Abstract
AbstractWe performed triaxial deformation experiments in Purbeck limestone (13.8% average porosity) across the brittle‐ductile transition and monitored the evolution of permeability and wave velocities as a function of strain. In the brittle regime, the rock yields in dilation. In the ductile regime, the rock first yields in compaction and then undergoes net dilation at some critical level of strain. The permeability increases after failure in the brittle regime and decreases with increasing compaction in the ductile regime. The wave velocities decrease with increasing strain, and the material becomes transversely isotropic. At axial strains of the order of 5%, the anisotropy parameters (from Thomsen, 1986) are around ε ≈ −0.2 and δ ≈ decrease with increasing axial strain beyond the yield point−0.3. Under hydrostatic conditions, the rock also yields in compaction. The hydrostatic yield point is not marked by any significant drop or increase in wave velocity during loading, but wave velocities decrease (and therefore crack density increases) significantly upon unloading. In all our tests, the permeability change is proportional to the initial porosity change until the point of net dilation is reached. The strain at that point also acts as a scaling factor for the relative drop in P and S wave velocities during deformation. All our experimental data point to a disconnection between the evolution of permeability, porosity, and wave velocities during deformation in the ductile regime: permeability is controlled by a fraction of the micropore network, while wave velocities are mostly influenced by microcracks that do not contribute significantly to either the total rock porosity or fluid flow properties.
Highlights
With the development of 4-D seismic monitoring of reservoirs and CO2 injection in carbonate formations (Angerer et al, 2002; Grochau et al, 2014), a fundamental understanding of the concomitant evolution of elastic wave velocity and petrophysical attributes of carbonate rocks at in situ conditions is necessary
Micromechanics of Inelastic Deformation Our experiments show a decrease in elastic wave velocities during deformation in both the brittle and the ductile regime
Our experimental data show that deformation in the ductile regime induces (1) the compaction of the macroporosity, followed by net dilation due to crack growth in the cement and microporous micrite, (2) an irreversible permeability reduction proportional to the amount of compaction, and (3) a decrease in wave velocity and the generation of a strong anelliptic elastic anisotropy
Summary
With the development of 4-D seismic monitoring of reservoirs and CO2 injection in carbonate formations (Angerer et al, 2002; Grochau et al, 2014), a fundamental understanding of the concomitant evolution of elastic wave velocity and petrophysical attributes of carbonate rocks at in situ conditions is necessary. Baud, Exner, et al (2017) showed the degree of cementation could be at the origin of large variability in mechanical strength and could promote or inhibit different localized failure modes during compaction of carbonates Despite their microstructural complexity, from a phenomenological point of view the macroscopic mechanical behavior of carbonate rocks is relatively well understood. From a phenomenological point of view the macroscopic mechanical behavior of carbonate rocks is relatively well understood In both micritic and allochemical limestones, Baud et al (2000) and Vajdova et al (2004) showed that yielding at elevated confining pressure occurs by shear enhanced compaction, followed at larger strains by net dilation. The combination of all our data allows us to develop a complete micromechanical understanding of the deformation processes, highlighting the crucial role of microcracks and micropores in the mechanical behavior and in the transport properties of the rock
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