An assessment of phase field fracture: crack initiation and growth

Kristensen, Philip K.; Niordson, Christian Frithiof; Martínez‐Pañeda, Emilio

doi:10.1098/rsta.2021.0021

Cited by 82 publications

(40 citation statements)

References 66 publications

(69 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, in PD and PF models the criteria for the crack growth is determined as a part of the solution and no external criteria is needed. (iii) Variational phase field methods for fracture are enjoying a notable success [49,50].…”

Section: Discussionmentioning

confidence: 99%

Thermodynamic Conditions for Consolidation of Dissimilar Materials in Bimetal and Functional Graded Structures

2022

View full text Add to dashboard Cite

Functional Graded Structures and Functional Graded parts, made using dissimilar materials, are designed to provide specific properties to the final product. One of the most promising methods for manufacturing 3D Functional Graded objects is 3D laser cladding and/or direct energy deposition. However, the construction of graded and especially layered graded structures in the process of joining materials with different thermophysical properties under certain conditions is accompanied by the formation of cracks along the phase boundaries, which are a consequence of residual stresses and/or chemical segregations. The conditions for phase consolidation are macroscopic balancing of residual stresses in the region of the interface. In a broader sense, in the field of the interface, it is necessary to consider the thermodynamic equilibrium of the phases in connection with mechanical equilibrium. In this regard, the article proposed criteria for the thermodynamic affinity of phases in the area of the Functional Graded Structures interface, including the coefficients of thermal expansion and isobaric and isochoric heat capacities of the phases. Examples of cracking and the use of the obtained criteria are provided.

show abstract

Section: Discussionmentioning

confidence: 99%

Thermodynamic Conditions for Consolidation of Dissimilar Materials in Bimetal and Functional Graded Structures

2022

View full text Add to dashboard Cite

show abstract

“…The composite microstructure is resolved ahead of the crack tip as an embedded cell, while the remaining ply material is homogenised as a transversely-isotropic elastic solid, see Fig. is mainly toughness-dominated due to the initial pre-crack [48]. A cohesive surface contact between fibre and matrix is defined using a quadratic traction-separation law.…”

Section: Experimental Validation: Transverse Crackmentioning

confidence: 99%

Phase field fracture predictions of microscopic bridging behaviour of composite materials

Tan¹,

Martínez-Pañeda²

2022

Preprint

View full text Add to dashboard Cite

We investigate the role of microstructural bridging on the fracture toughness of composite materials. To achieve this, a new computational framework is presented that integrates phase field fracture and cohesive zone models to simulate fibre breakage, matrix cracking and fibre-matrix debonding. The composite microstructure is represented by an embedded cell at the vicinity of the crack tip, whilst the rest of the sample is modelled as an anisotropic elastic solid. The model is first validated against experimental data of transverse matrix cracking from single-notched three-point bending tests. Then, the model is extended to predict the influence of grain bridging, brick-and-mortar microstructure and 3D fibre bridging on crack growth resistance. The results show that these microstructures are very efficient in enhancing the fracture toughness via fibre-matrix debonding, fibre breakage and crack deflection. In particular, the 3D fibre bridging effect can increase the energy dissipated at failure by more than three orders of magnitude, relative to that of the bulk matrix; well in excess of the predictions obtained from the rule of mixtures. These results shed light on microscopic bridging mechanisms and provide a virtual tool for developing high fracture toughness composites.

show abstract

“…However, discrete methods are limited when dealing with complex crack topologies, arbitrary crack trajectories or the interaction of multiple cracks. Phase field fracture methods have emerged as a promising alternative to discrete approaches [35][36][37]. By using an auxiliary (phase field) variable to track the interface between fractured and unbroken phases, complex cracking phenomena can be captured on the original finite element mesh.…”

Section: Introductionmentioning

confidence: 99%

Micromechanics-based phase field fracture modelling of CNT composites

Quinteros¹,

García-Macías²,

Martínez-Pañeda³

2022

Preprint

View full text Add to dashboard Cite

We present a novel micromechanics-based phase field approach to model crack initiation and propagation in carbon nanotube (CNT) based composites. The constitutive mechanical and fracture properties of the nanocomposites are first estimated by a mean-field homogenisation approach. Inhomogeneous dispersion of CNTs is accounted for by means of equivalent inclusions representing agglomerated CNTs. Detailed parametric analyses are presented to assess the effect of the main micromechanical properties upon the fracture behaviour of CNT-based composites. The second step of the proposed approach incorporates the previously estimated constitutive properties into a phase field fracture model to simulate crack initiation and growth in CNTbased composites. The modelling capabilities of the framework presented is demonstrated through three paradigmatic case studies involving mode I and mixed mode fracture conditions.

show abstract

An assessment of phase field fracture: crack initiation and growth

Cited by 82 publications

References 66 publications

Thermodynamic Conditions for Consolidation of Dissimilar Materials in Bimetal and Functional Graded Structures

Thermodynamic Conditions for Consolidation of Dissimilar Materials in Bimetal and Functional Graded Structures

Phase field fracture predictions of microscopic bridging behaviour of composite materials

Micromechanics-based phase field fracture modelling of CNT composites

Contact Info

Product

Resources

About