Computing the effective crack energy of heterogeneous and anisotropic microstructures via anisotropic minimal surfaces

Ernesti, Felix; Schneider, Matti

doi:10.1007/s00466-021-02082-6

Cited by 8 publications

(6 citation statements)

References 65 publications

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“…Classical fast marching algorithms are only applicable to isotropic crack resistances in the plane. To cover anisotropies in the crack resistance [46], anisotropic fast marching methods [89] may be explored.…”

Section: Discussionmentioning

confidence: 99%

“…From their work the effective crack energy is defined as the area of the crack resistance-weighted minimal surface cutting through the microstructure. Numerical approaches to computing the effective crack energy have been proposed by the authors [44][45][46] using FFT-based algorithms and periodic boundary conditions. Recently, Michel-Suquet addressed the approach based on Braides et al's [43] homogenization result using an alternative solution strategy by pointing out similarities with limit load analysis [47].…”

Section: State Of the Artmentioning

confidence: 99%

“…For the computations based on the minimum cut/maximum flow approach, we relied on an in-house FFT-based code [44][45][46]. The continuous equations were discretized with the CCMF discretization [68] and solved by a damped version of the alternating direction method of multipliers (ADMM) [71,72] with adaptive choice for the penalty parameter, see Ernesti-Schneider [45].…”

Section: Setupmentioning

confidence: 99%

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Investigations on the influence of the boundary conditions when computing the effective crack energy of random heterogeneous materials using fast marching methods

2022

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Recent stochastic homogenization results for the Francfort–Marigo model of brittle fracture under anti-plane shear indicate the existence of a representative volume element. This homogenization result includes a cell formula which relies on Dirichlet boundary conditions. For other material classes, the boundary conditions do not effect the effective properties upon the infinite volume limit but may have a strong influence on the necessary size of the computational domain. We investigate the influence of the boundary conditions on the effective crack energy evaluated on microstructure cells of finite size. For periodic boundary conditions recent computational methods based on FFT-based solvers exploiting the minimum cut/maximum flow duality are available. In this work, we provide a different approach based on fast marching algorithms which enables a liberal choice of the boundary conditions in the 2D case. We conduct representative volume element studies for two-dimensional fiber reinforced composite structures with tough inclusions, comparing Dirichlet with periodic boundary conditions.

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Section: Discussionmentioning

confidence: 99%

Section: State Of the Artmentioning

confidence: 99%

Section: Setupmentioning

confidence: 99%

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Investigations on the influence of the boundary conditions when computing the effective crack energy of random heterogeneous materials using fast marching methods

2022

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“…Even more striking, the size of the considered unit cells could be chosen to be extremely small, and still be representative [26][27][28]. Such a property is extremely desirable, in particular when it comes to nonlinear material properties of composites, and turned out to be critical when undertaking a number of scientific studies, including fatigue [29,30], fracture [31,32] and thermomechanically coupled problems [33,34].…”

Section: State Of the Artmentioning

confidence: 99%

A sequential addition and migration method for generating microstructures of short fibers with prescribed length distribution

Mehta

Schneider

2022

Comput Mech

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We describe an algorithm for generating fiber-filled volume elements for use in computational homogenization schemes. The algorithm permits to prescribe both a length distribution and a fiber-orientation tensor of second order, and composites with industrial filler fraction can be generated. Typically, for short-fiber composites, data on the fiber-length distribution and on the volume-weighted fiber-orientation tensor of second order is available. We consider a model where the fiber orientation and the fiber length distributions are independent, i.e., uncoupled. We discuss the use of closure approximations for this case and report on identifying the describing parameters of the frequently used Weibull distribution for modeling the fiber-length distribution. We discuss how to integrate these procedures in the Sequential Addition and Migration algorithm, developed for fibers of equal length, and work out algorithmic modifications accounting for possibly rather long fibers. We investigate the capabilities of the introduced methodology for industrial short-fiber composites, demonstrating the rather low dispersion of the effective elastic moduli for the generated unit cells.

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“…The topic of the effective toughness of a composite material considering the brittleness of its constituents as the only dissipative mechanism has been addressed in a number of studies over the last twenty years with an increasing interest in recent years. We will not review them in detail, referring the reader to the introductory sections in Ernesti and Schneider [17,18], limiting ourself to a reminder of the points which are essential for our purpose.…”

Section: Introductionmentioning

confidence: 99%

Merits and limits of a variational definition of the effective toughness of heterogeneous materials

Michel¹,

Suquet²

2022

Journal of the Mechanics and Physics of Solids

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Computing the effective crack energy of heterogeneous and anisotropic microstructures via anisotropic minimal surfaces

Cited by 8 publications

References 65 publications

Investigations on the influence of the boundary conditions when computing the effective crack energy of random heterogeneous materials using fast marching methods

Investigations on the influence of the boundary conditions when computing the effective crack energy of random heterogeneous materials using fast marching methods

A sequential addition and migration method for generating microstructures of short fibers with prescribed length distribution

Merits and limits of a variational definition of the effective toughness of heterogeneous materials

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