Aspects regarding the tribological behaviour of some magnetron sputtered Ti-Si-C coatings.
Ionescu, Cristian ; Munteanu, Daniel ; Munteanu, Alexandru 等
1. INTRODUCTION
The subject of the deposition of Ti-Si-C type thin films presents a
wide interest at world level, fact revealed by the numerous articles and
monographs published in the specialty literature (Barosum, 2000; Lopez
et al., 2007; Emmerlich et al., 2004; Barosum, 2001; Eklund et al.,
2005; Hogberg et al., 2005; Veprek, 1997). Despite of the fact that the
available data regarding Ti-Si-C system (MAX phase, generally) have an
increasing trend, the most of the researchers encourage the further
investigation on this system.
The research regarding the Ti-Si-C system has drawn toward a new
family of materials, i.e. MAX phases, [Ti.sub.3]Si[C.sub.2] being the
most investigated, (Barosum, 2000). The successful synthesis of MAX
phases in the form of thin films has attracted the attention over these
unique materials. The ternary compound known as the MAX phase
([M.sub.n+1] A [X.sub.n], where M = transition metal; A = A group
element; X = C and/or N; n=1-3) and, particularly, [Ti.sub.3]Si[C.sub.2]
phase, has attracted a considerable attention lately (Lopez et al.,
2007; Emmerlich et al., 2004; Barosum, 2001) because of the
extraordinary properties. In these materials, (Lopez et al., 2007;
Barosum, 2001), the metallic properties, such as electrical and thermal
conductivity and thermal shock resistance, are combined with ceramics
properties, such as good oxidation resistance, a refractivity and high
decomposition temperature (1800[degrees]C). MAX phase materials are
interesting from the technological point of view, because of ductility
and workability, (Emmerlich et al., 2004). This material presents, also,
a high rupture resistance and a very low friction coefficient. According
to (Emmerlich et al., 2004), thin films containing MAX phases,
particularly [Ti.sub.3]Si[C.sub.2], can become essentials in
applications such: electrical contacts and coatings with wear protection
role. The big disadvantage is the fact that the thin films containing
MAX phases can be obtained at deposition temperatures higher than
700[degrees]C, (Lopez et al., 2007; Emmerlich et al., 2004; Eklund et
al., 2005). Because of this high temperature, the choice of the
substrates becomes very important, because these do not have to change
the composition and especially the structure at the deposition
temperature. In this way, (Lopez et al., 2007), the research programmes
should be developed in order to solve this big disadvantage. On the
other hand, lower deposition temperatures lead to the formation of some
nanocomposite materials, considered promising for protective coatings
from the electrical contacts, because of the high wear, corrosion
resistance and high conductibility, (Eklund et al., 2005; Hogberg et
al., 2005).
The technique used for Ti-Si-C films deposition on high-speed steel
substrates is the one of sputtering. The sputtering technique is
(Munteanu et al., 2007) a deposition method of thin films in vacuum,
where the deposition particles in the form of neutral atoms or neutral
atoms groups, which have energy between 10 eV and 40 eV, are obtained by
vacuum sputtering of the solid-state deposition material.
In the last ten years, a relevant number of papers regarding the
deposition of nanostructured films by sputtering were published (Lopez
et al., 2007; Emmerlich et al., 2004; Veprek, 1997). The goal of these
researches is the obtaining of hard films, but also tenacious, thermal
stable and witch should present low friction coefficients. In the most
of the cases (Lopez et al., 2007), the motivation of the researches was
directly correlated with the influence that the crystalline grains have
over the properties, so over the performance of these multifunctional
coatings, knowing the fact that the final effects will be as relevant as
the grain size is smaller. For example, from the mechanical behaviour
point of view, (Lopez et al., 2007), a decrease of the grain size leads
to the improvement of the mechanical resistance and toughness, by the
process of blocking and stopping the dislocation pinning. Nanostructured
polycrystalline materials were obtained, consisting of atoms with
different chemical reactivity, witch then form different types of phases
that do not exist naturally. During the deposition operation, phase
segregation take place, creating multiphase materials, in witch, for
example, crystalline phases are encircled by other types of phases, in
the crystalline grain lattice. A nanocomposite material is created this
way, such the case of the well-known Me-Si-N system (where Me = Ti, W,
V), in which Me-N nanocristallites are incorporated in a Si-N amorphous
matrix, (Veprek, 1997).
2. EXPERIMENTAL DATA
The Ti-Si-C thin films studied in the present paper were deposited
on AISI M2 high-speed steel substrates, using the magnetron sputtering
technique. The principal parameters of the sputtering operation were:
substrate temperature in the deposition chamber was maintained at
300[degrees]C, substrate bias voltage -50V, argon flow 100 sccm,
target--substrate distance 65 mm, Ti target current varied between
0,25-0,5A.
Table 1 presents the composition of the deposited films. The
highest Ti content and the lowest C content were registered in the case
of sample A15, while the highest C content corresponds to the sample A
4.
The wear behaviour was appreciated using a CSM Instruments
Tribometer. The tribometer also gives information regarding the friction
coefficients. The principal parameters of the wear test were:
method--rotative "ball on disk", wear radius 5 mm, rotation
speed of the disk 4,8 cm/s, normal force 5 N. The working principle of
the tribometer is the following: the static partner (the ball) is loaded
over the sample with a constant force. While the disk is rotating with
the specified speed, the friction forces that appear at the ball--sample
contact are measured using a sensor. The wear for ball and sample is
calculated on the base of the volume of lost material during test. This
simple method facilitates the study of the friction and of the wear
behaviour of almost any type of solid-state material, by changing time,
load, speed, temperature, humidity.
3. RESULTS AND DISCUSSIONS
Table 2 presents the results (friction coefficients, wear) obtained
after the wear test. The A2 and A6 samples presented an insignificant
wear, which could be considered equal with zero. This insignificant wear
is a result of the high hardness registered in the case of the two
samples, from figure 1 resulting clearly the strong correlation between
the wear behaviour and the hardness of the analyzed coatings.
Figure 2 presents the correlation between the wear behaviour and
the residual stress state. It can be observed that a very good wear
behaviour is associated with low values of the residual stress.
Regarding the friction coefficients, figure 3 shows that the lowest
value of the friction coefficient was registered in the case of sample
A4, sample for witch it was registered the highest value of mass loss
during wear.
4. CONCLUSIONS
The paper presented some general aspects regarding the deposition
of Ti-Si-C films on high-speed steel substrates by magnetron sputtering.
Taking into account the tribological and the mechanical characteristics
of the Ti-Si-C coatings synthesized in this research, it is possible to
conclude the fact that there is a strong correlation between the
tribological properties (wear, friction) and hardness, residual stress
state. The further research should follow the obtaining of coatings with
different chemical composition, in order to see how it changes the
tribological behaviour of the coatings, if compare with the coatings
from this paper.
[FIGURE 1 OMITTED]
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
5. REFERENCES
Barsoum, M. (2000): The [M.sub.n+1] A [X.sub.n] phases: A new class
of solids: Thermodynamically stable nanolaminates, Progress in Solid
State Chem., vol. 28, no. 1, pp. 201-281
Barsoum, M. (2001): The MAX Phases: Unique New Carbide and Nitride
Materials, American Scientist, vol. 89, no. 4, (Jul.-Aug. 2001) pp.
334-343
Eklund, P. et al. (2005): Structural, electrical and mechanical
properties of nc-TiC/a-SiC Nanocomposite thin films, Journal of Vac.
Science and Technol., B.23, (Nov. 2005) pp. 2486-2495
Emmerlich, J. et al. (2004): Growth of [Ti.sub.3]Si[C.sub.2] thin
films by elemental target magnetron sputtering, Journal of Applied
Physics, vol. 96, no. 9, pp. 4817-4826
Hogberg, H. et al. (2005): Growth and characterization of MAX phase
thin films, Surface Coat. Technol. vol. 193, issues 13, pp. 6-10
Lopez, C. et al. (2007): Magnetron sputtered Ti-Si-C thin films
prepared at low temperatures, Surface and Coatings Technology, doi:
10.1017/j.surfcoat.2007.01.025
Munteanu, D. et al. (2007): Ti-Si-C and Ti-O-C type coatings
obtained by reactive magnetron sputtering, Transilvania University of
Brasov Publishing House, ISBN 978-973635-931-6, Brasov, Romania
Veprek, S. (1997): Conventional and new approaches towards the
design of novel superhard materials, Surface Coat. Technol. vol. 97,
issues 1-3, pp. 15-22
IONESCU, C[ristian]; MUNTEANU, D[aniel] & MUNTEANU, A[lexandru]
*
* Supervisor, Mentor
Tab. 1. The composition of the coatings
Composition, at.%
Sam
No. Ti Si C O Atomic formula
A2 51.14 2.62 43.09 3.25 Ti[Si.sub.0.05][C.sub.0.84]
A4 27.19 5.29 65.32 2.2 Ti[Si.sub.0.19][C.sub.2.40]
A6 48.79 5.01 44.24 1.96 Ti[Si.sub.0.10][C.sub.0.90]
A15 78.63 8.63 2.65 10.09 Ti[Si.sub.0.10][C.sub.0.03]
Tab. 2. The thickness and tribological characteristics of the
coatings
Medium
Sample Thickness Friction Wear rate
no. [micro]m C/Si coeff. mm3/N/m
A2 0.9 16.44 0.45797 [congruent to]0
A4 0.3 12.34 0.23547 1.38 x 10-5
A6 0.6 8.83 0.54169 [congruent to]0
A15 2 0.31 0.56149 1.02 x 10-5
