Heterojunctions between metals and carbon nanotubes as ultimate nanocontacts

Rodríguez–Manzo, Julio A.; Banhart, Florian; Terrones, Mauricio; Terrones, Humberto; Grobert, Nicole; Ajayan, Pulickel M.; Sumpter, Bobby G.; Meunier, Vincent; Wang, Mingsheng; Bando, Yoshio; Golberg, Dmitri

doi:10.1073/pnas.0900960106

Cited by 111 publications

(103 citation statements)

References 38 publications

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“…The controlled formation of heterojunctions between carbon nanotubes and different metal NCs ͑Fe, Co, Ni, and FeCo͒ was demonstrated. 358 The heterojunctions were formed from metal-filled MWNTs via intense electron beam irradiation in a TEM at elevated temperatures in the range of 450-700°C. Under irradiation, the segregation of metal and carbon atoms occurred, leading to the formation of heterojunctions between metal and graphite, Fig.…”

Section: Welding and Coalescence Of Carbon Nanotubes Under Electron Beammentioning

confidence: 99%

“…The inset shows a detail of the interface ͑white square͒ after noise filtering, where the bending of the nanotube layers to match the metal lattice is visible, from Ref. 358. ͑f͒ Junction between three MWNTs and a Co particle as made by electron irradiation of a metal-carbon nanotube composite.…”

Section: Engineering Carbon Nanostructures With a Focused Electron Beammentioning

confidence: 99%

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Ion and electron irradiation-induced effects in nanostructured materials

Krasheninnikov¹,

Nordlund²

2010

Journal of Applied Physics

932

591

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A common misconception is that the irradiation of solids with energetic electrons and ions has exclusively detrimental effects on the properties of target materials. In addition to the well-known cases of doping of bulk semiconductors and ion beam nitriding of steels, recent experiments show that irradiation can also have beneficial effects on nanostructured systems. Electron or ion beams may serve as tools to synthesize nanoclusters and nanowires, change their morphology in a controllable manner, and tailor their mechanical, electronic, and even magnetic properties. Harnessing irradiation as a tool for modifying material properties at the nanoscale requires having the full microscopic picture of defect production and annealing in nanotargets. In this article, we review recent progress in the understanding of effects of irradiation on various zero-dimensional and one-dimensional nanoscale systems, such as semiconductor and metal nanoclusters and nanowires, nanotubes, and fullerenes. We also consider the two-dimensional nanosystem graphene due to its similarity with carbon nanotubes. We dwell on both theoretical and experimental results and discuss at length not only the physics behind irradiation effects in nanostructures but also the technical applicability of irradiation for the engineering of nanosystems.

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Section: Welding and Coalescence Of Carbon Nanotubes Under Electron Beammentioning

confidence: 99%

Section: Engineering Carbon Nanostructures With a Focused Electron Beammentioning

confidence: 99%

Ion and electron irradiation-induced effects in nanostructured materials

Krasheninnikov¹,

Nordlund²

2010

Journal of Applied Physics

932

591

View full text Add to dashboard Cite

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“…The formation of CNTs could be attributed to the catalysis of iron particles and the decrease of vacuum degree in quartz tube during the cooling process. The grapheneCNTs system has significant technological advantages due to the combination of individual properties of graphene and CNTs in various applications (Kalita et al 2008;Rodríguez-Manzo et al 2009;Lee et al 2010;Zhang et al 2011).…”

Section: Fe-sem Analysismentioning

confidence: 99%

Preparation and Characterization of Biobased Graphene from Kraft Lignin

2017

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Graphene was manufactured from commercial kraft lignin, and its forming mechanism, structure, and properties were investigated. A single factor test was employed to determine the optimum conditions of the production of graphene nanosheets. Kraft lignin was mixed with iron powders as catalyst with different weight ratios. The mixed carbon source and catalyst were thermally treated at 1000 °C and incubated for a period of time in a tubular furnace. The thermally treated carbon materials were analyzed by field emission scanning electron microscopy (FE-SEM), Raman spectroscopy, atomic force microscopy (AFM), Fourier transform infrared spectroscopy (FTIR), and X-ray diffraction (XRD). The preferable conditions for production of graphene nanosheets from kraft lignin were determined. The graphene fold structure was obtained after thermally treating for 90 min when the ratio of carbon source to iron was 3:1. The results revealed that folded lamellar graphene structure increased with greater holding time. Carbon nanotubes (CNTs) were observed after thermal treatment for 105 min. These results indicate the formation of graphite crystal structure and multi-layered graphene from kraft lignin in the presence of iron catalyst.

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“…In the most widely used preparation process of chemical vapor deposition (CVD), the choice of transition metal catalyst particles provides a degree of control over the CNT morphology, the production yield, and the growth mode itself (base growth vs. tip growth) [21,22]. Consequently, the interface between the catalyst particle and the CNT is considered to play a key role for the CNT growth [17,[23][24][25][26]. Only few studies deal with the physical properties of these facets which are found to be particularly effective in dissociating the gaseous hydrocarbon feedstock during growth and which typically provide low activation energies for surface diffusion [17,27].…”

mentioning

confidence: 99%