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Year : 2025 | Volume : 03 | 02 | Page :

Nidhi Sahu,

Research Scholar, Department of Mechanical Engineering, Lingaya’s Vidyapeeth, Haryana, India

Abstract

Phase-field modeling has emerged as a powerful computational framework for predicting fracture behavior in engineering materials, offering a unified description of crack initiation, propagation, branching, and coalescence without the need for explicit crack tracking. This study presents an in-depth examination of phase-field modeling applied to both brittle and ductile fracture under complex loading conditions, including multiaxial stress states, cyclic loading, thermal gradients, and dynamic impact. The phase-field approach regularizes the sharp crack topology through an auxiliary scalar field, enabling smooth numerical representation of damage evolution while naturally capturing discontinuities in displacement. For brittle materials, the method accurately reproduces crack paths driven by tensile stresses and energy minimization, while for ductile materials the framework is extended by incorporating plastic deformation, strain-hardening behavior, and rate-dependent dissipation mechanisms. The study highlights the significance of selecting appropriate degradation functions, length-scale parameters, and constitutive laws to ensure physically meaningful predictions across different material classes. Coupled thermo-mechanical and elasto-plastic phase-field formulations are discussed to demonstrate the adaptability of the approach to real-world scenarios such as thermal shock, fatigue crack growth, and fracture in heterogeneous microstructures. Numerical simulations validate the model’s capability to capture transitions between brittle and ductile fracture modes and to predict mixed-mode crack propagation under complex boundary conditions. The findings confirm that phase-field modeling provides a versatile, robust, and computationally efficient tool for fracture mechanics, offering improved predictive accuracy for design, safety assessment, and failure analysis in structural, aerospace, automotive, and energy applications.

Keywords: Phase-field modeling; brittle fracture; ductile fracture; complex loading conditions; fracture mechanics; crack initiation and propagation; mixed-mode fracture.

How to cite this article:
Nidhi Sahu. Phase – Field Modeling of Brittle and Ductile Fracture Under Complex Loading Conditions. International Journal of Fracture Mechanics and Damage Science. 2025; 03(02):-.

How to cite this URL:
Nidhi Sahu. Phase – Field Modeling of Brittle and Ductile Fracture Under Complex Loading Conditions. International Journal of Fracture Mechanics and Damage Science. 2025; 03(02):-. Available from: https://journals.stmjournals.com/ijfmds/article=2025/view=235309

References

Zhang, F., Huang, W., Li, X., & Zhang, S. (2022). A Study on Phase-Field Models for Brittle Fracture. International Journal of Numerical Analysis and Modeling, 19(6), 1-38.
Dammaß, F., Kalina, K.A., Ambati, M., et al. (2023). Phase-field modelling and analysis of rate-dependent fracture phenomena at finite deformation. Computational Mechanics, 72, 859–883.
Huber, W., & Zaeem, M.A. (2023). A Mixed-Mode Phase-Field Model of Ductile Fracture. Journal of the Mechanics and Physics of Solids, 171, 105123.
Liu, B., Liu, , & Yang, L. (2023). Accelerating Fracture Simulation with Phase Field Methods Based on Drucker-Prager Criterion.

5. Efficient Phase-Field Modeling of Quasi-Static and Dynamic Crack Propagation under Mechanical and Thermal Loadings. (2025). Mathematics, 13(11), 1742.

Phase-field modeling of fracture via homogenization. (2025). International Journal of Fracture, 249, 46.
Variational Phase-Field Model for Ductile Fracture Depending on Hydrostatic Stresses. (2025). Meccanica, 60, 2151–2175.
Dunić, V., Gubeljak, N., Živković, M., et al. (2024). Experimental Characterization and Phase-Field Damage Modeling of Ductile Fracture in AISI 316L. Metals, 14(7), 787.
Phase-Field Models for Ductile Fatigue Fracture. (2024). Theoretical and Applied Fracture Mechanics, 136, 104842.
A Comparative Review of Peridynamics and Phase-Field Models for Engineering Fracture Mechanics. (2022). Computational Mechanics, 69, 1259–1293.
Xie, C., He, X., Liu, X., et al. (2024). Phase-Field Modeling for Anisotropic Ductile Damage of Magnesium Alloys at Finite Journal of Magnesium and Alloys, 12(7), 2967–2984.

Ahead of Print Subscription Review Article

International Journal of Fracture Mechanics and Damage Science

Volume	03
	02
Received	15/12/2025
Accepted	19/12/2025
Published	29/12/2025
Publication Time	14 Days

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