Sage Journals: Discover world-class research

Abstract

A numerical approach using a finite element method (FEM) was performed in order to determine the dielectric constant (ε^') of BaTiO₃—epoxy composites. In order to diminish computational resources and analyse simple models, composite topology was represented by periodic structures based on FCC configurations, but introducing novel packaging protocols, defining the way composites are filled as particle concentration is increased. The dielectric response of these anisotropic and periodic structures was mathematically represented through a quasi-static approximation using the Laplace equation. The amount of inclusions was varied in order to represent diluted and concentrated systems and structures were assessed for the whole feasible range of volume fractions. The numerical results were compared with experimental data concluding that only packaging protocols that consider higher particle—particle interaction are suitable to represent the dielectric behavior of concentrated-composite materials.

Keywords

polymer matrix composites dielectric finite element analysis.

Get full access to this article

View all access options for this article.

References

Uchino, K. and Takahashi, S. (1999). Dielectric Ceramic Materials. Ceramics Transactions , In: Nair and Bhalla (Eds), The American Ceramic Society, Ohio, 100: 455-468.

Beroual, A. and Brosseau, C. (2001). Comparison of Dielectric Properties Determined from a Computational Approach and Experiment for Anisotropic and Periodic Heterostructures, IEEE Trans. Dielectrics EI., 8: 921-929.

Goodman, G. (1991). Ceramic Capacitor Materials in Ceramic Materials for Electronics, 2nd edn, Marcel Dekker, New York.

Serdyuk, Y. , Podoltsev, D. and Gubanski, S. (2005). Numerical Simulations of Dielectric Properties of Composite Material with Periodic Structure, J. Electrostatics , 63: 1073-1091.

Beroual, A. and Brosseau, C. (2003). Computational Electromagnetics and the Rational Design of New Dielectric Heterostructures, Progress in Materials Science, 48: 373-456.

Yoon, D.-H. , Zhang, J. and Lee, B.I. (2003). Dielectric Constant and Mixing Model of BaTiO3 Composite Thick Films, Materials Research Bulletin, 38: 765-772.

Ramajo, L. , Ramajo, D. , Santiago, D. , Reboredo, M. and Castro, M. (2006). BaTiO3-filled Epoxy Resin Composites: Numerical Modelling of Dielectric Behaviour, Ferroelectrics, 338: 117-126.

Sanders, W.S. and Gibson, L.J. (2003). Mechanics of BCC and FCC Hollow Sphere Foams, Mat. Sci. Eng A, 352: 150-161.

Zinhiewicz, O.C. and Taylor, R.L. (1989). The Finite Element Method, 4th edn, MacGraw Hill Book Company, London.

10.

Ramajo, L. , Reboredo, M. and Castro, M. (2005). Dielectric Response and Relaxation Phenomena in Composites of Epoxy Resin with BaTiO3 Particles, Composites Part A, 36: 1267-1274.

Computational Approach of Dielectric Permitivities in BaTiO3—Epoxy Composites

Abstract

Keywords

Get full access to this article

References