Séminaire SIMM - Meng Wang (Hebrew University)

Jeudi 12 octobre de 14h00 à 15h00 - Charpak

Meng Wang (Racha Institute of Physics, Hebrew University of Jerusalem, Israel)
Supershear cracks in Tensile Fracture : How fast can materials break ?

Brittle materials fail by means of rapid cracks. At their tips, tensile cracks dissipate elastic energy stored in the surrounding material to create newly fractured surfaces, precisely maintaining `energy balance' by exactly equating the energy flux with dissipation. Using energy balance, fracture mechanics perfectly describes crack motions ; accelerating from nucleation to their maximal speed of c_R, the Rayleigh wave speed. Beyond c_R, tensile fracture is generally considered to be impossible [1], [2].
Recently, the potential emergence of an entirely new branch of fracture that is not incorporated in classical fracture mechanics has been predicted in lattice models to occur at high applied stretch [3], [4]. This theory predicts tensile cracks that are able to exceed the shear wave velocity, c_s, and potentially even the dilatation waves speed, c_p [5]. Here, by the use of brittle hydrogels, we experimentally demonstrate that such a wholly new and different class of tensile cracks indeed exists. We demonstrate that their dynamics are not governed by the principle of energy balance, the cornerstone of the classical theory of fracture. This new branch of cracks smoothly surpasses c_s to reach unprecedented speeds that approach the speed of dilatation waves. The transition from `classical' cracks to these `supershear' cracks takes place at critical values of applied strains. We, furthermore, show that the values of these, rather moderate (18-20%), critical strains are intimately related to the microscopic material structure. While it is still unclear whether this intriguing fracture mode is indeed that predicted theoretically by Marder [3], it is clear that these extreme tensile cracks have never before been clearly observed in experiments. This new mode of tensile fracture represents a fundamental paradigm shift in our understanding of ‘how things break'.

[1] L. B. Freund, Dynamic fracture mechanics. Cambridge university press (1998).
[2] K. B. Broberg, Cracks and Fracture. Academic Press (1999).
[3] M. Marder, Supersonic Rupture of Rubber, J. Mech. Phys. Solids, 54, 491–532 (2006).
[4] T. M. Guozden, E. A. Jagla, and M. Marder, Supersonic cracks in lattice models, Int. J. Fract., 162, 107–125 (2010).
[5] C. Behn and M. Marder, The transition from subsonic to supersonic cracks, Philos. Transact. A Math. Phys. Eng. Sci., 373, 20140122 (2015).

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Sciences et Ingénierie de la Matière Molle - UMR 7615

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