Literature DB >> 18505300

Atomic-scale in-situ observation of carbon nanotube growth from solid state iron carbide nanoparticles.

Hideto Yoshida1, Seiji Takeda, Tetsuya Uchiyama, Hideo Kohno, Yoshikazu Homma.   

Abstract

We have first observed the nucleation and growth process of carbon nanotubes (CNTs) from iron carbide (Fe 3C) nanoparticles in chemical vapor deposition with C 2H 2 by in situ environmental transmission electron microscopy. Graphitic networks are formed on the fluctuating iron carbide nanoparticles, and subsequently CNTs are expelled from them. Our atomic scale observations suggest that carbon atoms diffuse through the bulk of iron carbide nanoparticles during the growth of CNTs.

Entities:  

Year:  2008        PMID: 18505300     DOI: 10.1021/nl080452q

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


  32 in total

1.  In situ evidence for chirality-dependent growth rates of individual carbon nanotubes.

Authors:  Rahul Rao; David Liptak; Tonya Cherukuri; Boris I Yakobson; Benji Maruyama
Journal:  Nat Mater       Date:  2012-01-29       Impact factor: 43.841

2.  Heterojunctions between metals and carbon nanotubes as ultimate nanocontacts.

Authors:  Julio A Rodríguez-Manzo; Florian Banhart; Mauricio Terrones; Humberto Terrones; Nicole Grobert; Pulickel M Ajayan; Bobby G Sumpter; Vincent Meunier; Mingsheng Wang; Yoshio Bando; Dmitri Golberg
Journal:  Proc Natl Acad Sci U S A       Date:  2009-03-09       Impact factor: 11.205

3.  Nanocatalyst shape and composition during nucleation of single-walled carbon nanotubes.

Authors:  Jose L Gomez-Ballesteros; Juan C Burgos; Pin Ann Lin; Renu Sharma; Perla B Balbuena
Journal:  RSC Adv       Date:  2015       Impact factor: 3.361

4.  Metastable morphological states of catalytic nanoparticles.

Authors:  Pin Ann Lin; Bharath Natarajan; Michael Zwolak; Renu Sharma
Journal:  Nanoscale       Date:  2018-03-01       Impact factor: 7.790

5.  Direct evidence of atomic-scale structural fluctuations in catalyst nanoparticles.

Authors:  Pin Ann Lin; Jose L Gomez-Ballesteros; Juan C Burgos; Perla B Balbuena; Bharath Natarajan; Renu Sharma
Journal:  J Catal       Date:  2017-04-03       Impact factor: 7.920

6.  Dysprosium-catalyzed growth of single-walled carbon nanotube arrays on substrates.

Authors:  Yong Qian; Chunyan Wang; Bin Huang
Journal:  Nanoscale Res Lett       Date:  2009-11-29       Impact factor: 4.703

7.  Preferential Growth of Semiconducting Single-Walled Carbon Nanotubes on Substrate by Europium Oxide.

Authors:  Yong Qian; Bin Huang; Fenglei Gao; Chunyan Wang; Guangyuan Ren
Journal:  Nanoscale Res Lett       Date:  2010-07-18       Impact factor: 4.703

8.  A structure and activity relationship for single-walled carbon nanotube growth confirmed by in situ observations and modeling.

Authors:  Hsin-Yun Chao; Hua Jiang; Francisco Ospina-Acevedo; Perla B Balbuena; Esko I Kauppinen; John Cumings; Renu Sharma
Journal:  Nanoscale       Date:  2020-11-05       Impact factor: 7.790

9.  Degradation of Carbon Nanotube Array Thermal Interface Materials through Thermal Aging: Effects of Bonding, Array Height, and Catalyst Oxidation.

Authors:  Andreas Nylander; Josef Hansson; Torbjörn Nilsson; Lilei Ye; Yifeng Fu; Johan Liu
Journal:  ACS Appl Mater Interfaces       Date:  2021-06-23       Impact factor: 9.229

10.  Heteroepitaxial growth of single-walled carbon nanotubes from boron nitride.

Authors:  Dai-Ming Tang; Li-Li Zhang; Chang Liu; Li-Chang Yin; Peng-Xiang Hou; Hua Jiang; Zhen Zhu; Feng Li; Bilu Liu; Esko I Kauppinen; Hui-Ming Cheng
Journal:  Sci Rep       Date:  2012-12-13       Impact factor: 4.379
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