Indian Journal of Engineering & Materials Sciences

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Synthesis and (some) applications of carbon-nanotube-supported pyrolytic carbon nanocones


Affiliations
1 Center of Elaboration of Materials and Structural Studies (CEMES), UPR-8011 CNRS, Toulouse University, Toulouse 31055, France
2 Nanoscience Research Laboratory, Pontifical Catholic University Madre y Maestra (PUCMM), Apartado Postal 822,Santiago De Los Caballeros 51000, Dominican Republic
3 Center of Elaboration of Materials and Structural Studies (CEMES), UPR-8011 CNRS, Toulouse University, Toulouse 31055,, France
4 Institute of Fluid Mechanics of Toulouse (IMFT), UMR 5502 CNRS, Toulouse 31055, France

Graphene-based cones with nanosized apex can be obtained by means of a high temperature pyrolytic carbon deposition process using methane and hydrogen as gaseous feedstock and single carbon nanotubes as deposition substrates. Aside the cones, micrometer-sized carbon beads or fibre segments are deposited meanwhile which are a key morphological component for allowing handling and mounting the carbon cones and then using them for various applications. Based on both the literature dealing with pyrolytic carbon deposition processes and experimental observations, a peculiar deposition mechanism is proposed, involving the transient formation of pitch-like liquid phase droplets which deposit onto the individual carbon nanotubes. In this picture, it is believed that a key parameter is the diameter ratio for the droplets and the nanotubes, respectively. The cone concentric texture and perfect nanotexture are shown by high resolution transmission electron microscopy, which allows interesting mechanical and conducting properties to be predicted. Correspondingly, applications of the carbon nanocones as electron emitters for cold-field electron sources on the one hand, and as probes for various modes of near-field microscopy on the other hand, have been tested.
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  • Synthesis and (some) applications of carbon-nanotube-supported pyrolytic carbon nanocones

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Authors

Germercy Paredes Paredes
Center of Elaboration of Materials and Structural Studies (CEMES), UPR-8011 CNRS, Toulouse University, Toulouse 31055, France
Germercy Paredes
Nanoscience Research Laboratory, Pontifical Catholic University Madre y Maestra (PUCMM), Apartado Postal 822,Santiago De Los Caballeros 51000, Dominican Republic
Grégory Seine
Center of Elaboration of Materials and Structural Studies (CEMES), UPR-8011 CNRS, Toulouse University, Toulouse 31055,, France
Robin Cours
Center of Elaboration of Materials and Structural Studies (CEMES), UPR-8011 CNRS, Toulouse University, Toulouse 31055, France
Florent Houdellier
Center of Elaboration of Materials and Structural Studies (CEMES), UPR-8011 CNRS, Toulouse University, Toulouse 31055, France
Hatem Allouche
Center of Elaboration of Materials and Structural Studies (CEMES), UPR-8011 CNRS, Toulouse University, Toulouse 31055, France
Thierry Ondarçuhu
Institute of Fluid Mechanics of Toulouse (IMFT), UMR 5502 CNRS, Toulouse 31055, France

Abstract


Graphene-based cones with nanosized apex can be obtained by means of a high temperature pyrolytic carbon deposition process using methane and hydrogen as gaseous feedstock and single carbon nanotubes as deposition substrates. Aside the cones, micrometer-sized carbon beads or fibre segments are deposited meanwhile which are a key morphological component for allowing handling and mounting the carbon cones and then using them for various applications. Based on both the literature dealing with pyrolytic carbon deposition processes and experimental observations, a peculiar deposition mechanism is proposed, involving the transient formation of pitch-like liquid phase droplets which deposit onto the individual carbon nanotubes. In this picture, it is believed that a key parameter is the diameter ratio for the droplets and the nanotubes, respectively. The cone concentric texture and perfect nanotexture are shown by high resolution transmission electron microscopy, which allows interesting mechanical and conducting properties to be predicted. Correspondingly, applications of the carbon nanocones as electron emitters for cold-field electron sources on the one hand, and as probes for various modes of near-field microscopy on the other hand, have been tested.