Multi-scale structural design and biomechanics of the pistol shrimp snapper claw
The Arthropoda, the largest phylum of the Animal Kingdom, have successfully evolved to survive various ecological constraints under a wide range of environmental conditions. Central to this survival are the structural designs developed in their exoskeletons and their raptorial appendages for protect...
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sg-ntu-dr.10356-1394512020-06-01T10:13:59Z Multi-scale structural design and biomechanics of the pistol shrimp snapper claw Amini, Shahrouz Tadayon, Maryam Chua, Julianto Q. Isaiah Miserez, Ali School of Materials Science & Engineering School of Biological Sciences Centre for Biomimetic Sensor Science Engineering::Materials Crustaceans Appendages The Arthropoda, the largest phylum of the Animal Kingdom, have successfully evolved to survive various ecological constraints under a wide range of environmental conditions. Central to this survival are the structural designs developed in their exoskeletons and their raptorial appendages for protection and hunting. One such example, the pistol shrimp, is a shallow-water crustacean that is well-known for its aggressive hunting behavior, using its snapper claw to trigger the nucleation of cavitation bubbles that strike targets. In this study, we conducted a multi-scale structural/nanomechanics relationship study of this biotool to analyze its mechanical response to contact stresses. We found that the pistol shrimp snapper claw, which exhibits the capacity to emit a high-velocity water jet during rapid closure actions, is more brittle than other mineralized biotools, exhibiting accelerated wear damage under contact stresses. However, due to an angular offset between the dactylus and pollex of the snapper claw, the appendage never engages in any mechanical contact during the snapping action. This feature is in stark contrast to that reported in other fast raptorial appendages of crustaceans, notably the mantis shrimp dactyl club, which is designed to shatter close range targets in contact mode and exhibits a superior resistance to contact damage and wear. These findings suggest that adaptation of hunting appendages goes beyond their macroscopic morphology, and that multi-scale structural design concomitantly adapted to function, with enhanced structural complexification for tools that are subjected to more intense contact stresses. NRF (Natl Research Foundation, S’pore) 2020-05-19T08:59:55Z 2020-05-19T08:59:55Z 2018 Journal Article Amini, S., Tadayon, M., Chua, J. Q. I., & Miserez, A. (2018). Multi-scale structural design and biomechanics of the pistol shrimp snapper claw. Acta Biomaterialia, 73, 449-457. doi:10.1016/j.actbio.2018.04.038 1742-7061 https://hdl.handle.net/10356/139451 10.1016/j.actbio.2018.04.038 29684626 2-s2.0-85046118703 73 449 457 en Acta biomaterialia © 2018 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved. |
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Engineering::Materials Crustaceans Appendages Amini, Shahrouz Tadayon, Maryam Chua, Julianto Q. Isaiah Miserez, Ali Multi-scale structural design and biomechanics of the pistol shrimp snapper claw |
| description |
The Arthropoda, the largest phylum of the Animal Kingdom, have successfully evolved to survive various ecological constraints under a wide range of environmental conditions. Central to this survival are the structural designs developed in their exoskeletons and their raptorial appendages for protection and hunting. One such example, the pistol shrimp, is a shallow-water crustacean that is well-known for its aggressive hunting behavior, using its snapper claw to trigger the nucleation of cavitation bubbles that strike targets. In this study, we conducted a multi-scale structural/nanomechanics relationship study of this biotool to analyze its mechanical response to contact stresses. We found that the pistol shrimp snapper claw, which exhibits the capacity to emit a high-velocity water jet during rapid closure actions, is more brittle than other mineralized biotools, exhibiting accelerated wear damage under contact stresses. However, due to an angular offset between the dactylus and pollex of the snapper claw, the appendage never engages in any mechanical contact during the snapping action. This feature is in stark contrast to that reported in other fast raptorial appendages of crustaceans, notably the mantis shrimp dactyl club, which is designed to shatter close range targets in contact mode and exhibits a superior resistance to contact damage and wear. These findings suggest that adaptation of hunting appendages goes beyond their macroscopic morphology, and that multi-scale structural design concomitantly adapted to function, with enhanced structural complexification for tools that are subjected to more intense contact stresses. |
| author2 |
School of Materials Science & Engineering |
| author_facet |
School of Materials Science & Engineering Amini, Shahrouz Tadayon, Maryam Chua, Julianto Q. Isaiah Miserez, Ali |
| format |
Article |
| author |
Amini, Shahrouz Tadayon, Maryam Chua, Julianto Q. Isaiah Miserez, Ali |
| author_sort |
Amini, Shahrouz |
| title |
Multi-scale structural design and biomechanics of the pistol shrimp snapper claw |
| title_short |
Multi-scale structural design and biomechanics of the pistol shrimp snapper claw |
| title_full |
Multi-scale structural design and biomechanics of the pistol shrimp snapper claw |
| title_fullStr |
Multi-scale structural design and biomechanics of the pistol shrimp snapper claw |
| title_full_unstemmed |
Multi-scale structural design and biomechanics of the pistol shrimp snapper claw |
| title_sort |
multi-scale structural design and biomechanics of the pistol shrimp snapper claw |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/139451 |
| _version_ |
1681057675363745792 |