Co-Catalytic Solid-State Reduction Applied to Carbon Nanotube Growth

Bayer, Bernhard C.; Fouquet, Martin; Blume, Raoul; Wirth, Christoph; Weatherup, Robert S.; Ogata, Ken; Knop‐Gericke, Axel; Schlögl, Robert; Hofmann, Stephan; Robertson, John

doi:10.1021/jp210137u

Cited by 23 publications

(29 citation statements)

References 59 publications

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“…In the case of pure ballistic conduction and perfect metal‐CNT contact, each CNT should pose a quantum resistance of 6.45 kΩ in the bundle, resulting in the resistance values of 0.645 and 2.58 Ω for 10 × 10 nd 5 × 5 μm 2 vias, respectively, which are much smaller than our calculated values of 25 and 100 Ω. The origin of additional high resistance may be because of imperfect metal‐CNT contacts, diffusive conduction in the CNTs because of structural defects and oxidation of catalyst, as the sample was exposed to the atmosphere when transferred from sputter deposition system to the PTCVD system . Assuming diffusive conduction and perfect metal‐CNT contact, the resistance of a single CNT (250 kΩ in our case) is given from ref .…”

Section: Resultsmentioning

confidence: 55%

High Quality Carbon Nanotubes on Conductive Substrates Grown at Low Temperatures

Ahmad

Anguita

Stolojan

et al. 2015

Adv Funct Materials

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Keywords: nanomaterials, carbon nanotubes, photothermal chemical vapor deposition, low temperature growth 2 For carbon nanotubes (CNTs) to be exploited in electronic applications the growth of high quality material on conductive substrates at low temperatures (< 450 o C) is required. CNT quality is known to be strongly degraded when growth is conducted on metallic surface at low temperatures using conventional chemical vapor deposition (CVD). Here, we demonstrate production of high quality vertically-aligned CNTs at low substrate temperatures (350 -440 o C) on conductive TiN thin film using photo-thermal CVD by confining the heat required for growth to just the catalyst using an array of optical lamps and by optimizing the thickness of the TiN under-layer. The thickness of the TiN plays a crucial role in determining various properties including diameter, material quality, number of shells and metallicity. The highest structural quality with a visible Raman D-to G-band intensity ratio as low as 0.13 is achieved for 100 nm TiN thickness grown at 420 o C; a record low value for low temperature CVD grown CNTs. Electrical measurements of high density CNT arrays show the resistivity to be 1.25×10 -2 Ωcm represents some of the lowest values reported. Finally, the broader aspects of using this approach as a scalable technology for carbon nanomaterial production are also discussed.3

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Section: Resultsmentioning

confidence: 55%

High Quality Carbon Nanotubes on Conductive Substrates Grown at Low Temperatures

Ahmad

Anguita

Stolojan

et al. 2015

Adv Funct Materials

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“…As-grown CNTs are multiwalled, similar to previous reports. 16,27,42 Reference samples without a Ta support layer did not give CNT growth under nonreducing conditions. This clearly confirms that Ta is required for catalyst activation and acts as the primary reducing agent for the Fe, 27 with no significant catalyst activation from the C 2 H 2 gas itself under these conditions.…”

Section: ■ Resultsmentioning

confidence: 96%

“…We first use thermal CVD, i.e. conventional global substrate back heating, to investigate the influence of the Ta support layer thickness on the solid-state reduction 27 of the initially oxidized Fe catalyst (from transport/storage in ambient air), and hence the effectiveness of the layer stack for CNT CVD. Figure 2 compares thermal CNT CVD results for Fe(1 nm)/Ta(∼0− 130 nm) layer stacks for a nonreducing (∼10 −3 mbar vacuum; Figure 2a) and, as reference, for a reducing pretreatment atmosphere (100 sccm NH 3 at 1 mbar; Figure 2b).…”

Section: ■ Resultsmentioning

confidence: 99%

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Co-catalytic Absorption Layers for Controlled Laser-Induced Chemical Vapor Deposition of Carbon Nanotubes

Michaelis

Weatherup

Bayer

et al. 2014

ACS Appl. Mater. Interfaces

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The concept of co-catalytic layer structures for controlled laser-induced chemical vapor deposition of carbon nanotubes is established, in which a thin Ta support layer chemically aids the initial Fe catalyst reduction. This enables a significant reduction in laser power, preventing detrimental positive optical feedback and allowing improved growth control. Systematic study of experimental parameters combined with simple thermostatic modeling establishes general guidelines for the effective design of such catalyst/absorption layer combinations. Local growth of vertically aligned carbon nanotube forests directly on flexible polyimide substrates is demonstrated, opening up new routes for nanodevice design and fabrication.

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“…53 The same mechanism has been reported with Fe-Ta catalyst as the solid-state reduction. [54][55] The annealing in the presence of a reduction gas, as H 2 and/or NH 3 , enhances the fraction of metallic Co, which is active state to grow CNTs. A similar behaviour is also found in the analysis of the Mo 3d level.…”

Section: Figure 1amentioning

confidence: 99%

Low-Temperature Growth of Carbon Nanotube Forests Consisting of Tubes with Narrow Inner Spacing Using Co/Al/Mo Catalyst on Conductive Supports

Sugime

Esconjauregui

D’Arsié

et al. 2015

ACS Appl. Mater. Interfaces

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We grow dense carbon nanotube forests at 450 °C on Cu support using Co/Al/Mo multilayer catalyst. As a partial barrier layer for the diffusion of Co into Mo, we apply very thin Al layer with the nominal thickness of 0.50 nm between Co and Mo. This Al layer plays an important role in the growth of dense CNT forests, partially preventing the Co-Mo interaction. The forests have an average height of ∼300 nm and a mass density of 1.2 g cm(-3) with tubes exhibiting extremely narrow inner spacing. An ohmic behavior is confirmed between the forest and Cu support with the lowest resistance of ∼8 kΩ. The forest shows a high thermal effusivity of 1840 J s(-0.5) m(-2) K(-1), and a thermal conductivity of 4.0 J s(-1) m(-1) K(-1), suggesting that these forests are useful for heat dissipation devices.

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Co-Catalytic Solid-State Reduction Applied to Carbon Nanotube Growth

Cited by 23 publications

References 59 publications

High Quality Carbon Nanotubes on Conductive Substrates Grown at Low Temperatures

High Quality Carbon Nanotubes on Conductive Substrates Grown at Low Temperatures

Co-catalytic Absorption Layers for Controlled Laser-Induced Chemical Vapor Deposition of Carbon Nanotubes

Low-Temperature Growth of Carbon Nanotube Forests Consisting of Tubes with Narrow Inner Spacing Using Co/Al/Mo Catalyst on Conductive Supports

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