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Molecular mechanistic origin of the toughness of natural adhesives, fibres and composites

Author

Listed:
  • Bettye L. Smith

    (University of California at)

  • Tilman E. Schäffer

    (Max-Planck-Institute for Biophysical Chemistry)

  • Mario Viani

    (University of California at)

  • James B. Thompson

    (University of California at)

  • Neil A. Frederick

    (University of California at)

  • Johannes Kindt

    (University of California at)

  • Angela Belcher

    (The University of Texas at Austin)

  • Galen D. Stucky

    (University of California at)

  • Daniel E. Morse

    (University of California at)

  • Paul K. Hansma

    (University of California at)

Abstract

Natural materials are renowned for their strength and toughness1,2,3,4,5. Spider dragline silk has a breakage energy per unit weight two orders of magnitude greater than high tensile steel1,6, and is representative of many other strong natural fibres3,7,8. The abalone shell, a composite of calcium carbonate plates sandwiched between organic material, is 3,000 times more fracture resistant than a single crystal of the pure mineral4,5. The organic component, comprising just a few per cent of the composite by weight9, is thought to hold the key to nacre's fracture toughness10,11. Ceramics laminated with organic material are more fracture resistant than non-laminated ceramics11,12, but synthetic materials made of interlocking ceramic tablets bound by a few weight per cent of ordinary adhesives do not have a toughness comparable to nacre13. We believe that the key to nacre's fracture resistance resides in the polymer adhesive, and here we reveal the properties of this adhesive by using the atomic force microscope14 to stretch the organic molecules exposed on the surface of freshly cleaved nacre. The adhesive fibres elongate in a stepwise manner as folded domains or loops are pulled open. The elongation events occur for forces of a few hundred piconewtons, which are smaller than the forces of over a nanonewton required to break the polymer backbone in the threads. We suggest that this ‘modular’ elongation mechanism might prove to be quite general for conveying toughness to natural fibres and adhesives, and we predict that it might be found also in dragline silk.

Suggested Citation

  • Bettye L. Smith & Tilman E. Schäffer & Mario Viani & James B. Thompson & Neil A. Frederick & Johannes Kindt & Angela Belcher & Galen D. Stucky & Daniel E. Morse & Paul K. Hansma, 1999. "Molecular mechanistic origin of the toughness of natural adhesives, fibres and composites," Nature, Nature, vol. 399(6738), pages 761-763, June.
    • Handle: RePEc:nat:nature:v:399:y:1999:i:6738:d:10.1038_21607
    DOI: 10.1038/21607
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    Cited by:

    1. Bin Xue & Zoobia Bashir & Yachong Guo & Wenting Yu & Wenxu Sun & Yiran Li & Yiyang Zhang & Meng Qin & Wei Wang & Yi Cao, 2023. "Strong, tough, rapid-recovery, and fatigue-resistant hydrogels made of picot peptide fibres," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    2. Markus J. Buehler & Theodor Ackbarow, 2008. "Nanomechanical strength mechanisms of hierarchical biological materials and tissues," Computer Methods in Biomechanics and Biomedical Engineering, Taylor & Francis Journals, vol. 11(6), pages 595-607.
    3. Sawako Yamashiro & David M. Rutkowski & Kelli Ann Lynch & Ying Liu & Dimitrios Vavylonis & Naoki Watanabe, 2023. "Force transmission by retrograde actin flow-induced dynamic molecular stretching of Talin," Nature Communications, Nature, vol. 14(1), pages 1-14, December.

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