Modeling Transport of Cesium in Grimsel Granodiorite With Micrometer Scale Heterogeneities and Dynamic Update of <i>K<sub>d</sub></i>

Voutilainen, Mikko; Kekäläinen, Pekka; Siitari-Kauppi, Marja; Sardini, Paul; Muuri, Eveliina; Timonen, J.; Martin, Andrew J.

doi:10.1002/2017wr020695

Cited by 25 publications

(16 citation statements)

References 85 publications

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“…biotite) affect considerably the transport of radionuclides (Voutilainen et al. , ). The main minerals of Grimsel granodiorite, which was used in this work, are quartz (∼35%), plagioclase (∼30%), potassium feldspar (∼30%) and biotite (∼5%).…”

Section: Materials and Experimental Methodsmentioning

confidence: 99%

“…Furthermore, recent studies applying C-14-PMMA autoradiography have shown that mineral grains with intragranular nanometre scale pores (e.g. biotite) affect considerably the transport of radionuclides (Voutilainen et al, 2017). The main minerals of Grimsel granodiorite, which was used in this work, are quartz (ß35%), plagioclase (ß30%), potassium feldspar (ß30%) and biotite (ß5%).…”

Section: Samplesmentioning

confidence: 97%

“…The Grimsel in situ experiment and an in situ through diffusion experiment (TDE) in Olkiluoto have used caesium as a tracer in concentrations resembling the repository conditions. Results of caesium from the LTD experiment indicate that the mineral heterogeneity of the rock is important for retention of caesium (Jokelainen et al, 2013;Voutilainen et al, 2017). This factor combined with the high X-ray attenuation coefficient of caesium, and the possibility of facile intrusion via water solution, led to the decision to choose CsCl as the potential contrast agent.…”

Section: Introductionmentioning

confidence: 99%

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Imaging connected porosity of crystalline rock by contrast agent‐aided X‐ray microtomography and scanning electron microscopy

Kuva

Sammaljärvi

Parkkonen

et al. 2017

Journal of Microscopy

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We set out to study connected porosity of crystalline rock using X-ray microtomography and scanning electron microscopy with energy dispersive X-ray spectroscopy (SEM-EDS) with caesium chloride as a contrast agent. Caesium is an important radionuclide regarding the final deposition of nuclear waste and also forms dense phases that can be readily distinguished by X-ray microtomography and SEM-EDS. Six samples from two sites, Olkiluoto (Finland) and Grimsel (Switzerland), where transport properties of crystalline rock are being studied in situ, were investigated using X-ray microtomography and SEM-EDS. The samples were imaged with X-ray microtomography, immersed in a saturated caesium chloride (CsCl) solution for 141, 249 and 365 days and imaged again with X-ray microtomography. CsCl inside the samples was successfully detected with X-ray microtomography and it had completely penetrated all six samples. SEM-EDS elemental mapping was used to study the location of caesium in the samples in detail with quantitative mineral information. Precipitated CsCl was found in the connected pore space in Olkiluoto veined gneiss and in lesser amounts in Grimsel granodiorite. Only a very small amount of precipitated CsCl was observed in the Grimsel granodiorite samples. In Olkiluoto veined gneiss caesium was found in pinitised areas of cordierite grains. In the pinitised areas caesium was found in notable excess compared to chloride, possibly due to the combination of small pore size and negatively charged surfaces. In addition, elevated concentrations of caesium were found in kaolinite and sphalerite phases. The findings concerning the location of CsCl were congruent with X-ray microtomography.

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Section: Materials and Experimental Methodsmentioning

confidence: 99%

Section: Samplesmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

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Imaging connected porosity of crystalline rock by contrast agent‐aided X‐ray microtomography and scanning electron microscopy

Kuva

Sammaljärvi

Parkkonen

et al. 2017

Journal of Microscopy

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“…Last but not least, the migration of radionuclides in an EBS and host rock has been the focus of numerous studies. Voutilainen et al (2017) simulated transport of cesium in Grimsel granodiorite with micrometer-scale heterogeneities; they concluded that the heterogeneity of the mineral structure at the micrometer scale could significantly affect the diffusion and adsorption of cesium in Grimsel granodiorite at the centimeter scale. Jin et al (2016) conducted a surface complexation modeling of U(VI) adsorption, using a Generalized Composite model on granite at ambient/elevated temperature; model results showed that the exchange reaction is not important for U(VI) adsorption on granite.…”

Section: Introductionmentioning

confidence: 99%

On the long-term migration of uranyl in bentonite barrier for high-level radioactive waste repositories: The effect of different host rocks

Cao¹,

Zheng²,

Hou³

et al. 2019

Chemical Geology

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Repositories for high level radioactive waste hosted in argillite or granite with bentonite backfill are the two disposal concepts that been extensively studied. A general perception is that granite has very low sorption capacity and therefore is disadvantageous in retarding the migration of radionuclides in comparison with argillite. However, when there is bentonite backfill, does the sorption capacity of granite really matter for the migration of radionuclides? How different host rocks would affect the migration of U(VI) through the bentonite backfill of an engineered barrier system (EBS), and which properties of the host rocks cause those differences in migration, given that migration of radionuclides is a critical measure in assessing the performance of a repository? Here we present two coupled thermal, hydrological, and chemical models for the transport of U(VI), each with an identical setup except for the type of host rock (argillite vs granite rock). Comparisons between our models show that the different host rocks exert their influence on migration of U(VI) via regulating the chemical conditions in the bentonite, which affect the concentration of U(VI) at the source and the adsorption of U(VI) in the bentonite. The key chemical conditions are pH, Ca + , and HCO 3-concentration in pore-water, which are strongly affected by soluble carbonate minerals. Our models also show the occurrence of illitization (dissolution of smectite and precipitation of illite) in the bentonite, which affects the migration of U(VI) through changing pH and the quantity of adsorbents. Although generalization of current model results for granite and argillite should be done carefully, the simulations highlight the importance of pore-water chemistry in host rock, as well as bentonite-host rock interactions, when assessing the performance of a repository. In comparison to properties such as thermal conductivity, permeability, and adsorption capacity, properties that have been studied intensively, the pore-water chemistry of host rocks deserve equal or even more attention because of its strong influence on radionuclide migration.

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“…The domain pore spaces between these mineral grains and intragranular secondary pores form water‐filled, heterogeneous networks with varying geometric factors such as tortuosity and constrictivity related to diffusion and accessible reactive surfaces related to sorption (e.g., EUR, ; NASEM, ). A number of experimental and modeling studies have been conducted to understand the effects of heterogeneous minerals and pores distributions on diffusion and sorption processes (e.g., Iraola et al, ; Sardini et al, ; Voutilainen et al, , ). On the other hand, in fractured parts of crystalline rock, RN transport occurs primarily in the fractures, where preferential, advective water flow takes place (Neretnieks, ).…”

Section: Introductionmentioning

confidence: 99%

Effects of Fine‐Scale Surface Alterations on Tracer Retention in a Fractured Crystalline Rock From the Grimsel Test Site

Tachi

Ito

Akagi

et al. 2018

Water Resources Research

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Fine‐scale alterations found on fracture surfaces and between fracture surfaces and rock matrix are key uncertainties that need to be considered when developing solute transport models for fractured crystalline rocks. This paper presents a comprehensive approach developed for coupling laboratory tests, microscopic observations, and modeling in order to understand and quantify tracer transport processes occurring in natural fracture surfaces, using a single‐fractured granodiorite sample from the Grimsel Test Site, Switzerland. Laboratory tests including through‐diffusion, batch sorption, and flow‐through tests using five tracers with different retention properties indicated that tracer retention was consistently in the sequence of HDO or HTO (deuterated or tritiated water) ≈ Se < Cs < Ni < Eu and as well as showing the existence of a diffusion‐resistance layer near the fracture surface, cation excess, and anion exclusion effects for diffusion. Microscale heterogeneities around the fracture were clarified and quantified by coupling X‐ray computed tomography and electron probe microanalysis. A three‐layer model incorporating as much data as possible including weathered vermiculite, foliated mica, and undisturbed matrix layers, and their properties such as porosity, sorption, and diffusion parameters, obtained from laboratory diffusion tests and microscopic observations, provided a much better interpretation for breakthrough curves and concentration distributions near‐fracture surface of all tracers, measured in flow‐through tests, than either a one‐ or two‐layer model. Mechanistic understanding and detailed modeling considering the effects of fine‐scale surface alteration around a natural fracture should improve confidence for the safety assessment in fractured crystalline rocks.

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Modeling Transport of Cesium in Grimsel Granodiorite With Micrometer Scale Heterogeneities and Dynamic Update of K_d

Cited by 25 publications

References 85 publications

Imaging connected porosity of crystalline rock by contrast agent‐aided X‐ray microtomography and scanning electron microscopy

Imaging connected porosity of crystalline rock by contrast agent‐aided X‐ray microtomography and scanning electron microscopy

On the long-term migration of uranyl in bentonite barrier for high-level radioactive waste repositories: The effect of different host rocks

Effects of Fine‐Scale Surface Alterations on Tracer Retention in a Fractured Crystalline Rock From the Grimsel Test Site

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Modeling Transport of Cesium in Grimsel Granodiorite With Micrometer Scale Heterogeneities and Dynamic Update of Kd

Cited by 25 publications

References 85 publications

Imaging connected porosity of crystalline rock by contrast agent‐aided X‐ray microtomography and scanning electron microscopy

Imaging connected porosity of crystalline rock by contrast agent‐aided X‐ray microtomography and scanning electron microscopy

On the long-term migration of uranyl in bentonite barrier for high-level radioactive waste repositories: The effect of different host rocks

Effects of Fine‐Scale Surface Alterations on Tracer Retention in a Fractured Crystalline Rock From the Grimsel Test Site

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Product

Resources

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Modeling Transport of Cesium in Grimsel Granodiorite With Micrometer Scale Heterogeneities and Dynamic Update of K_d