Neutron and X-ray Imaging of fluid flow and deformation in limestones

This PhD uses simultaneous Neutron and X-ray tomography of naturally and laboratory-deformed limestones to characterise deformation-altered flow systems. Limestones, primarily composed of calcium carbonate, are approximately 10% of sedimentary rocks. They are characterised by extremely variable textures, dependant on their original solid components’ size and, being highly reactive, also on subsequent chemical reactions with mineral-bearing pore waters, resulting in highly variable porosity and permeability and pore network characteristics. Limestone deformation produces equally diverse mechanical and petrophysical consequences. However, unlike sandstones, they are still poorly studied, particularly geomechanically in the laboratory.

This PhD explores the impact of laboratory deformation on the flow properties of a range of limestones, creating deformation bands and/or fractures along which displacements up to a few mm occur. Laboratory-produced deformation bands are known to develop a distribution of local dilation or compaction and grain re-arrangement by local sliding, breakage or intense fragmentation. Similarly, fractures can be open or closed, single or organised in sets, sharing similar or different characteristics. Deformation bands and fractures can create excellent flow conduits or good seals and thus, facilitate or degrade fluid flow.

Herein, the deformation-fluid flow relationship will be examined primarily through 4D full-field measurements. The novelty lies in the simultaneous use of Neutron and X-ray imaging capability of the D50Tomo instrument during in-situ flow experiments under triaxial compression, which will be carried out in limestones containing natural and laboratory-induced deformation focusing on the flow patterns and preferential flow paths. We are currently developing a suitable Neutron-X-ray transparent cell with Lund University.

This PhD gives the student access to the pioneering D50Tomo (https://next-grenoble.fr/) at the Institut-Laue-Langevin (ILL), Grenoble, which in 2017 will become the first simultaneous Neutron and X-ray imaging facility. The project builds on existing collaborations with Lund University and ILL and the outcomes will have high international relevance and visibility.