Jump to main content
Jump to site search

Issue 46, 2018
Previous Article Next Article

Enhanced thermal conductivity in percolating nanocomposites: a molecular dynamics investigation

Author affiliations

Abstract

In this work we present a molecular dynamics investigation of thermal transport in a silica–gallium nitride nanocomposite. A surprising enhancement of the thermal conductivity for crystalline volume fractions larger than 5% is found, which cannot be predicted by an effective medium approach, not even including percolation effects, the model systematically leading to an underestimation of the effective thermal conductivity. The behavior can instead be reproduced if an effective volume fraction twice larger than the real one is assumed, which translates into a percolation effect surprisingly stronger than the usual one. Such a scenario can be understood in terms of a phonon tunneling between inclusions, enhanced by the iso-orientation of all particles. Indeed, if a misorientation is introduced, the thermal conductivity strongly decreases. We also show that a percolating nanocomposite clearly stands in a different position than other nanocomposites, where thermal transport is dominated by the interface scattering and where parameters such as the interface density play a major role, differently from our case.

Graphical abstract: Enhanced thermal conductivity in percolating nanocomposites: a molecular dynamics investigation

Back to tab navigation

Article information


Submitted
16 Jul 2018
Accepted
22 Oct 2018
First published
23 Oct 2018

Nanoscale, 2018,10, 21732-21741
Article type
Paper

Enhanced thermal conductivity in percolating nanocomposites: a molecular dynamics investigation

K. Termentzidis, V. M. Giordano, M. Katsikini, E. Paloura, G. Pernot, M. Verdier, D. Lacroix, I. Karakostas and J. Kioseoglou, Nanoscale, 2018, 10, 21732
DOI: 10.1039/C8NR05734F

Social activity

Search articles by author

Spotlight

Advertisements