Growth of carbon nanotubes via twisted graphene nanoribbons

Lim, Hong En; Miyata, Yasumitsu; Kitaura, Ryo; Nishimura, Yoshifumi; Nishimoto, Yoshio; Irle, Stephan; Warner, Jamie H.; Kataura, Hiromichi; Shinohara, Hisanori

doi:10.1038/ncomms3548

Cited by 98 publications

(112 citation statements)

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“…This demonstrates a remarkable property of carbon nanotubes to act not only as nanoreactors constraining the space around the chemical reaction and templating the formation of nanoclusters or the growth of nanoribbons, but also as electrically active host-structures lending their electrons when they are required for a chemical reaction to occur inside SWNT, and retrieving electrons back when they are no longer required by the guest-species. In summary, carbon nanotubes are becoming an increasingly important class of nanoscale containers and reactors, where the pathways of chemical reactions can change significantly as a result of the restricted space of the reaction [5][6][7][8][9][10][11][12][13][14][15][16][17], or due to the interactions between the reactant molecules or catalyst particles with the host-nanotube [23,24]. Being highly conducting and having a symmetric distribution of filled and empty electronic states, SWNT possess remarkable electric properties and a unique ability to donate or accept electrons, which make nanotubes distinct among other nanocontainers and nanoreactors.…”

Section: Equationmentioning

confidence: 99%

Carbon Nanotubes as Electrically Active Nanoreactors for Multi-Step Inorganic Synthesis: Sequential Transformations of Molecules to Nanoclusters and Nanoclusters to Nanoribbons

et al. 2016

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In organic synthesis, the composition and structure of products are predetermined by the reaction conditions; however, the synthesis of well-defined inorganic nanostructures often presents a significant challenge yielding non-stoichiometric or polymorphic products. In this study, confinement in the nanoscale cavities of single-walled carbon nanotubes (SWNT) provides a new approach for multi-step inorganic synthesis where sequential chemical transformations take place within the same nanotube. In the first step, SWNT donate electrons to the reactant iodine molecules (I2) transforming them to iodide anions (I -). These then react with metal hexacarbonyls (M(CO)6, M = Mo or W) in the next step yielding anionic nanoclusters [M6I14] 2-, the size and composition of which are strictly dictated by the nanotube cavity, as demonstrated by aberration corrected high resolution transmission electron microscopy (AC-HRTEM), scanning transmission electron microscopy (STEM) and energy dispersive X-ray (EDX) spectroscopy. Atoms in the nanoclusters [M6I14] 2-are arranged in a perfect octahedral geometry and can engage in further chemical reactions within the nanotube, either reacting with each other leading to a new polymeric phase of molybdenum iodide [Mo6I12]n, or with hydrogen sulphide gas giving rise to nanoribbons of molybdenum/tungsten disulphide [MS2]n in the third step of the synthesis. Electron microscopy measurements demonstrate that the products of the multi-step inorganic transformations are precisely controlled by the SWNT nanoreactor, with complementary Raman spectroscopy revealing the remarkable property of SWNT to act as a reservoir of electrons during the chemical transformation. The electron transfer from the hostnanotube to the reacting guest-molecules is essential for stabilising the anionic metal iodide 2 nanoclusters and for their further transformation to metal disulphide nanoribbons synthesised in the nanotubes in high yield.Keywords: Carbon Nanotube, Charge Transfer, Nanoparticle, Nanoreactor, Nanoribbon Single-walled carbon nanotubes (SWNT) are among the most effective and universal containers for molecules. Provided that the internal diameter of the host-nanotube is wider than the critical diameter of the guest-molecule, the insertion of molecules into SWNT is spontaneous and, in some cases, such as fullerenes and their derivatives, irreversible due to the ubiquitous van der Waals forces dominating the host guest interactions between the nanotube and molecules [1]. Fullerenes [2,3] or organic molecules [4][5][6][7][8][9][10] encapsulated in SWNT can then be triggered to react inside the nanotube to form unusual oligomers and polymers [11][12][13], graphene nanoribbons [14][15][16], nanotubes [8,17] or extraordinary molecular nanodiamonds [9]. These examples clearly demonstrate the use of SWNT as nanoscale chemical reactors, where the structure of the macromolecular product can be precisely controlled by spatial confinement of the reactions in the nanotube channel.In contrast to organic molecules,...

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Section: Equationmentioning

confidence: 99%

Carbon Nanotubes as Electrically Active Nanoreactors for Multi-Step Inorganic Synthesis: Sequential Transformations of Molecules to Nanoclusters and Nanoclusters to Nanoribbons

et al. 2016

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“…Pea pod-derived DWNTs and TWNTs have specific advantages and disadvantages over the DWNTs and TWNTs grown by the arc-discharge method and the CVD method [104,120,130,131,[134][135][136][137][138][139][140][141][142]150]. One advantage is that the method of growing the multi-walled structures by thermally-treating pea pods makes it possible to obtain high-purity CNTs without contaminants, such as metallic impurities.…”

Section: Pea Pod-derived Method: Advantages and Disadvantagesmentioning

confidence: 99%

“…This happens because the electronic structure of the constituent inner tubes is predominantly determined by the outer tubes, as well as by the high temperature observed during the thermal treatment. It is very interesting to note that the interlayer spacing in pea pod-derived structures strongly depends on the high temperatures achieved during the thermal treatment [104,120,130,131,[134][135][136][137][138][139][140][141][142]150].…”

Section: Pea Pod-derived Method: Advantages and Disadvantagesmentioning

confidence: 99%

“…The chirality distribution of the encapsulated molecules-derived inner tube of the DWNT is dependent on the choice of the precursor molecules [137]. Even when fullerenes with a similar structure, such as C 60 and C 70 , are used as the precursor, these molecules produce inner tubes with a different chirality distribution.…”

Section: Annealing Of Confined Molecules Inside Swntsmentioning

confidence: 99%

“…(Figure 7a). When external stimuli, such as heat [132], an electron beam [133] and UV light [134], were applied to the pea pod (Figure 7b), the C 60 molecules inside the SWNTs partially coalesced with neighboring C 60 molecules to eventually be transformed thereby forming the inner tube of a DWNT (Figure 7c) Lim et al [137] found that there are two different intermediate states of the inner tube depending on the encapsulated molecular species. In the case of PTCDA, graphene nanoribbon-like intermediates were formed during annealing (Figure 7d), whereas fullerenes, picene and pentacene formed deformed fullerene-like intermediates prior to DWNT formation (Figure 7e).…”

Section: Annealing Of Confined Molecules Inside Swntsmentioning

confidence: 99%

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A Review of Double-Walled and Triple-Walled Carbon Nanotube Synthesis and Applications

Fujisawa

Kim

et al. 2016

Applied Sciences

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Double-and triple-walled carbon nanotubes (DWNTs and TWNTs) consist of coaxially-nested two and three single-walled carbon nanotubes (SWNTs). They act as the geometrical bridge between SWNTs and multi-walled carbon nanotubes (MWNTs), providing an ideal model for studying the coupling interactions between different shells in MWNTs. Within this context, this article comprehensively reviews various synthetic routes of DWNTs' and TWNTs' production, such as arc discharge, catalytic chemical vapor deposition and thermal annealing of pea pods (i.e., SWNTs encapsulating fullerenes). Their structural features, as well as promising applications and future perspectives are also discussed.

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Single‐Walled Carbon Nanotubes: Functionalization by Intercalation

Shiozawa

Pichler

Pfeiffer

et al. 2015

Encyclopedia of Inorganic and Bioinorganic Chemistry

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The article reviews recent progresses in functionalization of single‐walled carbon nanotubes (SWCNTs). We describe detailed studies of electronic, chemical, and structural properties of intercalated and filled carbon nanotubes using state‐of‐the‐art spectroscopic and microscopic techniques. Intercalation with alkali metal allows one to finely tune the electron doping level of SWCNTs. A photoemission study of potassium intercalation compounds of SWCNT bundles unveils a transition of the metallic ground state of an SWCNT bundle from a Tomonaga–Luttinger liquid state to a Fermi liquid state. In turn, the filling of SWCNTs with fullerenes and organic molecules facilitates a reality of nanochemistry using carbon nanotubes as a nanoreactor. Spectroscopic and microscopic studies of the interconversion of encapsulated fullerenes and organic molecules show catalytic and noncatalytic processes for the inner tube growth from different filling precursors. Unique atomic wires and clusters can be created inside SWCNTs. We present that such chemical reactions of the encapsulated molecules result in the evolution of doping and bonding properties of the carbon nanotube host.

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Growth of carbon nanotubes via twisted graphene nanoribbons

Cited by 98 publications

References 36 publications

Carbon Nanotubes as Electrically Active Nanoreactors for Multi-Step Inorganic Synthesis: Sequential Transformations of Molecules to Nanoclusters and Nanoclusters to Nanoribbons

Carbon Nanotubes as Electrically Active Nanoreactors for Multi-Step Inorganic Synthesis: Sequential Transformations of Molecules to Nanoclusters and Nanoclusters to Nanoribbons

A Review of Double-Walled and Triple-Walled Carbon Nanotube Synthesis and Applications

Single‐Walled Carbon Nanotubes: Functionalization by Intercalation

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