DocumentCode
2608310
Title
Investigation to the herringbone nano-aragonite-sheet microstructure of Chamidae shell
Author
Chen, Bin ; Peng, Xianghe ; Sun, Shitao
Author_Institution
Dept. of Eng. Mech., Chongqing Univ., Chongqing
fYear
2007
fDate
2-5 Aug. 2007
Firstpage
1273
Lastpage
1276
Abstract
The observation of scanning electron microscope (SEM) on a Chamidae´s shell showed that the shell consists of aragonite layers and collagen protein matrix. All aragonite layers are parallel with the surface of the shell and consist of many long and thin aragonite sheets. These aragonite sheets are perpendicular to the layers where they are located. The observation also showed that the aragonite sheets in different layers possess different orientations, which compose a kind of herringbone microstructure of the sheets. More careful observation showed that the aragonite sheets consist further of lesser aragonite microsheets. The thickness of the aragonite microsheets possesses nanometer scale. The maximum pullout force of the herringbone microstructure was investigated and compared with that of the parallel microstructure based on their representative models. It showed that the herringbone microstructure can markedly increase the pullout force of the microsheets and improve the fracture toughness of the shell.
Keywords
bioceramics; biomechanics; fracture toughness; nanocomposites; proteins; scanning electron microscopy; Chamidae shell; aragonite layers; bioceramic composite; collagen protein matrix; fracture toughness; herringbone microstructure; herringbone nanoaragonite-sheet; pullout force; scanning electron microscope; Ceramics; Crystal microstructure; Crystalline materials; Educational institutions; Lattices; Nanotechnology; Protein engineering; Scanning electron microscopy; Sun; Surface cracks; Chamidae shell; fracture toughness; herringbone microstructure; maximum pullout force; nano-aragonite sheet;
fLanguage
English
Publisher
ieee
Conference_Titel
Nanotechnology, 2007. IEEE-NANO 2007. 7th IEEE Conference on
Conference_Location
Hong Kong
Print_ISBN
978-1-4244-0607-4
Electronic_ISBN
978-1-4244-0608-1
Type
conf
DOI
10.1109/NANO.2007.4601415
Filename
4601415
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