Motivated by the successful implementation of the phase-field method (PFM) to simulate
complicated fracture patterns at moderate computational costs in solid materials, many …

The prediction of fluid-and moisture-driven crack propagation in deforming porous media
has achieved increasing interest in recent years, in particular with regard to the modeling of …

In this paper, a fully coupled numerical model is developed for the modeling of the hydraulic
fracture propagation in porous media using the extended finite element method in …

Continuum porous media theories, extended by a diffusive phase-field modeling (PFM)
approach, introduce a convenient and efficient tool to the simulation of hydraulic fracture in …

In this study, we present an efficient numerical solution for studying hydraulic fracturing
under coupled thermal–hydraulic conditions in an elastic–plastic porous medium. The …

In this paper, a numerical model is developed for the fully coupled hydro‐mechanical
analysis of deformable, progressively fracturing porous media interacting with the flow of two …

A three-phase hydro-mechanical model for hydraulic fracturing is proposed. Three phases
include: porous solid, fracturing fluid and host fluid. Discontinuity is handled using extended …

Dynamics of the widespread saturated and semi-saturated soil–rock mixtures (SRMs) are of
importance in practical engineering. In this paper, a numerical manifold model is presented …

A fully coupled three-dimensional finite-element model for hydraulic fractures in permeable
rocks is presented, and used to investigate the ranges of applicability of the classical …

We present a method for the simulation of 3-D hydraulic fracturing in fully saturated porous
media. The discrete fracture (s) is driven by the fluid pressure. A cohesive fracture model is …