Nanoscale origins of spider dragline mechanical properties

Jessika E. Trancik, Jan T. Czernuszka, Fraser I. Bell, Christopher Viney

Research output: Contribution to journalArticle

Abstract

Several mechanical models, in which a material is treated as a composite of crystalline and amorphous and/or interphase material, were used to predict the tensile modulus of spider dragline along the fiber direction. The models included the Voigt average (which assumes that the fibers/crystals are continuous, and that the strain is the same in all components of the composite); a modified Halpin-Tsai model (which is suitable for predicting the longitudinal elastic modulus for short aligned fiber composites, and is thus more appropriate for silk); and the shear-lag or Cox model (which is a modification of the Voigt average that takes into account a discontinuous nature of stiff fibers/crystals and the resulting shear stress in the amorphous matrix). The latter two models yielded close approximations of an experimentally measured elastic modulus of Latrodectus hesperus (black widow spider) dragline under conditions of controlled temperature and humidity, given realistic inputs for the moduli of the individual components and the percent crystallinity. A literature model for the stress-strain behavior of silk was also considered, in the context of our experimental results from transmission electron microscopy (TEM) and X-ray diffraction (XRD) studies of L. hesperus dragline. TEM and XRD results indicated a bimodal size distribution of ordered regions; one population of crystals has a mean size of 2 nm, and another spans the size range 40-120 nm. The average elastic modulus measured from L. hesperus dragline is 23 GPa - close to the 25 GPa theoretical modulus for the case of large crystals in Termonia's model. The tensile strength of L. hesperus dragline is ca. 1.7 GPa, close to the case predicted for small crystals in Termonia's model. A combination of the small and large crystals could explain the forced elongation behavior of L. hesperus dragline. © 2005 Materials Research Society.

Original languageEnglish
Article numberY4.7
Pages (from-to)131-136
Number of pages6
JournalMRS Online Proceedings Library
Volume844
Publication statusPublished - 2005
EventMechanical Properties of Bioinspired and Biological Materials - Boston, MA, United States
Duration: 29 Nov 20042 Dec 2004

Fingerprint

spiders
mechanical properties
crystals
modulus of elasticity
silk
fibers
transmission electron microscopy
composite materials
fiber composites
diffraction
tensile strength
shear stress
elongation
humidity
crystallinity
x rays
time lag
shear

Cite this

Trancik, J. E., Czernuszka, J. T., Bell, F. I., & Viney, C. (2005). Nanoscale origins of spider dragline mechanical properties. MRS Online Proceedings Library, 844, 131-136. [Y4.7].
Trancik, Jessika E. ; Czernuszka, Jan T. ; Bell, Fraser I. ; Viney, Christopher. / Nanoscale origins of spider dragline mechanical properties. In: MRS Online Proceedings Library. 2005 ; Vol. 844. pp. 131-136.
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Trancik, JE, Czernuszka, JT, Bell, FI & Viney, C 2005, 'Nanoscale origins of spider dragline mechanical properties', MRS Online Proceedings Library, vol. 844, Y4.7, pp. 131-136.

Nanoscale origins of spider dragline mechanical properties. / Trancik, Jessika E.; Czernuszka, Jan T.; Bell, Fraser I.; Viney, Christopher.

In: MRS Online Proceedings Library, Vol. 844, Y4.7, 2005, p. 131-136.

Research output: Contribution to journalArticle

TY - JOUR

T1 - Nanoscale origins of spider dragline mechanical properties

AU - Trancik, Jessika E.

AU - Czernuszka, Jan T.

AU - Bell, Fraser I.

AU - Viney, Christopher

PY - 2005

Y1 - 2005

N2 - Several mechanical models, in which a material is treated as a composite of crystalline and amorphous and/or interphase material, were used to predict the tensile modulus of spider dragline along the fiber direction. The models included the Voigt average (which assumes that the fibers/crystals are continuous, and that the strain is the same in all components of the composite); a modified Halpin-Tsai model (which is suitable for predicting the longitudinal elastic modulus for short aligned fiber composites, and is thus more appropriate for silk); and the shear-lag or Cox model (which is a modification of the Voigt average that takes into account a discontinuous nature of stiff fibers/crystals and the resulting shear stress in the amorphous matrix). The latter two models yielded close approximations of an experimentally measured elastic modulus of Latrodectus hesperus (black widow spider) dragline under conditions of controlled temperature and humidity, given realistic inputs for the moduli of the individual components and the percent crystallinity. A literature model for the stress-strain behavior of silk was also considered, in the context of our experimental results from transmission electron microscopy (TEM) and X-ray diffraction (XRD) studies of L. hesperus dragline. TEM and XRD results indicated a bimodal size distribution of ordered regions; one population of crystals has a mean size of 2 nm, and another spans the size range 40-120 nm. The average elastic modulus measured from L. hesperus dragline is 23 GPa - close to the 25 GPa theoretical modulus for the case of large crystals in Termonia's model. The tensile strength of L. hesperus dragline is ca. 1.7 GPa, close to the case predicted for small crystals in Termonia's model. A combination of the small and large crystals could explain the forced elongation behavior of L. hesperus dragline. © 2005 Materials Research Society.

AB - Several mechanical models, in which a material is treated as a composite of crystalline and amorphous and/or interphase material, were used to predict the tensile modulus of spider dragline along the fiber direction. The models included the Voigt average (which assumes that the fibers/crystals are continuous, and that the strain is the same in all components of the composite); a modified Halpin-Tsai model (which is suitable for predicting the longitudinal elastic modulus for short aligned fiber composites, and is thus more appropriate for silk); and the shear-lag or Cox model (which is a modification of the Voigt average that takes into account a discontinuous nature of stiff fibers/crystals and the resulting shear stress in the amorphous matrix). The latter two models yielded close approximations of an experimentally measured elastic modulus of Latrodectus hesperus (black widow spider) dragline under conditions of controlled temperature and humidity, given realistic inputs for the moduli of the individual components and the percent crystallinity. A literature model for the stress-strain behavior of silk was also considered, in the context of our experimental results from transmission electron microscopy (TEM) and X-ray diffraction (XRD) studies of L. hesperus dragline. TEM and XRD results indicated a bimodal size distribution of ordered regions; one population of crystals has a mean size of 2 nm, and another spans the size range 40-120 nm. The average elastic modulus measured from L. hesperus dragline is 23 GPa - close to the 25 GPa theoretical modulus for the case of large crystals in Termonia's model. The tensile strength of L. hesperus dragline is ca. 1.7 GPa, close to the case predicted for small crystals in Termonia's model. A combination of the small and large crystals could explain the forced elongation behavior of L. hesperus dragline. © 2005 Materials Research Society.

M3 - Article

VL - 844

SP - 131

EP - 136

JO - MRS Online Proceedings Library

JF - MRS Online Proceedings Library

SN - 0272-9172

M1 - Y4.7

ER -

Trancik JE, Czernuszka JT, Bell FI, Viney C. Nanoscale origins of spider dragline mechanical properties. MRS Online Proceedings Library. 2005;844:131-136. Y4.7.