1. Interaction between phase transformations and dislocations at incipient plasticity of monocrystalline silicon under nanoindentation.
- Author
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Zhang, Junjie, Zhang, Jianguo, Wang, Zhanfeng, Hartmaier, Alexander, Yan, Yongda, and Sun, Tao
- Subjects
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PHASE transitions , *MATERIAL plasticity , *SILICON , *NANOINDENTATION , *DISLOCATIONS in crystals - Abstract
Structural phase transformation and dislocation slip are two important deformation modes of monocrystalline silicon. In the present work, we elucidate mechanisms of inhomogeneous elastic-plastic transition in spherical nanoindentation of monocrystalline silicon by means of molecular dynamics simulations. The Stillinger-Weber potential is utilized to present simultaneous phase transformations and dislocation activities in the silicon nanoindentation. And a bond angle analysis-based method is proposed to quantitatively clarify silicon phases. The influence of crystallographic orientation on the silicon nanoindentation is further addressed. Our simulation results indicate that prior to the “Pop-In” event, Si(0 1 0) undergoes inelastic deformation accompanied by the phase transformation from the Si-I to the Si-III/Si-XII, which is not occurred in Si(1 1 0) and Si(1 1 1). While the phase transformation from the Si-I to the bct-5 is the dominant mechanism of incipient plasticity for each crystallographic orientation, dislocation nucleation is also an operating deformation mode in the elastic-plastic transition of Si(0 1 0). Furthermore, interactions between phase transformations and dislocations are more pronounced in Si(0 1 0) than the other two crystallographic orientations. [ABSTRACT FROM AUTHOR]
- Published
- 2017
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