A general magneto-electro-elastic 3D FE model for free vibration and dynamic responses of multiphase composites

The fully coupled magneto-electro-elastic (MEE) properties of MEE composites complicate the prediction of their behavior in practical applications, particularly for three-dimensional (3D) vibration and dynamic responses. This paper introduces a generalized 3D MEE finite element model developed via secondary development in COMSOL. It allows users to obtain accurate results without finite element programming skills, significantly simplifying the complexity in the modeling of MEE materials. The accuracy of the proposed model in predicting natural frequency, modes, dynamic response, and stress wave propagation is first validated against exact solutions. Then, the model is employed to investigate the impacts of functional gradients, structural dimensions, perforated plate, damping, and pre-stress on the vibration characteristics and dynamic behavior of MEE composites. An empirical formula is further developed to precisely predict the fundamental frequency in MEE sandwich plates with varying stacking sequences and dimensions. For MEE sandwiches composed of piezoelectric (BaTiO₃) and magnetostrictive (CoFe₂O₄) materials with different stacking sequences, interesting novel features are observed, including the effect of piezomagnetic/piezoelectric stiffening, the influence of the geometry on the vibration and propagation of stress waves in the MEE structure. These findings offer valuable insights for the design of high-performance multiphase composites.