Hierarchical Functionally Gradient Structures of Bamboo, Barley, and Corn

Shigeyasu Amada

doi:10.1557/S0883769400048909

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Bamboo and certain other plants have excellent characteristics based on functionally gradient structures. Figure 1 shows a cross section of bamboo, corn, and barley culms. The collection of solid dots in bamboo is called the bundle sheath, which acts as fibers for the plant. These bundle sheaths are shown in the magnified photograph of corn and barley. These two plants are made of composite materials reinforced by fibers of the bundle sheath; the fiber strength is about 10 times that of the matrix. Furthermore, the fiber distribution is dense in the outer region and sparse in the inner region. It can be said that the fiber distribution forms a gradient structure. The fibers in barley are sparse in the narrow cross section and are different from the fibers in corn and bamboo. The number of honey-comb-shaped cells in barley is higher on the outside than the inside region. Therefore, barley also has a gradient structure. These relations of the microscopic gradient structure are displayed graphically by the cross-sectional photographs. Figures 1a and 1b present the fiber contents of bamboo and corn, respectively, with respect to radius measured from the outer radius. Figure 1c gives the gradient distribution of the cell number for barley with respect to radius. These gradient features probably relate to the bending-stress distribution caused by wind, rain, and snow—the so-called environmental loads.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Weaire, D. and Fortes, M.A. 1994. Stress and strain in liquid and solid foams. Advances in Physics, Vol. 43, Issue. 6, p. 685.

García-Ruiz, J.M. Navarro, A.Rodriguez and Kälin, O. 1995. Textural analysis of eggshells. Materials Science and Engineering: C, Vol. 3, Issue. 2, p. 95.

Chu, T.K. Stumborg, M.F. and Santiago, F. 1997. Heteroepitaxial deposition of Group IIa fluorides on gallium arsenide. Materials Science and Engineering: B, Vol. 47, Issue. 3, p. 224.

Amada, Shigeyasu Ichikawa, Yoshinobu Munekata, Tamotsu Nagase, Yukito and Shimizu, Hiroyuki 1997. Fiber texture and mechanical graded structure of bamboo. Composites Part B: Engineering, Vol. 28, Issue. 1-2, p. 13.

Amada, Shigeyasu and Shimizu, Naoyuki 1997. Functionally Graded Materials 1996. p. 731.

Ichikawa, Kiyoshi 2001. Functionally Graded Materials in the 21st Century. p. 103.

Amada, Shigeyasu and Untao, Sun 2001. Fracture properties of bamboo. Composites Part B: Engineering, Vol. 32, Issue. 5, p. 451.

Kim, Jang-Kyo Huang, Xing-Jia Yu, Tong-Xi Chan, Chi-Ming and Guo, Bao-Hua 2001. Interlaminar fracture behaviour of re-formed bamboo/aluminium sheet laminates. Journal of Adhesion Science and Technology, Vol. 15, Issue. 5, p. 535.

Zhang, J.Y Zeng, Q.Y Yu, T.X and Kim, J.K 2001. Residual properties of reformed bamboo/aluminium laminates after hygrothermal aging. Composites Science and Technology, Vol. 61, Issue. 8, p. 1041.

Bailey, A. J. Macmillan, J. Shrewry, P. R. Tatham, A. S. Waite, J. H. Vaccaro, E. Sun, C. and Lucas, J. M. 2002. Elastomeric gradients: a hedge against stress concentration in marine holdfasts?. Philosophical Transactions of the Royal Society of London. Series B: Biological Sciences, Vol. 357, Issue. 1418, p. 143.

Wei, En-Bo Yang, Zi-Dong and Song, Jin-Bao 2003. Effective dielectric response of graded spherical composites. Physics Letters A, Vol. 316, Issue. 6, p. 419.

Rao, P. Ramachandra 2003. Biomimetics. Sadhana, Vol. 28, Issue. 3-4, p. 657.

Ikeda, Yuko 2003. Graded styrene–butadiene rubber vulcanizates. Journal of Applied Polymer Science, Vol. 87, Issue. 1, p. 61.

Wei, En-Bo Tian, Ji-Wei and Song, Jin-Bao 2003. Dielectric response of composites with graded cylindrical particles. Journal of Physics: Condensed Matter, Vol. 15, Issue. 50, p. 8907.

Low, It‐Meng 2004. Depth‐Profiling of Crystal Structure, Texture, and Microhardness in a Functionally Graded Tooth Enamel. Journal of the American Ceramic Society, Vol. 87, Issue. 11, p. 2125.

Low, I.M. and Mahmood, U. 2004. Composite Technologies for 2020. p. 112.

Wei, En-Bo and Wu, Zi-Ku 2004. The nonlinear effective dielectric response of graded composites. Journal of Physics: Condensed Matter, Vol. 16, Issue. 29, p. 5377.

Ray, A. K. Mondal, S. Das, S. K. and Ramachandrarao, P. 2005. Bamboo—A functionally graded composite-correlation between microstructure and mechanical strength. Journal of Materials Science, Vol. 40, Issue. 19, p. 5249.

Conde, Yves Pollien, Arnaud and Mortensen, Andreas 2006. Functional grading of metal foam cores for yield-limited lightweight sandwich beams. Scripta Materialia, Vol. 54, Issue. 4, p. 539.

En-Bo, Wei Guo-Qing, Gu and Kin-Wah, Yu 2006. Dielectric responses of graded composites having generalized gradation profiles. Chinese Physics, Vol. 15, Issue. 1, p. 182.

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