Finite-temperature non-equilibrium quasi-continuum analysis of nanovoid growth in copper at low and high strain rates

Ponga, Mauricio; Ortiz, Michael; Ariza, Manuel R. Gómez

doi:10.1016/j.mechmat.2015.02.007

Cited by 34 publications

(36 citation statements)

References 42 publications

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“…In this work, we apply a novel computational method, referred to as Diffusive Molecular Dynamics (DMD), to investigate the detailed dynamics of hydride phase transformation in Pd nanoparticles, focusing on the two-way interaction between the motion of the phase boundary and the formation and evolution of misfit dislocations. DMD is a new paradigm for simulating long-term diffusive mass and heat transport while maintaining full atomic resolution [19,20,21,22,18,23,24,25,26,27,28]. The basic idea is to couple a calibrated empirical kinetic model for the evolution of lattice site occupancy with a non-equilibrium statistical thermodynamics model that supplies the requisite driving forces for kinetics.…”

Section: Accepted Manuscriptmentioning

confidence: 99%

Atomistic modeling and analysis of hydride phase transformation in palladium nanoparticles

Sun

Ariza

Ortiz

et al. 2019

Journal of the Mechanics and Physics of Solids

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Section: Accepted Manuscriptmentioning

confidence: 99%

Atomistic modeling and analysis of hydride phase transformation in palladium nanoparticles

Sun

Ariza

Ortiz

et al. 2019

Journal of the Mechanics and Physics of Solids

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“…Traiviratana et al [16] found that the emission of dislocation loops is the primary mechanism of void growth in face-centered cubic (FCC) Cu when the specimen is subject to tensile uniaxial strains; Potirniche et al [17] revealed a pronounced effect of the specimen size on dislocation formation from voids and plastic flow in FCC Ni; Chang et al [18] showed that with an increasing temperature, the yield stress decreases while the void growth rate remains invariant; Bringa et al [19] studied the effect of the loading orientation in the void behavior in Cu, and their results exhibited a complex coupling of void growth, GB debonding, and partial dislocation emission into grains in nanocrystals; Seppälä et al [20] quantified the effect of stress triaxiality on the void growth in Cu; Deng et al [15] uncovered a strong configurational effect on the coalescence of voids in Cu under a shock loading. Using the quasicontinuum method, Marian et al [21] and Ponga et al [22] studied the nanovoid deformation in FCC Al under tension and simple shear, identifying a transitional strain rate between a quasistatic and a dynamic regime. The void growth in other types of lattice, including the body-centered cubic (BCC) [23] and hexagonal closepacked (HCP) systems [5], has also been probed.…”

Section: Introductionmentioning

confidence: 99%

On the role of initial void geometry in plastic deformation of metallic thin films: A molecular dynamics study

2016

Materials Science and Engineering: A

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“…The factor of 2x is employed as PDLs are formed in the positive and negative direction of each Burgers vector. Using these values for n neglects the formation of dislocation junctions and locks [32,33], which could render some sites for PDL generation inoperable. On the other hand, only a single cylindrical growth of the void in the directions of the dislocation's Burgers vector where n = 2.…”

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confidence: 99%

Prismatic and helical dislocation loop generation from defects

2016

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Plastic deformation induced by stress concentrations near crystal defects occurs through the generation of prismatic dislocation loops (PDL). The production of PDLs leads to void growth and particle decoherence. In this work we use dislocation dynamics simulations to characterize two mechanisms for PDL formation. The first mechanism corresponds to a classical model of PDL generation from dislocation nucleation. The second mechanism considers PDL generation through cross-slip of a screw dislocation intersecting the particle. We systematically study the effect of the crystal lattice and defect type on PDL generation for both mechanisms as a function of pressure. The simulations show image stresses produced by the dislocation's interaction with the free surface of a void suppresses PDL generation. The highest PDL generation rates are found for a dislocation nucleated from a void in a body-centered cubic lattice. Our simulations also show helical coiling of screw dislocations produces a continuous emission of PDLs without the need for dislocation nucleation at pressures as low as 1.0 GPa.(DD) simulations. DD simulations are capable of accurately capturing the motion of dislocations in the vicinity of large stress gradients due to material heterogeneities [13]. Two-and threedimensional DD simulations excluding cross-slip have been used to capture the later stages of void growth through multiplication of dislocations in the crystal [14,15]. In these simulations, the number of dislocation sources in the vicinity of a void activated by its stress concentration 45 increases with the void size. This observation may indicate higher void growth rates for large voids. The reduction in active dislocation sources for small voids is likely to cause void growth to transition from multiplication of existing dislocations to dislocation nucleation for voids below 500 nm [15]. For voids on the order of 50 nm, three-dimensional DD simulations have shown that locally activated modes of dislocation motion, including dislocation cross-slip and nucleation, are 50 indispensable for PDL generation [7]. These DD simulations have also drawn attention to the importance of void image stresses for cross-slip in PDL formation at low pressures. Dislocation cross-slip at free surfaces has also been shown in three-dimensional DD simulations to be an important generator of dislocation sources available for dislocation multiplication [6,16,17].The formation of PDLs through cross-slip is largely dependent on the crystal lattice which 55 determines both the number of secondary glide planes available for cross-slip and their orientation relative to one another. Here, we consider PDL formation in face-centered cubic (fcc), body-centered cubic (bcc), and hexagonal close-packed (hcp) lattices. In atomistic simulations of hydrostatically loaded voids, the availability of cross-slip planes leads to the formation of foursided rhombus PDLs in fcc lattices [3] and hexagonal or triangular PDLs in bcc lattices [18, 4]. 140

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Finite-temperature non-equilibrium quasi-continuum analysis of nanovoid growth in copper at low and high strain rates

Cited by 34 publications

References 42 publications

Atomistic modeling and analysis of hydride phase transformation in palladium nanoparticles

Atomistic modeling and analysis of hydride phase transformation in palladium nanoparticles

On the role of initial void geometry in plastic deformation of metallic thin films: A molecular dynamics study

Prismatic and helical dislocation loop generation from defects

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