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Main Authors: Kulka, Teresa, Lekawa-Raus, Agnieszka E., Bulmer, John S., Koziol, Krzysztof, Balakirev, Fedor F., Lebedeva, Irina V., Majewski, Jacek A., Marganska, Magdalena, Milowska, Karolina Z.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.28250
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author Kulka, Teresa
Lekawa-Raus, Agnieszka E.
Bulmer, John S.
Koziol, Krzysztof
Balakirev, Fedor F.
Lebedeva, Irina V.
Majewski, Jacek A.
Marganska, Magdalena
Milowska, Karolina Z.
author_facet Kulka, Teresa
Lekawa-Raus, Agnieszka E.
Bulmer, John S.
Koziol, Krzysztof
Balakirev, Fedor F.
Lebedeva, Irina V.
Majewski, Jacek A.
Marganska, Magdalena
Milowska, Karolina Z.
contents Miniaturized electronics require lightweight conductors that maintain high conductance under demanding conditions. CNT networks are promising candidates, but their transport is governed by inter-nanotube junctions where electron waves interfere. Controlling this interference requires understanding how junction architecture shapes transmission. We explore coherent transport through experimentally relevant junctions, from single and multiple single-walled CNT (SWCNT) contacts to double-walled CNT (DWCNT) and triple-walled CNT (TWCNT) junctions, with atomistic tight-binding non-equilibrium Green's-function calculations, also under a perpendicular magnetic field. We use analytically solvable minimal models to identify transport regimes expected for quasi-1D nanoscale junctions, and an electron-waveguide picture to interpret their CNT-specific manifestations. For single SWCNT--SWCNT junctions, high-transmission windows are set mainly by overlap length, doping and magnetic field. Gateway states can enhance conductance when some CNT subbands are gapped, and in some cases a magnetic field can restore transmission by lifting an interference blockade. In more complex architectures, added paths become selective: multi-junctions generate resonant filtering, while additional walls redistribute transmission instead of acting as independent channels. DWCNT junctions remain outer-wall dominated and SWCNT-like, whereas TWCNT junctions become genuinely multi-channel and more field-sensitive. This explains the lower, more field-sensitive conductance of multi-walled CNT (MWCNT) fibres, in accord with our ultrahigh-field measurements on SWCNT and MWCNT fibres. Ultimately, this work turns microscopic interference mechanisms into design principles for high-conductance, field-stable CNT conductors.
format Preprint
id arxiv_https___arxiv_org_abs_2605_28250
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Taming quantum interference: a route to high electrical conductance in carbon nanotube assemblies
Kulka, Teresa
Lekawa-Raus, Agnieszka E.
Bulmer, John S.
Koziol, Krzysztof
Balakirev, Fedor F.
Lebedeva, Irina V.
Majewski, Jacek A.
Marganska, Magdalena
Milowska, Karolina Z.
Mesoscale and Nanoscale Physics
Materials Science
Miniaturized electronics require lightweight conductors that maintain high conductance under demanding conditions. CNT networks are promising candidates, but their transport is governed by inter-nanotube junctions where electron waves interfere. Controlling this interference requires understanding how junction architecture shapes transmission. We explore coherent transport through experimentally relevant junctions, from single and multiple single-walled CNT (SWCNT) contacts to double-walled CNT (DWCNT) and triple-walled CNT (TWCNT) junctions, with atomistic tight-binding non-equilibrium Green's-function calculations, also under a perpendicular magnetic field. We use analytically solvable minimal models to identify transport regimes expected for quasi-1D nanoscale junctions, and an electron-waveguide picture to interpret their CNT-specific manifestations. For single SWCNT--SWCNT junctions, high-transmission windows are set mainly by overlap length, doping and magnetic field. Gateway states can enhance conductance when some CNT subbands are gapped, and in some cases a magnetic field can restore transmission by lifting an interference blockade. In more complex architectures, added paths become selective: multi-junctions generate resonant filtering, while additional walls redistribute transmission instead of acting as independent channels. DWCNT junctions remain outer-wall dominated and SWCNT-like, whereas TWCNT junctions become genuinely multi-channel and more field-sensitive. This explains the lower, more field-sensitive conductance of multi-walled CNT (MWCNT) fibres, in accord with our ultrahigh-field measurements on SWCNT and MWCNT fibres. Ultimately, this work turns microscopic interference mechanisms into design principles for high-conductance, field-stable CNT conductors.
title Taming quantum interference: a route to high electrical conductance in carbon nanotube assemblies
topic Mesoscale and Nanoscale Physics
Materials Science
url https://arxiv.org/abs/2605.28250