Crystal plasticity modeling of the cyclic behavior of polycrystalline aggregates under non-symmetric uniaxial loading: Global and local analyses

Farooq, Harris; Cailletaud, Georges; Forest, Samuel; Ryckelynck, David

doi:10.1016/j.ijplas.2019.10.007

Cited by 47 publications

(12 citation statements)

References 71 publications

(76 reference statements)

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“…decrease for increasing number of cycles, see Farooq et al (2020) and Cruzado et al (2020) for recent discussions of ratcheting and the Bauschinger effect, respectively.…”

Section: Considered Crystal Plasticity Modelsmentioning

confidence: 99%

“…For modeling the response to cyclic loading accurately, the Bauschinger effect, which concerns a decrease of the resistance to plastic deformation also when a change in loading directions, for instance from tension to compression, takes place, needs to be accounted for Cruzado et al (2020). Also, the ratcheting behavior, i.e., the consistent accumulation of plastic slip under stress-driven cyclic loading conditions, is necessary to consider (Farooq et al 2020). Then, simulations for lifetime predictions may be set up (McDowell and Dunne 2010;, often based on kinematic hardening models (Gillner and Münstermann 2017), also considering thermal activation (Xie et al 2004), atmospheric conditions (Arnaudov et al 2020) or crack initiation (Anahid et al 2011) and crack growth (Dunne et al 2007).…”

Section: Introductionmentioning

confidence: 99%

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Identifying material parameters in crystal plasticity by Bayesian optimization

et al. 2021

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In this work, we advocate using Bayesian techniques for inversely identifying material parameters for multiscale crystal plasticity models. Multiscale approaches for modeling polycrystalline materials may significantly reduce the effort necessary for characterizing such material models experimentally, in particular when a large number of cycles is considered, as typical for fatigue applications. Even when appropriate microstructures and microscopic material models are identified, calibrating the individual parameters of the model to some experimental data is necessary for industrial use, and the task is formidable as even a single simulation run is time consuming (although less expensive than a corresponding experiment). For solving this problem, we investigate Gaussian process based Bayesian optimization, which iteratively builds up and improves a surrogate model of the objective function, at the same time accounting for uncertainties encountered during the optimization process. We describe the approach in detail, calibrating the material parameters of a high-strength steel as an application. We demonstrate that the proposed method improves upon comparable approaches based on an evolutionary algorithm and performing derivative-free methods.

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“…decrease for increasing number of cycles, see Farooq et al (2020) and Cruzado et al (2020) for recent discussions of ratcheting and the Bauschinger effect, respectively.…”

Section: Considered Crystal Plasticity Modelsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Identifying material parameters in crystal plasticity by Bayesian optimization

et al. 2021

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“…Another possible way to select the active slip systems is to use the rate-independent formulation proposed by Forest and Rubin (2016) and intensively used by Farooq et al (2020) (later referred to as RubiX formulation). It is characterized by a smooth elastic-plastic transition with no slip indeterminacy.…”

Section: Rate-independent Crystal Plasticitymentioning

confidence: 99%

Lagrange multiplier based vs micromorphic gradient-enhanced rate-(in)dependent crystal plasticity modelling and simulation

Scherer

Phalke

Besson

et al. 2020

Computer Methods in Applied Mechanics and Engineering

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A reduced strain gradient crystal plasticity theory which involves the gradient of a single scalar field is presented. Rate-dependent and rate-independent crystal plasticity settings are considered. The theory is then reformulated following first the micromorphic approach and second a Lagrange multiplier approach. The finite element implementation of the latter is detailed. Computational efficiency of the Lagrange multiplier approach is highlighted in an example involving regularization of strain localization. The numerical performance improvement is shown to reach up to two orders of magnitude in computation time speedup. Then, size effects predicted by micromorphic and Lagrange multiplier based formulations of strain gradient plasticity are assessed. First of all numerical comparisons are performed on single crystal wires in torsion. Saturation of the size effects induced by the micromorphic approach and absence of saturation with the Lagrange multiplier approach when sample size is decreased are demonstrated. The Lagrange multiplier based formulation is finally applied to characterize size effects predicted for the ductile growth of porous unit-cells at imposed stress triaxiality. Excellent agreement with micromorphic results is obtained.

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“…To quantify the mechanical fields in a polycrystal, crystal plasticity finite element calculations on aggregates (e.g. Farooq et al (2020)) or mean field approaches based on self-consistent scheme (see for instance…”

Section: Introductionmentioning

confidence: 99%

Cyclic response of electrodeposited copper films. Experiments and elastic–viscoplastic mean-field modeling

Girard

Frydrych

Kowalczyk-Gajewska

et al. 2021

Mechanics of Materials

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The goal of the present work is to identify and model the elastic-viscoplastic behavior of electrodeposited copper films under tension-compression loadings. From the experimental point of view, as proposed in the literature, a film of copper is electrodeposited on both sides of an elastic compliant substrate. The overall specimen is next subjected to tensile loading-unloadings. As the substrate remains elastic, the elastic-plastic response of copper under cyclic loading is experimentally determined. A clear kinematic hardening behavior is captured. To model the mechanical response, a new elastic-viscoplastic self-consistent scheme for polycrystalline materials is proposed. The core of the model is the tangent additive interaction law proposed in (Molinari, 2002). The behavior of the single grain is rate dependent where kinematic hardening is accounted for in the model at the level of the slip system. The model parameters are optimized via an evolutionary algorithm by comparing the predictions to the experimental cyclic response. As a result, the overall response is predicted. In addition, the heterogeneity in plastic strain activity is estimated by the model during cyclic loading.

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Crystal plasticity modeling of the cyclic behavior of polycrystalline aggregates under non-symmetric uniaxial loading: Global and local analyses

Cited by 47 publications

References 71 publications

Identifying material parameters in crystal plasticity by Bayesian optimization

Identifying material parameters in crystal plasticity by Bayesian optimization

Lagrange multiplier based vs micromorphic gradient-enhanced rate-(in)dependent crystal plasticity modelling and simulation

Cyclic response of electrodeposited copper films. Experiments and elastic–viscoplastic mean-field modeling

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