Improvements in the modulus and strength of multi-dimensional hybrid composites through synergistic reinforcement between 1D fiber and 0D particle fillers
Alumina toughened zirconia (ATZ), aluminum (Al) and titanium (Ti) particulate fillers were added to carbon fiber-reinforced polycarbonate composites (PC–CF) at the percolation threshold (20 vol.%) to form a hybrid composite with multi-dimensional fillers. Experiments indicate that the storage modulu...
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sg-ntu-dr.10356-1557542022-03-19T20:11:56Z Improvements in the modulus and strength of multi-dimensional hybrid composites through synergistic reinforcement between 1D fiber and 0D particle fillers Markandan, Kalaimani Kanaujia, Pawan Kumar Abhineet, Jain Palash Yap, Xiu Yun Gan, Chee Lip Lai, Chang Quan School of Materials Science and Engineering School of Mechanical and Aerospace Engineering Temasek Laboratories @ NTU Engineering::Materials Carbon Nanotubes Thermomechanical Properties Alumina toughened zirconia (ATZ), aluminum (Al) and titanium (Ti) particulate fillers were added to carbon fiber-reinforced polycarbonate composites (PC–CF) at the percolation threshold (20 vol.%) to form a hybrid composite with multi-dimensional fillers. Experiments indicate that the storage modulus and yield strength were increased by a maximum of 148% and 8%, respectively. In contrast, mechanical properties of the composite deteriorated when additional 1-dimensional (1D) chopped carbon fibers were incorporated in any amount. Using the Hashin–Shtrikman and Suquet analysis to remove the influence of filler material property, it was shown that the stiffening and strengthening occurred because 0D particles could be dispersed in the interstitial sites of the PC–CF composite more easily than 1D fibers without causing significant agglomeration. Theoretical predictions from previous studies and electrical conductivity measurements support this premise. Employment of this novel strategy produced polycarbonate hybrid composites with specific strengths exceeding that of magnesium alloys, steel and some aluminum alloy grades, as well as combinations of strength and density not found in current engineering materials. Submitted/Accepted version This work was funded with Temasek Labs Seed Grant (TLSP-19-05), which C.Q. Lai is grateful for. 2022-03-18T05:47:05Z 2022-03-18T05:47:05Z 2021 Journal Article Markandan, K., Kanaujia, P. K., Abhineet, J. P., Yap, X. Y., Gan, C. L. & Lai, C. Q. (2021). Improvements in the modulus and strength of multi-dimensional hybrid composites through synergistic reinforcement between 1D fiber and 0D particle fillers. Journal of Materials Science, 56(27), 15162-15179. https://dx.doi.org/10.1007/s10853-021-06277-3 0022-2461 https://hdl.handle.net/10356/155754 10.1007/s10853-021-06277-3 2-s2.0-85110916232 27 56 15162 15179 en TLSP-19-05 Journal of Materials Science © 2021 The Author(s). This is a post-peer-review, pre-copyedit version of an article published in Journal of Materials Science. The final authenticated version is available online at: http://dx.doi.org/10.1007/s10853-021-06277-3. application/pdf |
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Engineering::Materials Carbon Nanotubes Thermomechanical Properties Markandan, Kalaimani Kanaujia, Pawan Kumar Abhineet, Jain Palash Yap, Xiu Yun Gan, Chee Lip Lai, Chang Quan Improvements in the modulus and strength of multi-dimensional hybrid composites through synergistic reinforcement between 1D fiber and 0D particle fillers |
| description |
Alumina toughened zirconia (ATZ), aluminum (Al) and titanium (Ti) particulate fillers were added to carbon fiber-reinforced polycarbonate composites (PC–CF) at the percolation threshold (20 vol.%) to form a hybrid composite with multi-dimensional fillers. Experiments indicate that the storage modulus and yield strength were increased by a maximum of 148% and 8%, respectively. In contrast, mechanical properties of the composite deteriorated when additional 1-dimensional (1D) chopped carbon fibers were incorporated in any amount. Using the Hashin–Shtrikman and Suquet analysis to remove the influence of filler material property, it was shown that the stiffening and strengthening occurred because 0D particles could be dispersed in the interstitial sites of the PC–CF composite more easily than 1D fibers without causing significant agglomeration. Theoretical predictions from previous studies and electrical conductivity measurements support this premise. Employment of this novel strategy produced polycarbonate hybrid composites with specific strengths exceeding that of magnesium alloys, steel and some aluminum alloy grades, as well as combinations of strength and density not found in current engineering materials. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Markandan, Kalaimani Kanaujia, Pawan Kumar Abhineet, Jain Palash Yap, Xiu Yun Gan, Chee Lip Lai, Chang Quan |
| format |
Article |
| author |
Markandan, Kalaimani Kanaujia, Pawan Kumar Abhineet, Jain Palash Yap, Xiu Yun Gan, Chee Lip Lai, Chang Quan |
| author_sort |
Markandan, Kalaimani |
| title |
Improvements in the modulus and strength of multi-dimensional hybrid composites through synergistic reinforcement between 1D fiber and 0D particle fillers |
| title_short |
Improvements in the modulus and strength of multi-dimensional hybrid composites through synergistic reinforcement between 1D fiber and 0D particle fillers |
| title_full |
Improvements in the modulus and strength of multi-dimensional hybrid composites through synergistic reinforcement between 1D fiber and 0D particle fillers |
| title_fullStr |
Improvements in the modulus and strength of multi-dimensional hybrid composites through synergistic reinforcement between 1D fiber and 0D particle fillers |
| title_full_unstemmed |
Improvements in the modulus and strength of multi-dimensional hybrid composites through synergistic reinforcement between 1D fiber and 0D particle fillers |
| title_sort |
improvements in the modulus and strength of multi-dimensional hybrid composites through synergistic reinforcement between 1d fiber and 0d particle fillers |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/155754 |
| _version_ |
1728433423856435200 |