Isotropic Seebeck coefficient of aligned single-wall carbon nanotube films

Fukuhara, Kengo; Ichinose, Yota; Nishidome, Hiroyuki; Yomogida, Yohei; Katsutani, Fumiya; Komatsu, Natsumi; Gao, Weilu; Kono, Junichiro; Yanagi, Kazuhiro

doi:10.1063/1.5066021

Cited by 29 publications

(50 citation statements)

References 15 publications

(28 reference statements)

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“…Besides, Ichinose et al 32 suggested that the alignment of SWCNTs led to an enhanced σ but unchanged S for the aligned metallic film (sample #5), and a PF value of around 300 μW m −1 K −2 was achieved. Similar conclusion was also drawn in the study by Fukuhara et al 33 on SWCNT film (a mixture of metallic and semiconducting SWCNTs). The testing direction was illustrated in Figure 2F and SWCNT alignment degree was evaluated by polarization‐dependent Raman spectra (Figure 2G).…”

Section: Carbon Materials As Thermoelectric Materialssupporting

confidence: 89%

“…Reproduced with permission: Copyright 2018, American Institute of Physics. 33 K, S of the aligned SWNT sample before and after annealing. Reproduced with permission: Copyright 2000, American Institute of Physics 34 isotropic S according to Mott's theory.…”

Section: Effect Of Cnt Species and Alignmentmentioning

confidence: 99%

“…H‐J, σ , S , and PF as a function of gate voltage in the parallel and perpendicular directions in an aligned SWCNT thin film. Reproduced with permission: Copyright 2018, American Institute of Physics 33 . K, S of the aligned SWNT sample before and after annealing.…”

Section: Carbon Materials As Thermoelectric Materialsmentioning

confidence: 99%

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Carbon and carbon composites for thermoelectric applications

2020

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The urgent need for consistent, reliable, ecofriendly, and stable power sources drives the development of new green energy materials. Thermoelectric (TE) materials receive increasing attention due to their unique capability of realizing the direct energy conversion between heat and electricity, showing diverse applications in harvesting waste heat and low‐grade heat. Carbon materials such as carbon nanotubes (CNTs) and graphene have experienced a rapid development as TE materials because of their intrinsic ultrahigh electrical conductivity and light weight. Besides, polymer‐based carbon composites are particularly fascinating as the combination of the merits of polymers and filler materials leads to high TE performance and superior flexibility. Herein, the recent TE advances are systematically summarized in the studied popularity of carbon materials (ie, CNTs and graphene) and the category of polymers. The conducting polymer‐based carbon materials are particularly highlighted. Finally, the remaining challenges and some tentative suggestions possibly guiding future developments are proposed, which may pave a way for a bright future of carbon and carbon composites in the energy market.

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Section: Carbon Materials As Thermoelectric Materialssupporting

confidence: 89%

Section: Effect Of Cnt Species and Alignmentmentioning

confidence: 99%

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Carbon and carbon composites for thermoelectric applications

2020

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“…Owing to these unique properties, carbon nanotubes are regarded as emerging materials in many modern technological areas such as flexible electrodes [12][13][14] , field effect transistors [15][16][17] , thermoelectric devices [18][19][20] , and reinforced materials [8][9][10][11] .…”

Section: Introductionmentioning

confidence: 99%

Modulation of intertube band dispersion relation of carbon nanotube bundles by symmetry and intertube wave function coupling

Okada¹,

Gao²,

Maruyama³

2021

Jpn. J. Appl. Phys.

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Based on density functional theory with a local density approximation and the simple tight-binding approximation, we investigated an electronic structure of carbon nanotube bundles in terms of mutual nanotube arrangement. The dispersion relation near the Fermi level along the intertube direction was found to be sensitive to the nanotube species and their mutual orientation within the bundles. Nanotube bundles with three-fold symmetry exhibited a substantial orientation dependence in the band dispersion relation along the intertube direction. The tight-binding calculation and wave function analysis revealed that this orientation dependence arises from the intertube wave function coupling whether a node exists between nanotubes.

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“…At the intersectional and aligned regions, the intertube interaction plays decisive roles to determine the device performance, because the intertube interaction basically causes modulation of the electronic structure of the CNTs. Although the CNT mat films and aligned CNTs can work as a conducting channel in real devices, such as multi-stage ring oscillators 24,25 and thermoelectric devices [31][32][33] , little is known about the microscopic mechanism of carrier accumulation in CNT thin films by a gate electrode. In our previous work, we predicted that field inversion occurs at the intersectional region of two CNTs under a weak electric field 34,35 .…”

Section: Introductionmentioning

confidence: 99%

Structural effects on carrier doping in carbon nanotube thin-film transistors

Gao

Okada

2020

Journal of Applied Physics

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Based on density functional theory, we studied the electronic properties of carbon nanotube (CNT) thin films under an external electric field. The carrier accumulation resulting from an electric field depends slightly on the CNT species that form the thin films and their arrangement with respect to the electrode. Although most of the carriers are accumulated in the CNTs located at the electrode side, wave function hybridization between semiconducting CNTs slightly enhances the carrier penetration into the opposite CNT layer. Metallic CNTs strongly depress or enhance the carrier penetration for the thin films when they are located at the electrode side or not, respectively.

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Isotropic Seebeck coefficient of aligned single-wall carbon nanotube films

Cited by 29 publications

References 15 publications

Carbon and carbon composites for thermoelectric applications

Carbon and carbon composites for thermoelectric applications

Modulation of intertube band dispersion relation of carbon nanotube bundles by symmetry and intertube wave function coupling

Structural effects on carrier doping in carbon nanotube thin-film transistors

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