Abstract EN:

The first part of this thesis addresses a study of the geometry of rough fractures that have been obtained through controlled fracturing of granite and sandstone blocks. The surfaces are recorded using a specially deviced profiler, which allows mechanical and optical measurement. The recordings are well described by an isotropic self-affine model. The persistence of the correlations is significantly smaller for sandstone than it is for granite. In a second part, we study how the flow through a rough fracture is influenced by the roughness of the fracture walls, when inertial effects can be neglected. An experimental setup allows to observe a significant dependence of the of the fracture permeability on the orientation of the effective pressure gradient. A numerical model confirms these observations, and allows to interpret this " hydraulic anisotropy " in terms of flow channeling. Channeling is controlled by large scale heterogeneities in the aperture field; the importance of theseheterogeneities is greatly dependent on the matching of the two walls at large scales. . .