Acta Polytechnica


doi:10.14311/AP.2014.54.0320
Acta Polytechnica 54(5):320–324, 2014 © Czech Technical University in Prague, 2014

available online at http://ojs.cvut.cz/ojs/index.php/ap

STRUCTURING OF DIAMOND FILMS USING MICROSPHERE
LITHOGRAPHY

Mária Domonkosa, b, ∗, Tibor Ižáka, Lucie Štolcovác, Jan Proškac,
Pavel Demoa, b, Alexander Kromkaa

a Institute of Physics, Academy of Sciences of the Czech Republic v.v.i., Cukrovarnická 10/112, 162 53 Praha,
Czech Republic

b Department of Physics, Faculty of Civil Engineering, Czech Technical University in Prague, Thákurova 7,
166 29 Praha 6, Czech Republic

c Department of Physical Electronics, Faculty of Nuclear Sciences and Physical Engineering, Czech Technical
University in Prague, Břehová 7, 115 19 Praha, Czech Republic

∗ corresponding author: domonkos@fzu.cz

Abstract. In this study, the structuring of micro- and nanocrystalline diamond thin films is
demonstrated. The diamond films are structured using the technique of microsphere lithography
followed by reactive ion etching. Specifically, this paper presents a four-step fabrication process:
diamond deposition (microwave plasma assisted chemical vapor deposition), mask preparation (by
the standard Langmuir-Blodgett method), mask modification and diamond etching. A self-assembled
monolayer of monodisperse polystyrene (PS) microspheres with close-packed ordering is used as the
primary template. Then the PS microspheres and the diamond films are processed in capacitively
coupled radiofrequency plasma using various plasma chemistries. This fabrication method illustrates the
preparation of large arrays of periodic and homogeneous hillock-like structures. The surface morphology
of the processed diamond films is characterized by scanning electron microscopy and with the use of an
atomic force microscope. The potential applications of these diamond structures in various fields of
nanotechnology are also briefly discussed.

Keywords: nanostructuring, diamond thin films, polystyrene microspheres, reactive ion etching,
scanning electron microscopy.

1. Introduction
1.1. Diamond and its applications
The most commonly used methods for synthesiz-
ing diamond are high-pressure, high temperature
(HPHT) [1] and chemical vapour deposition methods
(CVD) [2]. Other methods include explosive forma-
tion (forming detonation nanodiamonds), sonication
of graphite solutions (ultrasound cavitation), laser
ablation, etc. Due to a unique combination of proper-
ties (e.g. extreme hardness, high thermal conductivity,
wide band gap, negative electron affinity, high mechan-
ical strength, chemical inertness, resistance to particle
bombardment, and biocompatibility) diamond is a
promising material for applications in various fields
of electronics, bioelectronics, sensorics, etc. [3].
The potential applications of diamond depend not

only on its intrinsic physical and chemical properties,
but also on its surface geometry. The defined surface
structuring allows these unique properties to be tuned
and exploited for a wider range of applications. For
example, structuring of films enhances the surface-to-
volume ratio and therefore increases the sensitivity
and other performances of fabricated devices [4]. For
example, increasing the surface area-to-volume ratio
of diamond films improves the field-emission proper-
ties by introducing the enhancement effect of the local

field near the tips [5]. Generally, various nanostruc-
tures can be fabricated from diamond films known
as nanowires, nanorods, nanoneedles, etc. Therefore,
there is still great interest in developing methods for
obtaining diamond nanostructures with high area den-
sity, high aspect ratio (depth/width), good uniformity
and controlled geometry over large areas [6].

1.2. Structuring of diamond films
On the basis of the fabrication or structuring method,
two basic concepts can be defined as: a) the bottom-
up strategy and b) the top-down strategy. For struc-
turing diamond films, the bottom-up strategy (e.g.
selective area deposition [7]) is rarely used because
of the greater complexity and low process reliability.
Wet chemical etching is not applicable due to the high-
temperature stability, super hardness and chemical
inertness of diamond. Among the top-down strate-
gies, only dry reactive ion plasma etching through a
mask can be used. The advantages are greater re-
liability, greater reproducibility, and a broad family
of possible masking materials (metals, polymers, ox-
ides or nitrides) than when the bottom-up strategy is
used. The mask, which defines the required geomet-
rical patterns, is formed using standard lithographic
processes (photolithography, electron beam lithogra-

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vol. 54 no. 5/2014 Structuring of Diamond Films Using Microsphere Lithography

Steps Process parameters
1a) MCD deposition MW power 3000 W

total gas pressure 7000 Pa
CH4/H2 5 %
CO2/H2 1.5 %
temperature 800 °C
process time 4 h

(pre-deposition: 2 % of CH4/H22 without CO2 for 10 min)
1b) NCD deposition MW power 3000 W

total gas pressure 7000 Pa
CH4/H2 5 %
CO2/H2 1.5 %
temperature 800 °C
process time 3 h

(pre-deposition: 2 % of CH4/H2 without N2 for 10 min)

2a) RIE process RF power 100 W
(O2-plasma) total pressure 12 Pa

O2 flow rate 50 sccm (for 7 min)
self-bias voltage −57 V

2b) RIE process RF power 100 W
(CF4/O2-plasma) total pressure 12 Pa

(1.) O2 flow rate 50 sccm (for 2 min)
(2.) O2/CH4 flow rate 40/10 sccm (for 8 min)
self-bias voltage −57 V

Table 1. Process parameters for CVD diamond deposition and diamond etching using the PS template as a direct
mask (for PS1500).

phy, nanoimprinting, etc.). However, these processes
are expensive or time-consuming. A possible mask
preparation process would involve utilizing a mono-
layer of plasma-treated microspheres with controllable
size and gap. In this study, we present structuring of
diamond thin films using the technique of microsphere
lithography.

2. Experimental section
A schematic illustration of the main technological
steps for diamond structuring is shown in Fig. 1:
(1.) Diamond deposition. Two types of diamond
films were grown in a focused microwave chemical
vapor deposition reactor (Aixtron P6) on a silicon
substrate 1 × 1 cm2 in size (for the plasma parame-
ters see rows 1 and 2 in Table 1).

(2.) PS mask preparation. Uniform periodic ar-
rays of polystyrene (PS) microspheres were achieved
by the standard Langmuir-Blodgett method, i.e.
self-assembly of microspheres in a hexagonally close-
packed monolayer at the water-air interface. The
initial diameter of the PS microspheres was 1500 nm.
Details abouth the preparation of the mask can be
found in ref. [8].

(3.) Mask modification – PS etching. The prepa-
ration of the hexagonally close packed monolayer

Figure 1. Schematic drawing of diamond film struc-
turing using a PS microsphere array.

was followed by reactive ion etching. The PS mi-
crospheres were modified in a capacitively coupled
plasma system (CCP-RIE, Phantom III, Trion Tech-
nology) in an oxygen atmosphere (for the etching
parameters see Table 1, row 3).

(4.) Diamond etching. The samples were subse-
quently also treated by the CCP-RIE system. Two
different gas mixtures were used: pure O2 and 20 %
of CF4 in O2 gas (see row 4 in Table 1).

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M. Domonkos, T. Ižák, L. Štolcová et al. Acta Polytechnica

Figure 2. Top-view SEM and AFM (2 × 2 µm) images of a), c) MCD and b), d) NCD diamond thin films before the
mask was prepared.

Figure 3. Raman spectra of a) MCD and b) NCD films measured by an excitation wavelength of 325 nm.

The plasma parameters were chosen on the basis of
our previous study on PS and diamond etching [9, 10].

The samples were systematically characterized after
each technological step. The morphology of the CVD
grown and plasma etched samples was characterized by
scanning electron microscopy (SEM, e_LiNE writer,
Raith GmbH) and with the use of an atomic force
microscope (Veeco Dimension 3100, NTMDT Ntegra).
Raman spectroscopy (Renishaw inVia Reflex) with
an excitation wavelength of 325 nm was employed to
determine the chemical character (i.e. sp3 versus sp2
carbon bonds) of the diamond films.

3. Results and discussions
Figure 2 shows the surface morphology and the to-
pography of the diamond films before the mask was
prepared, taken by scanning electron microscopy. The
diamond film with larger grain sizes (∼ 1 µm) was
labelled as MCD (microcrystalline, Fig. 2a), and the

diamond film with smaller grain sizes (< 50 nm) was
labelled as NCD (nanocrystalline, Fig. 2a). Both dia-
mond films were about 3 µm in thickness. Figure 2c,d
shows the 3D topography of the diamond films (before
the mask was prepared), provided by an atomic force
microscope (AFM).

The Raman spectra clearly confirmed the diamond
character in both films (Fig. 4a,b). For the MCD film,
the spectrum is dominated by a sharp peak located
at 1332 cm−1, which is the characteristic line for the
phonon mode of the sp3 crystalline diamond phase.
Two broad bands located at frequencies ∼ 1374 cm−1
and ∼ 1575 cm−1 are attributed to the D-band (de-
fects) and to the G-band (graphite), which represents
the non-diamond carbon bonds (sp2 phase). A weak
band centered at ∼ 1154 cm−1 corresponds to the
trans-polyacetylene-like groups at the grain bound-
aries [11]. This band is more intensive for NCD films,
where the crystals are much smaller, and more sp2
carbon bonds are present at grain boundaries. Thus,

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vol. 54 no. 5/2014 Structuring of Diamond Films Using Microsphere Lithography

Figure 4. Tilted-angle view (45°) SEM images of etched MCD diamond films (columns 1, 2) and NCD diamond
films (columns 3, 4) prepared using a PS microsphere mask (PS 1500 nm) by etching in oxygen plasma (a, c, e, g)
and with the addition of CF4 (b, d, f, h). (Note: the upper row and the bottom row differ only in magnification).

the intensity of the G-band increases and the intensity
of the diamond-peak (at 1332 cm−1) decreases, but it
is still resolvable in the Raman spectrum.
Right at the beginning of the plasma treatment

(step 2a in Table 1) we observed homogeneous etching
of PS over the whole sample. The close-packed arrays
of PS microspheres were converted into a non-close-
packed template with the preserved period of the
initial microsphere array (not shown here) [10].

The surface morphology of the diamond films after
the CCP-RIE processes (step 2a and 2b, Table 1) is
shown in figure 4. Periodic hillock-like structures with
a period of ∼ 1500 nm were observed. Their height
was estimated from the AFM image to be ∼ 600 nm
for MCD and ∼ 800 nm for NCD. The fabricated
hillock-like features were better recognized (i.e. their
geometrical border was better defined) for the NCD
films. This is attributed to the nanocrystalline char-
acter itself. In the case of MCD films, the fabricated
structures reveal non sharp edges (borders), which
we assign to the different etching rates for each crys-
tal facet of the diamond. This means that the (111)
facets were etched at different rates than the (100)
oriented diamond crystals, etc. [12]. The MCD films
consist of randomly and well faceted crystals and the
surface roughness is higher for the thicker films. From
this point of view, the NCD films do not reveal such
dependences or nonhomogenities on the microscopic
scale, i.e. the grain size and the surface roughness do
not vary with the film thickness.
The surface of the etched MCD and NCD films in

pure oxygen plasma (columns 1 and 3 of Fig. 4) cor-
responds well to our previous studies [9]. RIE etching
in O2 led to the formation of diamond needle-like
structures (or so-called whiskers). The main reason
for this effect is that the ions are vertically accelerated

to the substrate and not only chemical etching but
also physical sputtering takes place. Moreover, it is
well-known that oxygen etches sp3 diamond bonds
much faster than sp2 carbon bonds [13], resulting
in the formation of needle-like structures. In NCD
films, more sp2 carbon bonds at the grain bound-
aries correspond to the formation of needle-like struc-
tures [14].However, the addition of CF4 into O2 re-
sulted in flattening/smoothing of the diamond surface.

4. Conclusion
In summary, we have demonstrated that microsphere
lithography is a promising technique for structuring
diamond thin films in the so-called top-down strategy.
Diamond films were grown using a focused microwave
plasma CVD process, and their crystallographic char-
acter was controlled by the gas mixture that was used.
The MCD films were grown from a CO2 + CH4 + H2
gas mixture, and the NCD films were grown from a
N2 + CF4 + H2 gas mixture. Self-assembled, hexag-
onally close packed PS microsphere arrays obtained
by the Langmuir-Blodgett method were used as the
masking material. First, the PS layer was treated
in plasma to predefine the final geometry of the dia-
mond structures. During continued plasma etching,
the primary PS were removed.

Using this cost-effective and time-efficient method,
highly periodic and homogeneous hillock-like struc-
tures were achieved both for MCD films and for NCD
films. It is believed that diamond structures fabricated
over large areas will have a positive impact on their
further applications as photonic crystals in optics or as
active functional surfaces in sensorics, bioelectronics,
biomedicine and electrochemistry.

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M. Domonkos, T. Ižák, L. Štolcová et al. Acta Polytechnica

Acknowledgements
This work was supported by grants from the Czech Science
Foundation P108/12/G108 (T. I., A. K.). The work was
carried out in the framework of the LNSM infrastructure.

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	Acta Polytechnica 54(5):320–324, 2014
	1 Introduction
	1.1 Diamond and its applications
	1.2 Structuring of diamond films

	2 Experimental section
	3 Results and discussions
	4 Conclusion
	Acknowledgements
	References