Simulation analysis of influence factors for preparation of dispersed cap-open carbon nanotubes using CCVD

Zhen Feng Sun; Le Hua Qi; Shu Yang Shu; He Jun Li

doi:10.1177/0731684411408159

Simulation analysis of influence factors for preparation of dispersed cap-open carbon nanotubes using CCVD

Zhen Feng Sun, Le Hua Qi, Shu Yang Shu, He Jun Li

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

In order to investigate the reaction mechanism and production rate for the growth of dispersed cap-open carbon nanotubes (CNTs) in catalyst chemical vapor deposition, computational fluid dynamics (CFD) model with multi-step reaction was developed in this study. The CFD calculations coupled with temperature field and concentration field demonstrated that laminar flow conditions were presented and steep thermal gradient and concentration gradient existed in the axis of the reactor. Applying the CFD calculation, total deposition rate of CNTs in the reactor were predicted with the variation of the processing parameters. The results show that the maximum deposition rate can be obtained with the temperature from 1050 to 1200 K and the flow rate of the ethanol should be controlled over 300 sccm.

Original language	English
Pages (from-to)	763-768
Number of pages	6
Journal	Journal of Reinforced Plastics and Composites
Volume	30
Issue number	9
DOIs	https://doi.org/10.1177/0731684411408159
State	Published - May 2011

Keywords

carbon nanotubes
catalyst chemical vapor deposition
computational fluid dynamics
numerical simulation

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title = "Simulation analysis of influence factors for preparation of dispersed cap-open carbon nanotubes using CCVD",

abstract = "In order to investigate the reaction mechanism and production rate for the growth of dispersed cap-open carbon nanotubes (CNTs) in catalyst chemical vapor deposition, computational fluid dynamics (CFD) model with multi-step reaction was developed in this study. The CFD calculations coupled with temperature field and concentration field demonstrated that laminar flow conditions were presented and steep thermal gradient and concentration gradient existed in the axis of the reactor. Applying the CFD calculation, total deposition rate of CNTs in the reactor were predicted with the variation of the processing parameters. The results show that the maximum deposition rate can be obtained with the temperature from 1050 to 1200 K and the flow rate of the ethanol should be controlled over 300 sccm.",

keywords = "carbon nanotubes, catalyst chemical vapor deposition, computational fluid dynamics, numerical simulation",

author = "Sun, {Zhen Feng} and Qi, {Le Hua} and {Yang Shu}, Shu and Li, {He Jun}",

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AU - Sun, Zhen Feng

AU - Qi, Le Hua

AU - Yang Shu, Shu

AU - Li, He Jun

PY - 2011/5

Y1 - 2011/5

N2 - In order to investigate the reaction mechanism and production rate for the growth of dispersed cap-open carbon nanotubes (CNTs) in catalyst chemical vapor deposition, computational fluid dynamics (CFD) model with multi-step reaction was developed in this study. The CFD calculations coupled with temperature field and concentration field demonstrated that laminar flow conditions were presented and steep thermal gradient and concentration gradient existed in the axis of the reactor. Applying the CFD calculation, total deposition rate of CNTs in the reactor were predicted with the variation of the processing parameters. The results show that the maximum deposition rate can be obtained with the temperature from 1050 to 1200 K and the flow rate of the ethanol should be controlled over 300 sccm.

AB - In order to investigate the reaction mechanism and production rate for the growth of dispersed cap-open carbon nanotubes (CNTs) in catalyst chemical vapor deposition, computational fluid dynamics (CFD) model with multi-step reaction was developed in this study. The CFD calculations coupled with temperature field and concentration field demonstrated that laminar flow conditions were presented and steep thermal gradient and concentration gradient existed in the axis of the reactor. Applying the CFD calculation, total deposition rate of CNTs in the reactor were predicted with the variation of the processing parameters. The results show that the maximum deposition rate can be obtained with the temperature from 1050 to 1200 K and the flow rate of the ethanol should be controlled over 300 sccm.

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KW - catalyst chemical vapor deposition

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Simulation analysis of influence factors for preparation of dispersed cap-open carbon nanotubes using CCVD

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