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One-directional thermal transport in densely aligned single-wall carbon nanotube films

Individual carbon nanotubes (CNTs) possess extremely high thermal conductivities. However, the thermal conductivities and their anisotropy of macroscopic assemblies of CNTs have so far remained small. Here, we report results of directional thermal transport measurements on a nearly-perfectly aligned CNT film fabricated via controlled vacuum filtration. We found the thermal conductivity to be 43 +- 2.2 W m^-1 K^-1 with a record-high thermal anisotropy of 500. From the temperature dependence of the thermal conductivity and its agreement with the atomistic phonon transport calculation, we conclude that the effect of intertube thermal resistance on heat conduction in the alignment direction is negligible because of the large contact area between CNTs. These observations thus represent ideal unidirectional thermal transport, i.e., the thermal conductivity of the film is determined solely by that of individual CNTs.

preprint2019arXivOpen access
Shingi YamaguchiIssei TsunekawaNatsumi KomatsuWeilu GaoTakuma ShigaTakashi KodamaJunichiro KonoJunichiro Shiomi
physics.app-ph
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Shingi YamaguchiIssei TsunekawaNatsumi KomatsuWeilu GaoTakuma ShigaTakashi KodamaJunichiro KonoJunichiro Shiomi

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