2013
DOI: 10.1038/ncomms3634
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Mechanical adaptability of the Bouligand-type structure in natural dermal armour

Abstract: Arapaima gigas, a fresh water fish found in the Amazon Basin, resist predation by piranhas through the strength and toughness of their scales, which act as natural dermal armour. Arapaima scales consist of a hard, mineralized outer shell surrounding a more ductile core. This core region is composed of aligned mineralized collagen fibrils arranged in distinct lamellae. Here we show how the Bouligand-type (twisted plywood) arrangement of collagen fibril lamellae has a key role in developing their unique protecti… Show more

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Cited by 312 publications
(243 citation statements)
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“…Similar observations have been made with respect to the periodic region of the dactyl club and helicoidal structures found within most arthropod cuticles as well as other Submitted to 8 natural composite materials including lamellar bone, cell walls of wood and fish scales. [17,18,[28][29][30][31][32][33] Crack deflection is an extrinsic form of toughening that is well-documented in natural composite materials, specifically biomineralized tissues. [3] The periodic nature of hard and soft interfaces, in this case between alpha-chitin fibrils and hydroxyapatite crystals, results in a crack-tip shielding effect that changes the crack driving force and thereby arresting crack propagation.…”
Section: A Sinusoidally-architected Helicoidal Biocompositementioning
confidence: 99%
“…Similar observations have been made with respect to the periodic region of the dactyl club and helicoidal structures found within most arthropod cuticles as well as other Submitted to 8 natural composite materials including lamellar bone, cell walls of wood and fish scales. [17,18,[28][29][30][31][32][33] Crack deflection is an extrinsic form of toughening that is well-documented in natural composite materials, specifically biomineralized tissues. [3] The periodic nature of hard and soft interfaces, in this case between alpha-chitin fibrils and hydroxyapatite crystals, results in a crack-tip shielding effect that changes the crack driving force and thereby arresting crack propagation.…”
Section: A Sinusoidally-architected Helicoidal Biocompositementioning
confidence: 99%
“…25a) [13,[180][181][182]. When a collagen layer is formed, it often has a Bouligandlike structure in order to provide increased toughness and strength in many directions [44,183]. Scales are most commonly arranged in overlapping sheets that allow for smooth motion of the body for locomotion while ensuring full coverage for protection from predators [13,180].…”
Section: Overlapping Fish Scalesmentioning
confidence: 99%
“…One recently discovered and intriguing solution is the stomatopod's dactyl club that is used to strike highly mineralized prey 4 underwater, therefore requiring exceptional damage tolerance for sustaining instantaneous forces above 500 N. At the microscale, crack propagation via impact is impeded by elastic mismatches of locally parallel chitin fibril stacks with constant skews in angle from the layer below, forming a super-layer with oscillating elastic moduli that is representative of a Bouligand-type structure 41 . On a larger scale, the macroscopic configuration of the club includes three distinct domains: the impact surface, a transitional zone with an abrupt decrease in modulus and hardness with respective values of B65 and B3 GPa and a periodic region with oscillating modulus values of 10 and 25 GPa.…”
Section: Multiscale and Multiphasic Organizationmentioning
confidence: 99%