Shock wave propagation in carbon honeycomb nanostructure and effect of cell vacancies
Due to its periodic porous structure and high mechanical strength, carbon honeycomb (CHC), a new carbon allotrope, possesses a high energy absorption capability and thus great potential for the design and fabrication of advanced impact-resistant materials. In this work, the propagation and attenuati...
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sg-ntu-dr.10356-1639922022-12-28T06:11:36Z Shock wave propagation in carbon honeycomb nanostructure and effect of cell vacancies Li, Jiaqi Bai, Lichun He, Wei Liu, Bo Fang, Qihong Zhou, Kun School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Carbon Allotropes Carbon Honeycomb Due to its periodic porous structure and high mechanical strength, carbon honeycomb (CHC), a new carbon allotrope, possesses a high energy absorption capability and thus great potential for the design and fabrication of advanced impact-resistant materials. In this work, the propagation and attenuation of shock waves in CHC are investigated for the first time via molecular dynamics simulation. The simulation results indicate that the propagation speed of shock waves in CHC is highly anisotropic and the shock wave energy decays with the propagation distance exponentially regardless of the direction. In addition, the energy decay is accelerated at elevated temperatures. When vacancies are introduced into CHC, the shock wave propagation in it is significantly impeded due to the large deformations of the vacancies in the form of shrinkage and expansion caused by the shock wave. The calculation of the critical shock wave intensity at which structure failure of CHC initiates shows that the cell axis direction of CHC can sustain a high shock wave intensity which is over two times higher than those for the other two directions. The simulation results obtained in this work are helpful for the design, fabrication, and application of CHC-based and other porous impact-resistant materials. Published version The authors would like to acknowledge the financial support from the National Natural Science Foundation of China (No.11802087) and the high-performance computing resource from the National Supercomputing Center in Changsha. 2022-12-28T06:11:36Z 2022-12-28T06:11:36Z 2022 Journal Article Li, J., Bai, L., He, W., Liu, B., Fang, Q. & Zhou, K. (2022). Shock wave propagation in carbon honeycomb nanostructure and effect of cell vacancies. Carbon Trends, 8, 100186-. https://dx.doi.org/10.1016/j.cartre.2022.100186 2667-0569 https://hdl.handle.net/10356/163992 10.1016/j.cartre.2022.100186 2-s2.0-85132899169 8 100186 en Carbon Trends © 2022 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). application/pdf |
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Engineering::Mechanical engineering Carbon Allotropes Carbon Honeycomb Li, Jiaqi Bai, Lichun He, Wei Liu, Bo Fang, Qihong Zhou, Kun Shock wave propagation in carbon honeycomb nanostructure and effect of cell vacancies |
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Due to its periodic porous structure and high mechanical strength, carbon honeycomb (CHC), a new carbon allotrope, possesses a high energy absorption capability and thus great potential for the design and fabrication of advanced impact-resistant materials. In this work, the propagation and attenuation of shock waves in CHC are investigated for the first time via molecular dynamics simulation. The simulation results indicate that the propagation speed of shock waves in CHC is highly anisotropic and the shock wave energy decays with the propagation distance exponentially regardless of the direction. In addition, the energy decay is accelerated at elevated temperatures. When vacancies are introduced into CHC, the shock wave propagation in it is significantly impeded due to the large deformations of the vacancies in the form of shrinkage and expansion caused by the shock wave. The calculation of the critical shock wave intensity at which structure failure of CHC initiates shows that the cell axis direction of CHC can sustain a high shock wave intensity which is over two times higher than those for the other two directions. The simulation results obtained in this work are helpful for the design, fabrication, and application of CHC-based and other porous impact-resistant materials. |
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School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Li, Jiaqi Bai, Lichun He, Wei Liu, Bo Fang, Qihong Zhou, Kun |
| format |
Article |
| author |
Li, Jiaqi Bai, Lichun He, Wei Liu, Bo Fang, Qihong Zhou, Kun |
| author_sort |
Li, Jiaqi |
| title |
Shock wave propagation in carbon honeycomb nanostructure and effect of cell vacancies |
| title_short |
Shock wave propagation in carbon honeycomb nanostructure and effect of cell vacancies |
| title_full |
Shock wave propagation in carbon honeycomb nanostructure and effect of cell vacancies |
| title_fullStr |
Shock wave propagation in carbon honeycomb nanostructure and effect of cell vacancies |
| title_full_unstemmed |
Shock wave propagation in carbon honeycomb nanostructure and effect of cell vacancies |
| title_sort |
shock wave propagation in carbon honeycomb nanostructure and effect of cell vacancies |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/163992 |
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1753801167957131264 |