Abstract EN:

The use of nuclear energy requires safe solutions for the storage of radioactive waste. A solution proposed for high activity radioactive waste is the storage in deep low permeability geological formations such as claystones. In France, the feasability and safety of this solution is investigated in the Bure URL (Underground Research Lab) by Andra, the French agency for the management of radioactive wastes. Motivated by this challenge, we explore here the fracture properties of the Callovo-Oxfordian (COx) claystone present in Bure. Crack propagation is the main mechanism leading to material failure under traction. However, in anisotropic materials like claystone, the behavior of cracks both during their initiation and their propagation phase remains poorly understood. As a result, this work aims also at improving our understanding of the mechanisms of fracture in anisotropic materials, through the example of the COx claystone. In addition to that, the determination of the fracture properties of rocks in their in-depth conditions is a very diffcult challenge. We will show here that this diffculty can be overcome by analysing the roughness of the in-depth fractures. We will start this study by a systematic characterization of the fracture properties of the COx claystone from fracture tests performed in the laboratory. We will investigate both the crack propagation phase (through the measurement of the toughness in different directions of the material, for different water content levels) as well as the initiation phase (through the measurement of the cohesive strength in different directions too). We will then show how to measure these material parameters from a statistical analysis of the resulting fracture surfaces. In a second step, we will apply this newly developped method of material characterization to fractures produced during the excavation of the gallery and extracted in the URL at 490 m deep. This analysis will provide the fracture properties of COx claystone in in-situ conditions. Finally, the detailed characterization of the fracture properties of the COx claystone will be used in structural calculations to better understand the origin of the fractures located around the gallery. In particular, we will propose an original mechanism of tensile crack initiation under dominantly compressive loading conditions that allows us to capture the shape and size of the damaged zone observed around the gallery. On the long term, we believe that our work will help to the design of safer galleries dedicated to the storage of nuclear waste.