9 research outputs found
Evidencing the role of plants vs soils in the understanding of 137Cs phyto availability using a coupled experimental and modelling approach
International audience137Cs is a radionuclide with a half-life of 30 years that is commonly found in soils after nuclear fallout due to nuclear incidents or atmospheric nuclear weapon testing. Due to their properties of accumulation and retention, soils are key compartments for the transfer of contaminants such as 137Cs in the trophic chain. Ingestion of contaminated agricultural products being one of the main component of human exposure, it is essential to be able to predict the fate of 137Cs throughout the soil-plant continuum.The contaminant mobility into the soil, its transfer to the plant and its final distribution between all components are generally described by simple models (equilibrium-based, linear distributions). These models are operational but are not able to account for the variability of soils and plants encountered.Bioavailability is function of both soil physico-chemical characteristics, that impact the environmental availability, and plant physiology which determines the uptake rate and accumulation. The aim of this work is to highlight the preponderant factors controlling the 137Cs bioavailability in the soil-solution-plant continuum by using a model that account for both soil and plant characteristics. The proposed mechanistic model is based on thermodynamic reactions describing the interactions of Cs with the different soil reactive components, coupled with a physiological model of root absorption.Series of experiments were conducted to produce a contrasted data set of 137Cs soil to plant transfer. For those experiments, 2 different plants with contrasted Cs uptake capacities (Millet, Mustard) and 3 different soils with varying texture and mineralogy have been studied. Three weeks exposure studies were conducted with the RHIZOtestÂź which is a normative device to assess the bioavailability of contaminants in soil. They were completed with batch experiments aiming at characterizing the environmental availability of Cs in soils. A large range of 137Cs soil to plant transfer rates was measured for the different soil/pant combinations. For example a contrasted bioavailability of 137Cs was observed, with the same plant accumulating 10% to 40% of total Csâs stock depending on the soils. We also observed that during the time of the experiment the plant had absorbed most of the estimated environmental available Cs.Modelling those experiments allowed us to highlight the main soil and plant properties that have a great impact on the contaminant mobility. For example, plant physiological factors were the main driver of bioavailability in condition where environmental availability was not limited (e.g. sandy soils), whereas their roles were reduced in soils with high 137Cs sorption capacity. Such a model may help to reduce uncertainties in the prediction of 137Cs transfer to plants in environmental risk assessment, with a great potential to cover a large range of soils and plants
Modélisation dynamique de la mobilité du 137Cs dans le continuum sol-solution-plante : évaluation de la réponse du modÚle à des jeux de données expérimentaux contrastés
The aim of this work was to develop a robust and generical model able to predict 137Cs mobility into the soil-solution-plant continuum. The first part of this work was dedicated to several soil-plant transfer experiments. Two plants (millet, mustard) with contrasted Cs adsorption capacity and three soils with different Cs retention capacities have been used. Results obtained with the experiments permitted to observe the influence of the different system compartments on Cs mobility. Moreover, those experiments permitted to acquire a contrasted experimental data set. The second part of this work was to confront the model with the experimental data generated in the lab. This confrontation showed that the model was able to represent with a good agreement the distribution of the Cs into the soil-solution-plant continuum. Moreover, the model permitted to understand the influence of other cations in the mobility Cs in the system. Dynamic modeling of the 137 Cs in the soil-solution-plant continuum. Evaluation of the model response to contrasted experimental dataCe travail visait Ă dĂ©velopper un modĂšle gĂ©nĂ©rique capable de mieux prĂ©dire les transferts de 137Cs dans le systĂšme sol-solution-plante. La premiĂšre partie de ce travail a Ă©tĂ© consacrĂ©e Ă des expĂ©rimentations de transfert sol-plante du Cs en laboratoire. Deux plantes (millet, moutarde) ayant des capacitĂ©s dâabsorption du Cs potentiellement diffĂ©rentes et trois types de sol ayant des capacitĂ©s de rĂ©tention du Cs contrastĂ©es ont Ă©tĂ© utilisĂ©s. Cette partie expĂ©rimentale a permis de mettre en Ă©vidence lâinfluence des diffĂ©rentes phases du systĂšme sur la mobilitĂ© du Cs, mais aussi de gĂ©nĂ©rer un jeu de donnĂ©es utilisĂ© dans la deuxiĂšme partie de ce travail pour tester la capacitĂ© du modĂšle dĂ©veloppĂ© Ă simuler de transferts du Cs pour diffĂ©rents couples sol x plante. La confrontation modĂšle-mesure a permis de dĂ©montrer la bonne capacitĂ© du modĂšle Ă reprĂ©senter la mobilitĂ© du Cs pour chaque condition, mais aussi la nĂ©cessitĂ© de prendre en compte lâinfluence des cations majeurs pour modĂ©liser correctement la mobilitĂ© du Cs dans le systĂšme sol-solution-plant
Modélisation dynamique de la mobilité du 137Cs dans le continuum sol-solution-plante : évaluation de la réponse du modÚle à des jeux de données expérimentaux contrastés
The aim of this work was to develop a robust and generical model able to predict 137Cs mobility into the soil-solution-plant continuum. The first part of this work was dedicated to several soil-plant transfer experiments. Two plants (millet, mustard) with contrasted Cs adsorption capacity and three soils with different Cs retention capacities have been used. Results obtained with the experiments permitted to observe the influence of the different system compartments on Cs mobility. Moreover, those experiments permitted to acquire a contrasted experimental data set. The second part of this work was to confront the model with the experimental data generated in the lab. This confrontation showed that the model was able to represent with a good agreement the distribution of the Cs into the soil-solution-plant continuum. Moreover, the model permitted to understand the influence of other cations in the mobility Cs in the system. Dynamic modeling of the 137 Cs in the soil-solution-plant continuum. Evaluation of the model response to contrasted experimental dataCe travail visait Ă dĂ©velopper un modĂšle gĂ©nĂ©rique capable de mieux prĂ©dire les transferts de 137Cs dans le systĂšme sol-solution-plante. La premiĂšre partie de ce travail a Ă©tĂ© consacrĂ©e Ă des expĂ©rimentations de transfert sol-plante du Cs en laboratoire. Deux plantes (millet, moutarde) ayant des capacitĂ©s dâabsorption du Cs potentiellement diffĂ©rentes et trois types de sol ayant des capacitĂ©s de rĂ©tention du Cs contrastĂ©es ont Ă©tĂ© utilisĂ©s. Cette partie expĂ©rimentale a permis de mettre en Ă©vidence lâinfluence des diffĂ©rentes phases du systĂšme sur la mobilitĂ© du Cs, mais aussi de gĂ©nĂ©rer un jeu de donnĂ©es utilisĂ© dans la deuxiĂšme partie de ce travail pour tester la capacitĂ© du modĂšle dĂ©veloppĂ© Ă simuler de transferts du Cs pour diffĂ©rents couples sol x plante. La confrontation modĂšle-mesure a permis de dĂ©montrer la bonne capacitĂ© du modĂšle Ă reprĂ©senter la mobilitĂ© du Cs pour chaque condition, mais aussi la nĂ©cessitĂ© de prendre en compte lâinfluence des cations majeurs pour modĂ©liser correctement la mobilitĂ© du Cs dans le systĂšme sol-solution-plant
Dynamic modeling of 137Cs in the soil-solution-plant continuum : evaluation of the model response to contrasted experimental data
Ce travail visait Ă dĂ©velopper un modĂšle gĂ©nĂ©rique capable de mieux prĂ©dire les transferts de 137Cs dans le systĂšme sol-solution-plante. La premiĂšre partie de ce travail a Ă©tĂ© consacrĂ©e Ă des expĂ©rimentations de transfert sol-plante du Cs en laboratoire. Deux plantes (millet, moutarde) ayant des capacitĂ©s dâabsorption du Cs potentiellement diffĂ©rentes et trois types de sol ayant des capacitĂ©s de rĂ©tention du Cs contrastĂ©es ont Ă©tĂ© utilisĂ©s. Cette partie expĂ©rimentale a permis de mettre en Ă©vidence lâinfluence des diffĂ©rentes phases du systĂšme sur la mobilitĂ© du Cs, mais aussi de gĂ©nĂ©rer un jeu de donnĂ©es utilisĂ© dans la deuxiĂšme partie de ce travail pour tester la capacitĂ© du modĂšle dĂ©veloppĂ© Ă simuler de transferts du Cs pour diffĂ©rents couples sol x plante. La confrontation modĂšle-mesure a permis de dĂ©montrer la bonne capacitĂ© du modĂšle Ă reprĂ©senter la mobilitĂ© du Cs pour chaque condition, mais aussi la nĂ©cessitĂ© de prendre en compte lâinfluence des cations majeurs pour modĂ©liser correctement la mobilitĂ© du Cs dans le systĂšme sol-solution-planteThe aim of this work was to develop a robust and generical model able to predict 137Cs mobility into the soil-solution-plant continuum. The first part of this work was dedicated to several soil-plant transfer experiments. Two plants (millet, mustard) with contrasted Cs adsorption capacity and three soils with different Cs retention capacities have been used. Results obtained with the experiments permitted to observe the influence of the different system compartments on Cs mobility. Moreover, those experiments permitted to acquire a contrasted experimental data set. The second part of this work was to confront the model with the experimental data generated in the lab. This confrontation showed that the model was able to represent with a good agreement the distribution of the Cs into the soil-solution-plant continuum. Moreover, the model permitted to understand the influence of other cations in the mobility Cs in the system. Dynamic modeling of the 137 Cs in the soil-solution-plant continuum. Evaluation of the model response to contrasted experimental dat
Modélisation dynamique de la mobilité du 137Cs dans le continuum sol-solution-plante : évaluation de la réponse du modÚle à des jeux de données expérimentaux contrastés
The aim of this work was to develop a robust and generical model able to predict 137Cs mobility into the soil-solution-plant continuum. The first part of this work was dedicated to several soil-plant transfer experiments. Two plants (millet, mustard) with contrasted Cs adsorption capacity and three soils with different Cs retention capacities have been used. Results obtained with the experiments permitted to observe the influence of the different system compartments on Cs mobility. Moreover, those experiments permitted to acquire a contrasted experimental data set. The second part of this work was to confront the model with the experimental data generated in the lab. This confrontation showed that the model was able to represent with a good agreement the distribution of the Cs into the soil-solution-plant continuum. Moreover, the model permitted to understand the influence of other cations in the mobility Cs in the system. Dynamic modeling of the 137 Cs in the soil-solution-plant continuum. Evaluation of the model response to contrasted experimental dataCe travail visait Ă dĂ©velopper un modĂšle gĂ©nĂ©rique capable de mieux prĂ©dire les transferts de 137Cs dans le systĂšme sol-solution-plante. La premiĂšre partie de ce travail a Ă©tĂ© consacrĂ©e Ă des expĂ©rimentations de transfert sol-plante du Cs en laboratoire. Deux plantes (millet, moutarde) ayant des capacitĂ©s dâabsorption du Cs potentiellement diffĂ©rentes et trois types de sol ayant des capacitĂ©s de rĂ©tention du Cs contrastĂ©es ont Ă©tĂ© utilisĂ©s. Cette partie expĂ©rimentale a permis de mettre en Ă©vidence lâinfluence des diffĂ©rentes phases du systĂšme sur la mobilitĂ© du Cs, mais aussi de gĂ©nĂ©rer un jeu de donnĂ©es utilisĂ© dans la deuxiĂšme partie de ce travail pour tester la capacitĂ© du modĂšle dĂ©veloppĂ© Ă simuler de transferts du Cs pour diffĂ©rents couples sol x plante. La confrontation modĂšle-mesure a permis de dĂ©montrer la bonne capacitĂ© du modĂšle Ă reprĂ©senter la mobilitĂ© du Cs pour chaque condition, mais aussi la nĂ©cessitĂ© de prendre en compte lâinfluence des cations majeurs pour modĂ©liser correctement la mobilitĂ© du Cs dans le systĂšme sol-solution-plant
Cesium transfer to millet and mustard as a function of Cs availability in soils
International audience137Cs is one of the most persistent radioactive contaminant in soil after a nuclear accident. It can be taken up by plants and enter the human food chain generating major hazard for population health. Although a huge literature have highlighted the role of different processes involved in Cs uptake by plants, there is still no simple way to predict its transfer for a specific plant from a particular soil. The objective of this study is to assess the assumption that concentration ratio (CR) of Cs can be predicted from one plant taxon knowing the CR of another taxon taken as reference whatever the soils on which plants are grown. A series of plant/soil Cs transfer experiments were performed on Rhizotest using three soils with contrasted Cs retention capacity and two plants (millet and mustard) with contrasted Cs uptake capacity based on their phylogeny. Results highlighted a different behaviour than that expected, with CR of mustard being either higher, equal or lower than the one of millet depending on the soils. These results can be put in regards to the large variation of the CR of millet on these 3 soils (3 orders of magnitude). Parameters linked to plant physiology (growth, water use efficiency, potassium (K) uptake and distribution in planta) or K level in soil solution failed to explain the relative behaviour of millet compared to mustard as a function of soils. However considering Cs availability in soils and defining a new CR based on the amount of Cs available in the soil (CRavail) permits to decrease the range of variation of CR for a given plant between the soils
Evidencing the role of plants vs soils in the understanding of 137Cs phyto availability using a coupled experimental and modelling approach
International audience137Cs is a radionuclide with a half-life of 30 years that is commonly found in soils after nuclear fallout due to nuclear incidents or atmospheric nuclear weapon testing. Due to their properties of accumulation and retention, soils are key compartments for the transfer of contaminants such as 137Cs in the trophic chain. Ingestion of contaminated agricultural products being one of the main component of human exposure, it is essential to be able to predict the fate of 137Cs throughout the soil-plant continuum.The contaminant mobility into the soil, its transfer to the plant and its final distribution between all components are generally described by simple models (equilibrium-based, linear distributions). These models are operational but are not able to account for the variability of soils and plants encountered.Bioavailability is function of both soil physico-chemical characteristics, that impact the environmental availability, and plant physiology which determines the uptake rate and accumulation. The aim of this work is to highlight the preponderant factors controlling the 137Cs bioavailability in the soil-solution-plant continuum by using a model that account for both soil and plant characteristics. The proposed mechanistic model is based on thermodynamic reactions describing the interactions of Cs with the different soil reactive components, coupled with a physiological model of root absorption.Series of experiments were conducted to produce a contrasted data set of 137Cs soil to plant transfer. For those experiments, 2 different plants with contrasted Cs uptake capacities (Millet, Mustard) and 3 different soils with varying texture and mineralogy have been studied. Three weeks exposure studies were conducted with the RHIZOtestÂź which is a normative device to assess the bioavailability of contaminants in soil. They were completed with batch experiments aiming at characterizing the environmental availability of Cs in soils. A large range of 137Cs soil to plant transfer rates was measured for the different soil/pant combinations. For example a contrasted bioavailability of 137Cs was observed, with the same plant accumulating 10% to 40% of total Csâs stock depending on the soils. We also observed that during the time of the experiment the plant had absorbed most of the estimated environmental available Cs.Modelling those experiments allowed us to highlight the main soil and plant properties that have a great impact on the contaminant mobility. For example, plant physiological factors were the main driver of bioavailability in condition where environmental availability was not limited (e.g. sandy soils), whereas their roles were reduced in soils with high 137Cs sorption capacity. Such a model may help to reduce uncertainties in the prediction of 137Cs transfer to plants in environmental risk assessment, with a great potential to cover a large range of soils and plants
Evidencing the role of plants vs soils in the understanding of 137Cs phyto availability using a coupled experimental and modelling approach
International audience137Cs is a radionuclide with a half-life of 30 years that is commonly found in soils after nuclear fallout due to nuclear incidents or atmospheric nuclear weapon testing. Due to their properties of accumulation and retention, soils are key compartments for the transfer of contaminants such as 137Cs in the trophic chain. Ingestion of contaminated agricultural products being one of the main component of human exposure, it is essential to be able to predict the fate of 137Cs throughout the soil-plant continuum.The contaminant mobility into the soil, its transfer to the plant and its final distribution between all components are generally described by simple models (equilibrium-based, linear distributions). These models are operational but are not able to account for the variability of soils and plants encountered.Bioavailability is function of both soil physico-chemical characteristics, that impact the environmental availability, and plant physiology which determines the uptake rate and accumulation. The aim of this work is to highlight the preponderant factors controlling the 137Cs bioavailability in the soil-solution-plant continuum by using a model that account for both soil and plant characteristics. The proposed mechanistic model is based on thermodynamic reactions describing the interactions of Cs with the different soil reactive components, coupled with a physiological model of root absorption.Series of experiments were conducted to produce a contrasted data set of 137Cs soil to plant transfer. For those experiments, 2 different plants with contrasted Cs uptake capacities (Millet, Mustard) and 3 different soils with varying texture and mineralogy have been studied. Three weeks exposure studies were conducted with the RHIZOtestÂź which is a normative device to assess the bioavailability of contaminants in soil. They were completed with batch experiments aiming at characterizing the environmental availability of Cs in soils. A large range of 137Cs soil to plant transfer rates was measured for the different soil/pant combinations. For example a contrasted bioavailability of 137Cs was observed, with the same plant accumulating 10% to 40% of total Csâs stock depending on the soils. We also observed that during the time of the experiment the plant had absorbed most of the estimated environmental available Cs.Modelling those experiments allowed us to highlight the main soil and plant properties that have a great impact on the contaminant mobility. For example, plant physiological factors were the main driver of bioavailability in condition where environmental availability was not limited (e.g. sandy soils), whereas their roles were reduced in soils with high 137Cs sorption capacity. Such a model may help to reduce uncertainties in the prediction of 137Cs transfer to plants in environmental risk assessment, with a great potential to cover a large range of soils and plants