Acta Polytechnica


Acta Polytechnica 53(2):223–227, 2013 © Czech Technical University in Prague, 2013
available online at http://ctn.cvut.cz/ap/

POSITIONING OF THE PRECURSOR GAS INLET
IN AN ATMOSPHERIC DIELECTRIC BARRIER REACTOR, AND

ITS EFFECT ON THE QUALITY OF DEPOSITED TiOx THIN
FILM SURFACE

Jan Pichal∗, Julia Klenko

Czech Technical University in Prague, Faculty of Electrical Engineering, Technicka 2, Prague 6, Czech Republic
∗ corresponding author: pichal@fel.cvut.cz

Abstract. Thin film technology has become pervasive in many applications in recent years,
but it remains difficult to select the best deposition technique. A further consideration is that, due
to ecological demands, we are forced to search for environmentally benign methods. One such method
might be the application of cold plasmas, and there has already been a rapid growth in studies
of cold plasma techniques. Plasma technologies operating at atmospheric pressure have been attracting
increasing attention. The easiest way to obtain low temperature plasma at atmospheric pressure seems
to be through atmospheric dielectric barrier discharge (ADBD). We used the plasma enhanced chemical
vapour deposition (PECVD) method applying atmospheric dielectric barrier discharge (ADBD) plasma
for TiOx thin films deposition, employing titanium isopropoxide (TTIP) and oxygen as reactants,
and argon as a working gas. ADBD was operated in filamentary mode. The films were deposited
on glass. We studied the quality of the deposited TiOx thin film surface for various precursor gas inlet
positions in the ADBD reactor. The best thin films quality was achieved when the precursor gases
were brought close to the substrate surface directly through the inlet placed in one of the electrodes.
High hydrophilicity of the samples was proved by contact angle tests (CA). The film morphology
was tested by atomic force microscopy (AFM). The thickness of the thin films varied in the range
of (80 ÷ 210) nm in dependence on the composition of the reactor atmosphere. XPS analyses indicate
that composition of the films is more like the composition of TiOxCy.

Keywords: AFM, atmospheric dielectric barrier discharge, chemical composition, chemical vapour
deposition, inlet position, precursor gas, surface quality, thin film, TiOx, TiOxCy, XPS.

1. Introduction
Thin film deposition techniques and technologies have
undergone serious development and cultivation in re-
cent decades. A vast number of deposition methods
are now available [6, 7], but it still remains ardu-
ous to select the best deposition method which is,
at the same time, environment friendly. The appli-
cation of cold plasmas sustaining under atmospheric
pressure in combination with the chemical vapour de-
position method seems to be a promising approach.
Cold plasma is often produced in plasma jets, plasma
torches and ADBD (for details about ADBD, see
e.g. [5]). However, research in this area is still mostly
restricted to the laboratory stage. For practical rea-
sons, the most tested films are SiOx and TiOx coat-
ings.
This paper summarizes results obtained when

TiOx films are deposited on glass substrates us-
ing the PECVD method in an ADBD plasma reac-
tor when TTIP, (less toxic than TiCl4, which was
used e.g. in [2]), is applied as a precursor, namely
the connection between the precursor gas inlet po-
sition in the ADBD reactor and the deposited film
quality. Some preliminary results have been published
in [3, 4].

2. Experimental
2.1. The reactor and the experimental

conditions
Film deposition was performed with discharge power
of about 350 mW [14 kV, 50 Hz].
The experiments were carried out in an open

flow-through type plasma reactor with dimensions
(90 × 79 × 41) mm. The scheme of the plasma re-
actor is shown in Fig. 1. Plasma sustained be-
tween two brass electrodes [(45 × 8 × 18) mm HV elec-
trode, (40 × 17 × 18) mm ground electrode] placed
within the reactor. A barrier manufactured from glass
plate ((70 × 46 × 1) mm) covered the ground elec-
trode. The distance between the electrodes was
fixed at 4 mm. Three types of HV electrode were
used in the experiments, all of them with identi-
cal external dimensions, but they were differentiated
by the hole (diameter 3 mm) leading into the interelec-
trode region. The first electrode was without a hole,
the hole of the second type was connected with one
inlet (C) only, and the third type had two inlets,
C and D (see Fig. 1, for simplicity all four inlets possi-
tions are drawn here, although only one pair of inlets
was used in each experiment).

ADBD sustained in filamentary mode. Thin films

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Jan Pichal, Julia Klenko Acta Polytechnica

Figure 1. Scheme of the plasma reactor; 1 – ground
electrode, 2 – dielectric barrier, 3 – substrate, 4 – HV
electrode, 5 – evaporator, 6 – mass flow controller,
7 – HV supply, A, B, C, D – inlet positions.

were obtained at atmospheric pressure using ti-
tanium (IV) isopropoxide as a precursor (TTIP,
Ti[OCH(CH2)]4 and 97 % purity).

TTIP volatilized at temperatures of (30.0 ± 0.5) ◦C.
It was mixed with argon in the evaporator, trans-
ported into the reactor and reacted with oxygen
(or, in the first experiments, merely with dry air,
when atmospheric oxygen took part in the reaction).

The gas flow rates were adjusted by means of
the mass flow controllers. Deposition tests were per-
formed with TTIP/Ar flows (0.5 ÷ 4.0 ) slm. The oxy-
gen/dry air flow was controlled within (2.5 ÷ 10) slm.

The outer atmosphere was air with relative humidity
of (36 ÷ 47 ) % and room temperature about 20 ◦C.
The deposition time was 10 minutes in all experiments.

Unfortunately, the reactor has no “clean interface”,
so surface-related chemical reactions or contamination
by ambient air species began while the films being
removed from the reactor, before any test was initial-
ized.
These chemical reactions also proceeded while

the films were being stored. The deposited films were
stored in darkness at room temperature (20 ÷ 23 ) ◦C,
relative humidity (30 ÷ 40 ) %, in plastic boxes in air
at atmospheric pressure.

2.2. Film analysis
The surface morphology of the films was exam-
ined using the atomic force microscopy (AFM) tech-
nique in noncontact mode, performed under ambi-
ent conditions on an FRT AFM Scanning Probe
Microscope at the Technical University of Liberec.
All (2 × 2) µm scans were processed by Gwyddion
software for SPM (scanning probe microscopy) data
visualization and analysis.

To analyse the hydrophilicity, a contact angle test
(CA) was applied. CA was measured by a sessile
drop technique when a constant time (30 s) passed
after the dropping of distilled water about 0.5 µl in vol-
ume. The CA of each sample was performed in 5 differ-
ent positions at room temperature. The surface chem-

Figure 2. Topography of the TiOx films; inlets:
A (dry air from the atmosph.), C (TTIP/Ar, 0.5 slm).

ical composition of the films was investigated by X-ray
photoelectron spectroscopy (XPS). A multi-channel
hemispherical electrostatic analyser (Phobios 100,
Specs) was used. The Al Kα line (1486.6 eV) was used
with an X-ray incidence angle 45◦ to the surface plane.
The analyser was operated in retarding-field mode,
applying pass energy of 40 eV for the survey scans and
10 eV for all core level data. The XPS peak positions
were referenced at the aliphatic carbon component
at 285.0 eV. Due to inadequate equipment we were
unfortunately not able to clean the film profile by sput-
tering and perform XPS profile tests, so our research
had to focus on film surface tests only.

3. Results
Deposition of the films proceeds in substrate-surface
limited reactions. The films were deposited in ADBD
sustaining in filamentary mode.

The deposited surface was in general irregularly cor-
rugated, hummocky, with growing thickness in spots
where filaments bridged electrodes. Growing/dimin-
ishing thickness of the film area reflects local electric
field inhomogeneities associated with the existence
of filaments. The surface topography was similar
to layers deposited with TiCl4 precursor [2, 10].
The gassing of the reactor was performed through

various pairs of gas inlets (see Fig. 1). We used fol-
lowing combinations:

(1.) A (air at atm. pressure) and B (TTIP/Ar)
(2.) A (air at atm. pressure) and C (TTIP/Ar)
(3.) C (TTIP/Ar) and D (oxygen)
(4.) C (oxygen) and D (TTIP/Ar)

For each combination of inlets we tested the ef-
fect of TTIP and O2 in various concentrations
in the TTIP/Ar/O2 mixture on the film characteris-
tics.

Only the best results are mentioned in the following
summary.

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vol. 53 no. 2/2013 Positioning of the Precursor Gas Inlet in an Atmospheric Dielectric Barrier Reactory

Figure 3. Ti 2p XPS spectrum of the film, inlets A, C.

1. The reactor was gassed both with TTIP/Ar
(0.5 slm) and with dry air through inlets A and B
in the walls of the reactor. Several differents positions
of both inlets were tested, but only powder-like struc-
tures were deposited on the glass substrate for all used
combinations of A and B.

2. To reduce pulverization, the reactor was gassed
through inlet A in the wall of the reactor with dry
air, and TTIP/Ar (0.5 slm) was fed through inlet C
(the hole, 3 mm in diameter, in the HV electrode).

The film that formed on the glass substrate was
very thin and was barely detectable. We suppose that
the TTIP/oxygen reaction was weak, due to the low
concentration of oxygen atoms (from the air) in the re-
actor atmosphere. Then the precursor molecules flew
out from the inter-electrode space and later reacted
with oxygen atoms (and we observed the TiOx thin
film deposited on the inner walls of the reactor).

AFM measurements revealed the existence of some
salient parts on the uniform powder-like film surface
(Fig. 2). Small hummocks were also visible.

CA measurements were almost impossible due
to the inhomogeneity and the thinness of the film,
and the results were not reproduciable. Only powder-
like TiOx structures were deposited on the substrate
for TTIP/Ar flows higher than 0.5 slm.
The high-resolution XPS spectra for the main ele-

ments in the films are shown in Figs. 3–5. Figure 3
represents the Ti 2p spectrum that consists of 2p3/2
and 2p1/2 spin orbit components located at 458.8 eV
and 464.6 eV, respectively. This position of the peak
maxima indicates that the main titanium compound
is TiO2. The small components on the lower binding
energy side correspond to sub-stoichiometric titanium
oxide TiOx, x < 2.
The O 1s spectrum is shown in Fig. 4. The peak

consists of two distinct components at 530.5 eV
and 532.7 eV. The first component is classified as
TiO2, whereas the second component corresponds to
the carbon-oxygen species. The carbon-oxygen species
are about three times more abundant than oxygen

Figure 4. O 1s XPS spectrum of the film, inlets A, C.

Figure 5. C 1s XPS spectrum of the film, inlets A, C.

bound in titanium (24 % against 76 %). We suppose
that the carbon contamination was probably only su-
perficial. This contamination may have originated
both during the deposition process by impurities from
the air and by post-discharge reactions and adsorption
of various species from the ambient air atmosphere
after the film removal from the reactor.

3. To improve the quality of the films and opti-
mize the deposition conditions, both components
were introduced through the inlets in the HV elec-
trode, and the atmospheric air was replaced by oxygen
(C (TTIP/Ar) and D (oxygen)).

Nevertheless problems still persisted. AFM analysis
proved that the deposited films were not fully homoge-
neous (Fig. 6), and there were problems with creating
the powder-like structures. For further details, see [3].

4. The best quality films were deposited in the same
adjustment, but unlike with the previous combination
of inlets, oxygen (2.5 slm) was fed through inlet C
and TTIP/Ar mixture (1 slm or 2 slm), i.e. the TTIP
content (0.05 or 0.10) % was fed in through inlet D.
The mixture entered through the hole (diameter 3 mm)
in the HV electrode into the inter-electrode space.

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Jan Pichal, Julia Klenko Acta Polytechnica

Figure 6. Inlets: C (TTIP/Ar, 1 slm), D (O2, 2.5 slm).

Figure 7. Topography of the TiOx films;
inlets: C (TTIP/Ar, 1 slm), D (O2, 2.5 slm).

Figure 7 is AFM scan of the film surface deposited
under optimum conditions. The surface is similar
to the surface described in [10]. It is characterised
by higher hummocks than in Fig. 6, when film depo-
sition in surface-limited reactions was accompanied
by volume-limited dust generating reactions.
The CA tests proved that all samples were hydro-

philic immediately after deposition. For an Ar/TTIP
flow rate of 1 slm, the CA value attained 5◦ immedi-
ately after deposition. The hydrophilicity of the films
remained almost invariable in the first 7 days after
deposition. Later, the wettability had worsened and
within 28 days after deposition the CA value of all
samples exceeded 40◦.

Films deposited with TTIP/Ar flow 2 slm changed
more rapidly from hydrophilic to hydrophobic.
The chemical composition of the films (TTIP/Ar

flows (0.5 ÷ 4.0 slm), oxygen (2.5 ÷ 10) slm was al-
most constant. High-resolution spectra for the main
elements in films are shown in Figs. 8–10.
The relatively high hydrocarbon contamination

on the film surface was again most probably produced
by the post-discharge reactions, and by the adsorption
of various species from the ambient air atmosphere
after the film was removed from the reactor.

Figure 8. C 1s XPS spectrum of the film;
inlets C (oxygen, 2.5 slm), D (TTIP/Ar, 2 slm).

Figure 9. O 1s XPS spectrum of the film;
inlets C (oxygen, 2.5 slm), D (TTIP/Ar, 2 slm).

The carbon (contamination) is partially bonded
with titanium (the C−Ti bond is about 283 eV). Car-
bon forms mostly C−C (285 eV) backbone chains,
some of which are partly oxidized (Fig. 8).
The O 1s spectra are shown in Fig. 9. Note,

that FWHM (full width at half of maximum) is more
than 2 eV. This broadening is evidently caused by sub-
stoichiometric titanium oxides [1]. In addition, the sec-
ond peak at 532.8 eV can be considered as a contribu-
tion from single and double oxygen-carbon bonds [9].
Titanium is a reactive element and easily forms

oxides and carbides,which can be seen in the curve
of Ti 2p (Fig. 10). The location of the strongest peaks
at 458.8 eV and 465 eV indicates that the main tita-
nium species is TiO2 [8]. The small peaks at 457 eV
and 462.6 eV indicate mixed presence of substoi-
chiometric titanium oxides TixOy and titanium car-
bides TiC. The XPS spectra demonstrate that the ti-
tanium in the near surface area is strongly oxidized,
the dominant species being TiO2 and substoichiomet-
ric titanium oxides. The deposition process more

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vol. 53 no. 2/2013 Positioning of the Precursor Gas Inlet in an Atmospheric Dielectric Barrier Reactory

Figure 10. Ti 2p XPS spectrum of the film;
inlets C (oxygen, 2.5 slm), D (TTIP/Ar, 2 slm).

likely produced TiOxCy films instead of the primarily
desired TiOx films.
For more details see [4].

4. Conclusion
Film deposition on glass substrates was performed
by the PECVD method in the ADBD plasma reac-
tor. The plasma reactor was an open flow-through
type. ADBD sustained in filamentary mode. The re-
actor atmosphere consisted either of TTIP/Ar/dry air
or of a TTIP/Ar/oxygen mixture.
We studied the quality of the deposited TiOx

thin film surface for various precursor gas inlet po-
sitions in the ADBD reactor, and various precur-
sor/oxidizer mixture compositions. The best film
quality was achieved when the precursor and the oxy-
dizer entered the discharge region instantly after they
were mixed, through the hole adjacent to the sub-
strate.

The surface topography was influenced by the non-
equilibrium character of ADBD, leading to the irregu-
larly corrugated and hummocky surface of the film.

CA tests proved the high hydrophilicity of the sam-
ples immediately after deposition. Later, the wet-
tability of the films diminished, and the CA value
of all samples exceeded 40 degrees after 28 days;
the changes were probably related with chemical reac-
tions between the surface of the film and the chemical
groups involved in the air atmosphere.

XPS tests indicate that the deposition process more
likely produced TiOxCy films instead of the primar-
ily desired TiO2 or TiOx films. All samples exhibit
contamination with carbon, probably caused by post-
discharge reactions and by adsorption of various
species from the ambient air atmosphere after the film
was removed from the reactor.

Some problems of this deposition method are re-
lated with two different chemical processes that take

place during deposition: surface-related chemical pro-
cesses resulting in conventional PECVD film deposi-
tion, and undesired volume-related chemical processes
resulting in dust production. The dust-producing
mechanism prevails under certain working conditions
(e.g. higher oxygen flow rate values). Dust parti-
cles, when created, remain in the discharge region
and their layer(s) on the substrate hinder the effec-
tive formation of a more homogeneous film, and in-
fluence the quality of the film. Another problem
of PECVD thin film deposition with ADBD seems
to be with the filamentary character of the ADBD
in some applications, leading to generation of hum-
mocks that form a rough surface of the films.

Acknowledgements
This work was supported by Czech Technical University
in Prague grant No. SGS10/266/OHK3/3T/13.

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	Acta Polytechnica 53(2):223–227, 2013
	1 Introduction
	2 Experimental
	2.1 The reactor and the experimental conditions
	2.2 Film analysis

	3 Results
	4 Conclusion
	Acknowledgements
	References