A magnetoelectroelastic medium with an elliptical cavity under combined mechanical–electric–magnetic loading

The solution for an elliptical cavity in an infinite two-dimensional magnetoelectroelastic medium subject to remotely uniformly applied combined mechanical–electric–magnetic loadings is obtained by using the Stroh formalism and the exact boundary conditions along the surface of the cavity. By lettin...

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Published inTheoretical and applied fracture mechanics Vol. 45; no. 3; pp. 227 - 237
Main Authors Zhao, M.H., Wang, H., Yang, F., Liu, T.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier Ltd 01.06.2006
Elsevier
Subjects
Crack
Elliptic cavity
Exact sciences and technology
Exact solution
Fracture mechanics (crack, fatigue, damage...)
Fundamental areas of phenomenology (including applications)
Magnetoelectroelastic medium
Physics
Self-consistent method
Solid mechanics
Static elasticity (thermoelasticity...)
Strain energy density factor
Structural and continuum mechanics
Self-consistent method
Magnetoelectroelastic medium
Elliptic cavity
Strain energy density factor
Crack
Exact solution
Self consistency
Barium titanates
Modeling
Composite material
Combined load
Ferrite
Infinite medium
Cavity
Magnetic field
Magnetoelastic effect
Surface conditions
Crack array
Magnetostriction
Strain energy
Energy density
Multiaxial load
Electroelasticity
Stroh formalism
Piezoelectric materials
Magnetomechanical properties
Cobalt compound
Electromechanical properties
Online AccessGet full text
ISSN0167-8442
1872-7638
DOI10.1016/j.tafmec.2006.03.006

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Abstract The solution for an elliptical cavity in an infinite two-dimensional magnetoelectroelastic medium subject to remotely uniformly applied combined mechanical–electric–magnetic loadings is obtained by using the Stroh formalism and the exact boundary conditions along the surface of the cavity. By letting the minor-axis of the cavity to zero the solution for a crack is deduced. A self-consistent method is proposed to calculate the real crack opening under the combined mechanical–electric–magnetic loadings. The method requires that the crack opening is the minor-axis of the elliptical opening profile. Beside the real crack solution, four different extreme models, i.e., the impermeable crack, permeable crack, electrically impermeable and magnetically permeable crack and electrically permeable and magnetically impermeable crack, are discussed. An expression of the strain energy density factor is derived. Numerical results of the strain energy density at the crack tip are given for a BaTiO 3–CoFe 2O 4 composite with the piezoelectric BaTiO 3 material being the inclusion and the magnetostrictive CoFe 2O 4 material being the matrix. The effects of the proportion of the two phases, permeability of the crack to electric and magnetic fields, the electric and magnetic loadings on the strain energy density factor are discussed.
AbstractList The solution for an elliptical cavity in an infinite two-dimensional magnetoelectroelastic medium subject to remotely uniformly applied combined mechanical-electric-magnetic loadings is obtained by using the Stroh formalism and the exact boundary conditions along the surface of the cavity. By letting the minor-axis of the cavity to zero the solution for a crack is deduced. A self-consistent method is proposed to calculate the real crack opening under the combined mechanical-electric-magnetic loadings. The method requires that the crack opening is the minor-axis of the elliptical opening profile. Beside the real crack solution, four different extreme models, i.e., the impermeable crack, permeable crack, electrically impermeable and magnetically permeable crack and electrically permeable and magnetically impermeable crack, are discussed. An expression of the strain energy density factor is derived. Numerical results of the strain energy density at the crack tip are given for a BaTiO3-CoFe2O4 composite with the piezoelectric BaTiO3 material being the inclusion and the magnetostrictive CoFe2O4 material being the matrix. The effects of the proportion of the two phases, permeability of the crack to electric and magnetic fields, the electric and magnetic loadings on the strain energy density factor are discussed.
The solution for an elliptical cavity in an infinite two-dimensional magnetoelectroelastic medium subject to remotely uniformly applied combined mechanical–electric–magnetic loadings is obtained by using the Stroh formalism and the exact boundary conditions along the surface of the cavity. By letting the minor-axis of the cavity to zero the solution for a crack is deduced. A self-consistent method is proposed to calculate the real crack opening under the combined mechanical–electric–magnetic loadings. The method requires that the crack opening is the minor-axis of the elliptical opening profile. Beside the real crack solution, four different extreme models, i.e., the impermeable crack, permeable crack, electrically impermeable and magnetically permeable crack and electrically permeable and magnetically impermeable crack, are discussed. An expression of the strain energy density factor is derived. Numerical results of the strain energy density at the crack tip are given for a BaTiO 3–CoFe 2O 4 composite with the piezoelectric BaTiO 3 material being the inclusion and the magnetostrictive CoFe 2O 4 material being the matrix. The effects of the proportion of the two phases, permeability of the crack to electric and magnetic fields, the electric and magnetic loadings on the strain energy density factor are discussed.
Author Wang, H.
Liu, T.
Zhao, M.H.
Yang, F.
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Issue 3
Keywords Self-consistent method
Magnetoelectroelastic medium
Elliptic cavity
Strain energy density factor
Crack
Exact solution
Self consistency
Barium titanates
Modeling
Composite material
Combined load
Ferrite
Infinite medium
Cavity
Magnetic field
Magnetoelastic effect
Surface conditions
Crack array
Magnetostriction
Strain energy
Energy density
Multiaxial load
Electroelasticity
Stroh formalism
Piezoelectric materials
Magnetomechanical properties
Cobalt compound
Electromechanical properties
Language English
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Snippet The solution for an elliptical cavity in an infinite two-dimensional magnetoelectroelastic medium subject to remotely uniformly applied combined...
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SubjectTerms Crack
Elliptic cavity
Exact sciences and technology
Exact solution
Fracture mechanics (crack, fatigue, damage...)
Fundamental areas of phenomenology (including applications)
Magnetoelectroelastic medium
Physics
Self-consistent method
Solid mechanics
Static elasticity (thermoelasticity...)
Strain energy density factor
Structural and continuum mechanics
Title A magnetoelectroelastic medium with an elliptical cavity under combined mechanical–electric–magnetic loading
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