Quantitative assessment of the effects of agricultural practices designed to reduce 137Cs and 90Sr soil-plant transfer in meadows.
暂无分享,去创建一个
G Rauret | M. Vidal | G. Rauret | A. Rigol | S. Hillier | M Camps | A Rigol | S Hillier | M Vidal | M. Camps
[1] J. Wauters,et al. Prediction of solid/liquid distribution coefficients of radiocaesium in soils and sediments. Part two: a new procedure for solid phase speciation of radiocaesium , 1996 .
[2] K. H. Larson,et al. INFLUENCE OF CALCIUM ON PLANT UPTAKE OF SR 90 AND STABLE STRONTIUM , 1959 .
[3] S Krouglov,et al. Chemical fractionation of 90Sr, 106Ru, 137Cs and 144Ce in Chernobyl-contaminated soils: an evolution in the course of time , 1998 .
[4] B Baeyens,et al. Cesium and rubidium ion equilibriums in illite clay , 1983 .
[5] S. Levchuk,et al. Migration of 137Cs and 90Sr from chernobyl fallout in Ukrainian, Belarussian and Russian soils , 1997 .
[6] George Shaw,et al. Blockade by fertilisers of caesium and stronium uptake into crops: effects on the root uptake process , 1993 .
[7] G. M. Desmet,et al. Influence of agricultural countermeasures on the ratio of different chemical forms of radionuclides in soil and soil solution. , 1993 .
[8] Roel Merckx,et al. Concentrations of 137Cs and K in Soil Solution Predict the Plant Availability of 137Cs in Soils , 1997 .
[9] A. Page. Methods of soil analysis. Part 2. Chemical and microbiological properties. , 1982 .
[10] S. Hillier. Accurate quantitative analysis of clay and other minerals in sandstones by XRD: comparison of a Rietveld and a reference intensity ratio (RIR) method and the importance of sample preparation , 2000, Clay Minerals.
[11] M. Vidal,et al. Two approaches to the study of radiocaesium partitioning and mobility in agricultural soils from the Chernobyl area , 1995 .
[12] V. S. Anisimov,et al. Changes in the forms of 137Cs and its availability for plants as dependent on properties of fallout after the Chernobyl nuclear power plant accident , 1994 .
[13] V. Linnik,et al. 137Cs and 90Sr mobility in soils and transfer in soil–plant systems in the Novozybkov district affected by the Chernobyl accident , 1998 .
[14] A. Maes,et al. Quantitative analysis of radiocaesium retention in soils , 1988, Nature.
[15] Fred Adams,et al. A Comparison of Column‐Displacement and Centrifuge Methods for Obtaining Soil Solutions , 1980 .
[16] S. Hillier. Use of an for air brush to spray dry samples X-ray powder diffraction , 1999 .
[17] L. Sweeck,et al. Cationic interactions in radiocaesium uptake from solution by spinach , 1997 .
[18] Rob N.J. Comans,et al. Prediction of solid/liquid distribution coefficients of radiocaesium in soils and sediments. Part one: a simplified procedure for the solid phase characterisation , 1996 .
[19] G. M. Desmet,et al. Comparative study on the uptake of strontium-85 from nutrient solutions and potted soils by lettuce , 1990, Plant and Soil.
[20] Gemma Rauret,et al. Sequential Extractions for the Study of Radiocesium and Radiostrontium Dynamics in Mineral and Organic Soils from Western Europe and Chernobyl Areas , 1999 .
[21] George Shaw,et al. Application of fertilisers and ameliorants to reduce soil to plant transfer of radiocaesium and radiostrontium in the medium to long term — a summary , 1993 .