Effects of laminate architecture on fracture resistance of sponge biosilica: lessons from nature
Effects of laminate architecture on fracture resistance of sponge biosilica: lessons from nature
Hexactinellid sponges are known for their ability to synthesize unusually long and highly flexible fibrous spicules, which serve as the building blocks of their skeletal systems. The spicules consist of a central core of monolithic hydrated silica, surrounded by alternating layers of hydrated silica and proteinaceous material. The principal objective of the present study is to ascertain the role of the latter laminate architecture in the material's resistance to both crack initiation and subsequent crack growth. This has been accomplished through indentation testing on the giant anchor spicule of Monorhaphis chuni, both in the laminated region and in the monolithic core, along with a theoretical analysis of deformation and cracking at indents. The latter suggests that the threshold load for crack initiation is proportional to Kc4/E2H where Kc is fracture toughness, E is Young's modulus, and H is hardness. Two key experimental results emerge. First, the load required to form well-defined radial cracks from a sharp indent in the laminated region is two orders of magnitude greater than that for the monolithic material. Secondly, its fracture toughness is about 2.5 times that of the monolith, whereas the modulus and hardness are about 20% lower. Combining the latter property values with the theoretical analysis, the predicted increase in the threshold load is a factor of about 80, broadly consistent with the experimental measurements.
sponge spicule, silica, biomaterials, microstructures, layered materials, biomimetics
1241-1248
Miserez, Ali
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Weaver, James C.
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Thurner, Philipp J.
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Aizenberg, Joanna
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Dauphin, Yannique
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Fratzl, Peter
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Morse, Daniel E.
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Zok, Frank W.
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25 April 2008
Miserez, Ali
d0d51f68-b782-4176-b92a-87c9f4aed01f
Weaver, James C.
a8234238-bb1c-4bc2-8a1b-5484a8bbd5bd
Thurner, Philipp J.
ab711ddd-784e-48de-aaad-f56aec40f84f
Aizenberg, Joanna
cb740b3a-a4ff-43bd-bf9d-4524387b5778
Dauphin, Yannique
322ec5c9-c633-4172-9ee4-fe417a2b637e
Fratzl, Peter
9694f97c-d42c-417f-b17e-639e7c7c8d0b
Morse, Daniel E.
aaa0e018-1bd0-41f3-8ff8-b8a22015d742
Zok, Frank W.
8e80387c-46f9-44e1-bbc8-787f71d09308
Miserez, Ali, Weaver, James C., Thurner, Philipp J., Aizenberg, Joanna, Dauphin, Yannique, Fratzl, Peter, Morse, Daniel E. and Zok, Frank W.
(2008)
Effects of laminate architecture on fracture resistance of sponge biosilica: lessons from nature.
Advanced Functional Materials, 18 (8), .
(doi:10.1002/adfm.200701135).
Abstract
Hexactinellid sponges are known for their ability to synthesize unusually long and highly flexible fibrous spicules, which serve as the building blocks of their skeletal systems. The spicules consist of a central core of monolithic hydrated silica, surrounded by alternating layers of hydrated silica and proteinaceous material. The principal objective of the present study is to ascertain the role of the latter laminate architecture in the material's resistance to both crack initiation and subsequent crack growth. This has been accomplished through indentation testing on the giant anchor spicule of Monorhaphis chuni, both in the laminated region and in the monolithic core, along with a theoretical analysis of deformation and cracking at indents. The latter suggests that the threshold load for crack initiation is proportional to Kc4/E2H where Kc is fracture toughness, E is Young's modulus, and H is hardness. Two key experimental results emerge. First, the load required to form well-defined radial cracks from a sharp indent in the laminated region is two orders of magnitude greater than that for the monolithic material. Secondly, its fracture toughness is about 2.5 times that of the monolith, whereas the modulus and hardness are about 20% lower. Combining the latter property values with the theoretical analysis, the predicted increase in the threshold load is a factor of about 80, broadly consistent with the experimental measurements.
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Published date: 25 April 2008
Keywords:
sponge spicule, silica, biomaterials, microstructures, layered materials, biomimetics
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Local EPrints ID: 52536
URI: http://eprints.soton.ac.uk/id/eprint/52536
ISSN: 1616-301X
PURE UUID: 7238ae66-9096-446d-a0ff-277bb1ee9b38
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Date deposited: 10 Jul 2008
Last modified: 15 Mar 2024 10:37
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Contributors
Author:
Ali Miserez
Author:
James C. Weaver
Author:
Joanna Aizenberg
Author:
Yannique Dauphin
Author:
Peter Fratzl
Author:
Daniel E. Morse
Author:
Frank W. Zok
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