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Main Authors: Naeimi, A., Biehs, S. -A.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.10026
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author Naeimi, A.
Biehs, S. -A.
author_facet Naeimi, A.
Biehs, S. -A.
contents We reinvestigate the mechanism of near-field heat transfer rectification between two Weyl semimetal nanoparticles and a planar Weyl semimetal substrate via the coupling to non-reciprocal surface modes. We first show that the previously predicted rectification ratio of 2673 is incorrect and should rather be 1502. Furthermore we show that depending on the distance between the nanoparticles there can be a much more efficient heat flux rectification with ratios of about 6000. Furthermore, we identify a previously overlooked range of forward rectification and a range of strong backward rectification with rectification ratios larger than 8000 for relatively small Weyl node separations. We investigate the mechanism behind this large heat flux rectification and study its sensitivity with respect to certain material parameters and temperature showing that even larger rectification ratios up to 15000 are possible highlighting that certain Weyl semimetals are strong candidates for highly efficient heat flux rectification.
format Preprint
id arxiv_https___arxiv_org_abs_2412_10026
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Efficiency and Mechanism of Heat Flux Rectification with Non-Reciprocal Surface Waves in Weyl-Semi-Metals
Naeimi, A.
Biehs, S. -A.
Mesoscale and Nanoscale Physics
We reinvestigate the mechanism of near-field heat transfer rectification between two Weyl semimetal nanoparticles and a planar Weyl semimetal substrate via the coupling to non-reciprocal surface modes. We first show that the previously predicted rectification ratio of 2673 is incorrect and should rather be 1502. Furthermore we show that depending on the distance between the nanoparticles there can be a much more efficient heat flux rectification with ratios of about 6000. Furthermore, we identify a previously overlooked range of forward rectification and a range of strong backward rectification with rectification ratios larger than 8000 for relatively small Weyl node separations. We investigate the mechanism behind this large heat flux rectification and study its sensitivity with respect to certain material parameters and temperature showing that even larger rectification ratios up to 15000 are possible highlighting that certain Weyl semimetals are strong candidates for highly efficient heat flux rectification.
title Efficiency and Mechanism of Heat Flux Rectification with Non-Reciprocal Surface Waves in Weyl-Semi-Metals
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2412.10026