1. Investigating bulk mechanical properties on a micro-scale: Micro-tensile testing of ultrafine grained Ni–SiC composite to determine its fracture mechanism and strain rate sensitivity.
- Author
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Xu, Alan, Yang, Chao, Thorogood, Gordon, and Bhattacharyya, Dhriti
- Subjects
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STRAIN rate , *FOCUSED ion beams , *TRANSMISSION electron microscopy , *TENSILE tests , *FAILURE mode & effects analysis , *YIELD stress - Abstract
In this study, in-situ micro-tensile testing technique was used to investigate the mechanical properties of ultrafine grained Ni-3wt% SiC composite the size effect on the mechanical properties of the ultrafine grained Ni-3wt% SiC composite, and to further reveal the reasons for the low ductility of the bulk Ni-3wt%SiC composite. Dog-bone micro-tensile samples were manufactured using a Focused Ion Beam (FIB) milling machine to 15 μm length with a cross sectional area of 5 μm by 5 μm. The micro-tensile samples are pulled in tension at a quasi-static strain rate of 0.000087/s (LSR) and a relatively faster strain rate of 0.011/s (HSR). Analysis of experimental stress-strain plots for the LSR tests measured yield stress, ultimate tensile stress and modulus values that approach values previously reported for bulk/macro-level tensile tests. However, the elongation and fracture energy at the micro-level is approximately half that at the bulk scale. This discrepancy is attributed to the presence of unwanted carbon and silicon oxide impurities ∼1.5 μm in diameter which act as stress concentrators especially given their large size relative to the width of the tensile specimens. The composition of these impurities was validated by transmission electron microscopy, and they seem to be the most likely cause of low ductility of the Ni-3wt% SiC composite. In all, the study undertaken here was able to replicate mechanical properties observed at the macro scale as well as reproduce a strain rate effect. Furthermore, the failure mode of Ni-3wt% SiC composite was identified and analysed in detail. Image 1 • Micro-tensile Ni–SiC samples exhibited strain rate sensitivity comparable with literature values. • The yield stress and ultimate tensile stress of Ni–SiC micro-tensile samples closely match macro scale tests. • Presence of impurity particles within the matrix bring about premature failure of Ni–SiC composite. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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