The analysis of a mode I conducting crack under general applied loads in piezo-electro-magneto-elastic layer

Within the theory of linear magnetoelectroelasticity, the fracture analysis of a magneto-electrically limitedly permeable crack embedded in a magnetoelectroelastic layer is investigated. The prescribed normal stress and two cases of electromagnetic boundary conditions on the layer surfaces are adopted. Applying the Hankel transform technique, the boundary-value problem is reduced to solving three coupling Fredholm integral equations of second kind. These equations are solved exactly. The corresponding semi-permeable crack-face magnetoelectric boundary conditions are adopted and the electric displacement and magnetic induction of crack interior are obtained explicitly. This field inside the crack is dependent on the material properties, applied loadings, the dielectric permittivity and magnetic permeability of crack interior, and the ratio of the crack length and the layer thickness. Field intensity factors are obtained as explicit expressions.