Cement/clay interactions: feedback on the increasing complexity of modeling assumptions


Cementitious materials will be widely used in French concept of radioactive waste repositories. During their degradation over time, in contact with geological pore water, they will release hyper-alkaline fluids rich in calcium and alkaline cations. This chemical gradient likely to develop at the cement/clay interfaces will induce geochemical transformations. The first simplified calculations based mainly on simple mass balance calculation led to a very pessimistic understanding of the real expansion mechanism of the alkaline plume (see examples in Gaucher & Blanc, 2006). However, geochemical and migration processes are much more complex because of the dissolution of the barrier‟s accessory phases and the precipitation of secondary minerals. To describe and to understand this complexity, coupled geochemistry and transport calculations are a useful and a mandatory tool. Furthermore, such sets of modeling when properly calibrated on experimental results are able to give insights on larger time scale unreachable with experiments. Since approximately 20 years, numerous papers have described the results of reactive transport modeling of cement/clay interactions with various numerical assumptions. For example, some authors selected a purely thermodynamic approach (Adler et al., 1999; Burnol et al., 2006; Gaucher et al., 2004; Trotignon et al., 2006) while others preferred a coupled thermodynamic/kinetic approach (De Windt et al., 2008; 2004; Fernandez et al., 2010; Marty et al., 2009; Savage et al., 2010; 2002; Soler, 2003; Soler et al., 2011; Steefel & Lichtner, 1994; 1998; Trotignon et al., 2007; Vieillard et al., 2004; Watson et al., 2009). Unfortunately, most of these studies used different and not comparable parameters as space discretization, initial and boundary conditions, thermodynamic databases, clayey and cementitious materials, etc... This study revisits the types of simulations proposed in the past to represent the effect of an alkaline perturbation with regard to the degree of complexity that was considered. The main goal of the study is to perform simulations with a consistent set of data and an increasing complexity. In doing so, the analysis of numerical results will give a clear vision of key parameters driving the expansion of alteration fronts and mineralogical transformations. In addition, the validation of some simplifying hypothesizes in previous approaches will be tackled. In the present paper, the following modeling cases are considered:  alkaline fluid (Dirichlet boundary condition) in contact with clay stone;

Cite this paper

@inproceedings{Marty2012CementclayIF, title={Cement/clay interactions: feedback on the increasing complexity of modeling assumptions}, author={Nicolas C.M. Marty and Isabelle Munier and Eric C. Gaucher and Christophe Tournassat and St{\'e}phane Gaboreau and Quang Vong and Benoit Cochepin and Francis Claret}, year={2012} }