Sage Journals: Discover world-class research

Abstract

This paper presents a detailed analysis of an anti-plane crack problem in a polarized piezoelectric material layer, incorporating both strain and electric field gradient effects. The study focuses on an arbitrarily oriented crack and considers the influence of the polarization direction. The crack face boundary is assumed to be semi-permeable, with electrical and mechanical loads applied at the layer boundary. Two characteristic length parameters, $l_{1}$ and $l_{2}$ , are introduced to capture the strain gradient and electric field gradient effects, respectively. The governing equations along with the relevant boundary conditions are derived. By applying the eigenfunction expansion technique, the singularity index is established. The Fourier transform is then utilized to transform the problem into a hypersingular integral equation. This equation is solved numerically using the Chebyshev series approach. The closed-form analytical expressions are presented for various fracture parameters, including the crack sliding displacement, crack opening potential drop, stress intensity factor, electric displacement intensity factor, and electric crack condition parameter (ECCP). The Bisection method is used to demonstrate the convergence of ECCP. An illustrative numerical case study is presented for these fracture parameters to show the effect of polarization direction, orientation of the crack, intrinsic characteristic lengths, and applied loads.

Keywords

Piezoelectric materials strain gradient electric field gradient semi-permeable boundary condition fourier transform

Get full access to this article

View all access options for this article.

References

Parton

Fracture mechanics of piezoelectric materials. Acta Astronaut 1976; 3: 671–683.

Deeg

The analysis of dislocation, crack, and inclusion problems in piezoelectric solids. PhD Thesis, Stanford University, Stanford, CA, 1980.

Sosa

Plane problems in piezoelectric media with defect. Int J Solids Struct 1991; 28: 491–505.

Pak

Circular inclusion problem in anti-plane piezoelectricity. Int J Solids Struct 1992; 29: 2403–2419.

Bhargava

Jangid

Strip-coalesced interior zone model for two unequal collinear cracks weakening piezoelectric media. Appl Math Mech 2014; 35(10): 1249–1260.

Sharma

Singh

Bui

Simplified numerical algorithms for generalized strip saturated two equal collinear cracks in piezoelectric media using distributed dislocation technique. ZAMM-J Appl Math Mech 2023; 103(11): e202300004.

Singh

Jangid

A numerical solution for the interior electric displacement of the moving DBY-PS model for semi-permeable cracked piezoelectric material. Z Angew Math Mech 2024; 104: e202400361.

Mindlin

Tiersten

Effects of couple-stresses in linear elasticity. Arch Ration Mech Anal 1962; 11: 415–448.

Eringen

Suhubi

Nonlinear theory of simple micro-elastic solids I. Int J Eng Sci 1964; 2: 189–203.

10.

Eringen

Suhubi

Nonlinear theory of simple micro-elastic solids II. Int J Eng Sci 1964; 2: 389–404.

11.

Mindlin

Microstructure in linear elasticity. Arch Ration Mech Anal 1964; 16: 51–78.

12.

Mindlin

Eshel

On first strain-gradient theories in linear elasticity. Int J Solids Struct 1968; 4(1): 109–124.

13.

Gao

Park

Variational formulation of a simplified strain gradient elasticity theory and its application to a pressurized thick-walled cylinder problem. Int J Solids Struct 2007; 44: 7486–7499.

14.

Pan

Zhu

, et al. A thermodynamically consistent theory for flexoelectronics: interaction between strain gradient and electric current in flexoelectric semiconductors. Int J Eng Sci 2025; 208: 104165.

15.

Aifantis

On the role of gradients in the localization of deformation and fracture. Int J Eng Sci 1992; 30: 1279–1299.

16.

Aifantis

A simple approach to solve boundary-value problems in gradient elasticity. Acta Mech 1993; 101: 59–68.

17.

Lazar

Maugin

Aifantis

Dislocations in second strain gradient elasticity. Int J Solids Struct 2006; 43: 1787–1817.

18.

Lurie

Volkov-Bogorodsky

Leontiev

, et al. Eshelby’s inclusion problem in the gradient theory of elasticity: applications to composite materials. Int J Eng Sci 2011; 49: 1517–1525.

19.

Gao

Green’s function and Eshelby’s tensor based on a simplified strain gradient elasticity theory. Acta Mech 2009; 207: 163–181.

20.

Gao

Solution of Eshelby’s inclusion problem with a bounded domain and Eshelby’s tensor for a spherical inclusion in a finite spherical matrix based on a simplified strain gradient elasticity theory. J Mech Phys Solids 2010; 58: 779–797.

21.

Toupin

The elastic dielectric. J Ration Mech Anal 1956; 5: 849–915.

22.

Tiersten

On the nonlinear equations of thermoelectro-elasticity. Int J Eng Sci 1971; 9: 587–604.

23.

Majdoub

Sharma

Cagin

Enhanced size-dependent piezoelectricity and elasticity in nanostructures due to the flexoelectric effect. Phys Rev B 2008; 77: 125424.

24.

Shen

A theory of flexoelectricity with surface effect for elastic dielectrics. J Mech Phys Solids 2010; 58: 665–677.

25.

Mao

Purohit

Defects in flexoelectric solids. J Mech Phys Solids 2015; 84: 95–115.

26.

Mao

Purohit

Insights into flexoelectric solids from strain-gradient elasticity. J Appl Mech 2014; 81: 081004.

27.

Wang

Feng

A piezoelectric constitutive theory with rotation gradient effects. Eur J Mech-A/Solids 2004; 23: 455–466.

28.

Yang

Effects of electric field gradient on an anti-plane crack in piezoelectric ceramics. Int J Fract 2004; 127: L95–L100.

29.

Yang

Hang

Effects of electric field gradient on the mode-iii fracture in piezoelectric ceramics. Mech Res Commun 2004; 31: 345–350.

30.

Wang

Pan

Feng

Anti-plane green’s functions and cracks for piezoelectric material with couple stress and electric field gradient effects. Eur J Mech-A/Solids 2008; 27: 478–486.

31.

Yang

Zhou

Electric field gradient effects in an anti-plane circular inclusion in polarized ceramics. Proc R Soc Lond A 2006; 462: 3511–3522.

32.

Zhang

Fan

, et al. A non-classical theory of elastic dielectrics incorporating couple stress and quadrupole effects: part I – reconsideration of curvature-based flexoelectricity theory. Math Mech Solids 2021; 26(11): 1647–1659.

33.

Guo

Jin

, et al. A non-classical theory of elastic dielectrics incorporating couple stress and quadrupole effects: part II - variational formulations and applications in plates. Math Mech Solids 2022; 27(12): 2567–2587.

34.

Sladek

Wünsche

, et al. Effects of electric field and strain gradients on cracks in piezoelectric solids. Eur J Mech-A/Solids 2018; 71: 187–198.

35.

Sladek

Stanak

, et al. Fracture mechanics analysis of size-dependent piezoelectric solids. Int J Solids Struct 2017; 113–114: 1–9.

36.

Bhargava

Jangid

A study on influence of poling direction on piezoelectric plate weakened by two collinear semi-permeable cracks. Acta Mech 2014; 225: 109–129.

37.

Sharma

Jangid

Pak

The influence of bi-directional material gradation on a mode-III crack in functionally graded material via strain gradient elasticity theory. Eur J Mech-A/Solids 2024; 110: 105496.

The effects of strain and electric field gradients on an arbitrarily oriented semi-permeable crack in a polarized piezoelectric layer

Abstract

Keywords

Get full access to this article

References