Caesium sorption by hydrated cement as a function of degradation state: Experiments and modelling

• Published in: Waste management (Elmsford) Vol. 26; no. 7; pp. 725 - 732
• Main Authors: Ochs, M., Pointeau, I., Giffaut, E.
• Format: Journal Article Conference Proceeding
• Language: English
• Published: Oxford Elsevier Ltd 01.01.2006; New York, NY Elsevier Science
• Subjects: Applied sciences; CATIONS; CESIUM; Cesium - chemistry; CONCRETES; Construction Materials; Exact sciences and technology; HCP LATTICES; Hydrogen-Ion Concentration; LEAD; MANAGEMENT OF RADIOACTIVE WASTES, AND NON-RADIOACTIVE WASTES FROM NUCLEAR FACILITIES; Models, Theoretical; Other wastes and particular components of wastes; Pollution; PORTLAND CEMENT; RADIOACTIVE WASTES; SORPTION; UPTAKE; Wastes; Water - chemistry; Sorption; Complexation; Prediction; Lead; Radioactive waste storage; Forecast model; Portland cement; Modeling
• ISSN: 0956-053X; 1879-2456
• DOI: 10.1016/j.wasman.2006.01.033

To provide reliable K d data for Cs required for the performance assessment of cement-based radioactive waste repositories, two complementary approaches were followed. First, Cs sorption was determined on a range of hydrated cement paste (HCP) and mortar samples of CEM I and CEM V for different degradation states and solution compositions, as well as on some single mineral phases. Second, a surface complexation-diffuse layer model previously developed by Pointeau et al. [Pointeau, I., Marmier, N., Fromage, F., Fedoroff, M., Giffaut, E., 2001. Cs and Pb uptake by CSH phases of hydrated cement. Material Research Society Symposium Proceedings, 663, 105–113] for Cs sorption on synthetic CSH phases was simplified to facilitate its application to whole HCP and mortars or concrete, following re-assessment of the model parameters. All measurements were compared with model predictions. The sorption data obtained on the different solid phases as a function of conditions corroborate that CSH minerals are the main sorbing phase for Cs in HCP. The data also clearly show the important influence of pH and the dissolved concentration of Na, K and Ca on K d. It is further suggested that a decrease of pH is concomitant with a decrease of the Ca/Si ratio and a corresponding increase in surface sites with high affinity for Cs and, thus, K d. Elevated concentrations of cations able to compete with Cs for these sites lead to a decrease of K d, on the other hand. The simplified model was applied to the sorption measurements performed within this study as well as to a variety of literature data, mainly K d values for a variety of fresh HCP and mortar or concrete samples based on different samples of Ordinary Portland Cement as well as blended cements. The results show that the model can be applied reasonably well to a very large variety of conditions in terms of solid and solution compositions that cover a range of K d values from 10 −4 to ca. 3.2 m 3/kg. The large scatter typically observed for Cs sorption, especially on fresh HCP samples prepared from different formulations, can be explained quantitatively by the variable concentrations of Na and K in the respective solutions, which compete with Cs for fixation sites. On the other hand, the comparatively uniform conditions in degraded HCP typically render the prediction of K d values less uncertain than in case of fresh HCP.