Orientation effects on near-field radiative heat transfer between complex-shaped dielectric particles

TL;DR

This study investigates how the orientation of complex-shaped dielectric particles affects near-field radiative heat transfer, revealing that particle topology and minimum vacuum gap significantly influence conductance, with implications for irregular geometries.

Contribution

It provides the first detailed analysis of orientation effects on heat transfer between complex superellipsoid particles, highlighting the role of particle topology and gap distance.

Findings

Orientation can double conductance at certain distances.

Effects are more related to particle topology than symmetry.

Significant effects persist up to about 3.9 times the particle radius.

Abstract

The effect of orientation on near-field radiative heat transfer between two complex-shaped superellipsoid particles of SiO2 is presented. The particles under study are 50 nm in radius and of variable concavity. Orientation is characterized by the degree of rotational symmetry in the two-particle systems, and the radiative conductance is calculated using the discrete system Green's function approach to account for all electromagnetic interactions. Results reveal that the total conductance in some orientations can be up to twice that of other orientations when particles are at center-of-mass separation distances of 110 nm. Orientation effects are not significantly correlated with system rotational symmetries but are strongly correlated with the minimum vacuum gap distance between particles. As such, orientation effects on near-field radiative heat transfer are a consequence of particle topology, with more extreme topologies leading to a continuation of orientation effects at larger particle center-of-mass separation distances. The concave superellipsoid particles display significant orientation effects up to a center-of-mass separation distance approximately equal to 3.9 times the particle radius, while the convex superellipsoid particles display significant orientation effects up to a center-of-mass separation distance approximately equal to 3.2 times the particle radius. In contrast to previous anisotropic, spheroidal dipole studies, these results of complex-shaped superellipsoid particles suggest that orientation effects become negligible when heat transfer is a volumetric process for all orientations. This work is essential for understanding radiative transport between particles that have non-regular geometries or that may have geometrical defects or abnormalities.