摘要
Strain localization into shear bands in metallic glasses is typically described as a mechanism that occurs at the nano-scale, leaving behind a shear defect with a thickness of 10–20 nm. Here we sample the structure of a single system-spanning shear band that has carried all plastic flow with high-angle annular dark field scanning transmission electron microscopy (HAADF-STEM) and high-energy x-ray tomography (XRT). It is found that the shear-band thickness and the density change relative to the matrix sensitively depend on position along the shear band. A wide distribution of shear-band thickness (10 nm–210 nm) and density change (−1% to −12%) is revealed. There is no obvious correlation between shear-band thickness and density change, but larger thicknesses correspond typically to higher density changes. More than 100 micron-size shear-band cavities were identified on the shear-band plane, and their three-dimensional arrangement suggests a strongly fluctuating local curvature of the shear plane. These findings urge for a more complex view of a shear band than a simple nano-scale planar defect.
原文 | English |
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頁(從 - 到) | 206-216 |
頁數 | 11 |
期刊 | Acta Materialia |
卷 | 140 |
DOIs | |
出版狀態 | Published - 2017 11月 |
All Science Journal Classification (ASJC) codes
- 電子、光磁材料
- 陶瓷和複合材料
- 聚合物和塑料
- 金屬和合金