Smooth waves and shocks of finite amplitude in soft materials

Ziv, Ron; Gal, Shmuel

doi:10.1016/j.mechmat.2019.05.002

Cited by 12 publications

(21 citation statements)

References 38 publications

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“…While perfect incompressibility allows us to impose an arbitrary normal traction σ n = P 22 that will be instantaneously equilibrated throughout the body (as seen from (10b)), in a compressible material, coupling between the longitudinal and shearing deformations might become significant (see for example Ziv and Shmuel (2019)). Plugging (2) into (10a) gives us the nonlinear wave equation…”

Section: Equation Of Motionmentioning

confidence: 99%

Shear shock evolution in incompressible soft solids

Chockalingam

Cohen

2020

Journal of the Mechanics and Physics of Solids

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Nonlinear evolution of shear waves into shocks in incompressible elastic materials is investigated using the framework of large deformation elastodynamics, for a family of loadings and commonly used hyperelastic material models. Closed form expressions for the shock formation distance are derived and used to construct non-dimensional phase maps that determine regimes in which a shock can be realized. These maps reveal the sensitivity of shock evolution to the amplitude, shape, and ramp time of the loading, and to the elastic material parameters. In light of a recent study (Espindola et al., 2017), which hypothesizes that shear shock formation could play a significant role in Traumatic Brain Injury (TBI), application to brain tissue is considered and it is shown that the size matters in TBI research. Namely, for realistic loadings, smaller brains are less susceptible to formation of shear shocks. Furthermore, given the observed sensitivity to the imparted waveform and the constitutive properties, it is suggested that the non-dimensional maps can guide the design of protective structures by determining the combination of loading parameters, material dimensions, and elastic properties that can avoid shock formation.

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Section: Equation Of Motionmentioning

confidence: 99%

Shear shock evolution in incompressible soft solids

Chockalingam

Cohen

2020

Journal of the Mechanics and Physics of Solids

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“…In this case, the slower velocity c − is a monotonically increasing function of the strains, and the corresponding wave is referred to as genuinely nonlinear. The faster velocity c + has local minima at certain strains (Ziv and Shmuel, 2019), and hence the corresponding wave is not genuinely nonlinear. In the following sections we focus on strains far from these local minima, such that this mode can be considered genuinely nonlinear.…”

Section: Governing Equationsmentioning

confidence: 99%

“…The left half-space is subjected to a shock wave for which the pre-shock state is unstrained and at rest, and its post-shock state is 0.2, 2.3, 2.6, −32.4). These initial conditions were chosen to generate four shock waves, for which we obtain numerical solutions using Newton's method, as described by Ziv and Shmuel (2019) and in Appendix A. Fi g. 4(a) shows the distribution of ǫ 1 (upper panel) and ǫ 2 (lower panel) across −0.4 m < X 1 < 0.6 m at t = 10 ms. The black line corresponds to the numerical solution of the exact equations.…”

Section: Finite Shock Scattering At the Interface Between Two Half-spmentioning

confidence: 99%

“…Highly deformable materials with architectured microstructure are nowadays accessible by virtue of the current manufacturing abilities (Bandyopadhyay et al, 2015, Truby and. These materials exhibit geometrical and constitutive nonlinearities that give rise to rich physics , and in particular diverse wave phenomena such as unidirectional transmission, shocks and self-reinforcing waves (Nadkarni et al, 2014, 2016, Samsonov et al, 2017, Ziv and Shmuel, 2019, Deng et al, 2019a, Katz and Givli, 2019. Waves in nonlinear solids have recently regained scientific and technological interest, owing to the realization that their features can be harnessed for various applications, such as signal transmission (Raney et al, 2016), impact mitigation (Yasuda et al, 2019), energy harvesting (Hwang and Arrieta, 2018) and mechanical diodes (Deng et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…The model we use to describe the nonlinear response of the media in our test cases is the compressible Gent model (Gent, 1996). This model-originally developed for capturing the strain stiffening of rubber at large strains-was recently shown useful by Ziv and Shmuel (2019) for modeling shear shocks that were experimentally observed by Catheline et al (2003), Espíndola et al (2017), and modeling tensile-induced shocks that were experimentally observed by Niemczura and Ravi-Chandar (2011).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Observation of vector solitary waves in soft laminates using a finite volume method

Ziv¹,

Gal²

2020

Preprint

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Soft materials with engineered microstructure support nonlinear waves which can be harnessed for various applications, from signal communication to impact mitigation. Such waves are governed by nonlinear coupled differential equations whose analytical solution is seldom trackable, hence emerges the need for suitable numerical solvers. Based on a finite-volume method in one space dimension, we here develop a designated scheme for nonlinear waves with two coupled components that propagate in soft laminates. We apply our scheme to a periodic laminate made of two alternating compressible Gent layers, and consider two cases. In one case, we analyze a motion whose component along the lamination direction is coupled to a component in the layers plane, and discover vector solitary waves in a continuum medium. In the second case, we analyze a motion with two coupled components in the plane of the layers, and observe a train of linearly polarized solitary waves, followed by a single circularly polarized wave. The framework we developed offers a platform for further investigation of these waves and their extension to higher dimensional problems.

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Review of exploiting nonlinearity in phononic materials to enable nonlinear wave responses

Patil

Matlack

2021

Acta Mech

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Smooth waves and shocks of finite amplitude in soft materials

Cited by 12 publications

References 38 publications

Shear shock evolution in incompressible soft solids

Shear shock evolution in incompressible soft solids

Observation of vector solitary waves in soft laminates using a finite volume method

Review of exploiting nonlinearity in phononic materials to enable nonlinear wave responses

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