Dynamic Phase‐Field Fracture in Viscoelastic Materials using a First‐Order Formulation

Friebertshäuser, Kai; Thomas, Marita; Tornquist, Sven; Weinberg, Kerstin; Wieners, Christian

doi:10.1002/pamm.202200249

Proc Appl Math and Mech

2023

DOI: 10.1002/pamm.202200249

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Dynamic Phase‐Field Fracture in Viscoelastic Materials using a First‐Order Formulation

Kai Friebertshäuser

Marita Thomas

Sven Tornquist

et al.

Abstract: In this contribution we present analytical results on a model for dynamic fracture in viscoelastic materials at small strains that have been obtained in full depth in [1]. In the model, the sharp crack interface is regularized with a phase‐field approximation, and for the phase‐field variable a viscous evolution with a quadratic dissipation potential is employed. A non‐smooth penalization prevents material healing. The viscoelastic momentum balance is formulated as a first order system and coupled in a nonline… Show more

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2024

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Peridynamic computations of wave propagation and reflection at material interfaces

Partmann,

Dienst,

Weinberg

2024

Arch Appl Mech

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Peridynamics describes the material in a non-local form and is very suited for the simulation of dynamic fracture. However, one significant effect regarding dynamic fracture is the correct handling of elastic deformation, like the pressure and tension waves inside a body, due to dynamic boundary conditions like an impact or impulse. Many peridynamic material formulations have been developed with differences in this regard. This study investigates the elastic wave propagation characteristics of bond-based, ordinary state-based, continuum kinematics-inspired peridynamics and a local continuum consistent correspondence formulation. Multiple parameters of a longitudinal pressure wave inside an elastic bar are studied. While all formulations demonstrate adequate wave propagation handling, all except the correspondence formulation are sensitive to incomplete horizons. The local continuum consistent formulation does not suffer from the surface effect and models the wave propagation with perfect accuracy.

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Peridynamic computations of wave propagation and reflection at material interfaces

Partmann,

Dienst,

Weinberg

2024

Arch Appl Mech

View full text Add to dashboard Cite

show abstract

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Dynamic Phase‐Field Fracture in Viscoelastic Materials using a First‐Order Formulation

Cited by 1 publication

References 18 publications

Peridynamic computations of wave propagation and reflection at material interfaces

Peridynamic computations of wave propagation and reflection at material interfaces

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