Twin boundary spacing-dependent friction in nanotwinned copper

Zhang, Jun Jie; Wei, Yujie; Sun, Tao; Hartmaier, Alexander; Yan, Yongda; Li, Xiaodong

doi:10.1103/physrevb.85.054109

Cited by 35 publications

(7 citation statements)

References 32 publications

(35 reference statements)

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“…Previous experimental investigations and atomistic simulations have demonstrated that the plastic deformation of polycrystalline NT Cu under friction is governed by several individual deformation mechanisms working in parallel, such as dislocation slip, TB migration, detwinning, deformation twinning and GB-associated mechanism [21][22][23][24]. This work further indicates that the competition between individual deformation mechanisms strongly depends on internal microstructures and loading conditions, i.e.…”

supporting

confidence: 62%

Mechanisms of anisotropic friction in nanotwinned Cu revealed by atomistic simulations

Zhang

Hartmaier

Wei

et al. 2013

Modelling Simul. Mater. Sci. Eng.

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The nature of nanocrystalline materials determines that their deformation at the grain level relies on the orientation of individual grains. In this work, we investigate the anisotropic response of nanotwinned Cu to frictional contacts during nanoscratching by means of molecular dynamics simulations. Nanotwinned Cu samples containing embedded twin boundaries parallel, inclined and perpendicular to scratching surfaces are adopted to address the effects of crystallographic orientation and inclination angle of aligned twin boundaries cutting the scratching surface. The transition in deformation mechanisms, the evolution of friction coefficients and the friction-induced microstructural changes are analyzed in detail and are related to the loading conditions and the twinned microstructures of the materials. Furthermore, the effect of twin spacing on the frictional behavior of Cu samples is studied. Our simulation results show that the crystallographic orientation strongly influences the frictional response in different ways for samples with different twin spacing, because the dominant deformation mode varies upon scratching regions of different orientations. A critical inclination angle of 26.6• gives the lowest yield strength and the highest friction coefficient, at which the plasticity is dominated by twin boundary migration and detwinning. It is demonstrated that the anisotropic frictional response of nanotwinned Cu originates from the heterogeneous localized deformation, which is strongly influenced by crystallographic orientation, twin boundary orientation and loading condition.

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supporting

confidence: 62%

Mechanisms of anisotropic friction in nanotwinned Cu revealed by atomistic simulations

Zhang

Hartmaier

Wei

et al. 2013

Modelling Simul. Mater. Sci. Eng.

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“…The transition, with decreasing sample size, from twinning to stacking faults may also be reflected by another approach based on the nucleation process of twins and stacking faults. It has been argued that twinning progresses via partial dislocations and the plane-to-plane propagation of partial dislocation slips. − It was then shown that these two steps have opposite size dependence, − namely small sample sizes increase the probability of first partial dislocations while decreasing the probability of plane-to-plane propagation of partial dislocation slips. On average, it seems that smaller sample sizes will suppress twinning in this model.…”

supporting

confidence: 71%

“…Investigations of size dependent mechanical twinning under compression have already revealed some grain-size dependence. − The grain size effect of twinning has been reported in nanocrystalline Ni and Cu , and has been attributed to the competition between the grain size-dependence of partial dislocations and the layer-by-layer promotion of partial slip near the surface. Hexagonal close-packed Ti–5%Al (atom %) crystal pillars show that the stress required for deformation twinning increases drastically for compression and samples sizes (∼1 μm), below which twins are suppressed and replaced by dislocations .…”

mentioning

confidence: 99%

Breakdown of Shape Memory Effect in Bent Cu–Al–Ni Nanopillars: When Twin Boundaries Become Stacking Faults

et al. 2015

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Bent Cu–Al–Ni nanopillars (diameters 90–750 nm) show a shape memory effect, SME, for diameters D > 300 nm. The SME and the associated twinning are located in a small deformed section of the nanopillar. Thick nanopillars (D > 300 nm) transform to austenite under heating, including the deformed region. Thin nanopillars (D < 130 nm) do not twin but generate highly disordered sequences of stacking faults in the deformed region. No SME occurs and heating converts only the undeformed regions into austenite. The defect-rich, deformed region remains in the martensite phase even after prolonged heating in the stability field of austenite. A complex mixture of twins and stacking faults was found for diameters 130 nm < D < 300 nm. The size effect of the SME in Cu–Al–Ni nanopillars consists of an approximately linear reduction of the SME between 300 and 130 nm when the SME completely vanishes for smaller diameters.

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“…3(b) that variations of SSD thickness for different grinding speeds are at grinding distance 14 nm. Measurement of SSD thickness is based on variations of the potential energy of atoms in different regions with different deformation behaviors [49], and diamond structure atoms excluded for a clearer visualization of the defect structures [50]. Fig.…”

Section: Resultsmentioning

confidence: 99%

Subsurface damage mechanism of high speed grinding process in single crystal silicon revealed by atomistic simulations

Fang

Zhang

et al. 2015

Applied Surface Science

117

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Twin boundary spacing-dependent friction in nanotwinned copper

Cited by 35 publications

References 32 publications

Mechanisms of anisotropic friction in nanotwinned Cu revealed by atomistic simulations

Mechanisms of anisotropic friction in nanotwinned Cu revealed by atomistic simulations

Breakdown of Shape Memory Effect in Bent Cu–Al–Ni Nanopillars: When Twin Boundaries Become Stacking Faults

Subsurface damage mechanism of high speed grinding process in single crystal silicon revealed by atomistic simulations

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