Mixed displacement-pressure-phase field framework for finite strain fracture of nearly incompressible hyperelastic materials

Fucheng Tian; Jun Zeng; Mengnan Zhang; Liangbin Li

DOI:10.1016/j.cma.2022.114933
Corpus ID: 244773017

Mixed displacement-pressure-phase field framework for finite strain fracture of nearly incompressible hyperelastic materials

@article{Tian2022MixedDF,
  title={Mixed displacement-pressure-phase field framework for finite strain fracture of nearly incompressible hyperelastic materials},
  author={Fucheng Tian and Jun Zeng and Mengnan Zhang and Liangbin Li},
  journal={ArXiv},
  year={2022},
  volume={abs/2112.00294}
}

Fucheng Tian, Jun Zeng, Liangbin Li
Published 1 December 2021
Engineering
ArXiv

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Large strained fracture of nearly incompressible hyperelastic materials: Enhanced assumed strain methods and energy decomposition

Jia Ye, L. W. Zhang, J. Reddy
Engineering
2020

A phase-field model for fractures in nearly incompressible solids

K. Mang, T. Wick, W. Wollner
Physics
Computational Mechanics
2019

Within this work, we develop a phase-field description for simulating fractures in nearly incompressible materials. It is well-known that low-order approximations generally lead to volume-locking…

A dynamic phase field model with no attenuation of wave speed for rapid fracture instability in hyperelastic materials

Fucheng Tian, Jun Zeng, Xiaoliang Tang, Tingyu Xu, Liangbin Li
Physics
2020

A review on phase-field models of brittle fracture and a new fast hybrid formulation

In this contribution we address the issue of efficient finite element treatment for phase-field modeling of brittle fracture. We start by providing an overview of the existing quasi-static and…

On the advantages of mixed formulation and higher-order elements for computational morphoelasticity

C. Kadapa, Zhanfeng Li, M. Hossain, Jiong Wang
Engineering
2021

Design of simple low order finite elements for large strain analysis of nearly incompressible solids

E. A. S. Neto, D. Peric, M. Dutko, D. Owen
Engineering
1996

A variational phase-field model For ductile fracture with coalescence dissipation

T. Hu, Brandon Talamini, Andrew J. Stershic, M. Tupek, J. Dolbow
Physics
2021

A novel phase-field model for ductile fracture is presented. The model is developed within a consistent variational framework in the context of finite-deformation kinematics. A novel coalescence…

Rupture of 3D-printed hyperelastic composites: Experiments and phase field fracture modeling

Jonathan B. Russ, V. Slesarenko, S. Rudykh, H. Waisman
Engineering
2020

On some mixed finite element methods for incompressible and nearly incompressible finite elasticity

U. Brink, E. Stein
Mathematics
1996

We compare some mixed methods based on different variational formulations, namely a displacement-pressure formulation employed by de Borst and coworkers, the three-field formulation investigated by…

Phase field simulation for fracture behavior of hyperelastic material at large deformation based on edge-based smoothed finite element method

F. Peng, Wei Huang, Zhi-qian Zhang, Tian Fu Guo, Yu.E. Ma
Physics, Engineering
2020

Mixed displacement-pressure-phase field framework for finite strain fracture of nearly incompressible hyperelastic materials

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