Spatial Mapping of Fracture Aperture Changes With Shear Displacement Using X-ray Computerized Tomography

The shearing of fractures can be a significant source of permeability change by altering the distribution of void space within the fracture itself. Common methods to estimate the effects of shearing on properties, such as aperture, roughness, and connectivity, are incapable of providing these observations in situ. Laboratory protocols are needed that enable measurements of the spatial structure of the fracture aperture field in the medium, noninvasively. Here, we investigate changes in rough-walled Brazilian-induced tensile fracture aperture distribution with progressive shear displacement in Westerly granite and Carrara marble using a novel X-ray transparent core holder. The so-called calibration-free missing attenuation method is applied to reconstruct highly resolved (submillimeter) fracture aperture maps as a function of displacement (0 to 5.75mm) in induced fractures. We observe that shearing increases the core-averaged fracture aperture and significantly broadens the distribution of local values, mostly toward higher apertures. These effects are particularly strong in Westerly granite and may be the result of the higher initial roughness of its fracture surfaces. Also, while the correlation length of the aperture field increases in both parallel and perpendicular directions, significant anisotropy is developed in both samples with the progression of shearing. The results on Westerly granite provide a direct indication that fracture aperture remains largely unaffected until 1mm of displacement is achieved, which is important when estimating permeability enhancement due to natural and induced shear displacement in faults.