Recent Advances in Computational Fracture Mechanics

Computational fracture mechanics refers to the creation of numerical methods to approximate solids at failure. The last few years have experienced a resurgence of activity in the formulation of discrete and diffusive fracture mechanics models, particularly to place them within a sound mathematical framework, as well as to address open questions related to crack nucleation and evolution, especially in coupled materials and three dimensions.

This minisymposium represents a merge of two prior minisymposia, both focused on recent developments in fracture mechanics.  Applications of computational methodologies, such as, FEM, X-FEM, G-FEM, S-FEM, BEM and other advanced numerical techniques will be discussed in the mini-symposium. Application areas of interest span a wide range, from aerospace, automobile, naval architecture, nuclear power, mechanical/civil engineering, to other structural applications. The goal of this minisymposium is to bring together researchers working on the formulation and/or numerical analysis of methods in computational fracture mechanics, including but not limited to the following strategies:

- Strong Discontinuity Methods

- Extended and Generalized Finite Element Methods

- R-adaptive methods, such as those based on Configurational Forces 

- Meshfree methods, such as the Material Point Method and the Reproducing Kernel Particle Methods

- Phase-field and Variational Approaches to Fracture

- Discontinuous Galerkin and Polytopal Finite Element Methods

- Methods for Cohesive Fracture Models, including those based on cohesive elements

- Models for crack nucleation and evolution in materials with electric, magnetic, or chemical coupling

- Models and methods designed to effect a transition from damage to fracture

as well as researchers interested in the various physical phenomena accompanying the fracture process.