Abstract
Spent nuclear fuel repository safety evaluation today requires both laboratory and in situ field work in order to assess the parameters affecting the sorption and diffusion of radionuclides. Recent investigations at the Grimsel test site suggest that non-conservative errors in transport properties derived from laboratory scale experiments can lead to over-conservative estimates of matrix diffusion depths. As a result, the geosphere’s capability to retain radionuclides may be underestimated. In this study the in situ diffusion and the sorption of 134Cs and 22Na into granodiorite were determined using gamma spectroscopy. Autoradiography was used to reveal the minerals into which the radionuclides were sorbed. A rock sample was obtained from the Grimsel underground in situ diffusion test site in Switzerland. In the in situ test, a solution containing several different radionuclides was circulated continuously in a packed-off injection hole for two years and three months in order to study diffusion of the radionuclides into the surrounding bedrock. The gamma measurements show that in the course of the experiment 134Cs diffused 2.5 cm and 22Na 10 cm into the rock matrix, respectively. Caesium was found to have sorbed on mafic minerals biotite and chlorite. Results of this study were used in order to calculate an in situ effective diffusion coefficient for caesium and sodium in Grimsel granodiorite.
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Jokelainen, L., Meski, T., Lindberg, A. et al. The determination of 134Cs and 22Na diffusion profiles in granodiorite using gamma spectroscopy. J Radioanal Nucl Chem 295, 2153–2161 (2013). https://doi.org/10.1007/s10967-012-2268-y
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DOI: https://doi.org/10.1007/s10967-012-2268-y