Role and uncertainty of foliar transfer in radiological impact assessments: State of the art and future actions

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Numéro		Radioprotection Volume 44, Numéro 5, 2009 ECORAD 2008 - Radioecology and Environmental Radioactivity


Page(s)		791 - 798
DOI		https://doi.org/10.1051/radiopro/20095142
Publié en ligne		6 juin 2009

Aarkrog A. Translocation of radionuclides in cereal crops. Ecological aspects of radionuclides releases. Oxford Blackwell scientific Publishers (1983): 81–90. [Google Scholar]
Hoffman F. O., Thiessen K. M., Rael R. M. Comparison of interception and initial retention of wet-deposited contaminants on leaves of different vegetation types. Atmospheric Environment (1995) 29 (15): 1771–1775. [Google Scholar]
Kinnersley R. P. and. Scott L. K Aerial contamination of fruit through wet deposition and particulate dry deposition. Journal of Environmental Radioactivity (2001) 52 (2–3): 191–213. [Google Scholar]
Muller H. and Pröhl G. Ecosys-87: A dynamic model for assessing radiological consequences of nuclear accidents. Health Physics (1993) 64 (3): 232–252. [Google Scholar]
Bukovac M. J., Wittwer S. H., Tukey H. B. Above ground plant parts as a pathway for entry of fission products into the food chain with special reference to 89-90Sr and 137Cs. In: Radioactive fallout, soils, plants, foods, man. E. Fowler, Ed. Elsevier Press New York, (1965): 82–109. [Google Scholar]
Franke W. Mechanisms of foliar penetration of solutions. Ann. Rev. plant phys. (1967) 18, 281–300. [Google Scholar]
Aarkrog A. On the direct contamination of rye, barley, wheat and oats with Sr-85, Cs-134, Mn-54 and Ce141. Radiation Botany (1969) 9: 357–366. [Google Scholar]
Aarkrog A. and Lippert J. Direct contamination of barley with Cr-51, Fe-59, Co-58, Zn-65, Hg-203 and Pb-210. Radiation Botany (1971) 11: 463–472. [Google Scholar]
Aarkrog A. Direct contamination of barley with Be-7, Na-22, Cd-115, Sb-125, Cs-134 and Ba-133. Risoe report No. 256. Danish Atomic Energy Commission (1972): 163–175. [Google Scholar]
Aarkrog A. Radionuclide levels in mature grain related to radiostrontium content and time of direct contamination. Health Physics (1975) 28: 557–562. [Google Scholar]
Carini F. Radionuclides in plants bearing fruit: an overview. JER (1999) 46(1): 77–97. [Google Scholar]
Carini F., Green N., Spalla S. Radionuclides in fruit systems: A review of experimental studies. Science of The Total Environment (2006) 359(1–3): 188–193. [Google Scholar]
Middleton L. J. Absorption and translocation of strontium and caesium by plants from foliar sprays. Nature (1958) 181: 1300–1303. [Google Scholar]
Middleton L. J. Radioactive strontium and caesium in the edible parts of crop plants after foliar contamination. Inter. J. Rad (1959) 4: 387–402. [Google Scholar]
Middleton L. J. and. Squire H. M Further studies of radioactive strontium and caesium in agricultural crops after direct contamination. Int. J. Rad. Biol. (1963) 6(6): 549–558. [Google Scholar]
Shaw G., Minski M. J., Bell J. N. B. Retention, loss and translocation of radionuclides applied to foliar surfaces of wheat. Environmental and Experimental Botany (1992) 32(4): 391–404. [Google Scholar]
Madoz-Escande C., Henner P., Bonhomme T. Foliar contamination of Phaseolus vulgaris with aerosols of 137Cs, 85Sr, 133Ba and 123mTe: influence of plant development stage upon contamination and rain. JER (2004) 73(1): 49–71. [Google Scholar]
Choi Y. H, Lim K. M., Yu D., Park H. G., Choi Y. G., Lee C. M. Transfer pathways of 54Mn, 57Co, 85Sr, 103Ru and 134Cs in rice and radish plants directly contaminated at different growth stages. Ann. of Nuc. Ener. (2002) 29(4): 429–446. [Google Scholar]
Colle C., Madoz-Escande C., Leclerc E. Foliar transfer into the biosphere: review of translocation factors to cereals grains, JER, Special issue for AIEA/EMRAS program/Revision of Tech. Report Series n°364, submitted. [Google Scholar]
Gerdung S., Pöllot M., Fischer P., Grillmaier R. E., Müller P. Contamination of wheat, rye, and potatoes by foliar application of 134Cs. Journal of Radioanalytical and Nuclear Chemistry (1999) 240(2): 451–454. [Google Scholar]
Voigt G., Pröhl G., Müller H. Experiments on the seasonality of the cesium translocation in cereals, potatoes and vegetables. Radiation and Environmental Biophysics (1991) 30(4): 295–303. [Google Scholar]
Madoz-Escande C. and Santucci P. Weather-dependent change of cesium, strontium, barium and tellurium contamination deposited as aerosols on various cultures. JER (2005) 84(3): 417–439. [Google Scholar]
Baeza A., Paniagua J. M., Rufo M., Sterling A., Barandica J. Radiocaesium and radiostrontium uptake by turnips and broad beans via leaf and root absorption. Applied Radiation and Isotopes (1999) 50(3): 467–474. [Google Scholar]
Madoz-Escande C. Bonhomme T., Poncet-Bonnard D. Foliar contamination of plants with aerosols of 137Cs, 85Sr, 133Ba and 123mTe: Influence of rain. Radioprotection (2005) 40(Suppl.1): S421–S427. [Google Scholar]
Delmas J., Disdier R., Grauby A., Bovard P.. Radiocontamination expérimentale de quelques espèces cultivées soumises à l'irrigation par aspersion. In: Actes Ie Symp. Intern. de Radioéc., C.E.N. Cadarache, 8-12 sept. 1969: 707–729. [Google Scholar]
Brambilla M., Fortunati P., Carini F. Foliar and root uptake of 134Cs, 85Sr and 65Zn in processing tomato plants (Lycopersicon esculentum Mill.). JER (2002) 60(3): 351–363. [Google Scholar]
Carini, F., Anguissola Scotti I., Montruccoli M., Silva S. 134Cs foliar contamination of vine: translocation to grapes and transfer to wine. In M. Gerzabek (Ed) Internat. Symp. of Radioec. 10 years terrest. Radioecol. research follow. the Chernobyl accident. Vienna, Aust.: Aust. Soil Science Soc. and Fed. Envir. Agency. (1996): 163–169. [Google Scholar]
Carini F. and Lombi E. Foliar and soil uptake of 134Cs and 85Sr by grape vines. Science of the Total Environment (1997) 207(2–3): 157–164. [Google Scholar]
Carini F., Brambilla M., Mitchell N., Ould-Dada Z. Cesium-134 and Strontium-85 in Strawberry Plants following Wet Aerial Deposition. Journal of Environmental Quality (2003) 32(6): 2254–2264. [Google Scholar]
Macacini J. F., De Nadai Fernandes E. A., Taddei M. H. T. Translocation studies of 137Cs and 90Sr in bean plants (Phaseolus vulgaris): simulation of fallout. Environmental Pollution (2002) 120(1): 151–155. [Google Scholar]
Oncsik M. B., Eged K., Kis Z., Kanyar B. A validation study for the transport of 134Cs to strawberry. JER (2002). 61(3): 319–329. [Google Scholar]
Madoz-Escande C., Colle C., Adam C. Evolution of cesium and strontium contamination deposited on vines. Radioprotection Colloques (2002). 37 C1: 515–520. [Google Scholar]
Brambilla M., Strebl F., Carini F., Gerzabek M. Ventomod: a dynamic model for leaf to fruit transfer of radionuclides in processing tomato plants (Lycopersicon esculentum Mill.) following a direct contamination event. JER (2003) 65(3): 309–328. [Google Scholar]
Carini, F. and Bengtsson G. Post-deposition transport of radionuclides in fruit. JER (2001) 52 (2–3): 215–236. [Google Scholar]
Koranda, J. J. and Robison W. L. Accumulation of radionuclides by plants as a monitor system. Environmental Health Perspectives (1978). 27: 165–179. [Google Scholar]
Ould-Dada Z., Carini F., Eged K., Kis Z., Linkov I., Mitchell N.G., Mourlon C., Venter A. Radionuclides in fruit systems: Model prediction-experimental data intercomparison study. Science of The Total Environment (2006) 366 (2–3): 514–524. [Google Scholar]
Ould-Dada Z., Carini F., Mitchell N.G. A model testing study for the transfer of radioactivity to fruit. JER (2003) 70(3): 207–221. [Google Scholar]
Cataldo D. A., Garland T. R., Wildung R. E., Thomas J.M.. Foliar absorption of transuranic elements: Influence of physicochemical form and environmental factors. JEQ (1980) 9(3): 364–369. [Google Scholar]
Kashparov V., Colle C., Zvarich S., Yoschenko V., Levchuk S., Lundin S. Soil-to-plant halogens transfer studies 2. Root uptake of radiochlorine by plants. JER (2005) 79(3): 233–253. [Google Scholar]
Wan H.F., Mikkelsen R.L., Page A.L. Selenium uptake by some agricultural crops from central California soils. JEQ, (1988)~17(2):~269–272.~ [Google Scholar]

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