Monte Carlo and molecular dynamics simulations of Al-Ni nanocrystalline alloys show amorphous grain-boundary complexions enable shear-transformation-zone plasticity while short-range-ordered complexions drive stress-heterogeneity-controlled shear localization.
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Finite-element simulations show that a broad distribution of grain-boundary viscosities broadens the EAGBS relaxation spectrum from a sharp Debye peak into a weak wide-band background.
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Amorphous vs. Short-Range-Ordered Complexions: Consequences for Grain-Boundary-Mediated Plasticity in Nanocrystalline Al-Ni Alloys
Monte Carlo and molecular dynamics simulations of Al-Ni nanocrystalline alloys show amorphous grain-boundary complexions enable shear-transformation-zone plasticity while short-range-ordered complexions drive stress-heterogeneity-controlled shear localization.
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Effects of microstructural heterogeneity on the macroscopic spectrum of elastically accommodated grain-boundary sliding
Finite-element simulations show that a broad distribution of grain-boundary viscosities broadens the EAGBS relaxation spectrum from a sharp Debye peak into a weak wide-band background.