Litcius/Paper detail

Numerical and experimental crack-tip cohesive zone laws with physics-informed neural networks

Huy Tran, Yanfei Gao, Huck Beng Chew

2024Journal of the Mechanics and Physics of Solids19 citationsDOIOpen Access PDF

Abstract

The cohesive zone law represents the constitutive traction versus separation response along the crack-tip process zone of a material, which bridges the microscopic fracture process to the macroscopic failure behavior. Elucidating the exact functional form of the cohesive zone law is a challenging inverse problem since it can only be inferred indirectly from the far-field in experiments. Here, we construct the full functional form of the cohesive traction and separation relationship along the fracture process zone from far-field stresses and displacements using a physics-informed neural network (PINN), which is constrained to satisfy the Maxwell-Betti's reciprocal theorem with a reciprocity gap to account for the plastically deforming background material. Our numerical studies simulating crack growth under small-scale yielding, mode I loading, show that the PINN is robust in inversely extracting the cohesive traction and separation distributions across a wide range of simulated cohesive zone shapes, even for those with sharp transitions in the traction-separation relationships. Using the far-field elastic strain and residual elastic strain measurements associated with a fatigue crack for a ZK60 magnesium alloy specimen from synchrotron X-ray diffraction experiments, we reconstruct the cohesive traction-separation relationship and observe distinct regimes corresponding to transitions in the micromechanical damage mechanisms.

Topics & Concepts

Artificial neural networkMaterials sciencePhysical lawMechanicsStatistical physicsClassical mechanicsPhysicsComputer scienceArtificial intelligenceQuantum mechanicsAdhesion, Friction, and Surface InteractionsUltrasonics and Acoustic Wave PropagationModel Reduction and Neural Networks