The effect of various input parameters on the production of carbon nanostructures using a simple microwave plasma-enhanced chemical
vapour deposition technique has been investigated. The technique utilises a conventional microwave oven as the microwave energy source.
The developed apparatus is inexpensive and easy to install and is suitable for use as a carbon nanostructure source for potential
laboratory-based research of the bulk properties of carbon nanostructures. A result of this investigation is the reproducibility of
specific nanostructures with the variation of input parameters, such as carbon-containing precursor and support gas flow rate. It
was shown that the yield and quality of the carbon products is directly controlled by input parameters. Transmission electron
microscopy and scanning electron microscopy were used to analyse the carbon products; these were found to be amorphous, nanotubes
and onion-like nanostructures.
Carbon nanotubes (CNTs), since their discovery almost two decades ago, have proved to be interesting structures; exhibiting
field-emission, superconductivity, capillarity and high stiffness.1,2,3,4,5 These properties have allowed for the
development of numerous experimental devices, such as field effect transistors with a CNT channel, probe tips for microscopy
and chemical sensors.6,7,8 Other carbon nanostructures, such as nanonecklaces and onion-like nanostructures (ONSs),
9 have also been grown from similar processes to those used to produce CNTs.9,10 Various methodologies
have produced CNTs; the more popular methods being laser ablation, arc discharge and chemical vapour deposition (CVD).
11,12,13,14,15,16,17,18
In a CVD process, a gas comprising carbon, such as carbon monoxide or an evaporated hydrocarbon, is dissociated
into its constituent elements in the presence of a metallic catalyst. The metal catalyst provides nucleation points
for the growth of the carbon nanostructures, with the diameters of any CNTs grown depending on the size of the metal
particle on which it nucleates.19 A support gas (usually argon or hydrogen) may be introduced into the
system in order to reduce the quantity of amorphous carbon formed and increase CNT yield.
20,21,22,23 The described system is a variant of the CVD process and utilises plasma to provide additional energy to the system
to decompose the carbon-carrying precursor; this form of CVD process is known as plasma-enhanced chemical vapour deposition
(PECVD). A few of the advantages of this method are the flexibility of the carbon precursor and process parameters such as
reaction temperature and pressure. There is, subsequently, more freedom in controlling the method and manner of nanostructure
growth, making PECVD an attractive option for researchers. In order to research various carbon nanostructure properties, such as bulk conductivity, one needs a simple, reliable method
to produce such structures. To this end, we developed a plasma-enhanced chemical vapour deposition method which, with minor
adjustments, such as a change of hydrocarbon precursor and/or the variation of support gas flow rate, results in the formation
of different nanostructures.
The experimental setup utilised a microwave PECVD technique to atomise a hydrocarbon precursor. The entire process occurred within
a plasma chamber that was placed inside a 1000 W microwave oven and is shown schematically in Figure 1. The only modification made
to the oven was the replacement of the standard door with an aluminium sheet; the magnetron, waveguide and cavity remained intact.
The plasma chamber was made from borosilicate glass; comprising a modified standard 1000-mL flask with two glass inlet tubes attached
tangentially to the sides. The hydrocarbon precursor and support gases were injected into the plasma chamber through each of these
inlets. A third outlet tube was inserted into the ‘neck’ of the flask, leading to a rotary pump. The uppermost part of
the third tube also formed a stand for an aerial and substrate.
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Figure 1: Schematic of the microwave plasma-enhanced chemical vapour deposition system
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The presence of hydrogen is an important component in the production of CNTs in a CVD process.20 Hydrogen was therefore
selected as the support gas, at a flow rate that varied between 0 L/min and 10 L/min. Three base hydrocarbons were selected as a
carbon source based on their hydrogen-to-carbon ratio. These were ethanol (3:1), xylene (10:8) and toluene (8:7). The growth of
CNTs utilising these three hydrocarbons as the precursor has been previously demonstrated.19,24
,25,26,27 It has been
established that thiophene acts as a promoter in the formation of CNTs.28,29 For the ethanol experiments, varying
concentrations (by weight) of thiophene were added. The hydrocarbons were introduced into the plasma chamber by pumping in the
liquid form. An ‘aerial’, comprising a stainless steel base and a 2 mm diameter Nilo K® (Ni 29%, Fe 53%, Co 17%;
Goodfellow Cambridge Ltd, Huntingdon, United Kingdom) tip was located on the borosilicate stand within the plasma chamber.
Nilo K® was selected as its constituent elements have been previously utilised as catalysts in CVD processes.
28,30,31,32,33,34
The aerial served three purposes: confining the plasma to the immediate proximity of the aerial tip, functioning as a catalytic
source for CNT growth and providing a substrate on which the CNTs could form. Plasma confinement is vital in order to prevent
the melting of the plasma chamber. The operating temperature was estimated to be between 800 K and 1100 K, by observing the
effect of the plasma on the borosilicate chamber and the Nilo K® aerial. For all of the ethanol experiments (thiophene quantity notwithstanding), deposition occurred only on the aerial tip; the
xylene and toluene experiments, however, resulted in the sides of the plasma chamber being coated with a carbon film. The
quality of the nanoproduct formed was assessed via microscopy and analysis of samples was conducted using a JEOL JEM 1010
transmission electron microscope (JEOL Ltd, Tokyo, Japan) and a LEO 1450 scanning electron microscope (Carl Zeiss SMT Ltd, Cambridge, UK).
Scanning electron microscopy (SEM) analysis indicated that the technique reliably produced various carbon nanostructures, including
ONSs and CNTs. Figure 2 shows CNTs formed amidst amorphous carbon. Transmission electron microscopy (TEM) analysis revealed that the described technique yielded various nanostructures, including the
conventional CNTs, Y-junction tubes34 and ONSs. Figure 3 shows the nanostructures formed in the experiments conducted with
ethanol (excluding a promoter) as the carbon source. At low or no hydrogen flow, the product was dominated by amorphous carbon; Figure
3a shows amorphous carbon formed at a hydrogen flow rate of 1 L/min. As the hydrogen flow rate was increased, the quantity of amorphous
carbon was reduced and ONSs were formed; Figure 3b shows the ONSs formed at a hydrogen flow of 5 L/min. As the hydrogen flow rate was
increased even further, CNTs were formed, rather than ONSs; Figure 3c shows the CNTs that formed at 10 L/min. However, the CNTs formed
in the ethanol-only experiments were characterised by uneven tube walls and had variable diameters. This was a result of the variable
growth site sizes on the Nilo K® aerial tip.
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Figure 2: Scanning electron micrograph of carbon nanotubes formed at a non-optimal
point for the outlined process, where carbon nanotubes are shown in
the presence of amorphous carbon
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Figure 3: Transmission electron micrographs of the ethanol (without a promoter) experiment
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Figure 4 shows the product formed when 0.5% thiophene (by weight) was added to ethanol. It was immediately apparent that the addition
of thiophene resulted in an increase in the number of CNTs produced. Figure 4a shows uneven-walled CNTs formed with variable diameters
without the addition of hydrogen, while Figure 4b shows ONSs formed at a hydrogen flow rate of 7.5 L/min. It was observed that, when
compared to the ethanol-only experiments, the production of the ONSs was delayed (in terms of hydrogen flow rate). In the ethanol-only
experiments, the ONSs were found to grow when the hydrogen flow was between 5 L/min and 7.5 L/min, whereas when 0.5% thiophene was
added to ethanol, the ONSs only began to form at 7.5 L/min. It was also observed that as the hydrogen flow rate increased, there
was a decrease in the formation of amorphous carbon.
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Figure 4: Transmission electron micrograph showing the product
formed when 0.5% thiophene (by weight)
is added to ethanol
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Figure 5: Bundles of smooth-walled carbon nanotubes formed with 1.5% thiophene and a
hydrogen flow rate of 1 L/min; the CNTs grown here vary in individual tube
diameters and reduced quantities of amorphous carbon can be observed
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No ONSs, and a considerably reduced amount of amorphous carbon, were produced when 1.5% thiophene (by weight) was added to ethanol.
Without hydrogen, CNTs were formed in abundance, but were characterised by uneven tube walls and other deformations such as branching.
As the hydrogen flow rate was increased to 1 L/min, the quantity and quality of CNTs improved, as shown in Figure 5. CNTs grown here
had smooth walls, but exhibited slight variations in individual tube diameters, with reduced quantities of amorphous carbon in the sample.
A SEM micrograph of these tubes, with the sample sonicated in ethanol, is shown in Figure 6.
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Figure 6: A plethora of carbon nanotubes grown with an ethanol-thiophene solution as the
hydrocarbon source and hydrogen as the support gas; this sample was sonicated in
ethanol before scanning electron microscopy analysis
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As the hydrogen flow rate was increased even further, it was observed that amorphous carbon was removed. It appears, however, that there
was an optimal hydrogen flow rate for this process, beyond which the quality of the CNTs produced decreased, as shown in Figure 7.
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Figure 7: Poorly formed carbon nanotubes formed at a hydrogen flow rate of 10 L/min; while
the tubes have uneven walls, diameters appear to be consistent from tube to tube
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Figure 8: Transmission electron micrograph of onion-like
nanostructures grown with toluene as the
base hydrocarbon
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Changing the hydrocarbon precursor to toluene (without a promoter) yielded very different results. The only nanostructures found at all
hydrogen flow rates tested were ONSs. Figure 8 shows the product formed at, (a) the lower (0 L/min) and (b) upper limits (10 L/min) of
hydrogen flow. In both cases, the entire plasma chamber was coated with the product, compared to just the Nilo K® aerial
tip in the ethanol-based experiments. There appeared to be no amorphous carbon formed at any hydrogen flow rate when toluene was
introduced as the hydrocarbon precursor.
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Figure 9: Transmission electron micrograph of onion-like nanostructures
formed with xylene as the precursor and no support gas
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Utilising xylene as the hydrocarbon precursor yielded similar results to those from the toluene experiment. This result was not
unexpected, due to the similar hydrogen-to-carbon ratios of the two hydrocarbons. Amorphous carbon was absent from any of the samples and,
once again, ONSs were the only structures observed at all tested hydrogen flow rates. The plasma chamber, including the aerial, was coated
in the product. Figure 9 shows the ONSs formed without hydrogen.
This work has demonstrated that, under different input parameters (i.e. the variation of the hydrocarbon precursor or the flow rate
of hydrogen) our apparatus could selectively produce CNTs or ONSs. For the production of CNTs, one would use an ethanol-based solution
as the hydrocarbon source. The addition of thiophene to the ethanol promoted the growth of smoother CNTs and also increased the yield of
CNTs at a constant hydrogen flow rate. For the growth of ONSs, either toluene or xylene could be used. It was observed that an increase in
hydrogen flow reduced the formation of amorphous carbon. Variations in the CNT diameters were attributed to the non-uniform growth sites on
the Nilo K® aerial tip. As our apparatus utilised a minimally modified, conventional microwave oven for the production of
carbon nanostructures, we consider this method simpler and cheaper than other equivalent microwave PECVD techniques that incorporate
waveguide components such as matchers, directional couplers and tuners.
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