Stroh formalism in analysis of skew-symmetric and symmetric weight functions for interfacial cracks

Abstract

The focus of the paper is on the analysis of skew-symmetric weight functions for interfacial cracks in two-dimensional anisotropic solids. It is shown that the Stroh formalism proves to be an efficient tool for this challenging task. Conventionally, the weight functions, both symmetric and skew-symmetric, can be identified as non-trivial singular solutions of a homogeneous boundary-value problem for a solid with a crack. For a semi-infinite crack, the problem can be reduced to solving a matrix Wiener–Hopf functional equation. Instead, the Stroh matrix representation of displacements and tractions, combined with a Riemann–Hilbert formulation, is used to obtain an algebraic eigenvalue problem, which is solved in a closed form. The proposed general method is applied to the case of a quasi-static semi-infinite crack propagating between two dissimilar orthotropic media: explicit expressions for the weight functions are evaluated and then used in the computation of the complex stress intensity factor corresponding to a general distribution of forces acting on the crack faces.

Keywords

Interfacial crack Riemann–Hilbert problem Stroh formalism weight functions stress intensity factor

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References

Bercial-Velez

Antipov

Movchan

. High-order asymptotics and perturbation problems for 3D interfacial cracks. J Mech Phys Solids 2005; 53: 1128–1162.

Mishuris

Kuhn

. Asymptotic behaviour of the elastic solution near the tip of a crack situated at a nonideal interface. Z Angew Math Mech 2001; 81: 811–826.

Bueckner

. Weight functions and fundamental fields for the penny-shaped and the half plane crack in three-space. Int J Solids Struct 1985; 23: 57–93.

Bueckner

. Observations on weight functions. Eng Anal Bound Elem 1989; 6: 3–18.

Meade

Keer

. On the problem of a pair of point forces applied to the faces of a semi-infinite plane crack. J Elasticity 1984; 14: 3–14.

Lazarus

Leblond

. Three-dimensional crack-face weight functions for the semi-infinite interface crack-I: variation of the stress intensity factors due to some small perturbation of the crack front. J Mech Phys Solids 1998; 46: 489–511.

Piccolroaz

Mishuris

Movchan

. Symmetric and skew symmetric weight functions in 2D perturbation models for semi-infinite interfacial cracks. J Mech Phys Solids 2009; 57: 1657–1682.

Piccolroaz

Mishuris

Movchan

. Perturbation of mode III interfacial cracks. Int J Fract 2010; 166: 41–51.

Willis

Movchan

. Dynamic weight function for a moving crack. I. Mode I loading. J Mech Phys Solids 1995; 43: 319–341.

10.

Antipov

. An exact solution of the 3-D problem of an interface semi-infinite plane crack. J Mech Phys Solids 1999; 47: 1051–1093.

11.

Gao

. Weight function analysis for interface cracks: mis-mach versus oscillation. J Appl Mech 1991; 58: 931–938.

12.

Gao

. Weight function method for interfacial cracks in anisotropic bimaterials. Int J Fract 1992; 56: 139–158.

13.

Chen

. Weight functions for interface cracks in dissimilar anisotropic materials. Acta Mech Sin 2004; 20: 82–88.

14.

Stroh

. Steady state problems in anisotropic elasticity. J Math Phys 1962; 41: 77–103.

15.

Suo

. Singularities, interfaces and cracks in dissimilar anisotropic media. Proc R Soc Lond A 1990; 427: 331–358.

16.

Piccolroaz

Mishuris

. Integral identities for a semi-infinite interfacial crack in 2D and 3D elasticity. Preprint (2011) ArXiv: 11103612v1.

17.

Piccolroaz

Mishuris

Movchan

. Evaluation of the Lazarus–Leblond constants in the asymptotic model for the interfacial wavy crack. J Mech Phys Solids 2007; 55: 1575–1600.

18.

Lekhnitskii

. Theory of Elasticity of an Anisotropic Body. San Francisco, CA: Holden-Day, 1963.

19.

Ting

. Anisotropic Elasticity: Theory and Applications. Oxford: Oxford University Press, 1996.

20.

Suo

Kuo

Barnett

Willis

. Fracture mechanics for piezoelectric ceramics. J Mech Phys Solids 1992; 40: 739–765.

21.

Gao

Abbudi

Barnett

. Interfacial crack-tip field in anisotropic elastic solids. J Mech Phys Solids 1992; 40: 393–416.

22.

Hwu

. Relations among Stroh, Lekhnitskii and Muskhelishvili formulations. In: Proceedings of the 10th National Conference on Mechanical Engineering, Taipei, Taiwan, R.O.C., 1993, pp. 517–525.

23.

Dundurs

. Discussion of a paper by D. B. Bogy. J Appl Mech 1969; 36: 650–652.

24.

Radi

Mariano

. Stationary straight cracks in quasicrystals. Int J Fract 2010; 166: 105–120.

25.

Radi

Mariano

. Dynamic steady-state crack propagation in quasicrystals. Math. Meth. Appl. Sci. 2011; 34: 1–23.

26.

Gautier

Kelders

Groby

Dazel

De Ryck

Leclaire

. Propagation of acoustic waves in a one-dimensional macroscopically inhomogeneous poroelastic material. J Acoust Soc Am 2011; 130: 1390–1398.