# Modeling the effect of microstructure on elastic wave propagation in   platelet-reinforced composites and ceramics

**Authors:** Hortense Le Ferrand

arXiv: 1906.02582 · 2019-06-07

## TL;DR

This paper develops a model to analyze how microstructure influences elastic wave propagation in platelet-reinforced composites and ceramics, aiming to guide the design of materials with enhanced vibration resistance.

## Contribution

A new modeling approach is introduced to predict frequency bandgaps in periodic microstructures of composites and ceramics, aiding material design for vibration damping.

## Key findings

- Microstructural parameters significantly affect bandgap frequencies.
- Periodic architectures can be optimized for vibration energy dissipation.
- Guidelines for fabricating vibration-resistant ceramic materials are proposed.

## Abstract

Dense ceramics are irreplaceable in applications requiring high mechanical stiffness, chemical and temperature resistance and low weight. To improve their toughness, ceramics can be reinforced with elongated inclusions. Recent manufacturing strategies have been developed to control the orientations of disc-like micro-particles in polymeric and ceramic matrices and to build periodic microstructures. Given the infinite number of possible microstructures available, modeling tools are required to select the potentially best design. Periodic microstructures can be involved in elastic wave scattering to dissipate mechanical energy from vibrations. In this paper, a model is proposed to determine the frequency bandgaps associated to periodic architectures in composites and ceramics and the influence of microstructural parameters are investigated. The results are used to define guidelines for the future fabrication of hard bulk ceramic materials that combine traditional ceramic properties with high vibration resistance.

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Source: https://tomesphere.com/paper/1906.02582