Controlling dissociative adsorption for effective growth of carbon nanotubes

Diss-adsopt-APL2004

Dissociative adsorption has been widely simplified as part of the vapor–liquid–solid (VLS) growth

model. We found that the addition of specific carrier gases can critically modify the growth rate and

growth density of multiwall carbon nanotubes (MWNTs). These results were explained by

dissociative adsorption of C2H2 molecules and a solid-core VLS growth model. Based on these

integrated mechanisms, vertically aligned MWNTs were grown with an initial growth rate as high

as ,800 mm/h. This efficient growth process results at temperature and C2H2 partial pressures at

which the decomposition and segregation rates of carbon are balanced. Appropriate use of carrier

gas is one of the factors that could facilitate efficient and continuous growth of carbon nanotubes in

the future.

Surfactant-free dielectrophoretic deposition of multi-walled carbon nanotubes with tunable deposition density

DEP-Carbon2010

The effects of AC field strength and AC frequency on the density of dielectrophoretically deposited multi-walled carbon nanotubes (MWCNTs) were investigated and explained in terms of existing theory. We show that while both parameters can be used to control deposition density, the experimentally observed frequency trend can not be explained by the theoretical Clausius–Mossotti factors. We demonstrate the ability to make surfactant-free dispersions of long, difficult to disperse MWCNTs and use them with dielectrophoresis to make clean, single and few connections between electrodes.

Dielectrophoretic Deposition of Carbon Nanotubes with Controllable Density and Alignment

DEP_CNT_MRS2008

Controlled deposition of carbon nanotubes (CNTs) across desired electrodes is important

for the fabrication of nanoelectronic devices. Dieletrophoresis (DEP) has been recognized as a

convenient and affordable technique for the deposition of nanotubes and nanowires on

electrodes. Although DEP has been quite well studied for dielectric particles, the application for

depositing nanotubes is still at the early stage of development. Here, we show that multi-walled

CNTs can be deposited by DEP with controllable density and degree of alignment.

Vertically Aligned Carbon Nanotubes as the Sputter Resist in Space Propulsive Systems

CNTSpacePropulsionMRS2005

Two-types of vertically aligned multi-walled carbon nanotubes (VA-MWNTs) are

evaluated as the protective coatings against ion erosion in electric propulsion systems. A

series of experiments have been conducted to understand the erosion rate and erosion

mechanism of these VA-MWNTs. These experiments were carried out with Xe

propellant at an ion current density of 5 mA/cm2. We found that the erosion rates of both

types of VA-MWNTs were changing with time. Such a nonlinear erosion process is

explained according to a possible erosion mechanism.

High-density vertically aligned multiwalled carbon nanotubes with tubular structures

CNTs-APL2005

Ammonia sNH3d gas was thought to be essential for the growth of vertically aligned multiwalled

carbon nanotubes sVA-MWCNTsd and led to the formation of bamboo-like structures. Here, we

show that VA-MWCNTs with ideal tubular structures can be grown on substrates by various mixed

gases with or without NH3 gas. The growth of these VA-MWCNTs is guided by a growth model that

combined the dissociative adsorption of acetylene molecules sC2H2d and the successive

vapor-liquid-solid growth mechanism. Results indicate that the key factor for growing these

VA-MWCNTs is a balance between the decomposition rate of the C2H2 molecules on the iron

catalyst and the subsequent diffusion and segregation rates of carbon.

© 2005 American Institute of Physics. fDOI: 10.1063/1.1952575g

Effect of Carrier Gas on the Growth Rate, Growth Density, and Structure of Carbon Nanotubes

CNT_Syn_MRS2004

We attempt to understand the fundamental factors that determine the growth rate

of carbon nanotubes. In a series of experiments on growing multiwall carbon nanotubes

(MWNTs) by thermal chemical vapor deposition, we found that the addition of carrier

gas and the type of carrier gas can change the growth rate, growth density, and structures

of MWNTs. We explain these results based on the dissociative adsorption of C2H2 on Fe

nanoparticles and the vapor-liquid-solid (VLS) growth model. Finally, high-density,

vertically aligned MWNTs were grown when decomposition and segregation rates of

carbon were balanced.

Testing Multiwall Carbon Nanotubes on Ion Erosion for Advanced Space Propulsion

CNT_SpacePropulsionMRS2004

Are carbon nanotubes more resistant than diamonds against ion erosion?

Here, we report an evaluation of multiwall carbon nanotubes (MWNTs) as the protective

coating against plasma erosion in advanced space propulsion systems. We have compared

polycrystalline diamond films with MWNTs, amorphous carbon (a-C) and boron nitride

(BN) films. Two types of MWNTs were investigated including vertically aligned (VA)

MWNTs, and those horizontally laid on the substrate surfaces. Only diamond films and

VA-MWNTs survived erosion by 250 eV krypton ions of a flight-quality Hall-effect

thruster. VA-MWNTs are found to bundle at their tips after ion erosion.

A Dual-RF-Plasma Approach for Controlling the Graphitic Order and Diameters of Vertically-Alligned Multiwall Carbon Nanotubes

CNT_MRS2005

Plasma enhanced chemical vapor deposition (PECVD) is a unique technique for growing

vertically-aligned multiwall carbon nanotubes (VA-MWNTs) at controllable tube densities. This

technique is of considerable importance for low temperature growth of VA-MWNTs at desired

locations. However, the graphitic order of these MWNTs is inferior to those grown by laser

ablation, arc discharge, and thermal CVD techniques. Previously, these VA-MWNTs were

grown by a one-plasma approach (DC, microwave etc), either for gas decomposition or substrate

biasing. Here, we describe a dual-RF plasma enhanced CVD (dual-RF-PECVD) technique that

offers unique capability for controlling the graphitic order and diameters of VA-MWNTs.