Localised knife waves in a structured interface |
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| Authors: | Gennady S. Mishuris Alexander B. Movchan Leonid I. Slepyan |
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| Affiliation: | aInstitute of Mathematics and Physics, Aberystwyth University, UK;bDepartment of Mathematical Sciences, University of Liverpool, UK;cSchool of Mechanical Engineering, Tel Aviv University, Israel |
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| Abstract: | We consider a Mode III lattice with an interface layer where the dynamic crack growth is caused by a localised sinusoidal wave. In the wave–fracture scenario, the ‘feeding wave’ (here also called the knife wave) delivers energy to the moving crack front, while the dissipative waves carry a part of this energy away from the front. The questions addressed here are:- • What are the conditions of existence of the localised knife wave?
- • What is the lower bound of the amplitude of the feeding wave, which supports the crack propagation, for a given deformational fracture criterion?
- • How does the crack speed depend on the amplitude of the feeding wave?
- • What are the dissipative waves? How much energy is irradiated by these waves and what is the total dissipation?
- • What are the conditions of existence of the steady-state regime for the propagating crack?
We consider analytically two established regimes: the steady-state regime, where the motion of neighbouring masses (along the interface) differs only by a constant shift in time, and an alternating-strain regime, where the corresponding amplitudes differ by sign. We also present the numerical simulation results for a model of a high-contrast interface structure. Along with the energy of the feeding and dissipative waves, an energy radiated to the bulk of the lattice is identified. Keywords: A. Dynamic fracture; A. Vibrations; B. Inhomogeneous material; B. Supersonic crack; C. Integral transforms |
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| Keywords: | A. Dynamic fracture A. Vibrations B. Inhomogeneous material B. Supersonic crack C. Integral transforms |
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