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Literature DB >> 19691280

Longitudinal cutting of pure and doped carbon nanotubes to form graphitic nanoribbons using metal clusters as nanoscalpels.

Ana Laura Elías¹, Andrés R Botello-Méndez, David Meneses-Rodríguez, Viviana Jehová González, Daniel Ramírez-González, Lijie Ci, Emilio Muñoz-Sandoval, Pulickel M Ajayan, Humberto Terrones, Mauricio Terrones.

Abstract

We report the use of transition metal nanoparticles (Ni or Co) to longitudinally cut open multiwalled carbon nanotubes in order to create graphitic nanoribbons. The process consists of catalytic hydrogenation of carbon, in which the metal particles cut sp(2) hybridized carbon atoms along nanotubes that results in the liberation of hydrocarbon species. Observations reveal the presence of unzipped nanotubes that were cut by the nanoparticles. We also report the presence of partially open carbon nanotubes, which have been predicted to have novel magnetoresistance properties.(1) The nanoribbons produced are typically 15-40 nm wide and 100-500 nm long. This method offers an alternative approach for making graphene nanoribbons, compared to the chemical methods reported recently in the literature.

Entities: Chemical

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Year: 2010 PMID： 19691280 DOI： 10.1021/nl901631z

Source DB: PubMed Journal: Nano Lett ISSN： 1530-6984 Impact factor: 11.189

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Cited

18 in total

1. Self-assembly of a sulphur-terminated graphene nanoribbon within a single-walled carbon nanotube.

Authors: A Chuvilin; E Bichoutskaia; M C Gimenez-Lopez; T W Chamberlain; G A Rance; N Kuganathan; J Biskupek; U Kaiser; A N Khlobystov
Journal: Nat Mater Date: 2011-08-07 Impact factor: 43.841

2. Facile synthesis of high-quality graphene nanoribbons.

Authors: Liying Jiao; Xinran Wang; Georgi Diankov; Hailiang Wang; Hongjie Dai
Journal: Nat Nanotechnol Date: 2010-04-04 Impact factor: 39.213

3. Atomically precise bottom-up fabrication of graphene nanoribbons.

Authors: Jinming Cai; Pascal Ruffieux; Rached Jaafar; Marco Bieri; Thomas Braun; Stephan Blankenburg; Matthias Muoth; Ari P Seitsonen; Moussa Saleh; Xinliang Feng; Klaus Müllen; Roman Fasel
Journal: Nature Date: 2010-07-22 Impact factor: 49.962

4. In situ growth of large-area and self-aligned graphene nanoribbon arrays on liquid metal.

Authors: Le Cai; Wanzhen He; Xudong Xue; Jianyao Huang; Ke Zhou; Xiahong Zhou; Zhiping Xu; Gui Yu
Journal: Natl Sci Rev Date: 2020-12-16 Impact factor: 17.275

5. Controllable unzipping for intramolecular junctions of graphene nanoribbons and single-walled carbon nanotubes.

Authors: Dacheng Wei; Lanfei Xie; Kian Keat Lee; Zhibin Hu; Shihua Tan; Wei Chen; Chorng Haur Sow; Keqiu Chen; Yunqi Liu; Andrew Thye Shen Wee
Journal: Nat Commun Date: 2013 Impact factor: 14.919

6. Crossover point of the field effect transistor and interconnect applications in turbostratic multilayer graphene nanoribbon channel.

Authors: Ryota Negishi; Katsuma Yamamoto; Hirofumi Tanaka; Seyed Ali Mojtahedzadeh; Nobuya Mori; Yoshihiro Kobayashi
Journal: Sci Rep Date: 2021-05-13 Impact factor: 4.379

10. Counter-ion dependent, longitudinal unzipping of multi-walled carbon nanotubes to highly conductive and transparent graphene nanoribbons.

Authors: Dhanraj B Shinde; Mainak Majumder; Vijayamohanan K Pillai
Journal: Sci Rep Date: 2014-03-13 Impact factor: 4.379