A crystal plasticity model for slip in hexagonal close packed metals based on discrete dislocation simulations

Messner, Mark C.; Rhee, Min Suk; Arsenlis, A.; Barton, Nathan R.

doi:10.1088/1361-651x/aa687a

Cited by 23 publications

(12 citation statements)

References 52 publications

(92 reference statements)

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“…Another possible deformation mechanism for beryllium is the onset and migration of twins [18] of the {1012} 1011 system, a mechanism strongly dependent on the direction of loading with respect to the crystal orientation [19]. Since the twinning boundaries are strong barrier for dislocations (Hall-Petch type mechanism), the density of twins play a role is the hardening mechanisms, but with its own threshold and kinetics [20]. A model aiming at modeling plasticity and twinning should have dedicated parameters, which was not in the scope of the PTW model.…”

Section: Discussionmentioning

confidence: 99%

Flow Stress of beryllium: Attempt for a Bayesian Crossed-data Analysis from Hopkinson Bars to Rayleigh-Taylor Instabilities

et al. 2018

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In this paper, we demonstrate by a Bayesian approach the incapacity of the Preston-Tonks-Wallace (PTW) strength model to represent, with the same set of parameters, the flow stress of beryllium in both moder-ate and highly dynamic experiments, and suggest hypotheses explaining that limitation. Usual plasticity models such as Johnson-Cook (JC) and PTW are mostly adjusted onto quasi-static and dynamic uni-axial compression data acquired thanks to compression machines and split Hopkinson pressure bars. Nonetheless, they may be used beyond the range of mechanical loading in which they have been fitted. This is the case of the simulations of solid Rayleigh-Taylor instabilities (RTI) driven by high explosives. A recent work of Henry de Frahan et al. noticed the inability of various plasticity models to stand for the growth of beryllium RTI. Amongst them, the PTW model has been particularly examined through four different sets of parameters, each of them largely un-derestimates the growth of the experimental instability. Thus, this work is an attempt, regarding the plastic flow modeling of beryllium, to conciliate uni-axial compression tests (CT) and RTI by means of a crossed Bayesian analysis.

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Section: Discussionmentioning

confidence: 99%

Flow Stress of beryllium: Attempt for a Bayesian Crossed-data Analysis from Hopkinson Bars to Rayleigh-Taylor Instabilities

et al. 2018

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“…Although in elasto-viscoplasticity all non-zero shear stress levels produce some slip,

can be described as the critical resolved shear stress (CRSS) given the values considered for

(see further Table 2 ). It writes as the sum of the lattice friction stress

and a generalized dislocation strengthening relation that accounts for dislocation interactions between systems [ 35 , 36 ]. Moreover, following references [ 2 , 4 , 10 , 11 , 12 , 13 ],

is also assumed to depend on the individual grain size

in a Hall–Petch type relationship:

denotes the interaction coefficient which is related to the strength of the interaction between system

and

.…”

Section: Methodsmentioning

confidence: 99%

Combined Effects of Texture and Grain Size Distribution on the Tensile Behavior of α-Titanium

2018

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This work analyzes the role of both the grain size distribution and the crystallographic texture on the tensile behavior of commercially pure titanium. Specimens with different microstructures, especially with several mean grain sizes, were specifically prepared for that purpose. It is observed that the yield stress depends on the grain size following a Hall–Petch relationship, that the stress–strain curves have a tendency to form a plateau that becomes more and more pronounced with decreasing mean grain size and that the hardening capacity increases with the grain size. All these observations are well reproduced by an elasto-visco-plastic self-consistent model that incorporates grain size effects within a crystal plasticity framework where dislocations’ densities are the state variables. First, the critical resolved shear stresses are made dependent on the individual grain size through the addition of a Hall–Petch type term. Then, the main originality of the model comes from the fact that the multiplication of mobile dislocation densities is also made grain size dependent. The underlying assumption is that grain boundaries act mainly as barriers or sinks for dislocations. Hence, the smaller the grain size, the smaller the expansion of dislocation loops and thus the smaller the increase rate of mobile dislocation density is. As a consequence of this hypothesis, both mobile and forest dislocation densities increase with the grain size and provide an explanation for the grain size dependence of the transient low work hardening rate and hardening capacity.

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“…A clever way to parametrize the constitutive model for CP from DDD has been shown in Messner et al (2017). The CP model was developed to describe the slip resistance on a slip system taking into account interaction with all other slip systems by an interaction matrix H. The evolution of the dislocation density was described by another matrix K. Technically H and K have 1521 and 59319 free parameters, but the authors reduce these numbers by taking into account crystal and physical symmetries in the system and applying LASSO regression.…”

Section: Machine Learning In Dislocation Dynamics and Crystal Plasticitymentioning

confidence: 99%

“…So the search for a way to enable machine crafted features is in our opinion the main issue for ML approaches to DDD. In CP, the route is more straightforward and the two publications discussed above (Messner et al 2017;Pandey and Pokharel 2020) have already shone light on what can be done. Crystallographic information can be incorporated into the underlying constitutive model via LASSO or other regularization methods.…”

Section: Machine Learning In Dislocation Dynamics and Crystal Plasticitymentioning

confidence: 99%

From mechanism-based to data-driven approaches in materials science

Hiemer¹,

Zapperi

2021

Mater Theory

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A time-honored approach in theoretical materials science revolves around the search for basic mechanisms that should incorporate key feature of the phenomenon under investigation. Recent years have witnessed an explosion across areas of science of a data-driven approach fueled by recent advances in machine learning. Here we provide a brief perspective on the strengths and weaknesses of mechanism based and data-driven approaches in the context of the mechanics of materials. We discuss recent literature on dislocation dynamics, atomistic plasticity in glasses focusing on the empirical discovery of governing equations through artificial intelligence. We conclude highlighting the main open issues and suggesting possible improvements and future trajectories in the fields.

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A crystal plasticity model for slip in hexagonal close packed metals based on discrete dislocation simulations

Cited by 23 publications

References 52 publications

Flow Stress of beryllium: Attempt for a Bayesian Crossed-data Analysis from Hopkinson Bars to Rayleigh-Taylor Instabilities

Flow Stress of beryllium: Attempt for a Bayesian Crossed-data Analysis from Hopkinson Bars to Rayleigh-Taylor Instabilities

Combined Effects of Texture and Grain Size Distribution on the Tensile Behavior of α-Titanium

From mechanism-based to data-driven approaches in materials science

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