Phase field modeling of hydraulic fracture propagation in transversely isotropic poroelastic media

TL;DR

This paper develops a phase field model for hydraulic fracture propagation in transversely isotropic poroelastic media, incorporating anisotropic properties and coupling fluid flow with solid deformation, validated through 2D and 3D numerical examples.

Contribution

It introduces a novel phase field model that accounts for anisotropic fracture toughness and permeability in transversely isotropic media, coupled with Biot poroelasticity theory.

Findings

Successfully models hydraulic fracture in anisotropic media

Validates the approach with 2D and 3D numerical examples

Demonstrates capability to simulate complex fracture propagation

Abstract

This paper proposes a phase field model (PFM) for describing hydraulic fracture propagation in transversely isotopic media. The coupling between the fluid flow and displacement fields is established according to the classical Biot poroelasticity theory while the phase field model characterizes the fracture behavior. The proposed method uses a transversely isotropic constitutive relationship between stress and strain as well as anisotropy in fracture toughness and permeability. An additional pressure-related term and an anisotropic fracture toughness tensor are added in the energy functional, which is then used to obtain the governing equations of strong form via the variational approach. In addition, the phase field is used to construct indicator functions that transit the fluid property from the intact domain to the fully fractured one. Moreover, the proposed PFM is implemented using the finite element method where a staggered scheme is applied and the displacement and fluid pressure are monolithically solved in a staggered step. Afterwards, two examples are tested to initially verify the proposed PFM: a transversely isotropic single-edge-notched square plate subjected to tension and an isotropic porous medium subjected to internal fluid pressure. Finally, numerical examples of 2D and 3D transversely isotropic media with one or two interior notches subjected to internal fluid pressure are presented to further prove the capability of the proposed PFM in 2D and 3D problems.