Modeling and analysis of the migration of HTO and
237Np in a fractured granite core at the Äspö hard rock laboratory
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Publication Details
Output type: Journal article
Author list: Park C., Kienzler B., Vejmelka P., Jeong J.
Publisher: De Gruyter
Publication year: 2012
Volume number: 100
Issue number: 3
Start page: 197
End page: 205
Number of pages: 9
ISSN: 0033-8230
eISSN: 2193-3405
URL: http://api.elsevier.com/content/abstract/scopus_id:84859479169
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Open access status: closed
Abstract
Migration characteristics of HTO and
Np were analyzed through experiments performed with a fractured granite core in the Chemlab2 probe at the Äspö hard rock laboratory in Sweden. These experimental data covered the elution of HTO and
Np as well as information of retained actinides onto the fracture surfaces. The flow field was simulated with a two-dimensional variable aperture channel model. The mass transport process was described with a randomwalk method. Three types of basic migration processes were considered : advection, sorption and matrix diffusion. By a combination of these processes, specific effects of each process on transport were evaluated. The retardation of the neptunium were analysed quantitatively by the model. The results were compared to the experimental findings in terms of the elution curves and of distribution patterns on the fracture surface. The elution curves of HTO were used to determine the hydraulic properties in the fractured core such as the extent of a dispersion effect according to the flow rates. After termination of the migration test, the rock core was opened, and the retained radioactivities onto the fracture surfaces were measured to investigate an extend of
Np retardation and the retardation mechanism. A retardation factor was obtained by comparing the simulated results to the distribution of sorbed tracers along the flow path. The validity of sorption data from batch tests was also discussed for estimating migration of sorbing tracers. © by Oldenbourg Wissenschaftsverlag, München.
Keywords
Channel model, Fractured rock, Matrix-diffusion, Migration, Neptunium, Particle tracking method, Retardation, Sorption, Tritium
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