Abstract
Successful utilization of petroleum resources requires proper monitoring of the subsurface, where time-lapse
seismic is a prominent source of knowledge. The R-factor model is commonly used to model the strain sensitivity
of 4D seismic data. Field cores are systematically tested with different stress-change variants. We show that the
strain sensitivity is significantly influenced by the stress path and the angle of wave propagation (offset). It is well
known that shales are inherently anisotropic in terms of both static and dynamic stiffnesses. We find evidence that
shales also obey anisotropic strain sensitivities in their velocities and show that the assumption of isotropic strain
sensitivity implies a significant misfit to laboratory data. On the other hand, a satisfying fit to offset-variant timeshifts
from laboratory data is achieved when transversely isotropic strain sensitivity is implemented. Such tests
permit a calibrated higher order description of the strain sensitivity, and may provide an accurate basis with which
to understand how suitable models and correlations may be implemented in 4D field data analysis.
seismic is a prominent source of knowledge. The R-factor model is commonly used to model the strain sensitivity
of 4D seismic data. Field cores are systematically tested with different stress-change variants. We show that the
strain sensitivity is significantly influenced by the stress path and the angle of wave propagation (offset). It is well
known that shales are inherently anisotropic in terms of both static and dynamic stiffnesses. We find evidence that
shales also obey anisotropic strain sensitivities in their velocities and show that the assumption of isotropic strain
sensitivity implies a significant misfit to laboratory data. On the other hand, a satisfying fit to offset-variant timeshifts
from laboratory data is achieved when transversely isotropic strain sensitivity is implemented. Such tests
permit a calibrated higher order description of the strain sensitivity, and may provide an accurate basis with which
to understand how suitable models and correlations may be implemented in 4D field data analysis.