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Effects of Shape and Orientation of Pore Canals on Mechanical Behaviors of Lobster Cuticles

Published online by Cambridge University Press:  21 June 2018

Shiyun Lin
Affiliation:
State Key Laboratory of Coal Mine Disaster Dynamics and Control, College of Aerospace Engineering, Chongqing University, Chongqing 400030, China
Bin Chen*
Affiliation:
State Key Laboratory of Coal Mine Disaster Dynamics and Control, College of Aerospace Engineering, Chongqing University, Chongqing 400030, China
Zhongqi Fang
Affiliation:
State Key Laboratory of Coal Mine Disaster Dynamics and Control, College of Aerospace Engineering, Chongqing University, Chongqing 400030, China
Wei Ye
Affiliation:
State Key Laboratory of Coal Mine Disaster Dynamics and Control, College of Aerospace Engineering, Chongqing University, Chongqing 400030, China
*
*Author for correspondence: Bin Chen, E-mail: [email protected]
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Abstract

The work is to investigate the relationships between the microstructures and mechanical behaviors of lobster cuticles and reveal the inner mechanisms of the anisotropic mechanical properties of the cuticles and give the helpful guidance for the design of high-performance man-made composites. First, the tensile mechanical properties of the longitudinal and transverse specimens of the cuticles of American lobsters were tested with a mechanical-testing instrument. It is was found that the fracture strength and elastic modulus of the longitudinal specimens are distinctly larger than those of the transverse specimens. Then, the microstructural characteristics of the fracture surfaces of the specimens were observed with scanning electron microscope. It was observed that the pore canals in the cuticles are elliptic and their orientations are along the longitudinal orientation of the cuticles. Furthermore, the stresses and micro-damage of the longitudinal and transverse specimens were calculated with the rule of progressive damage by finite element method. It was revealed that the shape and orientation of the pore canals in the cuticles give rise to the anisotropic mechanical property of the cuticles and ensure that the cuticles possess the largest fracture strength and elastic modulus along their largest main-stress orientation.

Type
Biological Science Applications
Copyright
© Microscopy Society of America 2018 

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References

Brewer, JC Lagace, PA (1988) Quadratic stress criterion for initiation of delamination. J Compos Mater 22, 11411155.Google Scholar
Chang, FK Chang, KY (1987) A progressive damage model for laminated composites containing stress concentrations. J Compos Mater 21, 834855.Google Scholar
Chen, B, Fan, J, Gou, J Lin, S (2014) Hole-pin joining structure with fiber-round-hole distribution of lobster cuticle and biomimetic study. J Mech Behav Biomed Mater 40, 161167.Google Scholar
Chen, PY, Lin, A, Lin, Y, Seki, Y, Stokes, A, Peyras, J, Olevsky, E, Meyers, MA Mckittrick, J (2008a) Structure and mechanical properties of selected biological materials. J Mech Behav Biomed Mater 1, 208226.Google Scholar
Chen, PY, Lin, AYM, McKittrick, J Meyers, MA (2008b) Structure and mechanical properties of crab exoskeletons. Acta Biomater. 4, 587596.Google Scholar
Chen, Q Pugno, NM (2013) Bio-mimetic mechanisms of natural hierarchical materials: A review. J Mech Behav Biomed Mater 19, 333.Google Scholar
Dunlop, JWC Fratzl, P (2013) Multilevel architectures in natural materials. Scr Mater 68, 812.Google Scholar
Eadie, L Ghosh, TK (2011) Biomimicry in textiles: Past, present and potential. An overview. J R Soc Interface 8, 761775.Google Scholar
Erko, M, Hartmann, MA, Zlotnikov, I, Valverde Serrano, C, Fratzl, P Politi, Y (2013) Structural and mechanical properties of the arthropod cuticle: Comparison between the fang of the spider Cupiennius salei and the carapace of American lobster Homarus americanus. J Struct Biol 183, 172179.Google Scholar
Fan, J, Chen, B, Gao, Z Xiang, C (2005) Mechanisms in failure prevention of bio-materials and bio-structures. Mech Adv Mater Struct 12, 229237.Google Scholar
Fan, TX, Chow, SK Zhang, D (2009) Biomorphic mineralization: From biology to materials. Prog Mater Sci 54, 542659.Google Scholar
Hou, JP, Petrinic, N Ruiz, C (2000) Prediction of impact damage in composite plates. Compos Sci Technol 60, 273281.Google Scholar
Koester, KJ, Ager, JW Ritchie, RO (2008) The true toughness of human cortical bone measured with realistically short cracks. Nat Mater 7, 672677.Google Scholar
Lapczyk, I Hurtado, JA (2007) Progressive damage modeling in fiber-reinforced materials. Compos Part A Appl Sci Manuf 38, 23332341.Google Scholar
Meyers, MA, McKittrick, J Chen, PY (2013) Structural biological materials: Critical mechanics-materials connections. Science 339, 773779.Google Scholar
Nishino, T, Matsui, R Nakamae, K (1999) Elastic modulus of the crystalline regions of chitin and chitosan. J Polym Sci Part B Polym Phys 37, 11911196.Google Scholar
Raabe, D, Romano, P, Sachs, C, Al-Sawalmih, A, Brokmeier, HG, Yi, SB, Servos, G Hartwig, HG (2005a) Discovery of a honeycomb structure in the twisted plywood patterns of fibrous biological nanocomposite tissue. J Cryst Growth 283, 17.Google Scholar
Raabe, D, Romano, P, Sachs, C, Fabritius, H, Al-Sawalmih, A, Yi, SB, Servos, G Hartwig, HG (2006) Microstructure and crystallographic texture of the chitin-protein network in the biological composite material of the exoskeleton of the lobster Homarus americanus. Mater Sci Eng A 421, 143153.Google Scholar
Raabe, D, Sachs, C Romano, P (2005b) The crustacean exoskeleton as an example of a structurally and mechanically graded biological nanocomposite material. Acta Mater 53, 42814292.Google Scholar
Romano, P, Fabritius, H Raabe, D (2007) The exoskeleton of the lobster Homarus americanus as an example of a smart anisotropic biological material. Acta Biomater 3, 301309.Google Scholar
Sachs, C, Fabritius, H Raabe, D (2006a) Experimental investigation of the elastic-plastic deformation of mineralized lobster cuticle by digital image correlation. J Struct Biol 155, 409425.Google Scholar
Sachs, C, Fabritius, H Raabe, D (2006b) Hardness and elastic properties of dehydrated cuticle from the lobster Homarus americanus obtained by nanoindentation. J Mater Res 21, 19871995.Google Scholar
Smith, BL, Schäffer, TE, Vlani, M, Thompson, JB, Frederick, NA, Klndt, J, Belcher, A, Stuckyll, GD, Morse, DE Hansma, PK (1999) Molecular mechanistic origin of the toughness of natural adhesives, fibres and composites. Nature 399, 761763.Google Scholar
Tarsitano, SF, Lavalli, KL, Horne, F Spanier, E (2006) The constructional properties of the exoskeleton of homarid, palinurid, and scyllarid lobsters. Hydrobiologia 557, 920.Google Scholar
Tay, TE, Liu, G, Tan, VBC, Sun, XS Pham, DC (2008) Progressive failure analysis of composites. J Compos Mater 42, 19211966.Google Scholar
Zhou, F, Wu, Z, Wang, M Chen, K (2010) Structure and mechanical properties of pincers of lobster (Procambarus clarkii) and crab (Eriocheir Sinensis). J Mech Behav Biomed Mater 3, 454463.Google Scholar