ratio in a specific scenario. One of the main radionuclides associated to nuclear accidents impacting rural areas is {sup 137}Cs. This is one of the most worrisome radionuclides because of its physiochemical properties and its chemical similarity with potassium (K) and its extended physical mid-life (t1/2 = 30,17 years) that allows great environmental dispersion, ecological mobility and environmental endurance. Radiological studies related to {sup 137}Cs transfer factor show that pedological parameters that considerably explain the behavior of {sup 137}Cs in soil-plant system are: exchangeable K, clayed minerals, organic matter content and pH in soils. In this work, the computational method of artificial neural network (ANN) was applied to evaluate the possibility to forecast the TF of {sup 137}Cs in cereals, associated to pedological parameters considered potential indicators of its phyto availability: cationic exchange capacity (CEC), exchangeable K and pH. This study demonstrated that the ANN, having only as entry data

Caesium-137 soil-to-plant transfer for representative agricultural crops of monocotyledonous and dicotyledonous plants in post-Chernobyl steppe landscape

Science.gov (United States)

Paramonova, Tatiana; Komissarova, Olga; Turykin, Leonid; Kuzmenkova, Natalia; Belyaev, Vladimir

2016-04-01

The accident at the Chernobyl nuclear power plant in 1986 had a large-scale action on more than 2.3 million hectares agricultural lands in Russia. The area of radioactively contaminated chernozems of semi-arid steppe zone with initial levels of Cs-137 185-555 kBq/m2 in Tula region received the name "Plavsky radioactive hotspot". Nowadays, after the first half-life period of Cs-137 arable chernozems of the region are still polluted with 3-6-fold excess above the radioactive safety standard (126-228 kBq/m2). Therefore, qualitative and quantitative characteristics of Cs-137 soil-to-plant transfer are currently a central problem for land use on the territory. The purpose of the present study was revealing the biological features of Cs-137 root uptake from contaminated arable chernozems by different agricultural crops. The components of a grass mixture growing at the central part of Plavsky radioactive hotspot with typical dicotyledonous and monocotyledonous plants - galega (Galega orientalis, Fabaceae family) and bromegrass (Bromus inermis, Gramineae family) respectively - were selected for the investigation, that was conducted during the period of harvesting in 2015. An important point was that the other factors influenced on Cs-137 soil-to-plant transfer - the level of soil pollution, soil properties, climatic conditions, vegetative phase, etc. - were equal. So, biological features of Cs-137 root uptake could be estimated the most credible manner. As a whole, general discrimination of Cs-137 root uptake was clearly shown for both agricultural crops. Whereas Cs-137 activity in rhizosphere 30-cm layer of arable chernozem was 371±74 Bq/kg (140±32 kBq/m2), Cs-137 activities in plant biomass were one-two orders of magnitude less, and transfer factor (TF) values (the ratio of the Cs-137 activities in vegetation and in soil) not exceeded 0.11. At the same time bioavailability of Cs-137 for bromegrass was significantly higher than for galega: TFs in total biomass of the

Literature Review and Assessment of Plant and Animal Transfer Factors Used in Performance Assessment Modeling

International Nuclear Information System (INIS)

Robertson, David E.; Cataldo, Dominic A.; Napier, Bruce A.; Krupka, Kenneth M.; Sasser, Lyle B.

2003-01-01

A literature review and assessment was conducted by Pacific Northwest National Laboratory (PNNL) to update information on plant and animal radionuclide transfer factors used in performance-assessment modeling. A group of 15 radionuclides was included in this review and assessment. The review is composed of four main sections, not including the Introduction. Section 2.0 provides a review of the critically important issue of physicochemical speciation and geochemistry of the radionuclides in natural soil-water systems as it relates to the bioavailability of the radionuclides. Section 3.0 provides an updated review of the parameters of importance in the uptake of radionuclides by plants, including root uptake via the soil-groundwater system and foliar uptake due to overhead irrigation. Section 3.0 also provides a compilation of concentration ratios (CRs) for soil-to-plant uptake for the 15 selected radionuclides. Section 4.0 provides an updated review on radionuclide uptake data for animal products related to absorption, homeostatic control, approach to equilibration, chemical and physical form, diet, and age. Compiled transfer coefficients are provided for cow's milk, sheep's milk, goat's milk, beef, goat meat, pork, poultry, and eggs. Section 5.0 discusses the use of transfer coefficients in soil, plant, and animal modeling using regulatory models for evaluating radioactive waste disposal or decommissioned sites. Each section makes specific suggestions for future research in its area.

Literature Review and Assessment of Plant and Animal Transfer Factors Used in Performance Assessment Modeling

Energy Technology Data Exchange (ETDEWEB)

Robertson, David E.; Cataldo, Dominic A.; Napier, Bruce A.; Krupka, Kenneth M.; Sasser, Lyle B.

2003-07-20

A literature review and assessment was conducted by Pacific Northwest National Laboratory (PNNL) to update information on plant and animal radionuclide transfer factors used in performance-assessment modeling. A group of 15 radionuclides was included in this review and assessment. The review is composed of four main sections, not including the Introduction. Section 2.0 provides a review of the critically important issue of physicochemical speciation and geochemistry of the radionuclides in natural soil-water systems as it relates to the bioavailability of the radionuclides. Section 3.0 provides an updated review of the parameters of importance in the uptake of radionuclides by plants, including root uptake via the soil-groundwater system and foliar uptake due to overhead irrigation. Section 3.0 also provides a compilation of concentration ratios (CRs) for soil-to-plant uptake for the 15 selected radionuclides. Section 4.0 provides an updated review on radionuclide uptake data for animal products related to absorption, homeostatic control, approach to equilibration, chemical and physical form, diet, and age. Compiled transfer coefficients are provided for cow’s milk, sheep’s milk, goat’s milk, beef, goat meat, pork, poultry, and eggs. Section 5.0 discusses the use of transfer coefficients in soil, plant, and animal modeling using regulatory models for evaluating radioactive waste disposal or decommissioned sites. Each section makes specific suggestions for future research in its area.

Transfer factor values of 137 Cs from latosoils to vegetables

International Nuclear Information System (INIS)

Wasserman, Maria Angelica Moreira; Belem, Lilia Maria Juacaba

1996-01-01

Transfer Factor values for black beams, radish and carrot were obtained for soils artificially and accidentally contaminated in Goiania during 1987. Differences of 137 Cs-soil-to-plant transfer were discussed in the light of pedology and crop type. These values were about one order of magnitude higher than mean values reported by IUR for temperature climate for the same crops. These results advertising for the peculiar dynamics of 137 Cs in tropical soils and for needs to obtain regional data to be used in assessment dose models. (author)

Soil-plant transfer of Cs-137 and Sr-90 in digestate amended agricultural soils- a lysimeter scale experiment

Science.gov (United States)

Mehmood, Khalid; Berns, Anne E.; Pütz, Thomas; Burauel, Peter; Vereecken, Harry; Zoriy, Myroslav; Flucht, Reinhold; Opitz, Thorsten; Hofmann, Diana

2014-05-01

Radiocesium and radiostrontium are among the most problematic soil contaminants following nuclear fallout due to their long half-lives and high fission yields. Their chemical resemblance to potassium, ammonium and calcium facilitates their plant uptake and thus enhances their chance to reach humans through the food-chain dramatically. The plant uptake of both radionuclides is affected by the type of soil, the amount of organic matter and the concentration of competitive ions. In the present lysimeter scale experiment, soil-plant transfer of Cs-137 and Sr-90 was investigated in an agricultural silty soil amended with digestate, a residue from a biogas plant. The liquid fraction of the digestate, liquor, was used to have higher nutrient competition. Digestate application was done in accordance with the field practice with an application rate of 34 Mg/ha and mixing it in top 5 cm soil, yielding a final concentration of 38 g digestate/Kg soil. The top 5 cm soil of the non-amended reference soil was also submitted to the same mixing procedure to account for the physical disturbance of the top soil layer. Six months after the amendment of the soil, the soil contamination was done with water-soluble chloride salts of both radionuclides, resulting in a contamination density of 66 MBq/m2 for Cs-137 and 18 MBq/m2 for Sr-90 in separate experiments. Our results show that digestate application led to a detectable difference in soil-plant transfer of the investigated radionuclides, effect was more pronounced for Cs-137. A clear difference was observed in plant uptake of different plants. Pest plants displayed higher uptake of both radionuclides compared to wheat. Furthermore, lower activity values were recorded in ears compared to stems for both radionuclides.

Translocation of iodine-129 in soil and transfer to vegetation

International Nuclear Information System (INIS)

Handl, J.

1989-01-01

The translocation of I-129 in the soil and its long-term transfer from soil to plant have been investigated using an undisturbed soil column and a pasture on a river bank. The I-129 profiles in the soils of the monolith and the pasture exhibit clear differences in the distribution of radioiodine after 52 and 47 months, respectively. At those times after surface contamination of both soil types 88% (monolith) and 66% (pasture) of the total I-129 activity were found in the top soil layer of 10 cm, indicating that translocation in the pasture soil is faster than in the monolith. Apart from soil-specific parameters this behaviour may be explained by anaerobic conditions created in the soil due to high water levels in the nearby river attecting the chemical form of iodine. The distribution of stable iodine was found rather homogeneous in both soils with mean contents of 3 mg I-127 kg -1 d.w. in the upper 15 cm and 4 mg I-127 kg -1 d.w. in deeper layers in case of the monolith. For the pasture soil the corresponding values are about 4 and 5 mg I-127 kg -1 d.w. Transfer factors plant/soil (dry weight basis) of I-129 obtained from the monolith 39 g and 52 months after contamination are 1.5x10 -3 and 2.1x10 -3 , respectively. Data from the pasture 35 and 47 months after contamination show values of 9.0x10 -3 and 8.4x10 -3 , respectively. Transfer factors of stable iodine are significantly higher in both soils yielding an average value of 1.0 for the monolith and 0.3 for the pasture. Delay constants (related to a top soil layer of 10 cm) calculated for I-129 using data obtained from the long-term translocation processes to deeper soil layers in the monolith and in the pasture show values of 1x10 -9 s -1 and 4x10 -9 s -1 , respectively. (orig.) [de

Transfer Factors for Contaminant Uptake by Fruit and Nut Trees

Energy Technology Data Exchange (ETDEWEB)

Napier, Bruce A.; Fellows, Robert J.; Minc, Leah D.

2013-11-20

Transfer of radionuclides from soils into plants is one of the key mechanisms for long-term contamination of the human food chain. Nearly all computer models that address soil-to-plant uptake of radionuclides use empirically-derived transfer factors to address this process. Essentially all available soil-to-plant transfer factors are based on measurements in annual crops. Because very few measurements are available for tree fruits, samples were taken of alfalfa and oats and the stems, leaves, and fruits and nuts of almond, apple, apricot, carob, fig, grape, nectarine, pecan, pistachio (natural and grafted), and pomegranate, along with local surface soil. The samples were dried, ground, weighed, and analyzed for trace constituents through a combination of induction-coupled plasma mass spectrometry and instrumental neutron activation analysis for a wide range of naturally-occurring elements. Analysis results are presented and converted to soil-to-plant transfer factors. These are compared to commonly used and internationally recommended values. Those determined for annual crops are very similar to commonly-used values; those determined for tree fruits show interesting differences. Most macro- and micronutrients are slightly reduced in fruits; non-essential elements are reduced further. These findings may be used in existing computer models and may allow development of tree-fruit-specific transfer models.

Amelioration of soils contaminated with radionuclides: exploiting biodiversity to minimise or maximise soil to plant transfer

Energy Technology Data Exchange (ETDEWEB)

Willey, N. [University of the West of England, Centre for Research in Plant Science, Bristol (United Kingdom)

2004-07-01

Managing the transfer of radionuclides from soils into plants and thence food chains is an important immediate post-accident challenge for radio-ecologists. In the longer term, soil remediation is often necessary to eliminate the environmental impacts of accidents. Until the recent advent of molecular phylogenies for flowering plants there was no scientific framework through which to analyse the contribution of inter-species differences in radionuclide uptake by plants to these processes. We have already carried out such analyses for a variety of heavy metals and here report new biodiversity landscapes across the flowering plant phylum for radionuclides of Cs, Sr, S, Cl, I, Co and Ru that identify groups of plants with particularly low and high uptake. The plant groups are an untapped reservoir of biodiversity that might be exploited for minimising food chain contamination or maximising phyto-extraction of radionuclides. We have recently demonstrated the importance of biodiversity in minimising food chain contamination with {sup 137}Cs and exploiting biodiversity has recently brought spectacular and unexpected advances in phyto-extraction of As. The UK Food Standards Agency food chain model and recent advances in our phyto-extraction field trial at Bradwell Nuclear Power Station, UK will be used to illustrate for the first time the use of biodiversity landscapes for post-accident management and soil remediation. Biodiversity landscapes of inter-species differences in radionuclide uptake are also a foundation for a variety of developments in the genetic engineering of plant uptake and response to radionuclides. Results building on recent work we have carried out using K transport mutants of Arabidopsis and its implications for transport processes and engineering them in flowering plants will be discussed. Further, novel ongoing genomic and proteomic work into the molecular responses of Arabidopsis to ionising radiation and its implications for selecting plants from

Amelioration of soils contaminated with radionuclides: exploiting biodiversity to minimise or maximise soil to plant transfer

International Nuclear Information System (INIS)

Willey, N.

2004-01-01

Managing the transfer of radionuclides from soils into plants and thence food chains is an important immediate post-accident challenge for radio-ecologists. In the longer term, soil remediation is often necessary to eliminate the environmental impacts of accidents. Until the recent advent of molecular phylogenies for flowering plants there was no scientific framework through which to analyse the contribution of inter-species differences in radionuclide uptake by plants to these processes. We have already carried out such analyses for a variety of heavy metals and here report new biodiversity landscapes across the flowering plant phylum for radionuclides of Cs, Sr, S, Cl, I, Co and Ru that identify groups of plants with particularly low and high uptake. The plant groups are an untapped reservoir of biodiversity that might be exploited for minimising food chain contamination or maximising phyto-extraction of radionuclides. We have recently demonstrated the importance of biodiversity in minimising food chain contamination with 137 Cs and exploiting biodiversity has recently brought spectacular and unexpected advances in phyto-extraction of As. The UK Food Standards Agency food chain model and recent advances in our phyto-extraction field trial at Bradwell Nuclear Power Station, UK will be used to illustrate for the first time the use of biodiversity landscapes for post-accident management and soil remediation. Biodiversity landscapes of inter-species differences in radionuclide uptake are also a foundation for a variety of developments in the genetic engineering of plant uptake and response to radionuclides. Results building on recent work we have carried out using K transport mutants of Arabidopsis and its implications for transport processes and engineering them in flowering plants will be discussed. Further, novel ongoing genomic and proteomic work into the molecular responses of Arabidopsis to ionising radiation and its implications for selecting plants from

Soil-plant transfer models for metals to improve soil screening value guidelines valid for São Paulo, Brazil.

Science.gov (United States)

Dos Santos-Araujo, Sabrina N; Swartjes, Frank A; Versluijs, Kees W; Moreno, Fabio Netto; Alleoni, Luís R F

2017-11-07

In Brazil, there is a lack of combined soil-plant data attempting to explain the influence of specific climate, soil conditions, and crop management on heavy metal uptake and accumulation by plants. As a consequence, soil-plant relationships to be used in risk assessments or for derivation of soil screening values are not available. Our objective in this study was to develop empirical soil-plant models for Cd, Cu, Pb, Ni, and Zn, in order to derive appropriate soil screening values representative of humid tropical regions such as the state of São Paulo (SP), Brazil. Soil and plant samples from 25 vegetable species in the production areas of SP were collected. The concentrations of metals found in these soil samples were relatively low. Therefore, data from temperate regions were included in our study. The soil-plant relations derived had a good performance for SP conditions for 8 out of 10 combinations of metal and vegetable species. The bioconcentration factor (BCF) values for Cd, Cu, Ni, Pb, and Zn in lettuce and for Cd, Cu, Pb, and Zn in carrot were determined under three exposure scenarios at pH 5 and 6. The application of soil-plant models and the BCFs proposed in this study can be an important tool to derive national soil quality criteria. However, this methodological approach includes data assessed under different climatic conditions and soil types and need to be carefully considered.

Transference factor of radiocaesium for the different compartments of a mediterranean forest and the relation between the radiocaesium and the organic matter content in soils

International Nuclear Information System (INIS)

Rauret, G.; Sanchez-Reyes, A.F.; Febrian, I.; Llaurado, M.; Tejada, J.

1988-01-01

The new amount of radiocesium coming from Chernobyl may allow to study the soil-plant transfer factor for this element. The radiocesium distribution as well as the soil-plant transfer factor were studied for two zones located at the north east of Spain: the first one is a forest zone near the Catalan coast (Cabrils) and the second one is a mountainous zone 20 km far from the mediterranean Sea (Montseny). From the samples collected at Cabrils and at the Montseny zone, it is suggested to take the 134 Cs as a new indicator for the contamination originated after the Chernobyl accident. It seems reasonable to calculate the soil-plant transfer factor for this radioisotope instead of for 137 Cs, because of the 137 Cs double origin: the sixties fallout and the Chernobyl accident. The soil-plant 134 Cs transfer factor (T.F.) was calculated for different samples from the same sampling point and with similar organic matter content. The results for the Cabrils and Montseny zones are presented. It is observed that for aromatic plants the T.F. is about 0.6 while for green plants the T.F. is less than the above values. For moss, lichen and trumpery, the values obtained are in the range between 4 and 18, while for braken and mushrooms the T. F. values are less than 1

Korean experimental studies on the radionuclide transfer in crop plants

International Nuclear Information System (INIS)

Choi, Y.H.; Lim, K.M.; Choi, G.S.; Choi, H.J.; Lee, H.S.; Lee, C.W.

2003-01-01

In Korea, data on the radionuclide transfer in crop plants have been produced almost exclusively at the Korea Atomic Energy Research Institute (KAERI), where experimental studies have been carried out for last about 20 years. These works are briefly outlined in this paper which shows results with emphasis on rice data. Soil-to-plant transfer factors of radionuclides including radiocesium and radiostrontium were measured through greenhouse experiments for various crop species. Not only conventional transfer factors but also those based on the activity applied to unit area of the soil surface were investigated. Field studies on the transfer of fallout 137 Cs were carried out for rice and Chinese cabbage. As for parameters in relation to direct plant contamination, interception factors and translocation factors were obtained through greenhouse experiments. Plants were sprayed with radioactive solutions containing 54 Mn, 57 Co, 85 Sr, 103 Ru and 134 Cs at different growth stages. Experiments on the plant exposure to airborne HTO and I 2 vapor were also carried out. The transfer parameters generally showed great variations with soils, crops, radionuclides and isotope application times. Most experiments were designed for acute releases of radioactivity but some results are applicable to steady-state conditions, too. Many of the produced data would be of use also in other countries including Japan. (author)

Variability of 137Cs and 40K soil-to-fruit transfer factor in tropical lemon trees during the fruit development period

International Nuclear Information System (INIS)

Velasco, H.; Cid, A.S.; Anjos, R.M.; Zamboni, C.B.; Rizzotto, M.; Valladares, D.L.; Juri Ayub, J.

2012-01-01

In this investigation we evaluate the soil uptake of 137 Cs and 40 K by tropical plants and their consequent translocation to fruits, by calculating the soil-to-fruit transfer factors defined as F v = [concentration of radionuclide in fruit (Bq kg −1 dry mass)/concentration of radionuclide in soil (Bq kg −1 dry mass in upper 20 cm)]. In order to obtain F v values, the accumulation of these radionuclides in fruits of lemon trees (Citrus limon B.) during the fruit growth was measured. A mathematical model was calibrated from the experimental data allowing simulating the incorporation process of these radionuclides by fruits. Although the fruit incorporates a lot more potassium than cesium, both radionuclides present similar absorption patterns during the entire growth period. F v ranged from 0.54 to 1.02 for 40 K and from 0.02 to 0.06 for 137 Cs. Maximum F v values are reached at the initial time of fruit growth and decrease as the fruit develops, being lowest at the maturation period. As a result of applying the model a decreasing exponential function is derived for F v as time increases. The agreement between the theoretical approach and the experimental values is satisfactory. - Highlights: ► We assessed the transfer of 137 Cs and 40 K from soil to fruits in tropical plants. ► A mathematical model was developed to describe the dry mass growth of lemon fruits. ► The transfer factors ranged from 0.54 to 1.02 for 40 K and from 0.02 to 0.06 for 137 Cs. ► Maximum values of transfer factors were reached in the initial phase of fruit growth. ► The agreement between the theoretical and the experimental results was satisfactory.

Transfer of 137Cs from soil to plants in a wet montane forest in subtropical Taiwan

International Nuclear Information System (INIS)

Chih-Yu Chiu

1999-01-01

The distribution of 137 Cs in an undisturbed, multistoried, subtropical wet montane forest ecosystem surrounding Yuanyang Lake (lake surface level ca. 1670 m, in northeastern Taiwan), was investigated. The mossy forest here represents a currently-rare perhumid temperate environment in subtropical region. The radioactivity concentration of 137 Cs was determined by γ-spectroscopy with a Ge(Li) detector. Although the soil is extremely acidic (pH 3.3 to 3.6) and the rainfall is high, 137 Cs is evidently retained in the organic layer. The radioactivity concentration of 137 Cs in surface soil ranges from 28 to 71 Bq x kg -1 . The concentrations of 137 Cs in the ground moss layer and litter were much lower than that in the soil organic layer; this suggests that 137 Cs detected is not from the newly deposited radioactive fallout. The radioactivity concentration and transfer factor (TF) of 137 Cs varied with plant species. Shrubs and ferns have higher values than a coniferous tree (Taiwan cedar). The TF in this ecosystem is as high as 0.21 to 1.88. The high values of TF is attributed to the abundance of the organic matter in the forest soils. The rapid recycling of 137 Cs through the soil-plant system of this undisturbed multistoried ecosystem suggests the existence of an internal cycling that help the accumulation of 137 Cs in this ecosystem. (author)

Progress report on a filed study of soil-to-plant transfer of radioactive caesium, strontium and zinc in tropical Northern Australia

International Nuclear Information System (INIS)

Twining, J.; McOrist, G.; Zawadzki, A.; Shotton, P.

2000-09-01

This report covers: background, study location, design and rationale, farming practice and application, climate monitoring, summaries of the results of chemical analyses, gamma spectrometry and other analyses performed on plants and soil samples and calculation of transfer factors. Comparison with data from the literature, and a brief discussion of the results and implications for the on-going study are also presented. A detailed evaluation of the results has not been performed at this stage as the study is in progress.The main general observations to date are as follows. Transfer factors for caesium (Cs) and strontium (Sr) are not substantially different from the expected values based on the earlier studies mainly within temperate climates. In contrast, the values for zinc (Zn) are more than an order of magnitude greater than anticipated. Most of the radioactivity added to the soils has been retained in the top 5 cm of both soils. There has been a general decline in decay-corrected radioactivity in soils but also an indication of increased heterogeneity in surface distribution. Additional sampling will be undertaken to address this issue

Study of soil-plant transfer of {sup 226}Ra under greenhouse conditions

Energy Technology Data Exchange (ETDEWEB)

Soudek, Petr; Petrova, Sarka [Laboratory of Plant Biotechnologies, Joint Laboratory of Institute of Experimental Botany AS CR, v.v.i. and Crop Research Institute, v.v.i., Drnovska 507, 161 06 Prague 6 (Czech Republic); Benesova, Dagmar; Kotyza, Jan [Laboratory of Plant Biotechnologies, Joint Laboratory of Institute of Experimental Botany AS CR, v.v.i. and Crop Research Institute, v.v.i., Drnovska 507, 161 06 Prague 6 (Czech Republic); Faculty of Environment Technology, Institute of Chemical Technology, Technicka 5, 166 28 Prague 6 (Czech Republic); Vagner, Martin [Laboratory of Biologically Active Compounds, Institute of Experimental Botany AS CR, v.v.i., Rozvojova 263, Prague 6 (Czech Republic); Vankova, Radomira [Laboratory of Hormonal Regulations in Plants, Institute of Experimental Botany AS CR, v.v.i., Rozvojova 263, Prague 6 (Czech Republic); Vanek, Tomas, E-mail: vanek@ueb.cas.c [Laboratory of Plant Biotechnologies, Joint Laboratory of Institute of Experimental Botany AS CR, v.v.i. and Crop Research Institute, v.v.i., Drnovska 507, 161 06 Prague 6 (Czech Republic)

2010-06-15

A soil-plant transfer study was performed using soil from a former uranium ore processing factory in South Bohemia. We present the results from greenhouse experiments which include estimates of the time required for phytoremediation. The accumulation of {sup 226}Ra by different plant species from a mixture of garden soil and contaminated substrate was extremely variable, ranging from 0.03 to 2.20 Bq {sup 226}Ra/g DW. We found differences in accumulation of {sup 226}Ra between plants from the same genus and between cultivars of the same plant species. The results of {sup 226}Ra accumulation showed a linear relation between concentration of {sup 226}Ra in plants and concentration of {sup 226}Ra in soil mixtures. On the basis of these results we estimated the time required for phytoremediation, but this appears to be too long for practical purposes.

Examination of radioactive contamination in the soil-plant system and their transfer to selected animal tissues

International Nuclear Information System (INIS)

Chibowski, S.; Gladysz, A.

1999-01-01

This paper investigates gamma emitter radioactivity in a system consisting of soil and plants. Some selected sample of tissues of animals fed with the plants from these sites were also measured. In soil and plant samples artificial ( 137 Cs and 134 Cs) and natural (thorium and uranium series) isotopes were detected. Despite the relatively high content of the natural isotopes in plants and their seeds, their accumulation in animal tissues was not detected.The 40 K isotope was transferred in the chain soil-plant-animal in the highest degree. From the group of the natural isotopes, only 212 Pb was detected in examined animal tissue samples. Other natural isotopes were below detection level. In the samples heavy metal content was also examined. In any sample no element concentration was noticed above trade acceptable limit. (author)

Study of solution speciation, soil retention and soil-plant transfer of zirconium; Etude de la speciation en solution, de la retention dans les sols et du transfert sol-plante du zirconium

Energy Technology Data Exchange (ETDEWEB)

Ferrand, E

2005-12-15

Within the framework of the risks prevention policy of Andra, the radioactive zirconium introduction ({sup 93}Zr and {sup 95}Zr) into the environment could be carried out starting from the nuclear waste whose storage is envisaged in deep geological layers. Thus, the goal of this study was to evaluate the parameters and phenomena influencing speciation (various chemical forms) and the soil-plant transfer of zirconium. Experiments of adsorption/desorption of zirconium with different ligands likely to be present in soils (goethite and humic acid) and with two soils, with contrasted characteristics, close to the underground research laboratory of Andra (Meuse) were carried out. These results of adsorption were then confronted with those obtained by the MUSIC and NICA-DONNAN models carried out using the computer code ECOSAT. Zr presents a strong affinity for the two types of soils and the soils constituents. Specific interactions of internal sphere type with the goethite were highlighted using the model. Soil-solution partition coefficients, or K{sub d}, values increase with pH and contact time. Various types of edible plants, pea (Pisum sativum L.) and tomato (Lycopersicon esculentum L cv. St Pierre) were cultivated in hydroponic conditions and in soils spiked with various sources of Zirconium. The maximum zirconium contents are mainly measured in the roots of the plants. The soil-plant transfer factors measured during these experiments show a weak bioavailability of zirconium. An influence of speciation on Zr bioavailability is however highlighted. Some chemical forms, such as oxychloride or acetate, are more easily mobilized than others by the plant. (author)

Soil-plant transfer factors of radionuclides in mangroves in the State of Pernambuco, Brazil; Fatores de transferência solo-planta de radionuclídeos em manguezais do Estado de Pernambuco, Brasil

Energy Technology Data Exchange (ETDEWEB)

Paiva, J.D.S.; França, E.J. de, E-mail: paivajds@gmail.com [Centro Regional de Ciências Nucleares do Nordeste (CRCN-NE/CNEN-PE), Recife, PE (Brazil)

2017-07-01

Mangroves are the main inputs of chemical substances, considering the Brazilian estuarine environments. Natural radionuclides such as {sup 40}K and {sup 228}Ra can be transferred to vegetation. The objective of this work is to determine the transfer factors (TF) and aggregate transfer (TF{sub ag}) of radionuclides {sup 40}K and {sup 228}Ra in the soil-plant system of mangroves in the State of Pernambuco , Brazil. Concentrations of {sup 40}K and {sup 228}Ra activity in the soil of mangroves and in samples composed of leaves of individuals of the native plant species Rhizophora mangle, Laguncularia racemosa and Aviccenia Schaueriana were determined from Gamma Spectrometry with hyper-pure germanium detector (HPGe). The transfer and aggregate transfer factors were calculated according to the methodology proposed in the literature. The respective TF and TF{sub ag} values for the {sub 40}K radionuclide were 0.384 and 2.13 x 10{sup -3} for R. mangle; 0.394 and 2.05 x 10{sup -3} for L. racemosa and 1.348 and 3.44 x 10{sup -3} for Avicennia sp. For the radionuclide {sup 228}Ra, the results were lower for R. mangle (TF = 0.089; TF{sub ag} = 1.95 x 10{sup -4}) and L. race-mosa (TF = 0.142; TF{sub ag} = 3.46 x 10{sup -4}). For Avicennia schaueriana, the concentrations of {sup 228}Ra activity in the leaves were below the detection limit. The TF values found demonstrated a greater {sup 40}K transfer in Avicennia and {sup 228}Ra dominated mangroves for mangroves where the L. racemosa distribution predominates.

Tracing the origin of dissolved silicon transferred from various soil-plant systems towards rivers: a review

Directory of Open Access Journals (Sweden)

J.-T. Cornelis

2011-01-01

Full Text Available Silicon (Si released as H₄SiO₄ by weathering of Si-containing solid phases is partly recycled through vegetation before its land-to-rivers transfer. By accumulating in terrestrial plants to a similar extent as some major macronutrients (0.1–10% Si dry weight, Si becomes largely mobile in the soil-plant system. Litter-fall leads to a substantial reactive biogenic silica pool in soil, which contributes to the release of dissolved Si (DSi in soil solution. Understanding the biogeochemical cycle of silicon in surface environments and the DSi export from soils into rivers is crucial given that the marine primary bio-productivity depends on the availability of H₄SiO₄ for phytoplankton that requires Si. Continental fluxes of DSi seem to be deeply influenced by climate (temperature and runoff as well as soil-vegetation systems. Therefore, continental areas can be characterized by various abilities to transfer DSi from soil-plant systems towards rivers. Here we pay special attention to those processes taking place in soil-plant systems and controlling the Si transfer towards rivers. We aim at identifying relevant geochemical tracers of Si pathways within the soil-plant system to obtain a better understanding of the origin of DSi exported towards rivers. In this review, we compare different soil-plant systems (weathering-unlimited and weathering-limited environments and the variations of the geochemical tracers (Ge/Si ratios and δ³⁰Si in DSi outputs. We recommend the use of biogeochemical tracers in combination with Si mass-balances and detailed physico-chemical characterization of soil-plant systems to allow better insight in the sources and fate of Si in these biogeochemical systems.

Parameters on the radionuclide transfer in crop plants for Korean food chain dose assessment

International Nuclear Information System (INIS)

Choi, Yong Ho; Lim, K. M.; Cho, Y. H.

2001-12-01

For more realistic assessment of Korean food chain radiation doses due to the operation of nuclear facilities, it is required to use domestically produced data for radionuclide transfer parameters in crop plants. In this report, results of last about 15 years' studies on radionuclide transfer parameters in major crop plants by the Korea Atomic Energy Research Institute, were summarized and put together. Soil-to-plant transfer factors, parameters quantifying the root uptake of radionuclides, were measured through greenhouse experiments and field studies. In addition to traditional transfer factors, which are based on the activity in unit weight of soil, those based on the activity applied to unit area of soil surface were also investigated. Interception factors, translocation factors and weathering half lives, parameters in relation to direct plant contamination, were investigated through greenhouse experiments. The levels of initial plant contamination with HTO and I2 vapor were described with absorption factors. Especially for HTO vapor, 3H levels in crop plants at harvest were expressed with TFWT (tissue free water tritium) reduction factors and OBT (organically bound tritium) production factors. The above-mentioned parameters generally showed great variations with soils, crops and radionuclide species and application times. On the basis of summarized results, the points to be amended or improved in food chain dose assessment models were discussed both for normal operation and for accidental release

Selenium bioavailability and uptake as affected by four different plants in a loamy clay soil with particular attention to mycorrhizae inoculated ryegrass

International Nuclear Information System (INIS)

Munier-Lamy, C.; Deneux-Mustin, S.; Mustin, C.; Merlet, D.; Berthelin, J.; Leyval, C.

2007-01-01

The aim of this study was to investigate the influence of plant species, especially of their rhizosphere soil, and of inoculation with an arbuscular mycorrhizal (AM) fungus on the bioavailability of selenium and its transfer in soil-plant systems. A pot experiment was performed with a loamy clay soil and four plant species: maize, lettuce, radish and ryegrass, the last one being inoculated or not with an arbuscular mycorrhizal fungus (Glomus mosseae). Plant biomass and Se concentration in shoots and roots were estimated at harvest. Se bioavailability in rhizosphere and unplanted soil was evaluated using sequential extractions. Plant biomass and selenium uptake varied with plant species. The quantity of rhizosphere soil also differed between plants and was not proportional to plant biomass. The highest plant biomass, Se concentration in plants, and soil to plant transfer factor were obtained with radish. The lowest Se transfer factors were obtained with ryegrass. For the latter, mycorrhizal inoculation did not significantly affect plant growth, but reduced selenium transfer from soil to plant by 30%. In unplanted soil after 65 days aging, more than 90% of added Se was water-extractable. On the contrary, Se concentration in water extracts of rhizosphere soil represented less than 1% and 20% of added Se for ryegrass and maize, respectively. No correlation was found between the water-extractable fraction and Se concentration in plants. The speciation of selenium in the water extracts indicated that selenate was reduced, may be under organic forms, in the rhizosphere soil

Trophic transfer of soil arsenate and associated toxic effects in a plant-aphid-parasitoid system

Science.gov (United States)

Lee, Y. S.; Wee, J.; Lee, M.; Hong, J.; Cho, K.

2017-12-01

Terrestrial toxic effects of soil arsenic were studied using a model system consisting of soil which artificially treated with arsenic, Capsicum annum,Myzus persicae and Aphidus colemani. We investigated the transfer of arsenic in a soil-plant-aphid system and toxic effect of elevated arsenic through a plant-aphid-parasitoid system. To remove the effect of poor plant growth on aphid performance, test concentrations which have a no effect on health plant growth were selected. Arsenic concentration of growth medium, plant tissues (root, stem, leaf) aphids were measured to observe the arsenic transfer. Correlation matrix was made with arsenic in growth medium which extracted with three extractants (aquaregia, 0.01 M CaCl2 and deionized water), arsenic in plant tissues and plant performance. Toxic effects of elevated arsenic concentrations on each species were investigated at population level. Studied plant performances were dry weight of each tissue, elongation of roots and stems, area of leaves, chlorophyll content of leaves, protein content of leaves and sugar content of leaves. Mean development time, fecundity and honeydew excretion of the aphids and host choice capacity and parasitism success of the parasitoids were examined. In addition, enzyme activities of the plants and the aphids against reactive oxygen species (ROS) induced by arsenic stress were also investigated. The results suggest that arsenic concentration in plant tissues and aphids were elevated with increased concentration of arsenic in soil. Decreased fecundity and honeydew excretion of aphids were observed and decreased eclosion rate of parasitoids were observed with increased arsenic treatment in growth medium. The results showed low concentration of arsenic in soil can transfer through food chain and can impact on higher trophic level species.

Soil-to-plant transfer factors of stable elements and naturally occurring radionuclides. (1) Upland field crops collected in Japan

International Nuclear Information System (INIS)

Uchida, Shigeo; Tagami, Keiko; Hirai, Ikuko

2007-01-01

In long-term dose assessment models for radioactive waste disposal, an important exposure pathway to humans is via ingestion of contaminated foods. In order to obtain soil-to-plant transfer factors (TFs) of radionuclides under equilibrium conditions, naturally existing elements were measured as analogues of radionuclides. Crops grown in upland fields and associated soil samples were collected from 62 sampling sites throughout Japan. The total concentrations of 52 elements in the crops and 54 elements in the soil samples were measured. The TFs of 40 elements (Li, Na, Mg, Al, Si, P, K, Ca, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, As, Se, Rb, Sr, Y, Mo, Cd, Sn, Cs, Ba, La, Ce, Pr, Nd, Sm, Eu, Gd, Dy, Ho, Er, Pb, Th and U) were calculated on a dry weight basis. Among all the TF data, K showed the highest TF with a geometric mean (GM) of 2.1, followed by P. The GMs of TFs for rare earth elements, Th and U were on the order of 10 -4 . Most of the TF-GMs for green vegetables were higher than GMs of all crops for the elements. The obtained TFs of some elements for green vegetables and potatoes were compared with those in the technical report series-364 (TRS-364) compiled by IAEA in 1994. The TF-GMs were usually lower than the best estimates (expected values) listed in TRS-364; however, the GMs of TF for La and TF for Th observed for potatoes were slightly higher than the expected values. (author)

Transfer of wastewater associated pharmaceuticals and personal care products to crop plants from biosolids treated soil.

Science.gov (United States)

Wu, Chenxi; Spongberg, Alison L; Witter, Jason D; Sridhar, B B Maruthi

2012-11-01

The plant uptake of emerging organic contaminants such as pharmaceuticals and personal care products (PPCPs) is receiving increased attention. Biosolids from municipal wastewater treatment have been previously identified as a major source for PPCPs. Thus, plant uptake of PPCPs from biosolids applied soils needs to be understood. In the present study, the uptake of carbamazepine, diphenhydramine, and triclocarban by five vegetable crop plants was examined in a field experiment. At the time of harvest, three compounds were detected in all plants grown in biosolids-treated soils. Calculated root concentration factor (RCF) and shoot concentration factor (SCF) are the highest for carbamazepine followed by triclocarban and diphenhydramine. Positive correlation between RCF and root lipid content was observed for carbamazepine but not for diphenhydramine and triclocarban. The results demonstrate the ability of crop plants to accumulate PPCPs from contaminated soils. The plant uptake processes of PPCPs are likely affected by their physico-chemical properties, and their interaction with soil. The difference uptake behavior between plant species could not solely be attributed to the root lipid content. Copyright © 2012 Elsevier Inc. All rights reserved.

Transfer of lead (Pb) in the soil-plant-mealybug-ladybird beetle food chain, a comparison between two host plants.

Science.gov (United States)

Zhang, Can; Wang, Xingmin; Ashraf, Umair; Qiu, Baoli; Ali, Shaukat

2017-09-01

Contamination of soil with heavy metals has become an issue of concern on global scale. This study investigates the translocation of lead (Pb) along the soil - plant (eggplant and tomato) - mealybug (Dysmicoccus neobrevipes) - ladybird beetle (Cryptolaemus montrouzieri) food chain. Soil amendments used for this study were adjusted to 0, 25, 50 and 100mg/kg of Pb (w/w). The results revealed significantly higher transfer of Pb in tomato when compared to eggplant. Bio-magnification of Pb (2-4 times) was observed for soil - root transfer whereas Pb was bio-minimized in later part of food chain (shoot - mealybug - ladybird transfer). A dose dependent increase in transfer of Pb across the multi-trophic food chain was observed for both host plants. A decrease in coefficients of Pb transfer (from root - shoot and shoot - mealybug) was observed with increase in Pb concentrations. Our results also showed removal of Pb from the bodies of ladybird beetle during metamorphosis. Further studies are required to explain the mechanisms or physiological pathways involved in the bio-minimization of Pb across the food chain. Copyright © 2017 Elsevier Inc. All rights reserved.

Soil-to-crop transfer factors of radium in Japanese agricultural fields

International Nuclear Information System (INIS)

Uchida, S.; Tagami, K.

2007-01-01

The concentrations of 226 Ra in upland field crops (e.g., cabbage, leek, onion, potato, and so on) and associated soils collected from 45 locations throughout Japan were determined in order to obtain soil-to-crop transfer factors (TFs). Concentrations of 226 Ra in the soils collected in southwestern Japan were higher than those in northeastern Japan; however, no correlations between 226 Ra concentrations in crops and soils were observed. The TFs ranged from -3 to 5.8 x 10 -2 with a geometric mean of 6.4 x 10 -3 . These data were within the 95% confidential range of TF-Ra for several crops as reported in the IAEA Technical Reports Series No.364. Among the alkaline earth metals. TF-Ba was similar to TF-Ra. (author)

Transfer of {sup 40}K, {sup 238}U, {sup 210}Pb, and {sup 210}Po from soil to plant in various locations in south of Syria

Energy Technology Data Exchange (ETDEWEB)

Al-Masri, M.S. [Atomic Energy Commission of Syria, Damascus, P.O. Box 6091 (Syrian Arab Republic)], E-mail: scientific1@aec.org.sy; Al-Akel, B.; Nashawani, A.; Amin, Y.; Khalifa, K.H.; Al-Ain, F. [Atomic Energy Commission of Syria, Damascus, P.O. Box 6091 (Syrian Arab Republic)

2008-02-15

Transfer factors of {sup 40}K, {sup 238}U, {sup 210}Pb, and {sup 210}Po from soil to some agriculture crops in various locations in south of Syria (Dara'a and Assuwaydaa districts) have been determined. Soil and vegetable crops (green pepper, cucumber, tomato, and eggplant), legumes crops (lentil, chickpea, and broad bean), fruit trees (apple, grape, and olives) and cereals (barley and wheat) were collected and analyzed for {sup 238}U, {sup 210}Pb, and {sup 210}Po. The results have shown that higher transfer factors (calculated as Bq kg{sup -1} dry wt. plant material per Bq kg{sup -1} dry wt. soil) for {sup 210}Po, {sup 210}Pb and {sup 238}U were observed in vegetable leaves than fruits and cereals leaves; the highest values of transfer factor (TF) for {sup 238}U were found to be 0.1 for straw of chickpea. Transfer factors for {sup 210}Po varied between 2.8 x 10{sup -2} and 2 in fruits of eggplant and grain of barley, respectively. In addition, several parameters affecting transfer factors of the radionuclides were evaluated. The results can be considered as base values for TF of natural radionuclides in the region.

Relations between variously available fractions of trace metals in the soil and their actual plant-uptake

International Nuclear Information System (INIS)

Bujtas, K.; Csillag, J.

1999-01-01

In a pot experiment, availabilities of Cd, Cr, Ni, Pb, and Zn added to the soil as metal nitrates or as enrichment of sewage sludge were evaluated by comparing concentrations of their total potentially available, presumably plant-available and directly plant-available forms in the soil. At excessively increasing soil contamination, the plant-available concentrations increased more than the total soil contents, thus the relative availabilities of the metals increased. This was reflected in the amounts taken up by the young maize test plants and in the plant/soil transfer factors. Transfer factors calculated for the 'plant-available' soil metal contents depended less on the contamination level than those based on total soil metal contents. Refs. 8 (author)

Transfer factors of 137Cs and 90Sr from soil to some trees in Syria

International Nuclear Information System (INIS)

Al-Oudat, M.; Al-Asfary, A. F.; Mukalati, H.; Hamwi, A.; Kanakri, S.

2004-12-01

The transfer factor of Cs 137 and 90 Sr from contaminated soil (Aridisol = Yermosol according to FAO - UNESCO) to some common trees (olive, apricot, grape, pine, apple and lemon) were investigated under field condition for 3 to 6 years. There were large variation in transfer factors values among tree species, and between different parts of tree. The values in fruits for 137 Cs were: 0.011 (highest) in Apricot, 0.0071 in olive, and 0.0025 in vine, and about 0.0012 in olive oil (lowest). The mean transfer factor of 137 Cs in the one year old leaves and stems, ranged between 0.011 and 0.0093 in lemon (highest) and 0.0016 and 0.0015 in pine (lowest). The transfer factor values of 90 Sr were much higher than that of 137 Cs, they were in fruits: 0.13 in apricot, 0.093 in olive, and 0.075 in vine and 0.0053 in olive oil. The transfer factors values of 90 Sr ranged in one year old leaves between 2.89 (apple) and 0.1 (pine), while they ranged in one year old stems between 1.91 (apricot) and 0.16 (pine). The transfer factor of both 137 Cs and 90 Sr decrease in most trees parts with time especially in the one year old leaves, due to aging effects. The transfer factor values of 137 Cs and 90 Sr were lower than that reported for other areas. This might be due to the physical and chemical properties of the soil, where the soil used had a loamy clay structure with high ph (7.8) and high CEC (25.9 meq/100g), exchangeable potassium (1.6 meq/100g) and calcium (14.9 meq/100g), further more, climatic condition in the area, like high light intensity, high temperature and low air humidity, can lead to decrease the uptake of both 137 Cs and 90 Sr. (Authors)

Transfer factors for nuclear emergency preparedness

Energy Technology Data Exchange (ETDEWEB)

Kostiainen, E.; Haenninen, R. [Radiation and Nuclear Safety Authority (STUK) (Finland); Rosen, K.; Haak, E.; Eriksson, Aa. [Swedish Univ. of Agricultural Science (Sweden); Nielsen, S.P.; Keith-Roach, M. [Risoe National Lab. (Denmark); Salbu, B. [Agricultural Univ. of Norway (Norway)

2002-12-01

This report by the NKS/BOK-1.4 project subgroup describes transfer factors for radiocaesium and radiostrontium for the fallout year and the years after the fallout. The intention has been to collect information on tools to assess the order of magnitude of radioactive contamination of agricultural products in an emergency situation in Nordic environment. The report describes transfer paths from fallout to plant, from soil to plant and to animal products. The transfer factors of radionuclides (Sr, Cs, I) given in the report are intended to be used for making rough estimates of the contamination of agricultural products soon after the heaviness and composition of the deposition (Bq m{sup -2}) is known. (au)

Transfer factors for nuclear emergency preparedness

International Nuclear Information System (INIS)

Kostiainen, E.; Haenninen, R.; Rosen, K.; Haak, E.; Eriksson, Aa.; Nielsen, S.P.; Keith-Roach, M.; Salbu, B.

2002-12-01

This report by the NKS/BOK-1.4 project subgroup describes transfer factors for radiocaesium and radiostrontium for the fallout year and the years after the fallout. The intention has been to collect information on tools to assess the order of magnitude of radioactive contamination of agricultural products in an emergency situation in Nordic environment. The report describes transfer paths from fallout to plant, from soil to plant and to animal products. The transfer factors of radionuclides (Sr, Cs, I) given in the report are intended to be used for making rough estimates of the contamination of agricultural products soon after the heaviness and composition of the deposition (Bq m -2 ) is known. (au)

Transfer from soil to plants of 106Ru as nitrosyl and as chloride

International Nuclear Information System (INIS)

Handl, J.

1988-01-01

The transfer of 106 Ru in a soil-plant ecosystem was investigated with respect to two chemical forms in compact soil samples under greenhouse conditions with surface and deep-layer contamination. Considerable differences in the uptake of 106 Ru were observed between 106 RuCl3 and 106 Ru-nitrosyl during the first 5-8 wk after the contamination of the soil. The translocation of 106 Ru in the soil showed an inhomogeneous distribution of the radioruthenium, with a great part of the total activity remaining in the upper soil layer between 0 and 5 cm even 10 mo after contamination of the soil surface. During the whole experiment, reemission of 106 Ru into the air was investigated by using special air collectors under different temperature and light conditions. Although a continuous checking out for a time of about 8 mo, no measurable concentrations of 106 Ru could be out for a time of about 8 mo, no measurable concentrations of 106 Ru could be found in examined air filters

Modification of "1"3"7Cs transfer to rape (Brassica napus L.) phytomass under the influence of soil microorganisms

International Nuclear Information System (INIS)

Pareniuk, O.; Shavanova, K.; Laceby, J.P.; Illienko, V.; Tytova, L.; Levchuk, S.; Gudkov, I.; Nanba, K.

2015-01-01

After nuclear accidents, such as those experienced in Chernobyl and Fukushima, microorganisms may help purify contaminated soils by changing the mobility of radionuclides and their availability for plants by altering the physical and chemical properties of the substrate. Here, using model experiments with quartz sand as a substrate we investigate the influence of microorganisms on "1"3"7Cs transfer from substrate to plants. The highest transition of "1"3"7Cs from substrate to plants (50% increase compared to the control) was observed after Brassica napus L. seeds were inoculated by Azotobacter chroococcum. The best results for reducing the accumulation of "1"3"7Cs radionuclides (30% less) were noted after the inoculation by Burkholderia sp.. Furthermore, Bacillus megaterium demonstrated an increased ability to accumulate "1"3"7Cs. This research improves our prediction of the behavior of radionuclides in soil and may contribute towards new, microbiological countermeasures for soil remediation following nuclear accidents. - Highlights: • Representatives of soil bacteria can alter "1"3"7Cs soil-to-plant transfer factor. • This ability does not depend on the localization of bacteria on the root surface. • Selection of bacteria to increase or decrease the "1"3"7Cs transfer factor is possible.

Physical and chemical factors influencing radionuclide behaviour in arable soils

International Nuclear Information System (INIS)

Rauret, G.; Vidal, M.; Alexakhin, R.M.; Kruglov, S.V.; Cremers, A.; Wauters, J.; Valcke, E.; Ivanov, Y.

1996-01-01

Soil-to-plant transfer of radionuclides integrates plant physiological and soil chemical aspects. Therefore, it is necessary to study the factors affecting the equilibrium of the radionuclides between solid and soil solution phases. Desorption and adsorption studies were applied to the podsolic and peat soils considered in the ECP-2 project. In the desorption approach, both sequential extraction and 'infinite bath' techniques were used. In the adsorption approach, efforts were directed at predicting Cs and Sr-K D on the basis of soil properties and soil solution composition. Desorption approach predicts time-dynamics of transfer with time but it is un sufficient for comparatively predicting transfer. Adsorption studies informs about which are the key factors affecting radionuclide transfer. For Sr, availability depends on the CEC and on the concentration of the Ca + Mg in the soil solution. For Cs, availability is mainly dependent on the partitioning between FES -frayed edge sites-, which are highly specific and REC -regular exchange complex-, with low selectivity for Cs. Moreover, availability depends on the K and NH 4 , levels in the soil solution and fixation properties of the soil. Considering these factors, the calculation of the in situ K D values helps to predict the relative transfer of radionuclides. The calculation of the K D of the materials that could be used as countermeasures could permit the prediction of its suitability to decrease transfer and therefore to help in producing cleaner agricultural products

Cesium and potassium uptake by plants from soils

International Nuclear Information System (INIS)

Schaller, G.; Leising, C.; Krestel, R.; Wirth, E.

1990-11-01

The aim of the investigation was the reliable estimation of the Cs-137 root uptake by agricultural crops using the 'observed ratio model' (OR model) for the determination of transfer factors: Cs (plant)/K (plant) = OR x Cs (soil)/K (soil). For model validation representative soil (arable land, grass land, organic substrates from forests and peat) and plant samples from Bavaria were taken. These 4 parameters varied within a sufficiently wide range. In addition some samples from forest sites were taken. Soil and plant samples were taken at the same locations within 1 m 2 . (orig./HP) [de

Plant uptake of radiocesium from contaminated soils

International Nuclear Information System (INIS)

Pipiska, M.; Lesny, J.; Hornik, M.; Augustin, J.

2004-01-01

Phytoextraction field experiments were conducted on soil contaminated with radiocesium to determine the capacity of autochthonous grasses and weeds to accumulate 137 Cs. The aim of the study was to evaluate the potential of spontaneously growing vegetation as a tool for decontamination of non-agricultural contaminated land. As a test field, the closed monitored area of the radioactive wastewater treatment plant of the Nuclear Power Plant in Jaslovskie Bohunice, Slovakia was used. contamination was irregularly distributed from the level of background to spots with maximal activity up to 900 Bq/g soil. Sequential extraction analysis of soil samples showed the following extractability of radiocesium (as percent of total): water 2 = 0.3-1.1%; 1M CH 3 COONa = 0.3-0.9%; 0.04 M NH 4 Cl (in 25% CH 3 COOH) = 0.9-1.4% and 30% H 2 O 2 - 0.02 M HNO 3 = 4.5-9.0%.Specific radioactivity of the most efficiently bioaccumulating plant species did not exceed 4.0 BqKg -1 (dry weight biomass). These correspond to the soil-to-plant transfer factor (TF) values up to 44.4x10 -4 BqKg -1 crop, d.w.)/(BqKg -1 soil d.w). Aggregated transfer factor (T ag ) of the average sample of the whole crop harvested from defined area was 0.5x10 -5 (Bqkg -1 d.w. crop)/(Bqm -2 soil). It can be concluded that low mobility of radiocesium in analysed soil type, confirmed by sequential extraction analyses, is the main hindrance for practical application for autochthonous plants as a phytoremediation tool for aged contaminated area of non-cultivated sites. Plant cover can efficiently serve only as a soil surface-stabilising layer, mitigating the migration of radiocesium into the surrounding environment. (author)

Transfer equations for cesium-137 for coniferous forest understorey plant species

International Nuclear Information System (INIS)

Wirth, E.; Hiersche, L.; Kammerer, L.; Krajewska, G.; Krestel, R.; Mahler, S.; Roemmelt, R.

1994-01-01

The transfer of cesium-137 from organic soil horizons to understorey vegetation has been studied on two coniferous tree sites. In total, 14 different plants preferably taking up their nutrients from organic soil layers were taken into account. A relatively good correlation was found to exist between the transfer factor (Bq/kg plant dry wt./Bq/kg O-horizons dry wt.) for dicotyledons (r=0.51) and berry plants (r=0.63), but there was no correlation for monocotyledons (r= 0 .15). The correlations could not be improved by additionally taking potassium in plant and soil into account. These results are discussed in respect to different parameters influencing the amount of cesium-137 uptake, including plants supported by mycorrhizal fungi

Comparison of transfer factors of Sr-85 and Cs-134 for soils and crops of Greece

International Nuclear Information System (INIS)

Skarlou, V.; Papanicolaou, E. P.; Nobeli, C.

1994-01-01

The transfer of Sr-85 and Cs-134 from soil to plant (CR) was studied in two successive and similar in design glasshouse experiments. Six plant species (wheat, alfalfa, radish, string bean, cucumber, lettuce - only for Sr-85 - and endives - only for Cs-134), were grown in pots on eight Greek soils differing significantly in their physical and chemical properties. After the necessary measurements and analyses, big differences were detected in the transfer factors of both radionuclides with the soil types. The CRs of Sr-85 were higher than those of Cs-134 and for the tested crops and soils ranged between 0.3 and 36.5 for Sr-85 and between < 0.01 and 1.72 for Cs-134. The CRs of grains and seeds were much lower than those of leafy material for Sr-85 while the difference was not so high for Cs-134. The correlation between CRs and pH, negative in all cases, was significant or highly significant for all tested crops or plant parts (for Sr-85 r-bar = - 0.89, for Cs-134 r-bar = - 0.82). The values of CRs indicated a trend for negative correlation with other soil properties (cation exchange capacity-CEC, clay %). From exchangeable cations, exchangeable (Ca + Mg) as well as exchangeable bases, expressed as percentages of CEC, gave a significant or highly significant correlation with CRs of both radionuclides. (author)

Radionuclide transfer from soil to agricultural plants: measurements and modelling

International Nuclear Information System (INIS)

Sabbarese, C; Terrasi, F.; D'Onofrio, A.D.; Stellato, L.; Lubritto, C.; Ermice, A.; Cotrufo, M.F.

2002-01-01

To assess the internal doses to humans from ingestion of radionuclides present in agricultural products it is necessary to know the main processes which determine the transport of radionuclides in the environment (Russel, 1966; Peterson, 1983; IAEA, 1995). The available data, generally, do not reflect natural conditions, and the mechanisms of translocation and mobility of radionuclides within the soil-plant system are still not fully understood (Coughtrey and Thorne, 1983; Fresquez et a., 1998; Krouglov et al., 1997; Frissel, 1992; Roca and Vallejo, 1995; Desmet et al., 1990). The knowledge of the contributions of direct contamination of plant fruits and of the process of root to fruit transfer can improve the understanding of exposure through ingestion and of the mechanisms determining sorption and translocation. Several studies on the relations among specific activities of various radionuclides in different environmental compartments have been performed in the last decades (Coughtrey and Thorne, 1983; Fresquez et al., 1998; Krouglov et al., 1997; Howard et al., 1995; Strand et al., 1994; Konshin, 1992; Frissel, 1992; Alexakhin and Korneev, 1992; Desmet et al., 1990)

Ubiquity of insect-derived nitrogen transfer to plants by endophytic insect-pathogenic fungi: an additional branch of the soil nitrogen cycle.

Science.gov (United States)

Behie, Scott W; Bidochka, Michael J

2014-03-01

The study of symbiotic nitrogen transfer in soil has largely focused on nitrogen-fixing bacteria. Vascular plants can lose a substantial amount of their nitrogen through insect herbivory. Previously, we showed that plants were able to reacquire nitrogen from insects through a partnership with the endophytic, insect-pathogenic fungus Metarhizium robertsii. That is, the endophytic capability and insect pathogenicity of M. robertsii are coupled so that the fungus acts as a conduit to provide insect-derived nitrogen to plant hosts. Here, we assess the ubiquity of this nitrogen transfer in five Metarhizium species representing those with broad (M. robertsii, M. brunneum, and M. guizhouense) and narrower insect host ranges (M. acridum and M. flavoviride), as well as the insect-pathogenic fungi Beauveria bassiana and Lecanicillium lecanii. Insects were injected with (15)N-labeled nitrogen, and we tracked the incorporation of (15)N into two dicots, haricot bean (Phaseolus vulgaris) and soybean (Glycine max), and two monocots, switchgrass (Panicum virgatum) and wheat (Triticum aestivum), in the presence of these fungi in soil microcosms. All Metarhizium species and B. bassiana but not L. lecanii showed the capacity to transfer nitrogen to plants, although to various degrees. Endophytic association by these fungi increased overall plant productivity. We also showed that in the field, where microbial competition is potentially high, M. robertsii was able to transfer insect-derived nitrogen to plants. Metarhizium spp. and B. bassiana have a worldwide distribution with high soil abundance and may play an important role in the ecological cycling of insect nitrogen back to plant communities.

Studies on the transfer of Cs, Sr, Co, Mn and Zn from soil to plants and from medium to mushrooms by using radiotracer

International Nuclear Information System (INIS)

Ban-nai, Tadaaki; Muramatsu, Yasuyuki; Yoshida, Satoshi; Yanagisawa, Kei

1996-01-01

Radiotracer experiments were carried out to study radionuclide uptake by plants and mushrooms. Transfer factors of radionuclides from soil to leaf vegetables (cabbage, Chinese cabbage, komatsuna, spinach and lettuce) have been determined by radiotracers. The transfer factors of radioactive Cs, Sr, Mn, Co and Zn for edible parts of vegetables were 0.11, 0.24, 0.61, 0.05 and 0.52, respectively. The transfer factors of Mn, Co and Zn for spinach were higher than those for the other vegetables. The transfer factors of Cs for different organs of the leaf vegetables were rather homogeneous. The transfer factors of Sr and Mn were higher for older (outer) leaves than younger (inner) ones. In contrast to Sr and Mn, transfer factors of Zn for younger leaves were higher than those for older ones. In order to study radionuclide uptake by mushrooms, cultivation experiments in flasks were carried out using radiotracers, 137 Cs, 85 Sr, 60 Co, 54 Mn and 65 Zn. Four mushroom species Hebeloma vinosophyllum, Flammulina velutipes, Agrocybe cylindracea and Coprinus phlyctidosporus were used. In addition, Medicago sativa was also tested. Mushrooms tended to accumulate Cs, although there was a large difference between mushroom species. The concentration ratio had the highest value of 21 for Cs in vinosophyllum. The value was much higher than that in the plant sample. The present findings agreed with our previous observations in which Hebeloma species collected in forests contained large amount of 137 Cs. The effects of stable elements in the medium on the accumulations were investigated. The concentration ratios of Cs, Sr and Co were not influenced highly by coexisting stable elements in the medium. However, the ratio of Mn decreased as the amount of coexisting stable elements in the medium was increased. (J.P.N.)

Understanding transfer modes of radionuclides to plants

International Nuclear Information System (INIS)

Hurtevent, P.

2010-01-01

This article briefly comments recent works performed by the IRSN in order to better quantify the transfer of radionuclides from the environment to plants. Three major processes have been studied: root transfer or uptake, translocation, and organic matter recycling (or contamination recycling). The first one depends on the plant and on the soil where it grows. As far as translocation is concerned, the aerial contamination penetrates the plant through the leaves. The third one occurs when broken branches and leaves which have been contaminated, fall on the ground. Some measurements performed in forests near Chernobyl are evoked

Transfer of elements relevant to nuclear fuel cycle from soil to boreal plants and animals in experimental meso- and microcosms

Energy Technology Data Exchange (ETDEWEB)

Tuovinen, Tiina S., E-mail: tiina.tuovinen@uef.fi [Department of Environmental Science, University of Eastern Finland, P.O. Box 1627, FI-70211 Kuopio (Finland); Kasurinen, Anne; Häikiö, Elina [Department of Environmental Science, University of Eastern Finland, P.O. Box 1627, FI-70211 Kuopio (Finland); Tervahauta, Arja [Department of Biology, University of Eastern Finland, P.O. Box FI-70211, Kuopio (Finland); Makkonen, Sari; Holopainen, Toini; Juutilainen, Jukka [Department of Environmental Science, University of Eastern Finland, P.O. Box 1627, FI-70211 Kuopio (Finland)

2016-01-01

Uranium (U), cobalt (Co), molybdenum (Mo), nickel (Ni), lead (Pb), thorium (Th) and zinc (Zn) occur naturally in soil but their radioactive isotopes can also be released into the environment during the nuclear fuel cycle. The transfer of these elements was studied in three different trophic levels in experimental mesocosms containing downy birch (Betula pubescens), narrow buckler fern (Dryopteris carthusiana) and Scandinavian small-reed (Calamagrostis purpurea ssp. Phragmitoides) as producers, snails (Arianta arbostorum) as herbivores, and earthworms (Lumbricus terrestris) as decomposers. To determine more precisely whether the element uptake of snails is mainly via their food (birch leaves) or both via soil and food, a separate microcosm experiment was also performed. The element uptake of snails did not generally depend on the presence of soil, indicating that the main uptake route was food, except for U, where soil contact was important for uptake when soil U concentration was high. Transfer of elements from soil to plants was not linear, i.e. it was not correctly described by constant concentration ratios (CR) commonly applied in radioecological modeling. Similar nonlinear transfer was found for the invertebrate animals included in this study: elements other than U were taken up more efficiently when element concentration in soil or food was low. - Highlights: • We studied transfer of elements in boreal food chain using meso- and microcosms. • Elements related to nuclear fuel cycle and mining were examined. • Higher uptake at lower soil concentrations was observed for primary producers. • Snails took up elements mainly from food but for U also soil was an element source. • Non-linear transfer of essential elements was observed for herbivore and decomposer.

Variability in uptake of Cs isotopes by fenugreek plant from three soils

Energy Technology Data Exchange (ETDEWEB)

Pulhani, V; Dafauti, S; Dahiya, S; Hedge, A G [Environmental Studies Section, Health Physics Div., Bhabha Atomic Research Centre, Mumbai (India)

2008-07-01

Soil to plant transfer via root uptake is one of the major compartments in the radionuclide transfer pathways to man and can be used to assess the internal radiation dose via ingestion. The variability in the Transfer Factor (TF) of Cs isotopes was investigated in three different soils from nuclear power plant sites at Rajasthan and Narora with alkaline sandy loam alluvial and Madras with acidic coastal sandy loam alluvial soil. The soils were characterized for soil properties like texture, pH, EC, organic carbon, CaCO{sub 3} (%), CEC, silt, clay sand etc. and spiked with a mixture of 800 Bq {sup 137}Cs, 300 Bq {sup 134}Cs and 10mg of {sup 133}Cs (stable). Fenugreek (Trigonella foenum-graecum L.) from Leguminosae family an annual plant commonly used as a vegetable was grown in these soils to study the uptake of Cs. The uptake of heavy toxic elements like Pb, Cd, Ni, Cr etc. and nutrients Fe, Co, Cu, Zn, Mn, Ca, Mg, Na and K was also studied. The uptake of heavy toxic elements like Pb, Cd, Ni, Cr etc. and nutrients Fe, Co, Cu, Zn, Mn, Ca, Mg, Na and K was also studied. {sup 137}Cs and{sup 134}Cs was estimated using HPGe detector (15% Relative Efficiency, 54cc-coaxial, 2keV resolution at 1332keV of {sup 60}Co). Stable Cs, K and Na were determined by the Atomic Emission Spectrophotometry and Pb, Cd, Cr etc. by Atomic Absorption Spectrophotometry. Among the three soils the transfer factor for all the elements and Cs was highest for MAPS due to higher organic matter content and acidic pH followed by NAPS and RAPS. The {sup 137}Cs and {sup 134}Cs isotopes have been taken up to the same extent from soil and transfer factors are similar to each other. But the stable Cs uptake appears to be slightly high, probably because of excess of {sup 133}Cs (mg level) added as compared to the radioactive isotopes. In spite of this high difference in the soil concentrations of Cs isotopes, uptake of {sup 133}Cs is not very high indicating to a physiological limiting process for uptake

Plant uptake of 134Cs in relation to soil properties and time

International Nuclear Information System (INIS)

Massas, I.; Skarlou, V.; Haidouti, C.

2002-01-01

134 Cs uptake by sunflower and soybean plants grown on seven different soils and its relation to soil properties were studied in a greenhouse pot experiment. Soil in each pot was contaminated by dripping the 134 Cs in layers, and sunflower and soybean plants were grown for three and two successive periods, respectively. 134 Cs plant uptake was expressed as the transfer factor (TF) (Bq kg -1 plant/Bq kg -1 soil) and as the daily plant uptake (flux) (Bq pot -1 day -1 ) taking into account biomass production and growth time. For the studied soils and for both plants, no consistent trend of TFs with time was observed. The use of fluxes, in general, provided less variable results than TFs and stronger functional relationships. A negative power functional relationship between exchangeable potassium plus ammonium cations expressed as a percentage of cation exchange capacity of each soil and 134 Cs fluxes was found for the sunflower plants. A similar but weaker relationship was observed for soybean plants. The significant correlation between sunflower and soybean TFs and fluxes, as well as the almost identical highest/lowest 134 Cs flux ratios, in the studied soils, indicated a similar effect of soil characteristics on 134 Cs uptake by both plants. In all the studied soils, sunflower 134 Cs TFs and fluxes were significantly higher than the respective soybean values, while no significant difference was observed in potassium content and daily potassium plant uptake (flux) of the two plants

Results of about a seven years lysimeter study to the quantification of the mobility of radionuclides into the system soil-water-plant

International Nuclear Information System (INIS)

Gerzabek, M.H.; Strebl, F.; Temmel, B.

1999-04-01

The result of seven years lysimeter experiments (twelve soil monoliths, four soil types) to determine the uptake of 60 Co, 137 Cs and 226 Ra into agricultural crops and the leaching behaviour are presented. The mobility of the artificial radionuclides in soil profiles decreased in the following order: 60 Co ≥ 22 6Ra > 137 Cs. Total median values of soil-plant transfer factors (dry matter basis) for the three radionuclides decreased from 226 Ra (0.068 kg kg -1 ) to 137 Cs (0.043 kg kg -1 ) and 60 Co (0.018 kg kg -1 ). The physical and chemical properties of the experimental soils resulted in significant differences in transfer factors or fluxes between the investigated soils for 137 Cs and 226 Ra, but not for 60 Co. Differences in transfer between plant species and plant parts are distinct, with graminaceous species showing 5.8 and 15 times lower values for 137 Cs and 60 Co than dicodyle-donean species. In model calculations radionuclide losses through the different pathways (physical decay, leaching plant uptake and removal) were quantified. (author)

Paddy-field contamination with 134Cs and 137Cs due to Fukushima Dai-ichi Nuclear Power Plant accident and soil-to-rice transfer coefficients

International Nuclear Information System (INIS)

Endo, Satoru; Kajimoto, Tsuyoshi; Shizuma, Kiyoshi

2013-01-01

The transfer coefficient (TF) from soil to rice plants of 134 Cs and 137 Cs in the form of radioactive deposition from the Fukushima Dai-ichi Nuclear Power Plant (FDNPP) accident in March 2011 was investigated in three rice paddy fields in Minami-Soma City. Rice crops were planted in the following May and harvested at the end of September. Soil cores of 30-cm depth were sampled from rice-planted paddy fields to measure 134 Cs and 137 Cs radioactivity at 5-cm intervals. 134 Cs and 137 Cs radioactivity was also measured in rice ears (rice with chaff), straws and roots. The rice ears were subdivided into chaff, brown rice, polished rice and rice bran, and the 134 Cs and 137 Cs radioactivity concentration of each plant part was measured to calculate the respective TF from the soil. The TF of roots was highest at 0.48 ± 0.10 in the field where the 40 K concentration in the soil core was relatively low, in comparison with TF values of 0.31 and 0.38 in other fields. Similar trends could be found for the TF of whole rice plants, excluding roots. The TF of rice ears was relatively low at 0.019–0.026. The TF of chaff, rice bran, brown rice and polished rice was estimated to be 0.049, 0.10–0.16, 0.013–0.017 and 0.005–0.013, respectively. - Highlights: ► We investigated the transfer coefficient of 134 Cs and 137 Cs from soil to rice plants in Minami-Soma City due to the Fukushima accident in 2011. ► The rice ears, straws, roots, chaff, brown rice, polished rice, rice bran and soil samples have been measured by Ge-detector. ► Transfer coefficient of chaff, rice bran, brown rice, and polished rice is estimated as 0.049, ranging from 0.10 to 0.16, 0.013 to 0.017, and 0.005 to 0.013, respectively.

Transfer factors for assessing the dose from radionuclides in agricultural products

International Nuclear Information System (INIS)

Ng, Y.C.; Colsher, C.S.; Thompson, S.E.

1979-01-01

Transfer factors to predict the environmental transport of radionuclides through terrestrial foodchains to man were derived from the literature for radionuclides associated with the nuclear fuel cycle. We present updated transfer coefficients to predict the concentration of a radionuclide in cow's milk and other animal products and concentration factors (CF) to predict the concentration in a food or feed crop from that in soil. Where possible we note the variation of the transfer factor with physical and chemical form of the radionuclide and environmental factors, and characterize the distribution and uncertainty in the estimate. The updated transfer factors are compared with those listed in regulatory guides. The new estimates lead to recommended changes (both increases and decreases) in the listed transfer coefficients for milk and meat and to the suggested practice of adopting multiple soil-to-plant CF's that vary with the type of crop and soil in the place of a single generic CF to predict the concentration of a radionuclide in a crop from that in soil. The updated transfer factors will be useful to assess the dose from radionuclides released from nuclear facilities and evaluating compliance with regulations governing the release of radionuclides

Carbon flux from plants to soil microbes is highly sensitive to nitrogen addition and biochar amendment

Science.gov (United States)

Kaiser, C.; Solaiman, Z. M.; Kilburn, M. R.; Clode, P. L.; Fuchslueger, L.; Koranda, M.; Murphy, D. V.

2012-04-01

The release of carbon through plant roots to the soil has been recognized as a governing factor for soil microbial community composition and decomposition processes, constituting an important control for ecosystem biogeochemical cycles. Moreover, there is increasing awareness that the flux of recently assimilated carbon from plants to the soil may regulate ecosystem response to environmental change, as the rate of the plant-soil carbon transfer will likely be affected by increased plant C assimilation caused by increasing atmospheric CO2 levels. What has received less attention so far is how sensitive the plant-soil C transfer would be to possible regulations coming from belowground, such as soil N addition or microbial community changes resulting from anthropogenic inputs such as biochar amendments. In this study we investigated the size, rate and sensitivity of the transfer of recently assimilated plant C through the root-soil-mycorrhiza-microbial continuum. Wheat plants associated with arbuscular mycorrhizal fungi were grown in split-boxes which were filled either with soil or a soil-biochar mixture. Each split-box consisted of two compartments separated by a membrane which was penetrable for mycorrhizal hyphae but not for roots. Wheat plants were only grown in one compartment while the other compartment served as an extended soil volume which was only accessible by mycorrhizal hyphae associated with the plant roots. After plants were grown for four weeks we used a double-labeling approach with 13C and 15N in order to investigate interactions between C and N flows in the plant-soil-microorganism system. Plants were subjected to an enriched 13CO2 atmosphere for 8 hours during which 15NH4 was added to a subset of split-boxes to either the root-containing or the root-free compartment. Both, 13C and 15N fluxes through the plant-soil continuum were monitored over 24 hours by stable isotope methods (13C phospho-lipid fatty acids by GC-IRMS, 15N/13C in bulk plant

Availability of caesium radionuclides to plants - classification of soils and role of mycorrhiza

Energy Technology Data Exchange (ETDEWEB)

Drissner, J.; Buermann, W.; Enslin, F.; Heider, R.; Klemt, E.; Miller, R.; Schick, G.; Zibold, G. [Fachhochschule Ravensburg-Weingarten, D-88241 Weingarten (Germany)

1998-10-01

At different locations in spruce stands spread rather homogeneously over southern Baden-Wuerttemberg, samples of soil and plants were taken and the vertical distribution of the caesium radionuclides in the soil was studied. As a direct measure of the bioavailability, the aggregated transfer factor, T{sub ag}, was determined for fern, bilberry, raspberry, blackberry, and clover. The T{sub ag} (in m2 kg{sup -1}) is defined by the specific caesium activity (in Bq kg{sup -1}) of the dry mass of the plants, divided by the total inventory (in Bq m{sup -2}) of the soil. It varies between 0{center_dot}5 and 0{center_dot}001 m2kg{sup -1}, being highest for fern and lowest for blackberry or clover at all sampling sites. Most decisive for the value of the T{sub ag} are kind of humus deposit, thickness and pH value of the humus layers. Also important are the soil properties, whereas geology has only a minor influence on T{sub ag}. At different sampling sites in spruce forests, the T{sub ag} can vary by two orders of magnitude for one plant species. Caesium desorption experiments were performed. We could not find a dependence of the transfer of caesium to the plant on the desorbability of caesium from the soil, which implies a more complex transport mechanism than simple ion exchange in the soil solution. It is suggested that the transport of caesium is mediated by mycorrhiza fungi. Therefore, we studied the density of mycorrhiza hyphae in the O{sub f}, O{sub h} and A{sub h} soil horizons of two sites differing in T{sub ag} by a factor of 10. The densities of mycorrhiza hyphae in the O{sub h} and A{sub h} soil horizons each differ by a factor of 2 for the two sites. Yet, the effect of the hyphae density on radiocaesium uptake has to be a subject of further investigation. (Copyright (c) 1998 Elsevier Science B.V., Amsterdam. All rights reserved.)

Application of the International Union of Radioecologists soil-to-plant database to Canadian settings.

Energy Technology Data Exchange (ETDEWEB)

Sheppard, S C [Atomic Energy of Canada Ltd., Pinawa, MB (Canada). Whiteshell Labs.

1995-12-01

The International Union of Radioecologists (IUR) has compiled a very large database of soil-to-plant transfer factors. These factors are ratios of the radionuclide concentrations in dry plants divided by the corresponding concentrations in dry soil to a specified depth or thickness. In this report the factors are called CR values, for concentration ratio. The CR values are empirical and are considered element-specific. The IUR database has a lot of data for Cs, Sr, Co, Pu and Np, and contains records for Am, Ce, Cm, I, La, Mn, Ni, Pb, Po, Ra, Ru, Sb, Tc, Th, U and Zn. Where there was a large amount of data, interpolation for ranges of soil conditions was possible. The tables presented here summarize the data in a way that should be immediately useful to modellers. Values are averaged for a number of crop types and species. Correction factors are developed to facilitate interpolation among soil conditions. The data tables in this report do not substitute for site-specific measurements, but they will provide data where measurement is impossible and give a background to check more recent data. (author) 4 refs ., 48 tabs.

Effect of potassium fertilizers on 137Cs transfer from sandy soddy-podzolic soil to plants

International Nuclear Information System (INIS)

Belova, N.V.; Sanzharova, N.I.; Shishulina, M.V.; Moiseenko, F.V.; Vorob'eva, L.A.

2009-01-01

The purpose of the work is to study the behavior of potassium in sandy soddy podzolic soil and its influence on the availability of 137 Cs to plants of winter rye and lupine when applying various doses of potassium fertilizers (PF) and turf-manure compost (TMC). A many-years stationary experiment was established in the Bryansk region in 1986-1988 on soddy podzolic soil contaminated by the accident at the Chernobyl Power Station. The influence of fertilizer was studied in 4-field crop rotation in an experimental plot: seeded fallow (lupine, bird's-foot) – winter rye – potato – spring grains. Potassium and mineral fertilizers were applied. It was shown that the application of potassium fertilizers (from 0 to 180 kg/ha) increased the content of exchangeable potassium in the soil by 1.7-2-7 times and its mobility by 2.5-4.0 times which resulted in a decrease of 137Cs transfer to plants by 5.8-14 times. The inverse proportional relationship was found between the potassium mobility and the content of its mobile form and the accumulation coefficient of 137Cs by lupine and wheat rye plants. A linear relationship was reveled between the accumulation coefficient of 137Cs and the content of exchangeable radionuclide

Soil-to-Rice Seeds Transfer Factors of Radioiodine and Technetium for Paddy Fields around the Radioactive-Waste Disposal Site in Gyeongju

International Nuclear Information System (INIS)

Choi, Yong Ho; Lim, Kwang Muk; Jun, In; Park, Doo Won; Keum, Dong Kwon; Han, Moon Hee

2010-01-01

Radiotracer experiments were performed over two years using pot cultures in a greenhouse to investigate soil-torice seeds transfer factors of radioiodine and technetium for paddy fields around the radioactive-waste disposal site in Gyeongju. Before transplanting rice seedlings, the top about 20 cm soils were thoroughly mixed with 125 I (2007) and 99 Tc (2008), and the pots were irrigated to simulate flooded rice fields. Transfer factors were determined as the ratios of the radionuclide concentrations in dry rice seeds (brown rice) to those in dry soils. Transfer factors of radioiodine and technetium were in the ranges of 1.1 x 10 -3 ∼ 6.4 x 10 -3 (three soils) and 5.4 x 10 -4 ∼ 2.5 x 10 -3 (four soils), respectively, for different soils. It seems that the differences in the clay content among soils played a more important role for such variations than those in the organic matter content and pH. As the representative values of radioiodine and technetium transfer factors for rice seeds, 2.9 x 10 -3 and 1.1 x 10 -3 , respectively, were proposed. In order to obtain more highly representative values in the future, investigations for the sites of interest need to be carried out continuously

Enrichment of Cs-137 in some wild plants and determination of the transfer factors

International Nuclear Information System (INIS)

Molzahn, D.

1993-01-01

As a consequence of the nuclear weapons tests and the accident in the Chernobyl nuclear power plant some wild plants exhibit a relatively high enrichment in Cs-137. The examples cited here include heather, forest grown grass, ferns, needles and cones of spruces and firs and, obviously, also some species of mushrooms. While the transfer factors of cultivated plants range from 0.001 to 0.1 according to the literature and measurements of our own, values from 1 to 38 have been measured for heather, depending on the nature of the soil. One of the consequences of this relatively high enrichment is the enhanced cesium content in honeys produced from heather. It is intended to continue the relevant measurements in 1993. (orig.) [de

High plant uptake of radiocesium from organic soils due to Cs mobility and low soil K content

International Nuclear Information System (INIS)

Sanchez, A.L.; Wright, S.M.; Naylor, C.; Kennedy, V.H.; Dodd, B.A.; Singleton, D.L.; Barnett, C.L.; Stevens, P.A.

1999-01-01

Post-Chernobyl experience has demonstrated that persistently high plant transfer of 137 Cs occurs from organic soils in upland and seminatural ecosystems. The soil properties influencing this transfer have been known for some time but have not been quantified. A pot experiment was conducted using 23 soils collected from selected areas of Great Britain, which were spiked with 134 Cs, and Agrostis capillaris grown for 19--45 days. The plant-to-soil 134 Cs concentration ratio (CR) varied from 0.06 to 44; log CR positively correlated to soil organic matter content (R 2 = 0.84), and CR values were highest for soils with low distribution coefficients (K d ) of 134 Cs. Soils with high organic matter contents and high concentrations of NH 4 + in solution showed high 134 Cs mobility (low K d ). The plant-to-soil solution 134 Cs ratio decreased sharply with increasing soil solution K + . A two parameter linear model, used to predict log CR from soil solution K + and K d , explained 94% of the variability in CR values. In conclusion, the high transfer of 134 Cs in organic soils is related to both the high 134 Cs mobility (low clay content and high NH 4 + concentrations) and low K availability

Soil to plant transfer of radiocesium: application to the Chernobyl accident

International Nuclear Information System (INIS)

Antonopoulos-Domis, M.; Clouvas, A.; Gagianas, A.

1990-01-01

Radiocesium contamination of different annual crops, due to the Chernobyl accident, was systematically studied in two experimental agricultural farms in North Greece for the years 1987, 1988 and 1989. For the first three years after the Chernobyl accident it was generally observed that radiocesium contamination of almost all the annual crops appears to be time independent, the differences lying within the experimental error. Transfer Factors, relating radiocesium deposition to contamination of crops were found to be for cereals about 0.01, one order of magnitude smaller than those deduced from field experiments in Northern European Countries, mainly due to different soil characteristics. The results are also discussed in the framework of the UNSCEAR's empirical model and the corresponding parameters are deduced. (author)

Modelling soil and soil to plant transfer processes of radionuclides and toxic chemicals at long time scales for performance assessment of Radwaste disposal

Science.gov (United States)

Albrecht, Achim; Miquel, Stephan

2015-04-01

Performance assessments for surface nuclear waste disposal facilities require simulation of transfer processes from the waste canisters to a reference group living near-by. Such simulations need to be extended over several hundred to hundred thousand years, depending on waste type, restraining possibilities to represent short term system complexity and variability. Related modelling can be simplified as long as processes are represented conservatively with assessment endpoints estimated larger compared to more realistic modelling approaches. The indicators are doses for radionuclides (RN) and risk factors for toxic chemicals (TC, i.e. heavy metals, nitrate). We discuss a new simulation tool (SCM-Andra-multilayer-model, SAMM) that, among others, allows to model situations where RN/TC move through a soil profile characterised by temporal undersaturation and root growth (soil-plant subsystem of the biosphere model compared to the adjacent saturated geosphere). SAMM describes all relevant transfer and reaction processes (advection, diffusion, root transport, radioactive decay, chemical reactions incl. sorption - desorption) using well known differential equations solved numerically within MATLAB with scenario description and parameterisation defined in Excel sheets. With this conservative approach in mind, we apply global parameters for which the solid-solution (Kd) or soil-to-plant (TF) distribution coefficients are the most relevant. Empirical data are available for homogeneous situations, such as one compartment pot experiments, but rare for entire soil profiles. Similarly soil hydrology, in particular upward and downward advective fluxes are modelled using an empirical approach solely based on key soil hydrological parameters (precipitation, evapotranspiration, irrigation, water table level) and the soil porosity. Variability of soil hydrology in space and time, likely to change drastically even on hourly bases (i.e. intense precipitation event) or within a single

Iodine transfer from agricultural soils to edible part of crops

International Nuclear Information System (INIS)

Uchida, S.; Tagami, K.

2011-01-01

Information about the distribution and cycling of stable iodine (I) in the environment is useful for dose estimation from its long-lived radioiodisotope, 129 I, which is one of the most critical radionuclides to be managed for the safe disposal of nuclear fuel waste. The soil-to-plant transfer factor (TF) is an important parameter to predict internal radiation exposure pathways through the food chains using mathematical models. Therefore, we have measured stable I and bromine (Br) for comparison, in 142 crop samples and associated agricultural field soil samples collected throughout Japan. The crops were classified into eight groups, i.e. leafy vegetables, white part of leeks, fruit vegetables, tubers, root crops, legumes, wheat and barley (WB), and rice. The results showed that Br and I concentrations were higher in upland field soil samples than in paddy field soil samples. However, when we compared TF values of WB and brown rice, no statistical difference was observed. The highest geometric mean of TF for I, 1.4 x 10 -2 , was obtained for leafy vegetables and fruit vegetables and that for Br, 1.5, was for fruit vegetables. TF for I was much lower than Br, as reported previously, maybe due to their different chemical forms in soil and uptake behaviors by plant roots. (orig.)

Assessing soil and plant parameters affecting uranium availability and plant uptake

International Nuclear Information System (INIS)

Vandenhove, H.

2009-01-01

In the assessment of the potential impact of contaminants in soils and the requirement for the implementation of corrective actions, it is important to determine the contaminant's mobility and bioavailability and to identify the processes and parameters ruling it. Mobility and bioavailability of contaminants are among others affected by the physicochemical characteristics of the environment itself and plant properties. This is also the case for uranium (U), reported to be the most frequent radionuclide contaminant in ground and surface water and soils. The actual failure of the available transfer factor (TF) data and their broad relation to soil type to be an appropriate measure for food chain transfer in assessment models, calls for a more mechanistic understanding of the individual processes affecting bioavailability. The objectives of this study were (1) to test if Diffusive Gradient in Thin film (DGT) measured concentrations adequately assess U bioavailability and (2) to evaluate if differences in U uptake by plants can be explained by variation in root-mediated changes in selected soil properties and assess the role of organic acids in this process

Soil-plant transfer models for metals to improve soil screening value guidelines valid for São Paulo, Brazil.

NARCIS (Netherlands)

Dos Santos-Araujo, Sabrina N; Swartjes, Frank A; Versluijs, Kees W; Moreno, Fabio Netto; Alleoni, Luís R F

2017-01-01

In Brazil, there is a lack of combined soil-plant data attempting to explain the influence of specific climate, soil conditions, and crop management on heavy metal uptake and accumulation by plants. As a consequence, soil-plant relationships to be used in risk assessments or for derivation of soil

Peculiarities of radionuclide transfer to plants

International Nuclear Information System (INIS)

Butkus, D.; Andriulaityte, I.; Luksiene, B.; Druteikiene, R.

2003-01-01

The biosphere and its interacting components (air, soil, bottom sediments, flora, fauna, human beings) are constantly affected by ionizing radiation. One of the ionizing radiation sources is noble radioactive gas that is continually released into the environment because of the normal operation of nuclear power plants (short-lived and long-lived noble gas) and nuclear fuel-reprocessing plants (long-lived noble gas). Another source is related to nuclear tests and the Chernobyl NPP accident, when long-lived gaseous and aerosol radionuclides ( 85 Kr, transuranics, 137 Cs, 90 Sr, etc) were spread in all environmental systems. In order to evaluate the mechanism of radionuclide transfer to plants, model experimental investigation using gaseous 85 Kr and ionic state 137 Cs was undertaken. For this purpose specific chambers with defined physical parameters were applied. The gained tentative results show the importance of these experiments for the estimation of radionuclide transfer to plants and for the prognosis of human internal irradiation. (author)

General regularities of Sr 90 distribution in system soil-plant under natural conditions

International Nuclear Information System (INIS)

Gudeliene, I.; Marchiulioniene, D.; Petroshius, R.

2006-01-01

Sr 90 distribution in system 'soil - underground part of plant - aboveground part of plant' was investigated. It was determined that Sr 90 activity concentration in underground and aboveground part of plants and in mosses was not dependent on its activity concentration in soil. There was direct dependence of Sr 90 activity concentration in aboveground on underground parts of plants. Sr 90 transfer factor from soil to underground part of plants and mosses was directly dependent on this radionuclide activity concentration in them. (authors)

Mobility of radionuclides and MCPA in the soil-water-plant system. Final report

International Nuclear Information System (INIS)

Gerzabek, M.H.; Haberhauer, G.; Strebl, F.; Temmel, B.

1998-01-01

The present report describes results of soil-to-plant transfer investigations for radionuclides in the years 1990 - 1997 obtained in lysimeter experiments of the Research Centre Seibersdorf and results of an investigation with 14 C-labelled MCPA. The lysimeter facility consists of twelve soil monoliths from four sites (Eutric Cambisol, Dystric Cambisol, Dystric Cambisol on crystalline, Dystric Gleysol/drained) with three replicates each and is located in Seibersdorf/Austria, a region with a pannonian climate (pronounced differences between hot and dry summers and wet winter conditions, annual mean of precipitation: 517 mm, mean annual temperature: 9.8 degrees C). Besides soil-to-plant transfer factors (TF) for endive, maize, wheat, mustard, sugarbeet, potato, Faba bean, rye grass, fluxes were calculated taking into account biomass production and growth time. Total median values of TF's (dry matter basis) for the three radionuclides decreased from 226 Ra (0.068 kg kg -1 ) to 137 CS (0.043 kg kg -1 ) and 60 CO (0.018 kg kg -1 ); flux values exhibited the same ranking. The varying physical and chemical properties of the four experimental soils resulted in statistically significant differences in transfer factors or fluxes between the investigated soils for 1 37 Cs and 226 Ra, but not for 60 CO . Differences in transfer between plant species and plant parts are distinct, with graminaceous species showing, on average, TF values 5.8 and 15 times lower than dicodyledonous species for 137 Cs and 60 CO, respectively. This pattern was not found for 226 Ra. It can be concluded that transfer heavily influenced by soil characteristics, whilst the plant-specific factors are the main source of TF variability for 60 Co. The variability of 226 Ra transfer originates both from soil properties and plant species behaviour. Model calculations showed that for Cs, Co and Ra leaching - at least in medium term - has no distinct impact on the overall radioactivity losses of the soil profile

What are the most crucial soil factors for predicting the distribution of alpine plant species?

Science.gov (United States)

Buri, A.; Pinto-Figueroa, E.; Yashiro, E.; Guisan, A.

2017-12-01

Nowadays the use of species distribution models (SDM) is common to predict in space and time the distribution of organisms living in the critical zone. The realized environmental niche concept behind the development of SDM imply that many environmental factors must be accounted for simultaneously to predict species distributions. Climatic and topographic factors are often primary included, whereas soil factors are frequently neglected, mainly due to the paucity of soil information available spatially and temporally. Furthermore, among existing studies, most included soil pH only, or few other soil parameters. In this study we aimed at identifying what are the most crucial soil factors for explaining alpine plant distributions and, among those identified, which ones further improve the predictive power of plant SDMs. To test the relative importance of the soil factors, we performed plant SDMs using as predictors 52 measured soil properties of various types such as organic/inorganic compounds, chemical/physical properties, water related variables, mineral composition or grain size distribution. We added them separately to a standard set of topo-climatic predictors (temperature, slope, solar radiation and topographic position). We used ensemble forecasting techniques combining together several predictive algorithms to model the distribution of 116 plant species over 250 sites in the Swiss Alps. We recorded the variable importance for each model and compared the quality of the models including different soil proprieties (one at a time) as predictors to models having only topo-climatic variables as predictors. Results show that 46% of the soil proprieties tested become the second most important variable, after air temperature, to explain spatial distribution of alpine plants species. Moreover, we also assessed that addition of certain soil factors, such as bulk soil water density, could improve over 80% the quality of some plant species models. We confirm that soil p

Variations in soil-to-red pepper transfer factors of radionuclides with time of their application and fruit harvest

International Nuclear Information System (INIS)

Choi, Yong Ho; Lee, Won Yun; Lim, Kwang Muk; Park, Soo Won; Lee, Myung Ho; Lee, Chang Woo; Lee, Hyun Duk; Lee, Jeong Ho

1997-01-01

A mixed solution of 54 Mn, 60 Co, 85 Sr and 137 Cs was applied to the soil of culture boxes in a greenhouse 2 days before transplanting red pepper and at 3 different times during its growth for investigating transfer factors (m 2 /kg-dry) for its green and red fruits. Transfer factors varied with radionuclide, application time and harvest time by factors of about 20-100. They decreased mostly radionuclide, application time and harvest time by factors of about 20-100. They decreased mostly in the order of 85 Sr> 54 Mn> 60 Co> 137 Cs while 54 Mn and 60 Co was higher than 85 Sr when time lapse between application and harvest was short. Transfer factors of 85 Sr and 137 Cs at the last application were lower than those at the previous one by factors of 3-20 depending on harvest time. Variations in 54 Mn and 60 Co transfer factors with application time after transplanting were comparatively low. Transfer factors of 54 Mn, 60 Co and 85 Sr mixed with topsoil before transplanting were up to 3-9 times higher than those for the application onto soil surface 2 days after transplanting root-uptake concentrations of the radionuclides in red pepper fruit and taking proper measures for its harvest and consumption at the event of an accidental release during the growing season of red pepper

Health risks resulting from contaminants transfers in soil-plants systems: case study of Atrazine in Lactuca sativa.

Science.gov (United States)

Mathieu, Camoin

2015-04-01

Food safety is presently at the center of great part of scientific and political debates. This represents a field of study in its own right of health risks, including ingestion by humans of hazardous biological, physical, chemical or radiological substances, from contaminated foods during different stages of production. Plant cultivation step is often one of the main sources of contamination, whether of voluntary (pesticide application) or accidental (nuclear, industrial waste, etc.) origin. As a result, the plants growth in an contaminated environment may increase the risk of transfer within the plant, and finally the exposure of humans. Furthermore, pesticides are among the main contaminants investigated in the frame of human health risks resulting from food intakes. However, most of these scientific works focus mainly on their occurrence and persistence in water bodies, and few of them are interested in soil/plants transfer. In this context, the understanding of the processes governing transfers of pesticides in plants is become a necessity, in particular to prevent human risks linked the ingestion of food produced in contaminated environments. This objective can be reached by studying the pollutants behavior in soils/plants transfers, and using various substances/plants couples. In our study, we selected a salad/pesticide couple as our experimental model. Atrazine was chosen as model contaminant because of its problematic presence in a large amount of environmental compartments, its physico-chemical properties and because of its long-term toxicity. Lactuca sativa has been selected as model plant because of its importance in French agriculture, and specifically in Languedoc-Roussillon. Salad has been cultivated in peats and irrigated with an atrazine spiked water solution (concentrations from 10 to 100 μg/L). Plant growth in such conditions has been compared to a growth in clean condition (irrigation with non spiked water). Measurements of atrazine contents in

Transfer of Ni, Cr, Zn, Cu and 99mTc to plant biomass of Raphanus sativus L. Role of 125I-fulvic acid and the influence of different treatments on urban soil in Havana

International Nuclear Information System (INIS)

Santana Romero, Jorge Luis; Diaz Velazquez, Alberto; Garcia Cespedes, Damaris; Lima Cazorla, Lazaro; Saborit Sanchez, Israel; Olivares Rieumont, Susana; Rivas, Edgar; Manduca, Michel

2011-01-01

The importance of studying the transfer of heavy metals from soil to plant biomass is a current scientific topic. The global economic changes have caused accelerated environmental degradation processes in urban soils, in which important amount of agricultural production is obtained. The application of 'ecological' techniques on these soils, including the use of vermicompost, is be-coming more and more extensive and common. The question is: Is always safe and pertinent to apply vermicompost to urban soils?. Hence the importance of studying the heavy metal mobility and bioavailability to plant biomass in these conditions. In the present work, using different analytical techniques, a sample of Havana urban soil is characterized by determination of ph, electrical conductivity, organic material content and the total and EDTA extractable Ni, Cr, Zn and Cu levels. Fulvic acid was extracted from vermicompost and chemically characterized as well as its ability to chelate metals. The conditional stability constant, K of the fulvic acid-copper complex at different ph values was determined (log K cond = 7.39) using size-exclusion chromatography method. The Ni, Cr, Zn and Cu transfer study was conducted using biomass of Raphanus sativus L. The result shows significative statistical agreement with proposed experimental design 2 4-1 and allowed us to recognize the significant positive influence of factors such as the addition of Cu as possible pollutant in soil, ph, addition of fulvic acid and the time of addition of fulvic acid (vermicompost) at different physiological stages of plant development in increasing the bioavailability of Cu into plant biomass studied. The application of radiochemical methods with the use of fulvic acid labeled with 99mTc and 125I respectively allowed to ratify the influence of the factors studied on the transfer of heavy metals into biomass in terms of urban soil. It was possible to determine that the fulvic acid acts as a heavy metals transporter in

Carbon transfer in soil - plant system. Molecular labelling utilization for determining rhizosphere compounds

International Nuclear Information System (INIS)

Leguay, J.J.

2000-01-01

The growing up of the bacteria developing in the rhizosphere of plants is dependent on the compounds exudation by plant roots. Even the bacterial genetics use has permitted to identify diverse functions involved in the process of the rhizosphere colonisation ( mobility, heterotrophic bacteria, growing rate, antibiotics production), there is a big delay in vegetal partners. To decrease this delay we tried to characterize the interactions between a plant model, Arabidopsis thaliana and the rhizosphere bacteria. An experimental device has been conceived for measuring the transfer of carbon issued from the photosynthesis to roots and soil. The exudation by roots has been studied. The analysis of rhizospheric compounds in situ pose some methodological problems, especially, the rhizospheric compounds must be extracted from the soil matrix. we suggest an analysis method of rhizospheric compound and of their dynamics. (F.M.)

Site specific transfer factor studies for Kaiga region

International Nuclear Information System (INIS)

Karunakara, N.

2012-01-01

The Radioecology Laboratory of University Science Instrumentation Centre, Mangalore University is engaged in frontline research studies on different aspects of environmental radioactivity and radiation protection for the last 20 years. Extensive studies have been carried out on radiation levels, radionuclides distribution, and transfer of radionuclides through terrestrial, aquatic and atmospheric pathways in the environment of West Coast of India including the Kaiga nuclear power plant. The baseline studies on radioactivity levels around Kaiga region was carried out well before the nuclear power plant became operational and the data generated under these studies are considered to be highly valuable for future impact assessments. The nuclear power plant became operational in the year 1999 and since then this laboratory is involved in radiological impact assessment studies around the nuclear power plant. Detailed Kaiga specific studies are now ongoing to estimate the transfer factors and transfer coefficients for radionuclides for different pathways, such as, (i) soil to rice (ii) soil to different types of vegetables (iii) water/sediment to fish (iv) soil to grass (v) grass to cow milk and (vi) milk to child. For these studies, rice and vegetable fields were developed very close to the nuclear power plant in Kaiga to study the transfer of radionuclides. The water required for this field was drawn from coolant water discharge canal of the power plant. Rice and different types of vegetables were grown in the experimental fields in different seasons of the year and the uptake of radionuclides was studied. For a comparative study, rice and vegetables were also collected from the fields of farmers of nearby villages and analysed. The transfer of artificial radionuclides through pathway involving cow milk was also studied in detail. A grass field was developed and cows were adopted specifically for this study. The cows were allowed to graze freely in this grass field

Problem of a radiocapacity in a system soil-plant for bog ecosystem

International Nuclear Information System (INIS)

Kutlakhmedova-Vyshnyakova, V.

1998-01-01

The factors of the various components of a pasture bog ecosystem were evaluated on the example of the Volynsk area. Soil and water were found to contribute appreciably to the accumulation of radionuclides in plants in the bog ecosystem. Evaluation of the integral distribution of radionuclides ( 137 Cs) and the radiocapacity factors of the bog ecosystem components lead to F(soil) = 0.5, F(water) = 0.1, F(plants) = 0.25, and F(root) = 0.15. The radiocapacity factor determines the fraction of radionuclides from a general reserve concentrated in a particular component of the ecosystem. The higher values transfer factors of accumulation for plants in the bog ecosystem in comparison with terrestrial ecosystems (Tf 1.5-18) are noteworthy. Thus the contribution of soil to the formation Tf is from 60 % to 80 %, the remaining pathway in plants being from the water phase. This may be related with the high radiocapacity of soil in the bog ecosystem and (as a corollary) the rather small concentration of radionuclides in water in comparison with soil