Zener Pinning of Grain Boundaries and Structural Stability of Immiscible Alloys

Immiscible Cu-Ta alloys produced by mechanical alloying are currently the subject of intensive research due to their mechanical strength combined with extraordinary structural stability at high temperatures. Previous experimental and simulation studies suggested that grain boundaries (GBs) in Cu-Ta...

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Published in	JOM (1989) Vol. 68; no. 6; pp. 1596 - 1604
Main Authors	Koju, R. K., Darling, K. A., Kecskes, L. J., Mishin, Y.
Format	Journal Article
Language	English
Published	New York Springer US 01.06.2016 Springer Nature B.V
Subjects	Agreements Algorithms Alloys Atoms & subatomic particles Chemistry/Food Science Earth Sciences Energy Engineering Environment Experiments Grain boundaries Grain growth Grain size High temperature Nanocrystals Physics Shear strain Shear stress Simulation Solid solutions Studies Temperature Titanium alloys Velocity Atom Probe Tomography Nanocrystalline Alloy Monte Carlo Mechanical Alloy Translation Velocity
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Abstract	Immiscible Cu-Ta alloys produced by mechanical alloying are currently the subject of intensive research due to their mechanical strength combined with extraordinary structural stability at high temperatures. Previous experimental and simulation studies suggested that grain boundaries (GBs) in Cu-Ta alloys are stabilized by Ta nano-clusters coherent with the Cu matrix. To better understand the stabilization effect of Ta, we performed atomistic computer simulations of GB–cluster interactions in Cu-Ta alloys with various compositions and GB velocities. The study focuses on a single plane GB driven by an applied shear stress due to the shear-coupling effect. The results of the simulations are in close quantitative agreement with the Zener model of GB pinning. This agreement and the large magnitude of the unpinning stress confirm that the structural stability of these alloys is due to the drastically decreased GB mobility rather than a reduction in GB energy. For comparison, we simulated GB motion in a random solid solution. While the latter also reduces the GB mobility, the effect is not as strong as in the presence of Ta clusters. GB motion in the random solution itself induces precipitation of Ta clusters due to short-circuit diffusion of Ta in GBs, suggesting a possible mechanism of cluster formation inside the grains.
AbstractList	Stress-driven GB motion has been studied by atomistic simulations in Cu with Ta nano-clusters and in a random Cu-Ta solution. For the alloy with clusters, the simulations confirm the previously observed stability of the cluster size.13, 16,17,23 Adding more Ta in the alloys only increases the number density of Ta clusters with little or no effect on their size distribution. In contrast to previous simulations conducted on polycrystalline samples,13,23 in this paper we have focused on an individual GB. Immiscible Cu-Ta alloys produced by mechanical alloying are currently the subject of intensive research due to their mechanical strength combined with extraordinary structural stability at high temperatures. Previous experimental and simulation studies suggested that grain boundaries (GBs) in Cu-Ta alloys are stabilized by Ta nano-clusters coherent with the Cu matrix. To better understand the stabilization effect of Ta, we performed atomistic computer simulations of GB–cluster interactions in Cu-Ta alloys with various compositions and GB velocities. The study focuses on a single plane GB driven by an applied shear stress due to the shear-coupling effect. The results of the simulations are in close quantitative agreement with the Zener model of GB pinning. This agreement and the large magnitude of the unpinning stress confirm that the structural stability of these alloys is due to the drastically decreased GB mobility rather than a reduction in GB energy. For comparison, we simulated GB motion in a random solid solution. While the latter also reduces the GB mobility, the effect is not as strong as in the presence of Ta clusters. GB motion in the random solution itself induces precipitation of Ta clusters due to short-circuit diffusion of Ta in GBs, suggesting a possible mechanism of cluster formation inside the grains.
Author	Mishin, Y. Darling, K. A. Koju, R. K. Kecskes, L. J.
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Snippet	Immiscible Cu-Ta alloys produced by mechanical alloying are currently the subject of intensive research due to their mechanical strength combined with... Stress-driven GB motion has been studied by atomistic simulations in Cu with Ta nano-clusters and in a random Cu-Ta solution. For the alloy with clusters, the...
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SubjectTerms	Agreements Algorithms Alloys Atoms & subatomic particles Chemistry/Food Science Earth Sciences Energy Engineering Environment Experiments Grain boundaries Grain growth Grain size High temperature Nanocrystals Physics Shear strain Shear stress Simulation Solid solutions Studies Temperature Titanium alloys Velocity
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Title	Zener Pinning of Grain Boundaries and Structural Stability of Immiscible Alloys
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