The Effect of Effective Pressure on the Relationship Between Static and Dynamic Young’s Moduli and Poisson’s Ratio of Naparima Hill Formation Mudstones

Static elastic properties, derived from stress–strain data, and dynamic elastic properties, derived from P- and S-wave velocities, are significantly different for rocks. Most rocks are deformed nearly statically (due to tectonic forces and reservoir compaction during production of the reservoir) but...

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Bibliographic Details
Published in:Rock mechanics and rock engineering 2020-08, Vol.53 (8), p.3761-3778
Main Authors: Blake, O. O., Ramsook, R., Faulkner, D. R., Iyare, U. C.
Format: Article
Language:English
Subjects:
Axial loads
Civil Engineering
Deformation
Earth and Environmental Science
Earth Sciences
Elastic properties
Elasticity
Experiments
Geophysics/Geodesy
Lithofacies
Mechanical properties
Mudstone
Original Paper
P waves
Poisson's ratio
Pressure
Pressure effects
Properties
Reservoirs
Rock
Rocks
S waves
Saturation
Storage modulus
Strain
Strain gauges
Tectonics
Wave velocity
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Summary:Static elastic properties, derived from stress–strain data, and dynamic elastic properties, derived from P- and S-wave velocities, are significantly different for rocks. Most rocks are deformed nearly statically (due to tectonic forces and reservoir compaction during production of the reservoir) but static measurements are not as readily available as dynamic measurements. Hence, empirical relationships between the static and dynamic elastic properties are needed to convert the dynamic elastic properties to static values. In this study, the static and dynamic Young’s moduli and Poisson’s ratio were measured simultaneously for dry and fluid-saturated mudstone samples. The samples were axially loaded only within the elastic region to determine the static elasticity. The samples were from four different lithofacies within the Naparima Hill Formation, Trinidad, West Indies. Experiments were carried out at effective pressures up to 130 MPa to determine if the relationship, if any, is influenced by effective pressure. The results show that the dynamic Young’s modulus is greater than the static Young’s moduli. Saturation of the samples causes a decrease in the Young’s modulus and an increase in Poisson’s ratio. Saturation also increases the difference between the static and dynamic Young’s moduli and Poisson’s ratio. A linear relationship with high correlation ( R 2 greater than 0.9) was established between the static and dynamic Young’s moduli. The gradient of the linear relationship increases, while the intercept decreases, with increasing effective pressure and axial loading. No clear trend was observed between the static and dynamic Poisson’s ratio.
ISSN:0723-2632
1434-453X
DOI:10.1007/s00603-020-02140-0