Sequential slip transfer of mixed-character dislocations across Σ3 coherent twin boundary in FCC metals: a concurrent atomistic-continuum study

Sequential slip transfer across grain boundaries (GB) has an important role in size-dependent propagation of plastic deformation in polycrystalline metals. For example, the Hall–Petch effect, which states that a smaller average grain size results in a higher yield stress, can be rationalised in terms of dislocation pile-ups against GBs. In spite of extensive studies in modelling individual phases and grains using atomistic simulations, well-accepted criteria of slip transfer across GBs are still lacking, as well as models of predicting irreversible GB structure evolution. Slip transfer is inherently multiscale since both the atomic structure of the boundary and the long-range fields of the dislocation pile-up come into play. In this work, concurrent atomistic-continuum simulations are performed to study sequential slip transfer of a series of curved dislocations from a given pile-up on Σ3 coherent twin boundary (CTB) in Cu and Al, with dominant leading screw character at the site of interaction. A Frank-Read source is employed to nucleate dislocations continuously. It is found that subject to a shear stress of 1.2 GPa, screw dislocations transfer into the twinned grain in Cu, but glide on the twin boundary plane in Al. Moreover, four dislocation/CTB interaction modes are identified in Al, which are affected by (1) applied shear stress, (2) dislocation line length, and (3) dislocation line curvature. Our results elucidate the discrepancies between atomistic simulations and experimental observations of dislocation-GB reactions and highlight the importance of directly modeling sequential dislocation slip transfer reactions using fully 3D models. Three-dimensional modelling has uncovered important mechanistic clues to strengthening polycrystalline metals through plastic deformation. A team led by David McDowell at the Georgia Institute of Technology in the US used concurrent atomistic-continuum (CAC) simulations to investigate the challenging problem of how curved dislocations pile-up and interact with special ‘twin’ grain boundaries in copper and aluminum when the metals are subjected to mechanical strain. These line defects move until they meet barriers such as grain boundaries separating crystalline regions, where they ‘pile-up’ behind the leading defect and may inhibit further defects from forming, a process known as work hardening. The multiscale CAC technique coarse grains the lattice using 3-D rhombohedra, and then applies an integral form finite element method to describe dislocation motion between elements, critical for understanding work hardening.

[1]  William Schroeder,et al.  The Visualization Toolkit: An Object-Oriented Approach to 3-D Graphics , 1997 .

[2]  Michael J. Mehl,et al.  Interatomic potentials for monoatomic metals from experimental data and ab initio calculations , 1999 .

[3]  Sidney Yip,et al.  Chapter 64 – Dislocation Core Effects on Mobility , 2004 .

[4]  David L. McDowell,et al.  Viscoplasticity of heterogeneous metallic materials , 2008 .

[5]  I. M. Robertson,et al.  Dislocation interactions with grain boundaries , 2014 .

[6]  Jian Wang Atomistic Simulations of Dislocation Pileup: Grain Boundaries Interaction , 2015 .

[7]  Ellad B. Tadmor,et al.  Modeling Materials: Continuum, Atomistic and Multiscale Techniques , 2011 .

[8]  R. Ott,et al.  Defective twin boundaries in nanotwinned metals. , 2013, Nature materials.

[9]  I. Beyerlein,et al.  Incorporating interface affected zones into crystal plasticity , 2015 .

[10]  V. Levitas,et al.  Phase transformations in nanograin materials under high pressure and plastic shear: nanoscale mechanisms. , 2014, Nanoscale.

[11]  M. Sangid,et al.  Insights on slip transmission at grain boundaries from atomistic simulations , 2014 .

[12]  Arthur F. Voter,et al.  Structural stability and lattice defects in copper: Ab initio , tight-binding, and embedded-atom calculations , 2001 .

[13]  F. Inoko,et al.  Effect of piled-up dislocations on strain induced boundary migration (SIBM) in deformed aluminum bicrystals with originally ∑3 twin boundary , 2001 .

[14]  Youping Chen,et al.  Reformulation of microscopic balance equations for multiscale materials modeling. , 2009, The Journal of chemical physics.

[15]  Huajian Gao,et al.  Repulsive force between screw dislocation and coherent twin boundary in aluminum and copper , 2007 .

[16]  David L. McDowell,et al.  A quasistatic implementation of the concurrent atomistic-continuum method for FCC crystals , 2015 .

[17]  James B. Adams,et al.  Interatomic Potentials from First-Principles Calculations: The Force-Matching Method , 1993, cond-mat/9306054.

[18]  A. Rollett,et al.  Controlling Plastic Flow across Grain Boundaries in a Continuum Model , 2011 .

[19]  Horst Hahn,et al.  The interaction mechanism of screw dislocations with coherent twin boundaries in different face-centred cubic metals , 2006 .

[20]  E. Holm,et al.  Predicting the Hall-Petch Effect in FCC Metals Using Non-Local Crystal Plasticity , 2006 .

[21]  Maurice de Koning,et al.  Modelling grain-boundary resistance in intergranular dislocation slip transmission , 2002 .

[22]  David L. McDowell,et al.  Concurrent atomistic–continuum simulations of dislocation–void interactions in fcc crystals , 2015 .

[23]  F. Nabarro,et al.  Dislocations in solids , 1979 .

[24]  K. T. Ramesh,et al.  Nanomaterials: Mechanics and Mechanisms , 2009 .

[25]  T. Shimokawa,et al.  Dislocation Multiplication from the Frank–Read Source in Atomic Models , 2014 .

[26]  Dierk Raabe,et al.  Dislocation interactions and low-angle grain boundary strengthening , 2011 .

[27]  Toshiyasu Kinari,et al.  Interaction mechanism between edge dislocations and asymmetrical tilt grain boundaries investigated via quasicontinuum simulations , 2007 .

[28]  William A. Curtin,et al.  Parallel algorithm for multiscale atomistic/continuum simulations using LAMMPS , 2015 .

[29]  Ian M. Robertson,et al.  TEM in situ deformation study of the interaction of lattice dislocations with grain boundaries in metals , 1990 .

[30]  A. Rollett,et al.  Grain boundary energies in body-centered cubic metals , 2015 .

[31]  David L. McDowell,et al.  Coarse-grained atomistic simulation of dislocations , 2011 .

[32]  W. Curtin,et al.  Analysis of spurious image forces in atomistic simulations of dislocations , 2015 .

[33]  Yong-Wei Zhang,et al.  Polycrystal deformation in a discrete dislocation dynamics framework , 2014 .

[34]  William A. Curtin,et al.  Multiscale modelling of dislocation/grain boundary interactions. II. Screw dislocations impinging on tilt boundaries in Al , 2007 .

[35]  Nancy Wilkins-Diehr,et al.  XSEDE: Accelerating Scientific Discovery , 2014, Computing in Science & Engineering.

[36]  Marc Legros,et al.  Atomic-scale simulation of screw dislocation/coherent twin boundary interaction in Al, Au, Cu and Ni , 2011 .

[37]  William E. Lorensen,et al.  The visualization toolkit (2nd ed.): an object-oriented approach to 3D graphics , 1998 .

[38]  A. Cottrell Commentary. A brief view of work hardening , 2002 .

[39]  Horst Hahn,et al.  Interactions between non-screw lattice dislocations and coherent twin boundaries in face-centered cubic metals , 2008 .

[40]  David L. Olmsted,et al.  Lattice resistance and Peierls stress in finite size atomistic dislocation simulations , 2000, cond-mat/0010503.

[41]  Jian Lu,et al.  Strengthening and toughening by interface-mediated slip transfer reaction in nanotwinned copper , 2009 .

[42]  G. Lu,et al.  Dislocation cross-slip mechanisms in aluminum , 2011 .

[43]  A. Stukowski Visualization and analysis of atomistic simulation data with OVITO–the Open Visualization Tool , 2009 .

[44]  Huseyin Sehitoglu,et al.  Energy barriers associated with slip–twin interactions , 2011 .

[45]  V. Bulatov,et al.  Automated identification and indexing of dislocations in crystal interfaces , 2012 .

[46]  S. Pennycook,et al.  Atomic-scale processes revealing dynamic twin boundary strengthening mechanisms in face-centered cubic materials , 2012 .

[47]  C. Weinberger,et al.  Atomistic simulations of dislocation pinning points in pure face-centered-cubic nanopillars , 2012 .

[48]  J. Hirth,et al.  Twinning dislocation multiplication at a coherent twin boundary , 2011 .

[49]  Ting Zhu,et al.  Interfacial plasticity governs strain rate sensitivity and ductility in nanostructured metals , 2007, Proceedings of the National Academy of Sciences.

[50]  R. Scattergood,et al.  The strengthening effect of voids , 1982 .

[51]  Jens Lothe John Price Hirth,et al.  Theory of Dislocations , 1968 .

[52]  D. McDowell A perspective on trends in multiscale plasticity , 2010 .