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Main Authors: Maranets, Theodore, Wang, Yan
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.18647
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author Maranets, Theodore
Wang, Yan
author_facet Maranets, Theodore
Wang, Yan
contents In both particle and wave descriptions of phonons, the dense, aperiodically arranged interfaces in aperiodic superlattices are expected to strongly attenuate thermal transport due to phonon-interface scattering or broken long-range coherence. However, considerable thermal conductivity is still observed in these structures. In this study, we reveal that incoherent modes propagating in the aperiodic superlattice can convert, through interference, into coherent modes defined by an approximate dispersion relation. This conversion leads to high transmission across the aperiodic superlattice structure, which contains hundreds of interfaces, ultimately resulting in significant thermal conductivity. Such incoherent-to-coherent mode conversion behavior is extensively observed in periodic superlattices. This work suggests an effective strategy to manipulate the phonon band structure through layer patterning or material choice, enabling precise control of phonon transmission across aperiodic superlattices.
format Preprint
id arxiv_https___arxiv_org_abs_2405_18647
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Prominent phonon transmission across aperiodic superlattice through coherent mode-conversion
Maranets, Theodore
Wang, Yan
Materials Science
In both particle and wave descriptions of phonons, the dense, aperiodically arranged interfaces in aperiodic superlattices are expected to strongly attenuate thermal transport due to phonon-interface scattering or broken long-range coherence. However, considerable thermal conductivity is still observed in these structures. In this study, we reveal that incoherent modes propagating in the aperiodic superlattice can convert, through interference, into coherent modes defined by an approximate dispersion relation. This conversion leads to high transmission across the aperiodic superlattice structure, which contains hundreds of interfaces, ultimately resulting in significant thermal conductivity. Such incoherent-to-coherent mode conversion behavior is extensively observed in periodic superlattices. This work suggests an effective strategy to manipulate the phonon band structure through layer patterning or material choice, enabling precise control of phonon transmission across aperiodic superlattices.
title Prominent phonon transmission across aperiodic superlattice through coherent mode-conversion
topic Materials Science
url https://arxiv.org/abs/2405.18647