Fracture toughness of the stomatopod dactyl club is enhanced by plastic dissipation: a fracture micromechanics study
The dactyl club of stomatopods is a biological hammer used to strike on hard-shell preys. To serve its function, the club must be imparted with a high tolerance against both contact stresses and fracture. While the contact mechanics of the club has been established, fracture toughness characterizati...
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sg-ntu-dr.10356-1602142022-07-15T07:14:43Z Fracture toughness of the stomatopod dactyl club is enhanced by plastic dissipation: a fracture micromechanics study Chua, Isaiah Jia Qing Srinivasan, Dharun Vadugappatty Idapalapati, Sridhar Miserez, Ali School of Materials Science and Engineering School of Mechanical and Aerospace Engineering School of Biological Sciences Center for Sustainable Materials Engineering::Materials Stomatopod Dactyl Club The dactyl club of stomatopods is a biological hammer used to strike on hard-shell preys. To serve its function, the club must be imparted with a high tolerance against both contact stresses and fracture. While the contact mechanics of the club has been established, fracture toughness characterization has so far remained more elusive and semi-quantitative using nanoindentation fracture methods. Here, we used microcantilever fracture specimens with a chevron-notched crack geometry to quantitatively evaluate the fracture response of the impact region of dactyl clubs. The chevron-notched geometry was selected as it minimizes surface-related artefacts due to ion milling, and further allows to carry out fracture tests on samples free of pre-cracks with stable crack propagation even for brittle materials. Both linear elastic as well as elastic-plastic fracture mechanics methods, together with finite element modelling, were employed to analyse the fracture data. We find that crack-tip plastic dissipation is the main mechanism contributing to the fracture properties of the dactyl club material. Our study also suggests that the chevron-notched crack geometry is a suitable method to quantitatively assess the fracture toughness of hard biological materials. Nanyang Technological University This work was funded by the strategic initiative on Biomimetic and Sustainable Materials (IBSM) at NTU and by a Nanyang Presidential Graduate Scholarship (NPGS) awarded to J.Q.I.C. 2022-07-15T07:14:43Z 2022-07-15T07:14:43Z 2021 Journal Article Chua, I. J. Q., Srinivasan, D. V., Idapalapati, S. & Miserez, A. (2021). Fracture toughness of the stomatopod dactyl club is enhanced by plastic dissipation: a fracture micromechanics study. Acta Biomaterialia, 126, 339-349. https://dx.doi.org/10.1016/j.actbio.2021.03.025 1742-7061 https://hdl.handle.net/10356/160214 10.1016/j.actbio.2021.03.025 33727196 2-s2.0-85104976339 126 339 349 en Acta Biomaterialia © 2021 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved. |
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Engineering::Materials Stomatopod Dactyl Club Chua, Isaiah Jia Qing Srinivasan, Dharun Vadugappatty Idapalapati, Sridhar Miserez, Ali Fracture toughness of the stomatopod dactyl club is enhanced by plastic dissipation: a fracture micromechanics study |
| description |
The dactyl club of stomatopods is a biological hammer used to strike on hard-shell preys. To serve its function, the club must be imparted with a high tolerance against both contact stresses and fracture. While the contact mechanics of the club has been established, fracture toughness characterization has so far remained more elusive and semi-quantitative using nanoindentation fracture methods. Here, we used microcantilever fracture specimens with a chevron-notched crack geometry to quantitatively evaluate the fracture response of the impact region of dactyl clubs. The chevron-notched geometry was selected as it minimizes surface-related artefacts due to ion milling, and further allows to carry out fracture tests on samples free of pre-cracks with stable crack propagation even for brittle materials. Both linear elastic as well as elastic-plastic fracture mechanics methods, together with finite element modelling, were employed to analyse the fracture data. We find that crack-tip plastic dissipation is the main mechanism contributing to the fracture properties of the dactyl club material. Our study also suggests that the chevron-notched crack geometry is a suitable method to quantitatively assess the fracture toughness of hard biological materials. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Chua, Isaiah Jia Qing Srinivasan, Dharun Vadugappatty Idapalapati, Sridhar Miserez, Ali |
| format |
Article |
| author |
Chua, Isaiah Jia Qing Srinivasan, Dharun Vadugappatty Idapalapati, Sridhar Miserez, Ali |
| author_sort |
Chua, Isaiah Jia Qing |
| title |
Fracture toughness of the stomatopod dactyl club is enhanced by plastic dissipation: a fracture micromechanics study |
| title_short |
Fracture toughness of the stomatopod dactyl club is enhanced by plastic dissipation: a fracture micromechanics study |
| title_full |
Fracture toughness of the stomatopod dactyl club is enhanced by plastic dissipation: a fracture micromechanics study |
| title_fullStr |
Fracture toughness of the stomatopod dactyl club is enhanced by plastic dissipation: a fracture micromechanics study |
| title_full_unstemmed |
Fracture toughness of the stomatopod dactyl club is enhanced by plastic dissipation: a fracture micromechanics study |
| title_sort |
fracture toughness of the stomatopod dactyl club is enhanced by plastic dissipation: a fracture micromechanics study |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/160214 |
| _version_ |
1738844793939689472 |