Molecular dynamics simulations of grain interactions in shock-compressed highly textured columnar nanocrystals

Heighway, Patrick; McGonegle, David; Park, Nigel; Higginbotham, Andrew; Wark, J. S.

doi:10.1103/physrevmaterials.3.083602

Cited by 14 publications

(11 citation statements)

References 70 publications

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“…The amount of rotation is related to the discrepancy in slip between the two systems, since slip on those systems generates rotation in mutually opposing directions. During the elastic phase of the loading, there is a very small discrepancy in resolved shear stress between the two systems, resulting from two main sources: (1) elastic interactions at boundaries between neighbouring grains [32], and (2) perturbations in the initial alignments the grains from perfect [110] alignment. With Model 2, the plastic relaxation rate near the nucleation threshold is a very rapidly varying function of the resolved shear stress.…”

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confidence: 99%

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Crystal plasticity finite element simulation of lattice rotation and x-ray diffraction during laser shock-compression of Tantalum

Avraam¹,

McGonegle²,

Heighway³

et al. 2021

Preprint

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Wehrenberg et al [Nature 550 496 (2017)] used ultrafast in situ x-ray diffraction at the LCLS xray free-electron laser facility to measure large lattice rotations resulting from slip and deformation twinning in shock-compressed laser-driven [110] fibre textured tantalum polycrystal. We employ a crystal plasticity finite element method model, with slip kinetics based closely on the isotropic dislocation-based Livermore Multiscale Model [Barton et al., J. Appl. Phys. 109 (2011)], to analyse this experiment. We elucidate the link between the degree of lattice rotation and the kinetics of plasticity, demonstrating that a transition occurs at shock pressures of ∼27 GPa, between a regime of relatively slow kinetics, resulting in a balanced pattern of slip system activation and therefore relatively small net lattice rotation, and a regime of fast kinetics, due to the onset of nucleation, resulting in a lop-sided pattern of deformation-system activation and therefore large net lattice rotations. We demonstrate a good fit between this model and experimental x-ray diffraction data of lattice rotation, and show that this data is constraining of deformation kinetics.

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“…A critical resolved shear stress of 1.48 GPa for spontaneous heterogeneous dislocation nucleation in Tantalum has been suggested. The mechanical twin generation rate may also depend on initial material microstructure: MD simulation of nanopolycrystalline fibre-textured tantalum have shown a tendency for twins to nucleate from grain boundaries [32].…”

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confidence: 99%

Crystal plasticity finite element simulation of lattice rotation and x-ray diffraction during laser shock-compression of Tantalum

Avraam¹,

McGonegle²,

Heighway³

et al. 2021

Preprint

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“…To study plasticity-induced rotation in tantalum and copper under dynamic loading conditions, we perform classical molecular dynamics (MD) simulations with the open-source code lammps [29]. Atomic interactions in tantalum are modeled using the Ravelo Ta1 potential [30], which successfully reproduces the equation of state, elastic constants, Hugoniot particle velocities [31], and several other high-pressure properties [32][33][34] of tantalum in the megabar regime, and has come to be widely used in atomistic studies of tantalum under extreme loading conditions [14,16,[35][36][37][38][39][40]. For copper, we use the wellestablished Mishin potential [41], which has been used extensively in simulations of shock-loaded copper [42][43][44][45][46][47], and is thus well-characterized in the high-pressure regime of interest here.…”

Section: Methodology a Simulation Setupmentioning

confidence: 99%

“…The first of the three cases we consider is body-centered cubic (bcc) tantalum compressed along its [101] direction. Tantalum has garnered considerable interest from the dynamic compression community [14,16,30,39,40,[51][52][53][54][55][56][57] in part due to its high phase stability along the Hugoniot. Under shock, tantalum is thought to retain its ambient bcc structure until it shock-melts at pressures of around 300 GPa [14].…”

Section: A [101] Tantalummentioning

confidence: 99%

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Slip competition and rotation suppression in tantalum and copper during dynamic uniaxial compression

Heighway¹,

Wark²

2022

Preprint

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When compressed, a metallic specimen will generally experience changes to its crystallographic texture due to plasticity-induced rotation. Ultrafast x-ray diffraction techniques make it possible to measure rotation of this kind in targets dynamically compressed over nanosecond timescales to the kind of pressures ordinarily encountered in planetary interiors. The axis and the extent of the local rotation can provide hints as to the combination of plasticity mechanisms activated by the rapid uniaxial compression, thus providing valuable information about the underlying dislocation kinetics operative during extreme loading conditions. We present large-scale molecular dynamics simulations of shock-induced lattice rotation in three model crystals whose behavior has previously been characterized in dynamic-compression experiments: tantalum shocked along its [101] direction, and copper shocked along either [001] or [111]. We find that, in all three cases, the texture changes predicted by the simulations are consistent with those measured experimentally using in situ x-ray diffraction. We show that while tantalum loaded along [101] and copper loaded along [001] both show pronounced rotation due to asymmetric multiple slip, the orientation of copper shocked along [111] is predicted to be stabilized by opposing rotations arising from competing, symmetrically equivalent slip systems.

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Evolution of Shock Waves in Fe-Ni Samples with Different Structure

Korchuganov,

Kryzhevich,

Grigoriev

et al. 2024

Russ Phys J

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Molecular dynamics simulations of grain interactions in shock-compressed highly textured columnar nanocrystals

Cited by 14 publications

References 70 publications

Crystal plasticity finite element simulation of lattice rotation and x-ray diffraction during laser shock-compression of Tantalum

Crystal plasticity finite element simulation of lattice rotation and x-ray diffraction during laser shock-compression of Tantalum

Slip competition and rotation suppression in tantalum and copper during dynamic uniaxial compression

Evolution of Shock Waves in Fe-Ni Samples with Different Structure

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