Hardness and toughness of exoskeleton material in the stone crab, Menippe mercenaria

C. A. Melnick; Z. Chen; J. J. Mecholsky Jr.

doi:10.1557/JMR.1996.0367

Abstract

Techniques from the field of materials science and engineering were utilized to examine the mechanical effects of dark pigment in exoskeleton material on the distal portion of stone crab, Menippe mercenaria, chelae. We made specimens from dark-and light-colored exoskeleton material to measure hardness and fracture toughness. The results from these tests showed the dark material to be much harder and tougher than light-colored material from the same crab chela. Scanning electron microscope photographs are presented to document the microstructure and level of porosity. We think that the structural difference in material properties is due to the lower level of porosity and phenolic tanning in dark material and that this tanning caused the dark color and filling of porosity. The exoskeleton structure is a laminated organic-inorganic structure which can serve as a model for self-healing structures.

References

REFERENCES

1.Burtt, E. H., An Analysis of Physical, Physiological, and Optical Aspects of Avian Coloration with Emphasis on Wood-Warblers, Ornithological Monographs No. 38 (The American Ornithologists' Union, Washington, DC, 1986).CrossRef Google Scholar

2.Say, T., J. Acad. Natural Sciences of Philadelphia 1 (2), 448 (1818).Google Scholar

3.Bender, E. S., M. S. Thesis, University of Florida, Gainesville, FL (1971), 110 pp.Google Scholar

4.Roer, R. and Dillaman, R., American Zoologist 24, 893–909 (1984).CrossRef Google Scholar

5.Ghidalia, W., Structural and Biological Aspects of Pigments in the Biology of Crustacea, edited by Bliss, D. E. and Mantel, L. H. (Academic Press, Orlando, FL, 1985), Vol. 9, pp. 301–394.Google Scholar

6.Warner, G. F., The Biology of Crabs (Van Nostrand Reinhold Company, New York, 1977).Google Scholar

7.Vincent, J., Structural Biomaterials–Rev. ed. (Princeton University Press, Princeton, NJ, 1990).Google Scholar

8.Krishnan, G., Quarterly J. Microscopical Sci. 92, part 3, 333–342 (1951).Google Scholar

9.Savage, T. and Sullivan, J. R., Growth and Claw Regeneration of the Stone Crab, Menippe mercenaria (Florida Marine Research Publications, Florida Department of Natural Resources, 1978) No. 32, 23 pp.Google Scholar

10.Annual Book of ASTM Standards, Part 17, Refractories, Glass, and Other Ceramic Materials: Manufactured Carbon and Graphite, Products (American Society for Testing and Materials, Philadelphia, PA, 1974), pp. 103–106.Google Scholar

11.Annual Book of ASTM Standards, Part 10, Metals—Mechanical, Fracture, and Corrosion Testing; Fatigue; Erosion; Effect of Temperature (American Society for Testing and Materials, Philadelphia, PA, 1978), pp. 271–281.Google Scholar

12.Chantikul, P., Anstis, G. R., Lawn, B. R., and Marshall, D. B., J. Am. Ceram. Soc. 64 (9), 539–543 (1981).CrossRef Google Scholar

13.Welinder, B. S., Comp. Biochem. Physiol. 52A, 659–663 (1975).CrossRef Google Scholar

Crossref Citations

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

Raabe, D. Sachs, C. and Romano, P. 2005. The crustacean exoskeleton as an example of a structurally and mechanically graded biological nanocomposite material. Acta Materialia, Vol. 53, Issue. 15, p. 4281.

Raabe, D. Romano, P. Al-Sawalmih, A. Sachs, C. Servos, G. and Hartwig, H.G. 2005. Mesostructure of the Exoskeleton of the Lobster Homarus Americanus. MRS Proceedings, Vol. 874, Issue. ,

Raabe, Dierk Al-Sawalmih, A. Romano, P. Sachs, C. Brokmeier, Heinz Günter Yi, Sang Bong Servos, G. and Hartwig, H.G. 2005. Structure and Crystallographic Texture of Arthropod Bio-Composites. Materials Science Forum, Vol. 495-497, Issue. , p. 1665.

Sachs, C. Fabritius, H. and Raabe, D. 2006. Experimental investigation of the elastic–plastic deformation of mineralized lobster cuticle by digital image correlation. Journal of Structural Biology, Vol. 155, Issue. 3, p. 409.

Raabe, D. Romano, P. Sachs, C. Fabritius, H. Al-Sawalmih, A. Yi, S.-B. Servos, G. and Hartwig, H.G. 2006. Microstructure and crystallographic texture of the chitin–protein network in the biological composite material of the exoskeleton of the lobster Homarus americanus. Materials Science and Engineering: A, Vol. 421, Issue. 1-2, p. 143.

Schroeder, Amanda M. Waugh, David A. Feldmann, Rodney M. and Mutel, Matt H. E. 2006. Differential Cuticle Architecture and Its Preservation in Fossil and Extant Callinectes and Scylla Claws. Journal of Crustacean Biology, Vol. 26, Issue. 3, p. 271.

Raabe, D. Al-Sawalmih, A. Yi, S.B. and Fabritius, H. 2007. Preferred crystallographic texture of α-chitin as a microscopic and macroscopic design principle of the exoskeleton of the lobster Homarus americanus. Acta Biomaterialia, Vol. 3, Issue. 6, p. 882.

Fonseca, Duane B. Sainte‐Marie, Bernard and Hazel, François 2008. Longevity and Change in Shell Condition of Adult Male Snow Crab Chionoecetes opilio Inferred from Dactyl Wear and Mark‐Recapture Data. Transactions of the American Fisheries Society, Vol. 137, Issue. 4, p. 1029.

Chen, Po-Yu Lin, Albert Yu-Min McKittrick, Joanna and Meyers, Marc André 2008. Structure and mechanical properties of crab exoskeletons. Acta Biomaterialia, Vol. 4, Issue. 3, p. 587.

Meyers, Marc André Chen, Po-Yu Lin, Albert Yu-Min and Seki, Yasuaki 2008. Biological materials: Structure and mechanical properties. Progress in Materials Science, Vol. 53, Issue. 1, p. 1.

Schofield, Robert M.S. Niedbala, Jack C. Nesson, Michael H. Tao, Ye Shokes, Jacob E. Scott, Robert A. and Latimer, Matthew J. 2009. Br-rich tips of calcified crab claws are less hard but more fracture resistant: A comparison of mineralized and heavy-element biological materials. Journal of Structural Biology, Vol. 166, Issue. 3, p. 272.

Cribb, B.W. Lin, C.-L. Rintoul, L. Rasch, R. Hasenpusch, J. and Huang, H. 2010. Hardness in arthropod exoskeletons in the absence of transition metals. Acta Biomaterialia, Vol. 6, Issue. 8, p. 3152.

Lian, Jie and Wang, Junlan 2011. Mechanics of Biological Systems and Materials, Volume 2. p. 93.

Curran, Declan J. Fleming, Thomas J. Towler, Mark R. and Hampshire, Stuart 2011. Mechanical parameters of strontium doped hydroxyapatite sintered using microwave and conventional methods. Journal of the Mechanical Behavior of Biomedical Materials, Vol. 4, Issue. 8, p. 2063.

Meyers, Marc André McKittrick, Joanna and Chen, Po-Yu 2013. Structural Biological Materials: Critical Mechanics-Materials Connections. Science, Vol. 339, Issue. 6121, p. 773.

Amini, Shahrouz and Miserez, Ali 2013. Wear and abrasion resistance selection maps of biological materials. Acta Biomaterialia, Vol. 9, Issue. 8, p. 7895.

Lian, J. and Wang, J. 2014. Microstructure and Mechanical Anisotropy of Crab Cancer Magister Exoskeletons. Experimental Mechanics, Vol. 54, Issue. 2, p. 229.

Verma, Devendra and Tomar, Vikas 2014. An investigation into environment dependent nanomechanical properties of shallow water shrimp (Pandalus platyceros) exoskeleton. Materials Science and Engineering: C, Vol. 44, Issue. , p. 371.

Verma, Devendra and Tomar, Vikas 2014. Structural-nanomechanical property correlation of shallow water shrimp (Pandalus platyceros) exoskeleton at elevated temperature. Journal of Bionic Engineering, Vol. 11, Issue. 3, p. 360.

Studart, André R. Libanori, Rafael and Erb, Randall M. 2014. Bio‐ and Bioinspired Nanomaterials. p. 335.

Download full list

Article contents

Hardness and toughness of exoskeleton material in the stone crab, Menippe mercenaria

Abstract

Access options

References

REFERENCES

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

Article contents

Hardness and toughness of exoskeleton material in the stone crab, Menippe mercenaria

Abstract

Access options

References

REFERENCES

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests