Stress-fractional model for clay based on yielding and hardening rules considering thermomechanical restriction.

This study presents the development of an isothermal model for characterising the stress-strain behaviour of clay, in the framework of thermomechanical restrictions. Clay is assumed to be a decoupled material, where the accumulation of the Helmholtz free energy can be decoupled into two components, elastic and plastic, that result in the explicit definitions of the shift and dissipative stress tensors, respectively. An anisotropic yielding function fulfilling the first and second laws of thermodynamics is then derived from the rate of plastic dissipation, where the loading tensor and fractional plastic flow tensor are also obtained. A compression-and-shearing hardening mechanism is introduced by further evaluating the thermodynamic restrictions of the rate of Helmholtz free energy at critical state. The developed model contains seven constitutive parameters, where the identification methods are discussed. Finally, an application of the developed model to simulate the drained and undrained stress-strain responses of different clays are provided. • Anisotropic yielding function fulfilling the first and second laws of thermodynamics was derived. • Combined compression and shear hardening mechanisms were introduced considering thermomechanical restriction. • Evolution of fabric tensor was defined. • Model simulations of the stress-strain behaviour of clays were conducted. [ABSTRACT FROM AUTHOR]