Reduction of thermal conductance by coherent phonon scattering in two-dimensional phononic crystals of different lattice types

TL;DR

This study investigates how lattice type, period, porosity, and thickness influence thermal conductance reduction in two-dimensional silicon phononic crystals through coherent phonon scattering, revealing key dependencies on structural parameters and temperature.

Contribution

It provides a detailed analysis of how structural parameters affect thermal conductance in phononic crystals, highlighting the roles of period and porosity over lattice type and thickness.

Findings

Increasing period and porosity reduces thermal conductance.

Reduction is largely independent of lattice type and thickness.

Thermal conductance reduction is more significant at higher temperatures.

Abstract

The impact of lattice type, period, porosity and thickness of two-dimensional silicon phononic crystals on the reduction of thermal conductance by coherent modification of phonon dispersion is investigated using the theory of elasticity and finite element method. Increase in the period and porosity of the phononic crystal affects the group velocity and phonon density of states and, as a consequence, reduces the in-plane thermal conductance of the structure as compared to unpatterned membrane. This reduction does not depend significantly on the lattice type and thickness of phononic crystals. Moreover, the reduction is strongly temperature dependent and strengthens as the temperature is increased.