A crowding factor model for the thermal conductivity of particulate composites at non-dilute limit
Abstract
The effective thermal conductivity models for particulate composites are usually restricted to the dilute limit, with volumetric concentrations of particles typically less than 15%. By considering the particle interactions through a crowding factor, in this work, a new formula is developed to describe the thermal conductivity of composites with a dielectric matrix, for volume fractions of particles up to their maximum packing fraction. The crowding factor model is then applied to analyze two particulate composites with dielectric or metallic particles, where the effects of both interfacial thermal resistance and the electron-phonon coupling are taken into account. It is shown that the predictions of the proposed crowding factor model are larger than the ones predicted by the dilute-limit models, for composites with high volume fractions of particles, due to the particle interactions. The proposed crowding factor model extends the applicability of various thermal conductivity models for composites reported in the literature and its predictions are in good agreement with published experimental data.
- Publication:
-
Journal of Applied Physics
- Pub Date:
- August 2013
- DOI:
- 10.1063/1.4818409
- Bibcode:
- 2013JAP...114f4306O
- Keywords:
-
- alumina;
- aluminium;
- ceramics;
- copper;
- electron-phonon interactions;
- filled polymers;
- particle reinforced composites;
- silicon compounds;
- thermal conductivity;
- 66.70.Lm;
- 71.38.-k;
- 63.20.kd;
- Other systems such as ionic crystals molecular crystals nanotubes etc.;
- Polarons and electron-phonon interactions;
- Phonon-electron interactions