A viscoplastic model of creep in shale

Author(s)

Haghighat, Ehsan; Rassouli, Fatemeh S; Zoback, Mark D; Juanes, Ruben

Abstract

© 2020 Society of Exploration Geophysicists. We have developed a viscoplastic model that reproduces creep behavior and inelastic deformation of rock during loading-unloading cycles. We use a Perzyna-type description of viscous deformation that derives from a maximization of dissipated energy during plastic flow, in combination with a modified Cam-clay model of plastic deformation. The plastic flow model is of the associative type, and the viscous deformation is proportional to the ratio of driving stress and a material viscosity. Our model does not rely on any explicit time parameters; therefore, it is well-suited for standard and cyclic loading of materials. We validate the model with recent triaxial experiments of time-dependent deformation in clay-rich (Haynesville Formation) and carbonate-rich (Eagle Ford Formation) shale samples, and we find that the deformation during complex, multiscale loading-unloading paths can be reproduced accurately. We elucidate the role and physical meaning of each model parameter, and we infer their value from a gradient-descent minimization of the error between simulation and experimental data. This inference points to the large, and often unrecognized, uncertainty in the preconsolidation stress, which is key to reproducing the observed hysteresis in material deformation.

Date issued

2020-04

URI

https://hdl.handle.net/1721.1/132990

Department

Massachusetts Institute of Technology. Department of Civil and Environmental Engineering
Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences

Journal

GEOPHYSICS

Publisher

Society of Exploration Geophysicists

Citation

Ehsan Haghighat, Fatemeh S. Rassouli, Mark D. Zoback, and Ruben Juanes, A viscoplastic model of creep in shale, GEOPHYSICS 2020 85:3

Version: Author's final manuscript

ISSN

0016-8033

1942-2156