Radiative heat transfer between metallic nanoparticle clusters in both near field and far field
Minggang Luo, Jian Dong, Junming Zhao, Linhua Liu, Mauro Antezza

TL;DR
This paper investigates radiative heat transfer between metallic nanoparticle clusters, emphasizing magnetic polarization and many-body interactions, revealing their significant effects in near and far field regimes.
Contribution
It introduces a coupled electric and magnetic dipole approach to accurately model magnetic effects and analyzes the influence of cluster structure and orientation on heat transfer.
Findings
Magnetic polarization dominates heat transfer in Ag clusters.
Electric polarization alone underestimates heat conductance.
Many-body interactions have different effects for Ag and SiC clusters.
Abstract
Micro-nanoparticle systems have wide applications in thermal science and technology. In dense particulate system, the particle separation distance may be less than the characteristic thermal wavelength and near field effect will be significant and become a key factor to influence thermal radiation transfer in the system. In this study, radiative heat transfer (RHT) between two metallic nanoparticles clusters are explored using many-body radiative heat transfer theory implemented with the coupled electric and magnetic dipole (CEMD) approach, which effectively takes into account the contribution of magnetic polarization of metallic nanoparticles on heat exchange. As the focus, the effects of magnetic polarization and many-body interaction (MBI) on RHT were analyzed. The effects of fractal dimension and relative orientation of the clusters were also analyzed. Results show that the…
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