Time evolution of the growth of single graphene crystals and high
resolution isotope labelingjournal homepage: www.elsevier
.com/locate/carbon
Time evolution of the growth of single graphene crystals and high
resolution isotope labeling
Eric Whiteway a, *, Wayne Yang a, b, Victor Yu a, Michael Hilke
a
a Department of Physics, McGill University, Montreal, H3A 2T8,
Canada b Now at Bionanoscience Department, Kavli Institute of
Nanoscience, Delft University of Technology, Delft,
Netherlands
a r t i c l e i n f o
Article history: Received 11 May 2016 Received in revised form 18
August 2016 Accepted 14 September 2016 Available online 25
September 2016
* Corresponding author. E-mail address:
[email protected]
(E. W
http://dx.doi.org/10.1016/j.carbon.2016.09.034 0008-6223/© 2016
Elsevier Ltd. All rights reserved.
a b s t r a c t
We developed a method of precise isotope labeling to visualize the
continuous growth of graphene by chemical vapour deposition (CVD).
This method allows us to observe, as a function of time, the growth
of graphene monocrystals at a resolution of a few seconds. This
technique is used to extract the anisotropic growth rates, as well
as investigate the formation of dendrites, and the dependence of
growth rate on adsorption area of methane on copper. This technique
also gives precise start times for individual gra- phene nucleation
sites. We obtain a physical picture of the growth dynamics of
graphene and its dependence on various parameters. Finally, our
method is relevant to other CVD grown materials.
© 2016 Elsevier Ltd. All rights reserved.
1. Introduction
Graphene is a two dimensional material which has attracted a great
deal of attention for its unique physical and electronic prop-
erties [1e3]. Originally isolated by mechanical exfoliation of
graphite [4], more scalable methods necessary for production of
large scale graphene layers and industrial applications include
chemical vapour deposition [5,6] and graphitization of SiC [7].
Chemical vapour deposition (CVD) of graphene sheets on com- mercial
polycrystalline copper foils is a leading candidate for the
production of large high quality graphene films. One of the chal-
lenges in producing high quality graphene by CVD is controlling the
nucleation density of graphene crystals which in turn limits the
size of individual crystals. Grain boundaries where different
misor- iented graphene crystals come together are known to reduce
the mechanical strength and electronic properties of graphene
[8,9].
Since the pioneering work of Li et al. in graphene CVD on copper
foils [6] a great deal of work has been done in determining the
optimal conditions to produce large single crystal graphene and
understanding the role of various growth parameters in the CVD
process [10]. This has led to large gains in the size and quality
of single crystal graphene flakes which can be produced [11,12] up
to mm and cm scales. Analyzing and understanding the growth dy-
namics of CVD graphene, is one of the main contributions of
this
hiteway).
work. Previous works studying graphene CVD growth dynamics
have
been done. These have either relied on in-situ LEEMmeasurements
[13e16] or been done using an alternating isotope labelling method
employing fewer than ten time intervals [10,17,18]. In our work we
developed a method to continuously image and recreate the crystal
growth ex-situ, i.e., after the crystal is fully grown. This is
achieved by varying the relative ratio of the isotopes continuously
during the growth process. The isotope concentration will therefore
provide a unique label determining when the material was grown.
This method is similar to carbon dating, where the isotope
concentra- tion of radio active carbon decays over time and
therefore allows the dating of organic materials [19]. The
difference here, are the time scales involved (seconds) versus
hundreds of years and the spatial dependence, which allows us to
correlate the position with time.
Our method of continuous isotope labelling is less technically
demanding than in situ-LEEM measurements, and compared to previous
isotope labelling methods represents an order of magni- tude
improvement in the number of discernible time steps (less than 10
vs. greater than 80). This allows us to probe the dynamics of CVD
growth on copper in more detail thanwas previously possible. This
technique is used to extract new information on dendrite formation
and quantify the effect of adsorption area of methane on copper, as
well as extract data on the nucleation time of specific crystals
and build up movies of the CVD growth process.
The ability to visualize the growth of atomic materials has
important implications, particularly with the recent
development
E. Whiteway et al. / Carbon 111 (2017) 173e181174
and potential of hybrid materials beyond graphene [4,20], where the
atomic layering and growth history is an important factor. For
graphene, in particular, this method not only gives new insights on
the growth dynamics, like the formation of dendrites, of nucleation
sites or additional layers as discussed here, but the varying
isotope method can also be used to label certain areas of the
crystal without changing its electronic properties. Other
applications include the possibility to tune the nuclear spin
density [21], the ability to do phonon engineering [22], reduce
thermal conductivity due to phonon disorder [23], determine
chemical and vibrational prop- erties of different layers [18],
increase sensitivity to determine specific phonon modes [24], and
others [25e27].
Here we provide new results organized along three main themes:
continuous labeling and determination of the sensitivity of the
method, which can provide close to hundred independent labeling or
time steps; dynamic growth or the making of movies and time
snapshots of the growth, in particular the fractal growth of
graphene; growth rates and the dependence of the growth rates on
anisotropy, dendricity and growth diffusion area.
2. High resolution continuous labeling method
In general, the possibility to label a material locally is of
importance in a number of applications. Indeed, it allows infor-
mation to be encoded, without modifying the basic properties. In
the case of graphene, this can be particularly useful in areas
where transparency, organic composition or low mass is important,
such in labeling electronic devices or biomolecules. The labeling
is done by using different relative concentrations of isotopes,
which can then be used for encoding or transparent labeling. The
detection is achieved by Raman spectroscopy, which is used to
characterize graphene [28] and other graphitic materials [29]. Here
we use a combination of precisely controlled isotopic methane flow
(12C and 13C) and Raman mapping to probe the growth dynamics of
gra- phene crystals in much greater detail than is possible when
using only a binary on/off isotopic variation method [17].
Several samples were prepared using pure 12CH4, pure 13CH4 and
various mixes. The exact growth conditions are detailed in the
supporting information. In the 13C carbon isotope graphene we
observe a downshift in Raman peak position by a factor of
approximately
ffiffiffiffiffiffiffiffiffiffiffiffiffiffi 12=13
p as a result of the change in the mass of the
carbon atoms [6,24]. Sample A was prepared where the ratio of
12C:13C methane was modified stepwise throughout the growth in 10%
intervals to give ratios of 9:1, 8:2, etc. A Raman map of this
sample is shown in Fig. 1a where we observe bands of graphene with
different 2D peak positions. The Raman spectroscopy was performed
with a grating of 1800 lines/mm and resolution of 1.55 cm1.
Plotting the position of the 2D peak for each of these bands we
find and excellent agreement with the predicted linear behaviour
where the position of the peak is a function of the average mass of
carbon atoms in a given region. Taking x to be the fraction of 12C
and Du ¼ u2Dð12CÞ u2Dð13CÞ we have
u2DðtÞ ¼ u2Dð13CÞ þ xDu (1)
The fit is done to a linear functionwith u0 2Dð12CÞ and u2D(13C)
as
free parameters and gives values of 2686.7 cm1 and 2580.6 cm1
respectively. The theoretical line plotted in Fig. 1c shows the
expected result
taking u2D(12C) as 2687 cm1. The excellent agreement quantifies the
precision with which the isotopic ratio of our graphene during CVD
growth and extract this value by Raman spectroscopy of our samples.
The average standard deviation for the peak position for a given
concentration is s ¼ 1.4 cm1. This translates into a labeling
resolution of
Rl ¼ s=Dux1:3102 (2)
The high resolution allows the labeling of 1/Rl x 80 regions
independently. Moreover, most physical properties are not affected
by the labeling, except for Raman process. This can be used for a
variety of applications, such as encryption, variable nuclear spin
concentration, or even isotope concentration detection. In what
follows, we will use it in order to gain insight into the growth
mechanism of graphene.
3. Dynamic imaging
CVD growth using isotopic methane is a useful tool to charac-
terize the growth of polycrystalline sheets [6,17] and graphene
single crystals. Typically this has been done by using alternating
flow of 12C and 13C methane to produce graphene which displays a
tree-ring like growth pattern [6]. Here, several graphlocon samples
were prepared with the ratio of 12C to 13C varying linearly as a
function of time. Sample B, shown in Fig. 3, was first annealed in
hydrogen at 1073 C for 4 h to prepare the surface and then gra-
phenewas deposited during a 400 s growth phase with a combined
methane flow of 1.2 sccm. The flowrate of 12CH4 and 13CH4, as well
as the isotopic ratio are shown in Fig. 2 as a function of time.
Since the Raman peak position is proportional to the isotopic
concen- tration (Fig. 1), we can then extract the expected 2D peak
position at any given time using eq. (1).
The growth conditions employed for this sample were designed to
give an incomplete growth with dendritic graphlocons [30]. A Raman
map was taken with grid spacing of 900 nm. A spectrum was taken at
each point on the grid with a collection time of 1s. The position,
width and intensity of the 2D peak were then extracted. We observe
that the 2D position is lowest at the center of the graphlocon and
increases as we move towards the edges. This is consistent with a
growth that begins with primarily 13C methane, with the 12C
concentration increasing with time. The analysis could equally be
performed using the G or other Raman graphene peak, however the 2D
peak was chosen for the combination of large amplitude and high
Raman shift, which enable the position of the peak to be extracted
with greater precision and lower collection time relative to other
peaks. We also observe in the center of the graphene crystal a
region of bilayer graphene, characterized by a double Raman peak
structure. The growth times for each graphene layer are calculated
from the position of the two independent 2D peaks observed. In
fact, we observed two types of bilayer growth, either Bernal
stacked or not, sometimes even in the same crystal. In the case of
Bernal stacking, the 2D Raman peaks of each layer hy- bridize [31]
to form one peak corresponding to the average mass between the two
layers, while in the non-Bernal stacking, the two Raman peaks
identify the frequencies corresponding to the respective atomic
mass of each layer, with a weak enhancement due to graphene
enhanced Raman scattering [32]. This is indicated in Fig. 3 where
the bilayer is shown in orange. In the last square of Fig. 3 we
show only the contribution of the first Raman peak cor- responding
to the first layer.
This linear shift in peak position allows us to extract an absolute
time scale for the progression of the crystal formation. We can
visualize the growth of the graphlocon as a function of time by
considering the points in the Ramanmapwith u2D < u2D(t). In Fig.
3 we show snapshots of the graphlocon at 8 different points in
time. In the supplementary material the full movie of the graphene
growth is shown.
Supplementary video related to this article can be found at
http://dx.doi.org/10.1016/j.carbon.2016.09.034.
E. Whiteway et al. / Carbon 111 (2017) 173e181 175
3.1. Bilayer growth
We observe two different behaviours in the formation of bilayer
graphene, which are reflected in their Raman spectra. Either with
the two layers acting as independent single layers where we observe
a double peak structure in the 2D band or as a bernal bilayer where
we observe a single peak whose position corre- sponds to the
average carbon mass of the two layers.
The behaviour is correlated with the apparent relative orienta-
tion of the two layers. If the two crystals have the same
orientation we observe Bernal stacking evidenced by the decrease in
intensity of the 2D peak combinedwith a large increase in peak
width. This is consistent with the behaviour of bernal stacked
exfoliated gra- phene, wherewe observe decreased intensity and
increasing width in the 2D peak [31].
We also observe bilayers where the two layers are offset by
Fig. 2. Flowrate of 12C and 13C Methane for sample B in blue,
12C/13C ratio in orange. (A colour version of this figure can be
viewed online.)
approximately 30. In this case the layers behave as independent
bilayers and we observe a double peak structure with a large in-
tensity of the 2D peak relative to the G peak. Both of these
findings are consistent with previously reported orientation
dependence of the 2D peak [33].
Some bilayers display both types of stacking in regions, as seen in
Fig. 4. In this case we see an obvious difference in the 2D/G ratio
for each of three distinct regions, as well as the breaking of the
6- fold symmetry of the 2nd layer in the region that is not bernal
stacked. We shows also a representative spectra from each region
and note that they are distinct in the total number of peaks, peak
width and intensity, allowing us to easily determine the type of
stacking by Raman spectroscopy.
Using these spectral signatures to determine the stacking order we
took a sample of 50þ bilayers across three different samples found
that Bernal stacking is preferred by a ratio of approximately 2:1.
We also note that for both bilayer types we observed decreased
growth rates and delayed nucleation times relative to the first
layer of graphene.
4. Growth rates: anisotropy, dendricity, and diffusion area
It's clear from the isotope labelling that the graphene crystal
grows from the center outwards. This is consistent with previous
studies on CVD graphene growth [17,34,35]. In some of these studies
the crystal symmetry was also determined and various shapes have
been observed, including four-fold and six-fold sym- metries,
depending on the growth conditions and substrate [36]. However, the
local growth rates have not yet been analyzed. Using our data from
the method described in section 3 we are able to extract the growth
rates and directions at every point in the crystal.
4.1. Anisotropy
The growth anisotropy is not affected by the growth stage and
is
Fig. 3. Sample B. Visualizing the growth of a graphene crystal:
Snapshots of the graphene growth showing the combined intensity of
the 2D peak as a function of time. Intensities are scaled to
differentiate between layers 1 and 2. Last square: Raman maps of a
dendritic graphene crystal indicating the Raman shift of the 2D
peak and associated time from the peak position to time
correspondence. Only the layer 1 peak position is shown. (A colour
version of this figure can be viewed online.)
E. Whiteway et al. / Carbon 111 (2017) 173e181176
constant over time during the growth and independent of the size of
the crystal. The radial growth is indeed linear with radius (see
Fig. 3a) and therefore time, since we chose x ~ t. The 12C and 13C
methane flows are calibrated, so that the total methane flow is
constant over time to allow for a precise determination of the time
dependence. To analyze the anisotropy in more detail, we
compare
Fig. 4. Sample B a) High resolution Raman map showing the relative
intensity of the 2D and to the location of the spectra shown in b)
spectra representing the three distinct regions or the G band for
both bilayers as well as different behaviours of the 2D peak
depending on
the growth rate in different directions for a weakly dendritic gra-
phene crystal, shown in Fig. 5b. This sample was prepared with a
combined CH4 flow rate of 1.2 sccm and a H2 flow rate of 80 sccm,
during a 3 min growth phase. The highest growth rates are clus-
tered along 6 arms spaced by roughly 60. By taking profiles along
the fastest and slowest directions we observe that the
average
G peaks of a bilayer region in the center of a graphene crystal.
The markers correspond monolayer, Bernal bilayer and independent
bilayer. We note a double peak structure in stacking type. (A
colour version of this figure can be viewed online.)
Fig. 5. Sample C. a) Colour map indicating the spectral intensity
as a function of Raman shift and position, taken along the fast and
slow profiles of the crystal as indicated in b. b) Magnitude of the
growth velocity shows an increased rate of growth along the six
primary arms of the graphene crystal. c) Effect of methane pressure
on growth speed. (A colour version of this figure can be viewed
online.)
E. Whiteway et al. / Carbon 111 (2017) 173e181 177
growth rate is roughly doubled along the fast profiles when
compared to the slow ones, 9.0 mm/min vs 4.7 mm/min.
The growth rate was extracted for growths performed across a range
of methane gas flows. Comparing the calculated partial pressure of
methane gas with the growth rate we observe a clear linear
relationship. Fig. 5c shows the relationship. In all cases this
data was measured along the fastest growth direction, and includes
samples prepared using the 12C/13C technique discussed in this
article as well as pure 12C samples where the growth rate is
calculated from the diameter of the graphlocon and the growth time.
To probe whether this relationship holds within the same single
crystal, we synthesized sample F using a variable overall methane
flow as well as shifting the 12C/13C ratio and the same range of
growth rates as those extracted from individual growths was
obtained.
4.2. Fractal shape and dendricity
In Ref. [30] it was shown that fractal graphene crystals can be
synthesized using CVD. Fractal shapes can lead to an enhanced
broadband efficiency in antenna designs [37] and the correspond-
ing increased edge to surface ratio, can lead to an enhanced reac-
tivity for chemical processes at the edge [38]. Pushing the
anisotropy further could even lead to the synthesis of quasi one
dimensional arms or graphene nano-ribbons.
A large dendritic sample was synthesized using low pressure and low
gas flow rates. The copper foil was sonicated in acetic acid for
30min prior to growth in order to suppress graphene nucleation and
allow larger domains to form. A high resolution Raman map shows
details of the formation of the dendritic arms of the gra- phene
crystal. The growth rates were extracted along the primary arm of
the crystal as well as several dendrites and shows the dendrites
forming concurrently with the main arm. The average linear growth
velocity is extracted by fitting the distance along each profile to
the time corresponding to the 2D peak position at each point on the
profile. We see that the main arm has a velocity of 18 mm/min while
the dendrites on the side arms have a slower average velocity 11e12
mm/min even though this is along the ”fast” direction. If we slice
our data more finely we can see that many of the dendrites in fact
show an accelerating growth rate. This increasing growth rate as
the dendrites become more pronounced suggests that the growth is
dependent on the local available copper surface, which we discuss
in more detail in the next section. A similar analysis was
performed for several different samples. All samples were produced
using a similar low pressure CVD growth, but with small variations
on the conditions. From the Raman maps of these samples we can
extract the area and perimeter of the graphlocon as a function of
time.
We consider the scaling exponent a defined by A ~ Pa, where A is
the area and P the perimeter. A compact hexagonwould give a ¼ 2,
whereas for a more dendritic shape the value should be lower [39].
In previous works, various scaling exponents have been extracted,
ranging between 1.43 and 2 for different flakes under different
growth conditions and particularly sensitive to growth tempera-
ture [30]. In these works, a could only be extracted once at the
end of the growth for every grown crystal. Here, on the other hand,
we are able to determine how a evolves during the growth process.
We see that the scaling exponent doesn't change as a function of
time as shown below. This means that the growth conditions
determines a, which is time-invariant, while the growth time simply
de- termines the final size of the crystal. Hence, for a dendritic
crystal, the growth rate in the fastest direction is not constant,
but a is.
In Fig. 6b we show the area versus perimeter of 4 different
graphene crystals. A powerlaw fit gives values of a ranging from
1.4 to 1.98 for the scaling exponent. The range of validity of a
single powerlaw extends over the entire size of the crystal,
demonstrating the time invariance of a during the growth process.
We also note that the fractal dimension increases with an
increasing ratio of hydrogen to methane during the growth. In one
case (sample C) we obtain a value of a considerably larger than for
the other samples. This sample, also shown in Fig. 5b, was
preparedwith amuch larger hydrogen flow of 80 sccmwhen compared to
all the other samples, which ranged from 4 to 12 sccm H2 and leads
to fewer dendrites and a x 2.
4.3. Diffusion growth area
Earlier studies have already examined the time dependence of
dendrite growth andmerging in graphene and found that growth is
faster at the tip of the dendrite and slower for regions in between
dendrites and slower at the end of the growth [34].
We observe a similar effect. Fig. 7a shows the Raman map of a fully
covered graphene sheet grown using a linear isotope shift, sample
G. The growth rate is taken along many different profiles and we
see that as we approach a grain boundary the growth rate slows
considerably. In this sample the typical growth rate is in the
range of 20e30 mm/min whereas near the boundaries it drops below 10
mm/min.
To gain insight into this process we analyze sample D, the
dendritic graphene crystal shown Fig. 6a. We show that the growth
rate correlates with the locally available copper surface and argue
that the dendritic growth is limited by the diffusion of the
adsorbed C species on the available copper surface. We estimate the
related diffusion radius to be 6 mm as discussed below.
We extracted the growth rate along many different profiles along
the edge by focusing on the fastest growth direction. From
Fig. 6. Sample D a) Extracting the average growth rate of the
primary arm and several dendrites of a large graphlocon b)
Perimeter and area of the graphlocon as a function of time for
several samples prepared with different growth conditions. Data
points are offset on the y-axis to show the difference in slope,
such that the area of samples C, B and E are scaled by factors of
8,4 and 2 respectively. (A colour version of this figure can be
viewed online.)
E. Whiteway et al. / Carbon 111 (2017) 173e181178
the high resolution raman map we can obtain for any given time t,
the exact shape of the graphlocon as well as the growth rate in any
direction. In Fig. 8 we see two examples illustrating results for
different dendrites. The top line shows the behaviour of a dendrite
growing into free space. As the dendrite grows the shape becomes
more pronounced and the available copper surface increases. This
results in an increasing growth rate. The second line shows a
dendrite growing into occupied space. In this case as the dendrite
grows the available copper surface is decreasing and the growth
rate is limited by the lack of available surface. This results in a
decreasing growth rate. The correlation between the locally avail-
able copper surface and the growth rate was averaged across 20
dendrites. We observe an approximately linear relationship above
30% available surface and a roughly constant growth rate of 5 mm/
min below 30%.
In order to determine the approximate radius of the diffusion area
we first assume that the growth rate is a linear function of free
surface area over the range of 30%e70%. We fit the data in that
range considering radii from 1 to 20 mm and extract the coefficient
of determination r2 for the linear regression. The radius corre-
sponding to the maximum r2 determines our diffusion radius, which
we find to be approximately 6 mm. This value is similar to the
observed spacing of dendrites seen in Fig. 6a. The mechanism
emerging from this, is that the methane is adsorbed on the copper
surface and then diffuses on that surface. Once a graphene nucle-
ation has started, the edge of the crystal requires more methane
while at the same time expelling the accumulated hydrogen from the
copper induced catalytic conversion of methane to carbon. The rate
of this reaction depends on the local concentration of
hydrogen
Fig. 7. Sample G a) Raman map showing the 2D peak position of a
full coverage graphene gr together. (A colour version of this
figure can be viewed online.)
and methane gases. The more methane is available within its
diffusion area, the faster the growth of graphene.
4.4. Nucleation dynamics
Control of graphene nucleation is critical in the production of
high quality monocrystal graphene. Suppressing nucleation is a
critical component in synthesizing large scale graphene crystals
[40]. Previous studies on the effects of different parameters on
nucleation density have shown it to depend on a number of factors
including copper surface morphology [41], preprocessing [42,43] and
growth parameters [10,44]. However all of these studies are limited
by a lack of fine grained time information and an absolute time
scale and cannot establish exactly when nucleation occurs.
Here we show that graphene nucleation is time dependent with
individual crystals nucleating at different times independent of
other factors. The absolute time scale provided by our labeling al-
lows us to extract the exact nucleation time of individual graphene
crystals and to understand the size dependence of graphene crys-
tals in a given sample as a function of their nucleation time. Our
results also show that smaller single layer graphene crystals form
as a result of delayed nucleation and that the mechanism and growth
rate are the same for both smaller and larger crystals. Indeed,
Fig. 9a shows two crystals growing in the same area. The colormap
clearly indicates that the large crystal nucleated earliest and the
smaller nucleated at a later time.
By extracting the growth rate along several profiles we can see
that the rate is consistent across the larger and smaller crystal
but that the nucleation time, indicated by the peak position at
the
owth b) growth rates extracted from the map show a sharp decrease
as crystals merge
Fig. 8. Sample D. Top: Example of an accelerating dendrite. Filled
green circle indicates the free copper surface, Sf, while the arrow
indicates the magnitude of the growth velocity, v. Middle: Growth
velocity as a function of time, with large circles indicating the
snapshots shown. Bottom: an example of a decelerating dendrite. A
full movie can be seen in the supplementary material. (A colour
version of this figure can be viewed online.)
E. Whiteway et al. / Carbon 111 (2017) 173e181 179
center of the crystal is much later in the small crystal. We can
conclude that the large graphlocon formed starting immediately upon
introduction of methane into the three minute CVD process whereas
the smaller crystals did not begin until approximately
Fig. 9. Sample B. a) Different size crystals are shown to start at
different times, by taking l started earlier than the smaller
crystal. b) Linear fit to the profiles shown in c shows that th
time of the two crystals. (A colour version of this figure can be
viewed online.)
1 min later. In contrast, the growth rates extracted from both
crystals are very similar and approximate 8e9 mm/min. The origin
for the different nucleation times could be the result of
impurities, which are deep inside the copper and that slowly
diffuse to the
ine profiles on crystals of different size we show that the growth
of the larger crystal e data is well fitted to a constant growth
rate and gives both the growth rate and start
Fig. 10. Sample G. a) Distribution of the nucleation times
indicating delayed nucleation of the majority of crystals. Also
indicates the graphene coverage in the area relative to the number
of nucleations of b) Spatial and size distribution of graphene
nucleations, the nucleation time of each crystal is indicated by
the colour map. The individual nucletions are represented at their
maximum size prior to merging with neighbouring crystals. (A colour
version of this figure can be viewed online.)
E. Whiteway et al. / Carbon 111 (2017) 173e181180
surface during the growth process. An analysis of approximately 100
nucleation sites was per-
formed and we find that the greatest number of nucleations occur
with some delay. This was done by taking a large area Raman map
approximately 0.7 mm2 of a sample fully covered in graphene. In
Fig. 10 we show a histogram of the nucleation time for this sample
as well as the location and size of each crystal prior to the
completion of the growth. In this case of a 7 min full coverage
growth we found that nucleation rate peaked at approximately 3
min.
The fact that the maximum nucleation rate is delayed suggests that
their may be some underlying mechanism for graphene nucleation. The
exact mechanism for graphene nucleation is not known but our
results are consistent with the possibility of nucleation based on
diffusion of impurities to the copper surface.
We can divide the graphene CVD process into three stages. 1: An
initial nucleation phase which is time dependent with individual
graphene crystals nucleating at different times. 2: A linear growth
rate phase where the maximum speed is constant and determined by
the gas composition and flow rate. 3: Final phase where growth rate
is limited by the free copper surface area.
Using continuous isotope labelling we are able to quantify the
results of each growth phase in order to understand nucleation,
linear growth and free surface limited growth regimes.
5. Conclusions
To conclude, we have developed a technique, which allows us to
image dynamically the growth of graphene mono-crystals in addition
for providing a tool to label different parts of the crystal. This
imaging technique enables the assessment of the various anisotropic
and non-monotonous growth rates responsible for the dendritic and
fractal growth of graphene. These graphene mono- crystals grow from
nucleation sites, which are typically impurities or deformations in
the copper substrate. We observed that the graphene nucleation is
time dependent with individual crystals nucleating at different
times independent of other factors. Smaller single layer graphene
crystals form as a result of delayed nucle- ation, but the
mechanism and growth rate are the same for both smaller and larger
crystals. Finally, the dynamic imaging allows us to draw a precise
picture of the CVD growth process, including the relevant diffusion
area of the adsorbed species responsible for the growth. Moreover,
this technique can easily be expanded to other materials whenever
source elements with different isotopes are available, as in the
case of MoS2 or h-BN.
Acknowledgments
We thank NSERC (201269) and FQRNT for financial assistance. We
would also like to thank Mr. James Medvescek for his valuable
insights into entrance lengths and laminar flow development. As
well asMr. Robert Gagnon for the technical assistance and Dr. Samir
Elouatik for the Raman spectroscopy.
Appendix A. Supplementary data
Supplementary data related to this article can be found at http://
dx.doi.org/10.1016/j.carbon.2016.09.034.
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1. Introduction
3. Dynamic imaging
3.1. Bilayer growth
4.1. Anisotropy
4.3. Diffusion growth area