Natural iodine in a clay formation: Implications for iodine fate in geological disposals

Claret, Francis; Lerouge, Cathérine; Laurioux, Thierry; Bizi, Mohamed; Conte, Thibauld; Ghestem, Jean Philippe; Wille, Guillaume; Satō, Tsutomu; Gaucher, Éric C.; Giffaut, Éric; Tournassat, Christophe

doi:10.1016/j.gca.2009.09.030

Cited by 58 publications

(36 citation statements)

References 55 publications

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“…Hu et al (2005) suggested that some inorganic iodine (I À or IO 3 À ) could be present by sorption to the mineral phase, which possesses positively charged surfaces. While it is possible that iodine (likely as iodate) can be trapped in the mineral pool such as carbonate (Claret et al, 2010), this is not the case for the soils of this study, since barely any inorganic carbon was detected based on the difference between the total carbon and total organic carbon of the whole soils (Electronic Annex EA-1). Other minerals (quartz, kaolinite, goethite, etc.)…”

Section: Importance Of Soil Organic Matter As a Radioiodine Sinkmentioning

confidence: 92%

“…Recently, Yamaguchi et al (2010) using iodine K-edge X-ray absorption near-edge structure (XANES) reported soil organic matter (SOM) is capable of oxidizing I À or reducing IO 3 À and subsequently binding iodine to reactive carbon sites. Even though it was apparently observed that a main reservoir for iodine can be the carbonate fraction in a Callovian-Oxfordian (COx) clay rock, one needs to consider the fact that organic matter contents in these clay materials under investigation were mostly below 1% (Claret et al, 2010). Li et al (2011) provided indirect evidence that iodide was enzymatically transported into the soil bacterial cell and incorporated into cellular components via covalent binding.…”

Section: Introductionmentioning

confidence: 99%

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Is soil natural organic matter a sink or source for mobile radioiodine (129I) at the Savannah River Site?

Zhang

et al. 2011

Geochimica et Cosmochimica Acta

103

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Section: Importance Of Soil Organic Matter As a Radioiodine Sinkmentioning

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Is soil natural organic matter a sink or source for mobile radioiodine (129I) at the Savannah River Site?

Zhang

et al. 2011

Geochimica et Cosmochimica Acta

103

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“…The mass ratios of different phases were extracted from the BRGM mineralogical database [40] considering the C2b2 lithostratigraphic level (see Fig. 2 in [41]). Illite and illite/smectite (I/S) were identified as the main clay phases of the COx claystone.…”

Section: Callovian-oxfordian Claystone Modelmentioning

confidence: 99%

Benchmarks for multicomponent reactive transport across a cement/clay interface

Marty¹,

Bildstein

Blanc³

et al. 2015

Comput Geosci

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International audienceThe use of the subsurface for CO2 storage, geothermal energy generation, and nuclear waste disposal will greatly increase the interaction between clay(stone) and concrete. The development of models describing the mineralogical transformations at this interface is complicated, because contrasting geochemical conditions (Eh, pH, solution composition, etc.) induce steep concentration gradients and a high mineral reactivity. Due to the complexity of the problem, analytical solutions are not available to verify code accuracy, rendering code intercomparisons as the most efficient method for assessing code capabilities and for building confidence in the used model. A benchmark problem was established for tackling this issue. We summarize three scenarios with increasing geochemical complexity in this paper. The processes considered in the simulations are diffusion-controlled transport in saturated media under isothermal conditions, cation exchange reactions, and both local equilibrium and kinetically controlled mineral dissolution-precipitation reactions. No update of the pore diffusion coefficient as a function of porosity changes was considered. Seven international teams participated in this benchmarking exercise. The reactive transport codes used (TOUGHREACT, PHREEQC, with two different ways of handling transport, CRUNCH, HYTEC, ORCHESTRA, MIN3P-THCm) gave very similar patterns in terms of predicted solute concentrations and mineral distributions. Some differences linked to the considered activity models were observed, but they do not bias the general system evolution. The benchmarking exercise thus demonstrates that a reactive transport modelling specification for long-term performance assessment can be consistently addressed by multiple simulators

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“…Prevailing fossils are bivalves from the upper part of the benthos, but pelagic bivalves (posidonomya), sponges, foraminifers, brachiopods, and echinoderms from the deep benthos are also present. Previous observations of carbonate bioclasts were performed in the framework of the study of iodine in carbonates (Claret et al, 2010;Lerouge et al, 2010b). The diagenetic carbonates are virtually all micritic calcite forming the cement of the rock but minor 10 lmsized euhedral calcite and dolomite grains are also dispersed in the sediment (Buschaert et al, 2004;Gaucher et al, 2004;Clauer et al, 2007).…”

Section: Petrography -Previous Workmentioning

confidence: 99%

Mineralogical and isotopic record of biotic and abiotic diagenesis of the Callovian–Oxfordian clayey formation of Bure (France)

Lerouge

Grangeon

Gaucher

et al. 2011

Geochimica et Cosmochimica Acta

Self Cite

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The Callovian-Oxfordian (COx) clayey unit is being studied in the Eastern part of the Paris Basin at depths between 400 and 500 m depth to assess of its suitability for nuclear waste disposal. The present study combines new mineralogical and isotopic data to describe the sedimentary history of the COx unit. Petrologic study provided evidence of the following diagenetic mineral sequence: (1) framboidal pyrite and micritic calcite, (2) iron-rich euhedral carbonates (ankerite, sideroplesite) and glauconite (3) limpid calcite and dolomite and celestite infilling residual porosity in bioclasts and cracks, (4) chalcedony, (5) quartz/calcite. Pyrite in bioturbations shows a wide range of d 34 S (À38& to +34.5&), providing evidence of bacterial sulphate reduction processes in changing sedimentation conditions. The most negative values (À38& to À22&), measured in the lower part of the COx unit indicate precipitation of pyrite in a marine environment with a continuous sulphate supply. The most positive pyrite d 34 S values (À14& up to +34.5&) in the upper part of the COx unit indicate pyrite precipitation in a closed system. Celestite d 34 S values reflect the last evolutionary stage of the system when bacterial activity ended; however its deposition cannot be possible without sulphate supply due to carbonate bioclast dissolution. The 87 Sr/ 86 Sr ratio of celestite (0.706872-0.707040) is consistent with deposition from Jurassic marine-derived waters. Carbon and oxygen isotopic compositions of bulk calcite and dolomite are consistent with marine carbonates. Siderite, only present in the maximum clay zone, has chemical composition and d 18 O consistent with a marine environment. Its d 13 C is however lower than those of marine carbonates, suggesting a contribution of 13 C-depleted carbon from degradation of organic matter. d 18 O values of diagenetic chalcedony range between +27& and +31&, suggesting precipitation from marine-derived pore waters. Late calcite crosscutting a vein filled with chalcedony and celestite, and late euhedral quartz in a limestone from the top of the formation have lower d 18 O values ($+19&), suggesting that they precipitated from meteoric fluids, isotopically close to present-day pore waters of the formation. Finally, the study illustrates the transition from very active, biotic diagenesis to abiotic diagenesis. This transition appears to be driven by compaction of the sediment, which inhibited movement of bacterial cells by reduction of porosity and pore sizes, rather than a lack of inorganic carbon or sulphates.

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Natural iodine in a clay formation: Implications for iodine fate in geological disposals

Cited by 58 publications

References 55 publications

Is soil natural organic matter a sink or source for mobile radioiodine (129I) at the Savannah River Site?

Is soil natural organic matter a sink or source for mobile radioiodine (129I) at the Savannah River Site?

Benchmarks for multicomponent reactive transport across a cement/clay interface

Mineralogical and isotopic record of biotic and abiotic diagenesis of the Callovian–Oxfordian clayey formation of Bure (France)

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