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Dynamical Fracture Instabilities Due to Local Hyperelasticity at Crack Tips

Published online by Cambridge University Press:  01 February 2011

Markus J. Buehler
Affiliation:
[email protected], Massachusetts Institute of Technology, Civil and Environmental Engrg., 77 Mass. Ave Room 1-272, Cambridge, MA, 02139, United States, 617 452 2750
Huajian Gao
Affiliation:
[email protected], Brown University, Division of Engineering, Rhode Island, 02912, United States
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Abstract

When materials break and cracks propagate, bonds between atoms are broken generating two new material surfaces. Most existing theories of fracture assume a linear elastic stress-strain law. However, the relation between stress and strain in real solids is strongly nonlinear due to large deformation near a moving crack tip, a phenomenon referred to as hyperelasticity or nonlinear elasticity. Cracks moving at low speeds create atomically flat mirror-like surfaces, whereas cracks at higher speeds leave misty and hackly fracture surfaces. This change in fracture surface morphology is a universal phenomenon found in a wide range of different brittle materials, but the underlying physical reason has been debated over an extensive period. Using massively parallel large-scale atomistic simulations employing a new, simple atomistic material model allowing a systematic transition from linear elastic to strongly nonlinear material behaviors, we show that hyperelasticity can play a governing role in dynamical crack tip instabilities in fracture of brittle materials. We report a generalized model that treats the instability problem as a competition between different mechanisms controlled by local stress field and local energy flow near the crack tip. Our results indicate that the fracture instabilities do not only appear in defected materials, but instead are an intrinsic phenomenon of dynamical fracture. Our findings help to explain controversial experimental and computational results, including experimental observation of crack propagation at speeds beyond the shear wave speed in rubber-like materials.

Type
Research Article
Copyright
Copyright © Materials Research Society 2006

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