Thesis for the Degree of Doctor of Philosophy - DTU Orbit

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8 Marchetti et al. (1997) 12.7 10 8 , all similar to the bulk value of 18.05 10 8 . The Chernobyl soil 129 I/I ratio is not much higher than the iodine ratio for some Russian lakes (Reithmeier et al., 2007) that range from (3.5e8.4) 10 8 . From our results 42e44% of 127 I is bound to the insoluble fraction, as humin and minerals, while only 12e22% of 129 I(Table 3 and Fig. 1a,b) remains in this fraction of the oxic and anoxic sediments. These results are noteworthy and reflect that the 127 I has been present much longer in those sediments than 129 I and therefore has been fixed more strongly to humin and minerals than 129 I which may be added to the sediment more recently and also from other sources than stable iodine. A similar observation was also reported for soil near the reprocessing facility in Karlsruhe (Germany) (Schmidtz and Aumann, 1995) where a major part of stable iodine between 56 and 71% was strongly associated with the mineral fraction, while 8e26% of the total 129 I was recovered in this fraction, reflecting different sources and residence (contact) time of 127 I and 129 I. Our data further show that the distribution of 129 I/ 127 I values differed significantly between phases (Fig. 2) and samples, indicating that equilibrium has not yet been reached for a large fraction of the released 129 I. This means that geochemical models based on stable iodine behavior cannot be used to trace the behavior of 129 I. Relatively higher 129 I/ 127 I values were observed in the solid phase (oxides, humic acid, fulvic acid and humin and minerals, Table 3) of the Danish agricultural soil. In oxic sediment and soil reference material 375 IAEA, higher 129 I/ 127 I values (Table 3 and Fig. 2) where observed in oxide, humic and fulvic acid (Table 3). In the anoxic sediment the highest 129 I/ 127 I values (0.3e0.6 10 8 ) were observed in readily available fraction including water soluble, exchangeable and carbonate fractions, while lower values (0.01e0.02 10 8 ) were found in humic acid and humin and minerals fractions. Our results are in agreement with previous studies (Muramatsu et al., 1996; Muramatsu and Yoshida, 1999; Sheppard and Hawkins, 1995; Yuita, 1994) effectuated on anoxic/ oxic soils which reveal a high desorption of radioactive iodine 125 I from soil solid phase to soil solution and low soil adsorption of new added 125 I under anoxic conditions when compared with oxic soils. Investigating the solid to liquid distribution coefficient, Kd, for iodine ( 125 I) in lake sediments, Bird and Schwartz (1996) found lower Kd, under anoxic when compared with oxic conditions. Their results also reveal higher sediment adsorption of new added 125 I in oxic conditions while an opposite trend occurs in anoxic environments. On the background of the above and since the highest 129 I/ 127 I value was found in the readily available fraction it is concluded that the mobility and availability of 129 I in the anoxic sediment is markedly greater compared with oxic sediment and studied soils samples. Further, the primary association of 129 I with the low molecular weight fulvic acid which is water soluble through pH scale, is another evidence that the investigated anoxic sediment is not a particularly effective sink for long lived 129 I. 6. Conclusions For the first time 129 I associated with humic and fulvic acid respectively and with humin in soil and sediments samples is reported. The results of sequential extraction presented here point out that partition of 127 I and 129 I in soil and marine sediments agreed with results presented by other authors regarding association of large part of iodine in the organic fraction. Our data further indicated new findings about the partition of iodine within the organic fraction with respect to pH and oxygen conditions as well as the environmental situation. Within the organic fraction the isotopes V. Hansen et al. / Journal of Environmental Radioactivity xxx (2011) 1e9 distribution seemed to be controlled by pH conditions where pH value below 5.0e5.5 promoted occurrence of 127 I and 129 I in the humic acid while at pH > 6 the partitioning was in the fulvic acid. Anoxic conditions seemed to increase the mobility and availability of iodine compared to oxic, while subaerial situation (soils) reduced the availability of water soluble fraction compared to subaqueous (marine) one. The enhanced mobility may be more of a problem in oxygen deficient salt marches, bog areas and flooded rice paddys than in otherwise oxic soils. The 129 I is still in disequilibrium in the studied reservoir suggesting that caution must be taken in the evaluation of radioactive iodine geochemistry in the environment. Acknowledgements VH is grateful to the Radioecology and Tracers Programme (headed by Sven P. Nielsen) at the Radiation Research Division, Risø National Laboratory for Sustainable Energy, Technical University of Denmark, for supporting her Ph.D. project. References Aldahan, A., Englund, E.G., Possnert., I., Cato, Hou, X.L., 2007a. Iodine-129 enrichment in sediment of the baltic Sea. Appl. Geochem. 22, 637e647. Aldahan, A., Alfimov, V., Possnert, G., 2007b. 129 I anthropogenic budget: major sources and sinks. Appl. Geochem. 22, 606e618. Andersson, K.G., Qiao, J., Hansen, V., 2009. On the requirements to optimize restoration of radioactively contaminated soil areas (Chapter 15). In: Steinberg, R.V. (Ed.), Contaminated Soils: Environmental Impact, Disposal and Treatment. NOVA Science Publishers, ISBN 978-1-60741-791-0, pp. 419e432. Bird, G.A., Schwartz, W., 1996. Distribution coefficients, Kds, for iodide in Canadian Shield Lake Sediments under oxic and anoxic conditions. J.Environ. Radioact. 35 (3), 261e279. Brezonik, P.L., 1994. Chemical Kinetics and Process Dynamics in Aquatic Systems. (Lewis Boca Raton, FL). Carroll, J.L., Zaborska, A., Papucci, C., Schirone, A., Carroll, M.L., Pempkowiak, J., 2008. Accumulation of organic carbon in western Barents Sea sediments. Deep- Sea Research II 55, 2361e2371. Ceccanti, B., Alcaniz-Baldellou, J.M., Gispert-Negrell, M., Gassiot-Matas, M., 1986. Characterization of organic matter from two different soils by pyrolysis-gas chromatography. Soil Sci. 142 (2), 83e90. Englund, E., Aldahan, A., Hou, X.L., 2010. Speciation of iodine (127I and 129I) in lake sediments. Nucl. Instrum. Methods. Phys. Res. B. 268, 1102e1105. Fehn, U., Moran, J.E., Snyder, G.T., Muramatsu, Y., 2007. The initial 129I/I ratio and the presence of ‘old’ iodine in continental margins. Nucl. Instrum. Methods. Phys. Res. B. 259, 496e502. Feiters, M.C., Kupper, F.C., Meyer-Klaucke, W., 2005. X-ray absorption spectroscopic studies on model compounds for biological iodine and bromine. J. Synchrotron Radiat. 12, 85e93. Filius, J.D., Lumsdon, D.G., Meeussen, J.C.L., Hiemstra, T., Van Riemsdijk, W.H., 2000. Adsorption of fulvic acid on goethite. Geochimica et Cosmochimica Acta 64 (1), 51e60. Francois, R., 1987. The influence of humic substances on the geochemistry of iodine in nearshore and hemipelagic marine sediments. Geochimica et Cosmochimica Acta 51, 2417e2427. Fuge, R., 1996. Geochemistry of iodine in relation to iodine deficiency diseases. Environ. Geochem. Health 113, 201e212. Gallagher, D., McGee, E., Mitchell, P., Alfimov, V., Aldahan, A., Possnert, G., 2005. Retrospective search for evidence of the 1957 Windscale fire in NE Ireland using 129I and other long-lived nuclides. Environ. Sci. Technol. 39, 2927e2935. Gonzalez-Vila, F.J., Martin, F., 1985. Chemical structural characteristics of humic acid extracted from composted municipal refuse. Agric. Ecosystems Environ. 14, 267e278. Hjorth, T., 2004. Effects of freeze drying on partitioning patterns of major elements and trace metals in lake sesdiments. Anal. Chim. Acta. 526, 95e102. Hou, X., 2004. Application of 129I as an environmental tracer. J. Radioanal. Nucl. Chem. 262 (1), 67e75. Hou, X., Dahlgaard, H., Rietz, B., Jacobsen, U., Nielsen, S.P., Aarkrog, A., 1999. Determination of 129I in seawater and some environmental materials by neutron activation analysis. Analyst 124, 1109e1114. Hou, X.L., Fogh, C.L., Kucera, J., Andersson, K.G., Dahlgaard, H., Nielsen, S.P., 2003. Iodine -129 and caesium 137 in chernobyl contaminated soil and their chemical fractionation. Sci. Total. Environ. 308, 97e109. Hou, X.L., Hansen, V., Aldahan, A., Possnert, G., Lind, O.C., Lujaniene, G., 2009a. A review on speciation of iodine-129 in the environmental and biological samples. Anal. Chim. Acta. 632, 181e196. Hou, X., Aldahan, A., Possnert, G., Lujaniene, G., Lehto, J., Skipperud, L., Lind, O.C., Salbu, B. 2009b. Speciation analysis of radionuclides in the environmental- NKS-B SPECIATION project report 2009. NKS-205. Roskilde, Denmark. Please cite this article in press as: Hansen, V., et al., Partition of iodine ( 129 I and 127 I) isotopes in soils and marine sediments, Journal of Environmental Radioactivity (2011), doi:10.1016/j.jenvrad.2011.07.005
Hutta, M., Gora, R., 2003. Novel stepwise gradient reversed-phase liquid chromatography separations of humic substances, air particulate humic-like substances and lignins. J. Chromatogr. 1012, 67e79. Illés, E., Tombácz, E., 2006. The effect of humic acid adsorption on pH-dependent surface charging and aggregation of magnetite nanoparticles. J. Colloid Interface Sci. 295 (1), 115e123. Jirousek, L., Pritchard, E.F., 1971. On the chemical iodine of tyrosine with protein sulfenyl iodine and sulfenyl periodide derivatives: the behaviour of thiol proteineiodine system. Biochem. Biophys. Acta 243, 230e238. Kodama, S., Takahashi, Y., Okumura, K., Uruga, T., 2006. Speciation of iodine in solid environmental samples by iodine K-edge XANES: application to soils and ferromanganese oxides. Sci. Total. Environ. 363, 275e284. Lassen, P., Carlsen, L., 1994. Radioactive labeling and charcterisation of humic materials. Environ. Int. 20 (1), 127e134. Lee, C.F., 1967. Kinetics of reaction between chlorine and phenolic compounds. In: Faust, S.D., Haunter, J.V. (Eds.), Principles and Application of Water Chemistry. Wiley, New York, pp. 54e74. Liu, Y., Gunten, H.R., 1988. Migration Chemistry and Behaviour of Iodine Relevant to Geological Disposal of Radioactive Wastes, A Literature Review with a Compilation of Sorption Data. PSI-16, Paul Scherrer Institute, Switzerland. Lo’pez-Gutie’rrez, J.M., Garcı ’a-Leo’n, M., Schnabel, Ch., Suter, M., Synal, H.A., Szidat, S., Garcı’a-Tenorio, R., 2004. Relative influence of 129I sources in sediment core from the kattegat area. Sci. Total. Environ. 323, 195e210. Marchetti, A.A., Gu, F., Rob, R., Stmume, T., 1997. Determination of total iodine and sample preparation for AMS measurement of 1291in environmental matrices. Nucl. Instrum. Methods. Phys. Res. B. 123, 352e355. Muramatsu, Y., Yoshida, S., 1999. Effects of microorganisms on the fate of iodine in the soil environment. Geomicrobiol. J. 16, 85e93. Muramatsu, Y., Yoshida, S., Uchida, S., Hasebe, A., 1996. Iodine desorption from rice paddy soil. Water. Air. Soil. Pollut. 86, 359e371. Parfitt, R.L., 1978. Anion adsorption by soil and soil materials. Adv. Agron. 30, 1e50. Rådlinger, G., Heumann, K.G., 2000. Transformation of iodide in natural and wastewater systems by fixation on humic substances. Environ. Sci. Technol. 34, 3932e3936. Rapin, F., Tessier, A., Campbell, P.G.C., Carignan, R., 1986. Potential artifacts in the determination of metal partitioning in sediments by sequential extraction procedure. Environ. Sci. Technol. 20 (8). Reiller, P., Mercier-Bion, F., Gimenez, N., Barre, N., Miserque, F., 2006. Iodination of humic acid samples from different origins. Radiochim. Acta 94, 739e745. Reithmeier, H., Lazarev, V., Rühm, W., Nolte, E., 2007.129I measurements in lake water for an estimate of regional 129I depositions. Sci. Total. Environ. 376, 285e293. Schlegel, M.L., Reiller, P., Mercier e Bion, F., Barre, N., Moulin, V., 2006. Molecular environment of iodine in naturally iodinated humic substances: insight from X-ray absorption spectroscopy. Geochimica et Cosmochimica Acta 70, 5536e5551. Schmidtz, K., Aumann, D.C., 1995. A study on the association of two iodine isotopes, of natural iodine-127 and of the fission product iodine-129, with soil components using a sequential extraction procedure. J. Radioanal. Nucl. Chem. 198 (1), 229e236. Schnitzer, M., Khan, S.U., 1978. Soil Organic Matter. Elseiver, New York. Schulze, D.G., Bertsch, P.M., 1995. Synchrotron X-ray Techniques in Soil, Plant, and Environmental Research Advances in Agronomy, vol. 55. Elsevier. 1e66. Sheppard, M.I., Hawkins, J.L., 1995. Iodine and microbial interactions in an organic soil. J. Environ. Radioact. 29 (2), 91e109. V. Hansen et al. / Journal of Environmental Radioactivity xxx (2011) 1e9 9 Sheppard, I.M., Thibault, D., 1992. Chemical behavior of iodine in organic and minerals soils. Appl. Geochem. 7, 265e272. Shimamoto, Y.S., Takahashi, Y., 2008. Superiority of K-edge XANES over LIII-edge XANES in the speciation of iodine in natural soils. Anal. Sci. 24, 405e409. Shimamoto, Y.S., Takahashi, Y., Terada, Y., 2011. Formation of organic iodine supplied as iodide in a soil-water system in Chiba, Japan. Environ. Sci. Technol. 45, 2086e2092. Shirshova, L.T., 1991. Polydispersity of Soil Humic Substances. Nauka Pab., Moscow (in Russian). Simpson, M.J., Johnson, P.C.E., 2006. Identification of mobile aliphatic sorptive domains in soil humin by solid e state 13C nuclear magnetic resonance, Environmental Toxicology and Chemistry 1, pp. 52e57. Stevenson, F.J., 1994. Humic Chemistry: Genesis, Composition, Reactions, second ed.. Wiley, New York. Szidat, S., Schmidt, A., Handl, J., Jakob, D., Botsch, W., Michel, R., Synal, H.A., Schnabel, C., Suter, M., Lopez-Gutierrez, J.M., Stade, W., 2000. Iodine-129: sample preparation, quality control and analyses of pre-nuclear materials and of natural waters from Lower Saxony, Germany. Nucl. Instrum. Methods. Phys. Res. B. 172, 699e710. Tessier, A., Campbell, P.G.C., Bisson, M., 1979. Sequential extraction procedure for the speciation of particulate trace-metals. Anal. Chem. 51, 844e851. Tessier, E., Amouroux, D., Abril, G., Lemaire, E., Donard, O.F.X., 2002. Formation and volatilization of alkyl-iodides and selenides in macrotidal estuaries. Biogeochemistry 59, 183e206. Tipping, E., 1981. The adsorption of aquatic humic substances by iron oxides. Geochim. Cosmochim. Acta 45, 191e199. Tonelli, D., Seeber, R., Ciavatta, C., Gessa, C., 1997. Extraction of humic acids from a natural matrix by alkaline pyrophosphate. Evaluation of the molecular weight of fractions obtained by ultrafiltration. Fresenius J.Anal. Chem. 359, 555. Warwick, P., Zhao, R., Higgo, J.J., Smith, B., Williams, G.M., 1993. The mobility and stability of iodine-humic and iodine-fulvic complexes through sand. Sci. Total. Environ. 130-131, 459e465. Whitehead, C.D., 1974. The sorption of iodide by soil components. J. Sci. Food Agric. 25, 73e79. Wong, G.T.F., 1991. The marine geochemistry of iodine. Rev. Aquat. Sci. 4 (1), 45e73. Wong, G.T.F., Zhang, L.S., 2003. The geochemical dynamics of iodine in marginal seas: the southern East China Sea. Deep-Sea Reasearch (II) 50, 1147e1162. Yamada, H., Kiriyama, T., Onagawa, Y., Hisamori, I., Miyazaki, C., Yonebayashi, K., 1999. Speciation of iodine in soils. Soil Sci. Plant Nutr. 45 (3), 563e568. Yamaguchi, N., Nakano, M., Tanida, H., Fujiwara, H., Kihou, N., 2006. Redox reaction of iodine in pady soil investigated by field observation and the I KeEdge XANES fingerprinting method. J. Environ. Radioact. 86, 212e226. Yiou, F., Raisbeck, G.M., Zhou, Z.Q., Kilius, L.R., 1994. 129I from nuclear fuel reprocessing; potential as an oceanographic tracer. Nucl. Instrum. Methods. Phys. Res. B. 92, 436e439. Yuita, K., 1992. Dynamics of iodine, bromine and chlorine in soil. II Chemical forms of iodine in soil solutions. Soil Sci. Plant Nutr. 38, 281e287. Yuita, K., 1994. Overview and dynamics of iodine and bromine in the environment: 1. Dynamics and iodine and bromine in soil-plant system. JARQ 28, 90e99. Yuita, K., Kihou, N., Yabusaki, S., Takahashi, Y., Saitoh, T., Tsumura, A., Ichihashi, H., 2005. Behavior of iodine in a forest plot, an upland field and a paddy field in the upland areas of Tsukuba, Japan. Iodine concentration in precipitation, irrigation water, ponding water and soil water to a depth of 2.5 m. Soil Sci. Plant Nutr. 57, 1011e1021. Please cite this article in press as: Hansen, V., et al., Partition of iodine ( 129 I and 127 I) isotopes in soils and marine sediments, Journal of Environmental Radioactivity (2011), doi:10.1016/j.jenvrad.2011.07.005
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Chemical Speciation Analysis and En
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Thesis for the Degree of Doctor of
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Abstract This thesis deals with che
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environment since they reflect the
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organiske jodformer. Adsorption af
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None of this would have been possib
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Abbreviations and acronyms b+ - pos
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3.1 Analytical Development………
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Table 1 Some properties of iodine P
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In soils/sediments iodine occurs as
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Table 2 Nuclear properties of iodin
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Liquid scintillation counting (LSC)
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The bioavailability of radioactive
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data (Englund et al., 2010; Hou et
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2. Analytical procedures used in th
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2.3 Quantification of total iodine
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Fig. 5 Quantification of total iodi
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iodate were measured by counting 12
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Fig. 6 Sequential extraction proced
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a Fig. 8 Calibration curve for (a)
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experiment was subjected to combust
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Table 7 Adsorption of iodine specie
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numbers 11-14), which is about the
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marine environment from nuclear fue
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127 I - (ppb) 127 IO3 - (ppb) a b 1
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Although the oxygen concentration d
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129 I TBq 2,00E+00 1,80E+00 1,60E+0
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• Adsorption of iodine species on
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Reference Aldahan A, Kekli A, Possn
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Fuge R& Johnson C. 1986. The geoche
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Lo´pez-Gutie´rrez JM, Garcı ´a-
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Shinohara K. 2004. Measurement and
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http://www.irsn.fr/EN/news/Document
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Review Analytica Chimica Acta 632 (
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Table 1 Nuclear properties and prod
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Fig. 2. Liquid discharges of 129 I
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Fig. 5. Schematic diagram and pictu
Page 75 and 76: 129 I in iodide and iodate is then
Page 77 and 78: Fig. 8. Diagram of air sampler for
Page 79 and 80: Fig. 10. Iodine L3-edge (a) and K-e
Page 81 and 82: analysis of 129 I in water sample a
Page 83 and 84: Yi P, Aldahan A, Hansen V, Possnert
Page 85 and 86: FIGURE 1. Sampling sites (the red s
Page 87 and 88: FIGURE 3. Horizontal distribution o
Page 89 and 90: FIGURE 5. Time series data of 129 I
Page 91 and 92: Environmental Science & Technology
Page 93 and 94: prepared using KI and KIO3. No diff
Page 95 and 96: of their contribution to the Baltic
Page 97 and 98: Fig. S-1 Sampling sites (the red so
Page 99 and 100: Fig. S-3 Vertical distribution of I
Page 101 and 102: Fig. S-5 Marine discharges function
Page 103 and 104: Fig.S-7 Relationship between I-129
Page 105 and 106: Table S-1 Results of I-129 and I-12
Page 107 and 108: S17
Page 109 and 110: Paper III Hansen,V., Yi, P., Hou, X
Page 111 and 112: conversion process between iodide a
Page 113 and 114: Table 1 Analytical results of 129 I
Page 115 and 116: August April I-129 iodide ( 10 8 at
Page 117 and 118: References Aldahan A, Kekli A, Poss
Page 119 and 120: Partition of iodine ( 129 I and 127
Page 121 and 122: Norway (Table 1). CTD-casts with ox
Page 123 and 124: 5. Discussion 5.1. Separation of hu
Page 125: In the present study 40e60% of 129
Page 129 and 130: Analysis of 129 I and 127 I in arch
Page 131 and 132: et al., 2002). Due to the fact that
Page 133 and 134: espectively. The iodine was leached
Page 135 and 136: salinities in the same area. Apart
Page 137 and 138: North Sea. 129 I/ 127 I ratios in w
Page 139 and 140: Table 2 Analytical results of 129-I
Page 141 and 142: 129 I/ 127 I 1,40E-07 1,20E-07 1,00
Page 143 and 144: References Aldahan A, Englund E, Po
Page 145 and 146: O’Dowd, C.; Jimenez, J. L.; Bahre
Page 147 and 148: Iodine ( 129 I and 127 I) speciatio
Page 149 and 150: water in winter by molecular oxygen
Page 151 and 152: 0.2 M KNO3. The effluent and the wa
Page 153 and 154: maximum values is at 0.03-0.06×10
Page 155 and 156: into the English Channel from the L
Page 157 and 158: References Aldahan A, Kekli A, Poss
Page 160 and 161: Risø-PhD-81(EN)
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