Some Issues on Crystal Plasticity Models Formulation: Motion Decomposition and Constitutive Law Variants

Трусов, П. В.; Shveykin, A. I.; Kondratev, Nikita S.

doi:10.3390/cryst11111392

Cited by 10 publications

(3 citation statements)

References 87 publications

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“…We use the advanced two-level model of inelastic deformation designed to take into account geometric nonlinearity [ 65 ]. A comprehensive description of the model is given [ 45 , 46 ].…”

Section: Description Of the Subgrain Orientation Evolution Using The ...mentioning

confidence: 99%

Subgrain Coalescence Simulation by Means of an Advanced Statistical Model of Inelastic Deformation

et al. 2022

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The development of technological methods for processing and manufacturing of functional (with a priori targeted properties) polycrystalline materials and products made of these materials still remains an acute problem. A multilevel modeling approach offers researchers the opportunity to describe inelastic deformation by applying internal variables that give an effective characterization of the material structure at different structural scale levels. High temperature plastic deformation is accompanied by these processes, which leads to a significant rearrangement of the meso- and microstructure of the material. The most substantial contribution to changing the properties of polycrystals is made by the evolution of grain and defect structures at the expense of dynamic recrystallization, which significantly depends on dynamic recovery. In this paper, we consider the problem of the coalescence of subgrains undergoing rotation during inelastic hot deformation. This process is called subgrain coalescence, and it is one of the dynamic recovery mechanisms responsible for changes in the fine subgrain structure. Under applied thermomechanical loads, the coalescence process promotes the formation of recrystallization nuclei and their subsequent growth, which can greatly change the grain structure of a polycrystal. The problem was solved in terms of the advanced statistical model of inelastic deformation, modified to describe the subgrain coalescence process. The model takes into account the local interactions between contacting structural elements (subgrains). These have to be considered so that the grain coalescence caused by a decrease in subboundary energies during their progressive merging can be adequately analyzed. For this purpose, a subgrain structure quite similar to the real structure was modeled using Laguerre polyhedra. Subgrain rotations were investigated using the developed model, which relies on the consideration of the excess density edge component of the same sign dislocations on incidental subgrain boundaries. The results of modeling of a copper polycrystal are presented, and the effects of temperature and strain rate on the subgrain coalescence process is demonstrated.

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“…We use the advanced two-level model of inelastic deformation designed to take into account geometric nonlinearity [ 65 ]. A comprehensive description of the model is given [ 45 , 46 ].…”

Section: Description Of the Subgrain Orientation Evolution Using The ...mentioning

confidence: 99%

Subgrain Coalescence Simulation by Means of an Advanced Statistical Model of Inelastic Deformation

et al. 2022

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“…In this paper, we use the constitutive model formulated in rate form and written in terms of the actual configuration, which yields results close to those obtained by the formulation in terms of the unloaded configuration [103][104][105][106][107][108]. In [109,110], the authors described in detail these models and, with intent to establish a relationship between them, used the formulation with an explicit separation of the rigid moving coordinate system in the multiplicative representation of the deformation gradient [84,111].…”

Section: Two-level Statistical Constitutive Model For Describing the ...mentioning

confidence: 87%

Advanced Statistical Crystal Plasticity Model: Description of Copper Grain Structure Refinement during Equal Channel Angular Pressing

Romanov

Shveykin

Трусов

2023

Metals

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The grain structure of metals changes significantly during severe plastic deformation (SPD), and grain refinement is the main process associated with SPD at low homologous temperatures. Products made of ultrafine-grained materials exhibit improved performance characteristics and are of considerable industrial interest, which generates a need for the creation of comprehensive grain refinement models. This paper considers the integration of the ETMB (Y. Estrin, L.S. Toth, A. Molinari, Y. Brechet) model, which describes the evolution of an average cell size during deformation into the two-level statistical crystal plasticity constitutive model (CM) of FCC polycrystals. The original relations of the ETMB model and some of its modifications known from the literature were analyzed to obtain an accurate, physically admissible description of the grain refinement process. The characteristics of the grain substructure determined with the framework of the advanced ETMB model were taken into account in the CM in a hardening formula. By applying the CM with the integrated ETMB model, numerical experiments were performed to simulate the changes in the grain structure of copper during equal channel angular pressing (ECAP) at room temperature. The results obtained are in good agreement with the experimental data. The ideas about further development of the proposed model are outlined.

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“…Steels and iron-based alloys [2-9]; • Non-ferrous alloys with fcc-(Ni- [10,11] and Cu-based [12][13][14]), or hcp crystal structure (Mg- [15,16] and Ti-based [17,18]). Other examples include Zirconium [19], Bi-Sn alloy [20] or polycarbonate resins [21]; • Multicomponent and high-entropy alloys [22][23][24]; • General theoretical studies on crystal plasticity [25][26][27].…”

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confidence: 99%

Crystal Plasticity (Volume II)

Polkowski

2022

Crystals

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Some Issues on Crystal Plasticity Models Formulation: Motion Decomposition and Constitutive Law Variants

Cited by 10 publications

References 87 publications

Subgrain Coalescence Simulation by Means of an Advanced Statistical Model of Inelastic Deformation

Subgrain Coalescence Simulation by Means of an Advanced Statistical Model of Inelastic Deformation

Advanced Statistical Crystal Plasticity Model: Description of Copper Grain Structure Refinement during Equal Channel Angular Pressing

Crystal Plasticity (Volume II)

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