3D phase-field cohesive fracture

Unifying energy, driving force, and stress criteria for crack nucleation and propagation direction

verfasst von: Ye Feng, Lu Hai
Abstract: This paper presents a 3D variational phase-field cohesive fracture model that incorporates crack direction information into the energy functional. Through an analytical homogenization procedure, the crack normal is obtained in closed form based on the principle of energy minimization. We find that, within the proposed model, several widely recognized crack direction criteria—including the minimum potential energy, maximum driving force, and maximum cohesive stress—are consistent and unified. The remaining criteria are simply stress-space descriptions of the same physical state, derived from the strain-space minimum potential energy criterion through the Legendre transformation. The performance of the proposed model is demonstrated through four representative numerical examples involving tension, torsion, anti-plane shear, and mixed-mode loading. The results indicate that, as the proposed model faithfully converges to the 3D cohesive zone model with a mixed-mode cohesive law, it is capable of predicting complex 3D crack morphologies during nucleation and growth, and is general enough to describe both tensile- and shear-dominated 3D fractures.
Organisationseinheit(en): Institut für Kontinuumsmechanik
Externe Organisation(en): Northwestern Polytechnical University
National Key Laboratory of Strength and Structural Integrity
Typ: Artikel
Journal: Journal of the Mechanics and Physics of Solids
Band: 196
Anzahl der Seiten: 31
ISSN: 0022-5096
Publikationsdatum: 03.2025
Publikationsstatus: Veröffentlicht
Peer-reviewed: Ja
ASJC Scopus Sachgebiete: Physik der kondensierten Materie, Werkstoffmechanik, Maschinenbau
Elektronische Version(en): https://doi.org/10.1016/j.jmps.2025.106036 (Zugang: Offen)
: Details im Forschungsportal „Research@Leibniz University“

BibTeX

@article{c0f91c7f1765429b924455ff125b12b8,
title = "3D phase-field cohesive fracture: Unifying energy, driving force, and stress criteria for crack nucleation and propagation direction",
abstract = "This paper presents a 3D variational phase-field cohesive fracture model that incorporates crack direction information into the energy functional. Through an analytical homogenization procedure, the crack normal is obtained in closed form based on the principle of energy minimization. We find that, within the proposed model, several widely recognized crack direction criteria—including the minimum potential energy, maximum driving force, and maximum cohesive stress—are consistent and unified. The remaining criteria are simply stress-space descriptions of the same physical state, derived from the strain-space minimum potential energy criterion through the Legendre transformation. The performance of the proposed model is demonstrated through four representative numerical examples involving tension, torsion, anti-plane shear, and mixed-mode loading. The results indicate that, as the proposed model faithfully converges to the 3D cohesive zone model with a mixed-mode cohesive law, it is capable of predicting complex 3D crack morphologies during nucleation and growth, and is general enough to describe both tensile- and shear-dominated 3D fractures.",
keywords = "3D crack, Cohesive fracture, Crack direction, Maximum driving force, Mixed-mode fracture, Phase-field model, Variational principle",
author = "Ye Feng and Lu Hai",
note = "Publisher Copyright: {\textcopyright} 2025 The Authors",
year = "2025",
month = mar,
doi = "10.1016/j.jmps.2025.106036",
language = "English",
volume = "196",
journal = "Journal of the Mechanics and Physics of Solids",
issn = "0022-5096",
publisher = "Elsevier Ltd.",
}