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Journal of Elasticity

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05-01-2023

Dynamic Concentrations and Potentials of Embedded Eccentrically Coated Magneto-Electro-Elastic Fiber Subjected to Anti-Plane Shear Waves

Authors: H. M. Shodja, A. Ordookhani, A. Tehranchi

Published in: Journal of Elasticity | Issue 1/2023

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Abstract

This paper examines the problem of the fully coupled magneto-electro-elastic (MEE) scattering of SH-waves incident upon a heterogeneous MEE scatterer which is embedded in an unbounded medium. The scatterer consists of a circular core and a circular encapsulator with eccentricity. All three regions: the core, encapsulator, and the surrounding matrix have distinct MEE properties and fully coupled constitutive relations. The generated coupled MEE fields coexist simultaneously in all these regions without resort to any simplifying assumptions. The precise description of the multifunctionality involves the solution of three fully coupled partial differential equations in three different regions. The associated Green’s function equations involve 9 independent components of Green’s functions. The behaviors of the regions are described by the generalized constitutive equations suitable for transversely isotropic MEE properties. Conventionally, wave function approach has been used to study the elastodynamic fields associated with the purely elastic axisymmetric problems; such a treatment encounters serious difficulties in the presence of eccentricity. As a rigorous analytical remedy the dynamic magneto-electro-mechanical equivalent inclusion method (DMEMEIM) will be developed in this work. To this end, the notions of eigenstress, eigenbody-force, eigenelectric, and eigenmagnetic fields will be introduced. As it will be shown, the employment of these notions in conjunction with the eigenfunction space of the pertinent coupled field equations provides a meticulous mathematical framework for the treatment of the proposed problem. The exact analytical formulation for the fully coupled total MEE scattering cross-section is derived. The ramifications of the MEE couplings as well as the wavenumber on the induced scattered fields are considered. As it will be seen, the magnetic field has a substantial effect on the total scattering cross-section. The interfacial stresses are remarkably affected not only by the eccentricity, but also by the magnetic parameters. Moreover, the dynamic electric displacement concentration factor (DEDCF), the dynamic stress concentration factor (DSCF), the electric potential, and the magnetic potential will be examined for different wavenumbers.

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Barratt, P., Collins, W.: The scattering cross-section of an obstacle in an elastic solid for plane harmonic waves. In: Mathematical Proceedings of the Cambridge Philosophical Society, vol. 61, pp. 969–981. Cambridge University Press, Cambridge (1965)

Bing, J., Daining, F., Kehchih, H.: The effective properties of piezocomposites, part I: single inclusion problem. Acta Mech. Sin. 13(4), 339–346 (1997) CrossRef

Chen, P., Shen, Y.: Propagation of axial shear magneto–electro-elastic waves in piezoelectric–piezomagnetic composites with randomly distributed cylindrical inhomogeneities. Int. J. Solids Struct. 44(5), 1511–1532 (2007) MATHCrossRef

Chen, P., Shen, Y., Tian, X.: Dynamic potentials and Green’s functions of a quasi-plane magneto-electro-elastic medium with inclusion. Int. J. Eng. Sci. 44(8–9), 540–553 (2006) MATHCrossRef

Dunn, M.L., Wienecke, H.: Inclusions and inhomogeneities in transversely isotropic piezoelectric solids. Int. J. Solids Struct. 34(27), 3571–3582 (1997) MATHCrossRef

Eringen, A.C., Suhubi, E.S.: Elastodynamics. Vol II. Academic Press, New York (1975) MATH

Eshelby, J.D.: The determination of the elastic field of an ellipsoidal inclusion, and related problems. Proc. R. Soc. Lond. Ser. A, Math. Phys. Sci. 241(1226), 376–396 (1957) MATH

Eshelby, J.D.: Elastic inclusion and inhomogeneities. Prog. Solid Mech. 2, 89–140 (1961)

Fan, H., Qin, S.: A piezoelectric sensor embedded in a non-piezoelectric matrix. Int. J. Eng. Sci. 33(3), 379–388 (1995) MATHCrossRef

10.

Fang, X.Q., Hu, C., Huang, W.H.: Dynamic stress of a circular cavity buried in a semi-infinite functionally graded piezoelectric material subjected to shear waves. Eur. J. Mech. A, Solids 26(6), 1016–1028 (2007) MATHCrossRef

11.

Fu, L.S., Mura, T.: The determination of the elastodynamic fields of an ellipsoidal inhomogeneity. J. Appl. Mech. 50(2), 390–396 (1983) MATHCrossRef

12.

Furuhashi, R., Mura, T.: On the equivalent inclusion method and impotent eigenstrains. J. Elast. 9(3), 263–270 (1979) CrossRef

13.

Hashemi, R., Weng, G., Kargarnovin, M., Shodja, H.: Piezoelectric composites with periodic multi-coated inhomogeneities. Int. J. Solids Struct. 47(21), 2893–2904 (2010) MATHCrossRef

14.

Hori, M., Nemat-Nasser, S.: Double-inclusion model and overall moduli of multi-phase composites. Mech. Mater. 14(3), 189–206 (1993) CrossRef

15.

Jin, X., Wang, Z., Zhou, Q., Keer, L.M., Wang, Q.: On the solution of an elliptical inhomogeneity in plane elasticity by the equivalent inclusion method. J. Elast. 114(1), 1–18 (2014) MATHCrossRef

16.

Kuo, H.Y., Yu, S.H.: Effect of the imperfect interface on the scattering of SH wave in a piezoelectric cylinder in a piezomagnetic matrix. Int. J. Eng. Sci. 85, 186–202 (2014) CrossRef

17.

Levin, V.M., Michelitsch, T.M., Gao, H.: Propagation of electroacoustic waves in the transversely isotropic piezoelectric medium reinforced by randomly distributed cylindrical inhomogeneities. Int. J. Solids Struct. 39(19), 5013–5051 (2002) MATHCrossRef

18.

Li, J.Y., Dunn, M.L.: Anisotropic coupled-field inclusion and inhomogeneity problems. Philos. Mag. A 77(5), 1341–1350 (1998) CrossRef

19.

Li, J.Y., Dunn, M.L.: Micromechanics of magnetoelectroelastic composite materials: average fields and effective behavior. J. Intell. Mater. Syst. Struct. 9(6), 404–416 (1998) CrossRef

20.

Li, Y.D., Lee, K.Y., Zhang, N.: A generalized hypergeometric function method for axisymmetric vibration analysis of a piezoelectric actuator. Eur. J. Mech. A, Solids 31(1), 110–116 (2012) MATHCrossRef

21.

Liu, W., Kriz, R.D.: Axial shear waves in fiber-reinforced composites with multiple interfacial layers between fiber core and matrix. Mech. Mater. 31(2), 117–129 (1999) CrossRef

22.

Michelitsch, T.M., Gao, H., Levin, V.M.: Dynamic Eshelby tensor and potentials for ellipsoidal inclusions. Proc. R. Soc. Lond., Ser. A, Math. Phys. Eng. Sci. 459(2032), 863–890 (2003) MATHCrossRef

23.

Mikata, Y.: Determination of piezoelectric Eshelby tensor in transversely isotropic piezoelectric solids. Int. J. Eng. Sci. 38(6), 605–641 (2000) MATHCrossRef

24.

Mikata, Y., Nemat-Nasser, S.: Interaction of a harmonic wave with a dynamically transforming inhomogeneity. J. Appl. Phys. 70(4), 2071–2078 (1991) CrossRef

25.

Mura, T.: General Theory of Eigenstrains. Micromechanics of Defects in Solids, pp. 1–62. Springer, Berlin (1982) CrossRef

26.

Mura, T.: Inclusion problems. Appl. Mech. Rev. 41(1), 15–20 (1988) CrossRef

27.

Mura, T., Shodja, H.M., Hirose, Y.: Inclusion problems. Appl. Mech. Rev. 49(10S), S118–S127 (1996) CrossRef

28.

Nan, C.-W.: Magnetoelectric effect in composites of piezoelectric and piezomagnetic phases. Phys. Rev. B 50(9), 6082 (1994) CrossRef

29.

Pao, Y.H., Mow, C.: Scattering of plane compressional waves by a spherical obstacle. J. Appl. Phys. 34(3), 493–499 (1963) MATHCrossRef

30.

Porter, R.: Plate arrays as a perfectly-transmitting negative-refraction metamaterial. Wave Motion 1(100), 102673 (2021) MATHCrossRef

31.

Sarvestani, A., Shodja, H., Delfani, M.: Determination of the scattered fields of an SH-wave by an eccentric coating-fiber ensemble using DEIM. Int. J. Eng. Sci. 46(11), 1136–1146 (2008) MATHCrossRef

32.

Sato, H., Shindo, Y.: Multiple scattering of plane elastic waves in a fiber-reinforced composite medium with graded interfacial layers. Int. J. Solids Struct. 38(15), 2549–2571 (2001) MATHCrossRef

33.

Shindo, Y., Nozaki, H., Datta, S.: Effect of Interface Layers on Elastic Wave Propagation in a Metal Matrix Composite Reinforced by Particles (1995) CrossRef

34.

Shindo, Y., Niwa, N., Togawa, R.: Multiple scattering of antiplane shear waves in a fiber-reinforced composite medium with interfacial layers. Int. J. Solids Struct. 35(7–8), 733–745 (1998) MATHCrossRef

35.

Shodja, H., Delfani, M.: 3D elastodynamic fields of non-uniformly coated obstacles: notion of eigenstress and eigenbody-force fields. Mech. Mater. 41(9), 989–999 (2009) CrossRef

36.

Shodja, H.M., Shokrolahi-Zadeh, B.: Ellipsoidal domains: piecewise nonuniform and impotent eigenstrain fields. J. Elast. 86(1), 1–18 (2007) MATHCrossRef

37.

Shodja, H., Kargarnovin, M., Hashemi, R.: Electroelastic fields in interacting piezoelectric inhomogeneities by the electromechanical equivalent inclusion method. Smart Mater. Struct. 19(3), 035025 (2010) CrossRef

38.

Shodja, H.M., Jarfi, H., Rashidinejad, E.: The electro-elastic scattered fields of an SH-wave by an eccentric two-phase circular piezoelectric sensor in an unbounded piezoelectric medium. Mech. Mater. 75, 1–12 (2014) CrossRef

39.

Van Suchtelen, J.: Product properties: a new application of composite materials. Philips Res. Rep. 27(1), 28–37 (1972)

40.

Wang, J., Michelitsch, T.M., Gao, H., Levin, V.M.: On the solution of the dynamic Eshelby problem for inclusions of various shapes. Int. J. Solids Struct. 42(2), 353–363 (2005) MATHCrossRef

41.

Xiao, Z., Bai, J.: On piezoelectric inhomogeneity related problem—part I: a close-form solution for the stress field outside a circular piezoelectric inhomogeneity. Int. J. Eng. Sci. 37(8), 945–959 (1999) CrossRef

42.

Zhou, K., Hoh, H.J., Wang, X., Keer, L.M., Pang, J.H., Song, B., Wang, Q.J.: A review of recent works on inclusions. Mech. Mater. 60, 144–158 (2013) CrossRef

Title: Dynamic Concentrations and Potentials of Embedded Eccentrically Coated Magneto-Electro-Elastic Fiber Subjected to Anti-Plane Shear Waves
Authors: H. M. Shodja
A. Ordookhani
A. Tehranchi
Publication date: 05-01-2023
Publisher: Springer Netherlands
Published in: Journal of Elasticity / Issue 1/2023
Print ISSN: 0374-3535
Electronic ISSN: 1573-2681
DOI: https://doi.org/10.1007/s10659-022-09967-4

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Other articles of this Issue 1/2023

Acknowledgment and Editorial Transition

Lung Mechanics: A Review of Solid Mechanical Elasticity in Lung Parenchyma

A Remark on Stress of a Spatially Uniform Dislocation Density Field

A Boundary-Field Formulation for Elastodynamic Scattering

Editorial

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