Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 506-513 Received for review: 2022-01-26
© 2022 The Authors. CC BY 4.0 Int. Licensee: SV-JME Received revised form: 2022-07-08
DOI:10.5545/sv-jme.2022.30 Original Scientific Paper Accepted for publication: 2022-07-11
*Corr. Author’s Address: Lodz University of Technology, Institute of Materials Science and Engineering,  
1/15 Stefanowski Street,90-924 Lodz, Poland, robert.pietrasik@p.lodz.pl
506
Nitriding HS6-5-2 Steel in Inductively Coupled Plasma
Binienda, M. – Pietrasik, R. – Pawęta, S. – Matczak, K. – Krotewicz, W.
Marek Binienda
1
 – Robert Pietrasik
2,
* – Sylwester Pawęta
2
 – Krzysztof Matczak
1
 – Witold Krotewicz
1
1 
Zemat Technology Group, Poland 
2 
Lodz University of Technology, Institute of Materials Science and Engineering, Poland
This article presents research on the possibility of obtaining a hardened surface layer via nitriding in coupled plasma (ICP) for HS6-5-2 steel. 
The subject of the investigation was the influence of the process parameters on the properties of the obtained layers. The surface layers 
were characterized using an optical microscope, SEM (Scanning Electron Microscope), EDS (Energy Dispersive Spectroscopy), XRD (X-Ray 
Diffraction), and a microhardness tester. The generator power was changed gradually from 500 W to 2 kW and the tests were carried out for 
various process durations, from 15 to 45 minutes at a set pressure. The obtained results show the possibility of obtaining nitrided surface 
layers with a thickness of up to 0.1 mm and a significant increase in hardness in a very short time.
Keywords: plasma, nitriding, surface layer, hardness
Highlights
• 	 The maximum hardness of about 1100 HV was obtained: an increase in hardness by 350 % in relation to the starting material.
• 	 Nitrided layers with a thickness of 100 µm were obtained following a very short process: 45 minutes.
• 	 The influence of process parameters on the properties of the nitrided layers is shown.
• 	 The nucleation and growth mechanism of the nitrided layers obtained by this method is described.
0  INTRODUCTION
The constant development of technology means that 
there is a need to optimize the functional properties of 
materials used in the production of tools and machine 
parts. On one hand, this process can be achieved by 
producing tool materials with better properties, which 
requires the use of expensive alloying additives in 
a multi-stage technological process [1] and [2]. On 
the other hand, research to modify the surface layer 
to obtain new, more favourable functional features 
of ready-made tools is being carried out. Despite 
significant progress in the development of surface 
engineering, methods for increasing the durability and 
reliability of tools and structural elements, especially 
those of small dimensions, still cause problems [3] 
and [4]. One of the most frequently used technologies, 
especially for small dimension elements, is nitriding 
[5] to [7]. Nitriding done by the classical thermo-
chemical treatment method leads to ε (Fe
2-3
N) and γ’ 
(Fe
4
N) [8] to [10] brittle layer formation. In the case of 
gaseous-controlled processes, it is possible to control 
the phase composition of the layers, but the processes 
take a relatively long time, even for thin layers [11]. 
Plasma-assisted nitriding is presented in the literature 
on the subject primarily concerning ionic discharge, 
which is the phenomenon of accelerating particles in 
an electric field. The high kinetic energy of ions is 
created as a result of the potential difference between 
the electrodes, both in the glow discharge of direct 
current and in the high-frequency electric field. In 
the first case, the existence of strong field strength 
is obvious and directly dependent on the potential 
difference applied to the electrodes. In high-frequency 
plasma discharge, the discharge is obtained between 
opposite electrodes as a result of applying a high-
energy and high-frequency signal from a generator 
to them. Such plasma is called “capacitively coupled 
plasma” (CCP). The generator can be connected by 
means of electrodes directly to the discharge area or 
by galvanic isolation of one of the electrodes using a 
capacitor or an insulator. 
The disadvantage of the direct variant of 
connecting the linings with the discharge is the 
possibility of contamination of the treatment 
atmosphere with matter from the electrodes due to 
their contact with the plasma. In the case of isolating 
one of the electrodes, due to the different masses and 
the related mobility of ions and electrons, the high 
frequency of electrode polarization changes means 
that heavy ions cannot keep up with the changes in the 
electric field. As a result, a constant, non-discharged 
charge accumulates on one of the electrodes, causing 
the electrode to be polarized with a constant voltage. 
This phenomenon is called “autopolarization”, and 
its consequence is the creation of a strong, directed 
electric field, which accelerates the ions, by giving 
them high kinetic energy, causing the spraying of the 
processed samples. This is the main reason that this 
method of plasma production cannot be used to nitride 
objects while keeping their surface and edges intact.

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 506-513
507 Nitriding HS6-5-2 Steel in Inductively Coupled Plasma
Another disadvantageous effect of the directed 
electric field is the shadow phenomenon, which 
makes it necessary to change the position of the 
workpieces during the process [12]. It should be 
emphasized, however, that CCP plasma is used in 
numerous industrial applications in which high ion 
energy is useful, e.g., ion etching, surface cleaning, or 
expanding.
The use of inductively coupled plasma obtained 
in a strong magnetic field due to the flow of Foucault 
currents eliminates the occurrence of an accelerating 
electric field. The magnetic field of the solenoid 
causes the flow of eddy currents both in the gas region 
and in the workpiece, which simultaneously fulfil two 
tasks: they resistively heat both the gas (nitrogen) 
creating a plasma ring discharge and the workpieces 
to the penetration depth, where the value depends on 
the resistivity of both the ionized gas and the sample 
and frequency. Multiple ionization of particles in a 
low-temperature non-isothermal plasma [13] makes it 
an effective source of the nitriding agent and can be 
used for diffusive saturation of metals. However, the 
use of such an induced plasma for steel nitriding is 
practically unknown, as single works on a laboratory 
scale [14] have only been recognized. In contrast, 
inductively coupled plasma is widely used for the 
physical deposition of various types of coatings [15].
A proprietary stand for nitriding in high-frequency 
plasma was designed and built to perform the tests 
(Fig. 1). The device consists of a high-frequency 
generator set with an inductor, which contains a 
reactor inside. The set of vacuum pumps allows the 
appropriate vacuum to be obtained. Nitrogen with a 
purity of 99.999 % is taken from a cylinder via the 
mass flow controller.
Fig. 1.  Block diagram of the device for Inductively Coupled Plasma
As part of this work, the HS6-5-2 steel was 
subjected to tests. Cutting tools made of this steel, 
including the drills, taps, and reamers most commonly 
used in industry and households, constitute a specific 
group: they are exposed to work in very difficult 
conditions. Practice shows that small-size tools 
are not sharpened but replaced with new ones [16]. 
Therefore, the modification of the surface by nitriding 
in inductively coupled plasma, leading to a numerous 
increase in their durability while maintaining high 
core impact strength, is economically justified.
1  EXPERIMENTAL PROCEDURE
The samples used for the tests were HS6-5-2 steel bars 
with a diameter of 4 mm, a length of 50 mm with the 
composition in accordance with the standard shown 
in Table 1. The samples were in the raw steel state 
(without heat treatment).
Table 1.  Standardized chemical composition [wt. %] of HS6-5-2 
steel
C Cr Mo
0.80 to 0.88 3.80 to 4.50 4.70 to 5.20
V W Si
1.70 to 2.10 5.90 to 6.70 Max 0.45
The samples were nitrided in a stand built for 
nitriding in inductively coupled plasma discharge 
with a frequency from a band intended for industrial, 
scientific, and medical (ISM) applications, in a 
continuous operation mode. The device was made of 
a reactor in the form of a quartz tube, 750 mm long 
and 100 mm in diameter, and was connected to a set 
of vacuum pumps, which included a turbomolecular 
pump and a scroll pump. The operating pressure of 
the process under a nitrogen atmosphere of 99.9999 
% purity was 100 Pa, and its flow was controlled by 
a mass flow controller (MFC). The plasma discharge 
took place within a coil made of a copper pipe with 
a diameter of 8 mm and was powered by a generator 
with a frequency of 27.12 MHz. The power was 
changed in steps ranging between 500 W, 1 kW, 1.5 
kW, and 2 kW. The samples placed in quartz glass 
process tables were nitrided at constant pressure and 
changed the duration of the process (15 min, 30 min, 
45 min) for the set generator power.
The cross-section microstructures of specimens 
were observed using a Nikon MA200 optical 
microscope (Nikon Instech Co., Ltd., Tokyo Japan). 
The microstructure and chemical composition of 
the surface layers were also investigated by using a 

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 506-513
508 Binienda,	M.	–	Pie trasik ,	R.	–	P a węta,	S.	–	Matczak ,	K .	–	Kr o t e wicz,	W .
scanning electron microscope (SEM) JEOL JSM-
6610 LV (JEOL Ltd., Tokyo Japan) equipped with 
an energy dispersion spectroscope (EDS) X-MAX 
80 Oxford Instruments (Oxford Instruments Group, 
Abingdon, United Kingdom). The X-ray diffraction 
(XRD) was done on a device from PANalytical 
Empyrean (Malvern Panalytical Ltd, Malvern, United 
Kingdom). The source was an x-ray tube with cobalt 
anode-emitting characteristic radiation (CoKα = 1.74 
Å). Primary beam optic consisted of Goebel mirror 
for Co radiation, fixed divergence slit 0.5 deg, Soller 
slit 0.04 rad, and mask 10 mm. Diffracted beam 
optic consisted of parallel plate collimator 0.18 deg, 
Soller slits 0.04 rad and proportional Xe detector. 
The hardness distribution of the nitrided layers was 
measured using a Vickers microhardness tester 
NEXUS 4305 (INNOV ATEST Ltd., Maastricht, 
Netherlands). The surface hardness on the sample 
prepared for metallographic tests was measured at a 
distance of 10 µm from the edge of the sample and 
successively further inside the sample every 5 µm. 
Measurements were made with 0.98 N load. The 
surface roughness profile parameters were tested 
with the T8000 RC profilometer by Hommel-Etamic. 
Parameter Ra arithmetic mean of the profile ordinates, 
was determined in accordance with the PN-EN ISO 
4287:1999 standard.
Time SEM image EDS nitrogen distribution
15 min
30 min
45 min.
Fig. 2.  Images of the SEM structures and the corresponding EDS nitrogen distributions obtained at a generator power of 500 W  
for different process times.

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 506-513
509 Nitriding HS6-5-2 Steel in Inductively Coupled Plasma
2  RESULTS AND DISCUSSION
As a result of the processes carried out at a generator 
power of 500 W, zones of nitride compounds on 
the surface were only obtained without an internal 
nitriding zone, regardless of time. Images of the 
SEM structures and the corresponding EDS nitrogen 
distribution distributions are shown in Fig. 2.
With a generator power of 500 W (Fig. 2), only 
the rudiments of the layer can be observed in the 
form of a white zone of nitride compounds: initially 
composed of γ’ nitrides, and after longer dosing of 
nitrogen, transforming into ε nitrides. In this case, 
the internal nitriding zone was not obtained probably 
because of the low temperature of the samples, which 
was not sufficient to dissolve the nitrides and diffuse 
nitrogen into the samples. In the case of the shortest 
time (15 min), the nitrogen content in the nitride zone 
was about 6 % by weight, which proves that it is 
mainly γ’ nitride (Fe
4
N). If the process is prolonged 
to 30 min, the nitrogen content increases, on average, 
to a level of about 10 % by weight. This value and 
the fact that the content exceeds 8 % prove that we 
are dealing with ε nitride (Fe
2-3
N). Analogically, for 
a time of 45 min, the average nitrogen content is 
about 12 % by weight, so we are dealing with slightly 
more saturated nitrogen, specifically the nitride ε  
(Fe
2-3
N).
These observations are consistent with the X-ray 
diffraction test (Fig. 3), where the spectra for the 
samples after 15 min and 45 min nitriding processes 
are presented. In the first case, the γ’ (Fe
4
N) nitrides 
are visible only. In the case of the longer process (45 
a)   
b)  
Fig 3.  XRD spectra for nitrided samples at 500 W generator power, during a) 15 min and b) 45 min

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 506-513
510 Binienda,	M.	–	Pie trasik ,	R.	–	P a węta,	S.	–	Matczak ,	K .	–	Kr o t e wicz,	W .
min), the stress of nitrides ε (Fe
3
N) and residuals of γ‘ 
(Fe
4
N) are visible, respectively.
This may prove that the process of constituting 
nitrided layers takes place through the nucleation of 
γ’ nitrides, which (together with a longer nitrogen 
supply) transform into ε nitride. However, with the 
indicated generator power, the obtained substrate 
temperature is too low and does not allow nitrogen 
diffusion deeper into the samples, as evidenced by the 
absence of an internal nitriding zone, and is confirmed 
by the lack of increase in the hardness of the sample 
directly under the nitride layer (the hardness at a 
depth of 10 µm is about 300 HV). In contrast, surface 
hardness ranges from 960 HV , in the case of γ′ nitride 
on the surface, to 700 HV for ε.
The processes carried out using higher generator 
powers allowed diffusion layers of various uniformity 
and thickness, as well as structural formation, to be 
obtained. The summary of the obtained structures is 
shown in Fig. 4.
The analysis of the photos shows that there is 
a clear correlation between the parameters of the 
process and the thickness and structure of the obtained 
layers. Increasing the generator power to 1 kW results 
in the appearance of the beginnings of the diffusion 
zone with a very irregular depth. A longer process 
time results in an increase in nitrogen saturation, but 
the layers are highly heterogeneous. At 1.5 kW, the 
diffusion layer is clearly visible but is not uniform and 
has an island structure, especially for shorter process 
times. It is clearly visible at shorter process times (e.g., 
for 15 min, the depth of the diffusion zone ranges 
from 26 µm to 42 µm, but a white zone of nitride 
compounds appears on the surface above the areas of 
the thicker zone of internal nitriding). Increasing the 
time to 45 min makes the thickness uniform; however, 
the nitride compounds were not diffused. The use of a 
2 kW generator results in even layers with a constant 
thickness after a 15 min process. However, an 
undiffused zone of nitride compounds is visible. Only 
Generator 
power
Process time
15 min 30 min 45 min
1 kW
1.5 kW
2 kW
Fig. 4.  Summary of metallographic structures obtained for different generator powers and process times

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 506-513
511 Nitriding HS6-5-2 Steel in Inductively Coupled Plasma
extending the duration of the process clearly results in 
increasing the depth of nitrogen diffusion into the steel 
structure and in obtaining layers with only the internal 
nitriding zone, without a zone of nitride compounds 
on the surface (white zone).
The results of XRD studies are the confirmation 
of the above-described phenomenon and the model of 
nucleation and growth of nitrided layers in inductively 
coupled plasma. Fig. 5 shows XRD spectrum, which 
was made for sample processed in the parameters 
considered optimal: 2 kW generator power, for 45 
min. It shows reflections from the Fe phase: ferrite, 
and nitrides, Fe
4
N and CrN. Of course, there are 
also visible carbide phases, e.g., of the Fe
3
W
3
C type, 
which are typical for this type of steel. The reflex at 52 
deg is slightly shifted to the left (compressive stresses) 
and slightly widened, which indicates the existence of 
a solid nitrogen solution gradient in Fe and, therefore, 
the presence of the diffusion zone in the structure.
Fig. 6 presents a list of optical images of the surface 
appearance of the initial samples, after the process 
in which the nitride compounds zone was obtained  
(P = 500 W, t = 45 min.), and after the diffusion of the 
nitride compounds zone (P = 2 kW, t = 45 min.). For 
the initial samples, the surface roughness parameter 
Ra was 0.58 µm. In the case of nitrided samples with 
a zone of nitride compounds, the sample changes to 
dull grey (Fig. 6), which is related to the presence of ε 
nitride on the surface and is consistent with the Ra = 
0.87 µm roughness measurement results. However, in 
the case of surfaces from which the nitride layers have 
been diffused and in the structure, we only observe 
a diffusion zone, the colour changes to a darker one, 
and the appearance is less dull (Fig. 6). The reduction 
of roughness after the diffusion of the nitrides is also 
visible in the results of measurements of the Ra = 0.69 
µm parameter.
a) 
b) 
c) 
Fig. 6.  Summary of the surface appearance of samples in 
different technological conditions; a) the surface appearance of 
the initial sample before the nitriding process, b) the appearance 
of the sample surface after nitriding with the zone of nitride 
compounds, and c) the appearance of the sample surface after 
nitriding and after the zone of nitride compounds diffused
To determine the effective thickness of the 
obtained surface layers, hardness distributions were 
made as a function of the distance from the edge of the 
sample. Due to the unevenness of the layers, especially 
for lower generator power, five hardness distributions 
were made. The average results, compiled separately 
for each of the generator powers for the tested process 
time lengths, are shown in Figs. 7 to 9. It should be 
emphasized that high hardness values were obtained 
despite the core not being hardened.
The maximum hardness of the samples exceeds 
1100 HV , with an initial (core) hardness of about 300 
HV , which translates into a 360 % increase in hardness. 
There is also a general tendency of increasing 
maximum hardness with increasing generator power 
and process time.
Fig 5.  XRD spectrum for nitrided sample at 2 kW generator power, 45 min

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 506-513
512 Binienda,	M.	–	Pie trasik ,	R.	–	P a węta,	S.	–	Matczak ,	K .	–	Kr o t e wicz,	W .
Fig. 7.  Comparison of microhardness distribution of surface layers 
obtained with a 1 kW generator power for different process times
Fig. 8.  Comparison of microhardness distribution of surface layers 
obtained with a 1.5 kW generator power for different process times
Fig. 9.  Comparison of microhardness distribution of surface layers 
obtained with a 2 kW generator power, for different process times
Based on the hardness distributions made for 
a power of 1 kW, 1.5 kW, and 2 kW, the effective 
thicknesses of individual layers were determined 
in accordance with DIN 50190-3 (criterion 50 HV 
above the core hardness), while for the generator 
power of 500 W, the layer thickness was determined 
metallographically. Table 2 shows the thickness of the 
obtained layers as a function of generator power and 
process duration.
When analysing the obtained layer thicknesses, 
it can be observed that, in line with theoretical 
predictions, the layer thicknesses increase along 
with generator power and with the extension of the 
process time. However, due to the thickness of the 
layers, their uniformity and phase structure, only the 
layers obtained with a generator power of 2 kW and 
process times of 30 min and 45 min are of practical 
importance for the application. In these cases, uniform 
layers were obtained without the white zone and the 
precipitation of nitrides at the grain boundaries of the 
former austenite, thus the most desirable for potential 
applications for small cutting tools. 
It should be emphasized that the layers of usable 
thickness are obtained after a very short process (45 
min). If counting a complete pump-down cycle, this 
time is approximately 1.5 hours. Compared to gas 
nitriding methods, for which the full cycle of such 
thickness is about 9 hours, this is a very good result. 
Comparison of the ionic or plasma methods with 
other methods of induction provides the following 
conclusions: the time is similar, but the inductively 
coupled plasma allows to eliminate the edge 
dissolution phenomenon and avoid the shadow effect.
Table 2.  Summary of the thicknesses of the obtained layers as a 
function of generator power and process duration
Generator 
power
Process time
15 min 30 min 45 min
500 W 2.4 µm 4.0 µm 4.7 µm
1 kW 13 µm 47 µm 59 µm
1.5 kW 26 µm 53 µm 65 µm
2 kW 68 µm 87 µm 107 µm
3  CONCLUSIONS
1.  It is possible to obtain nitrided layers with the 
correct structure in inductively coupled plasma. 
It is very important from a technological and 
economic point of view, i.e., a significant 
reduction of the process time with the possibility 
of full regulation of the structure of the layers, 
also without the zone of nitride compounds.
2.  The possibility of nitriding in inductively 
coupled plasma on an industrial scale is also 
very important from an ecological point of view. 
The process uses inert nitrogen instead of toxic 
ammonia. In the new technology, there are also 
no emissions that require the utilization of post-
process gases.

Strojniški vestnik - Journal of Mechanical Engineering 68(2022)7-8, 506-513
513 Nitriding HS6-5-2 Steel in Inductively Coupled Plasma
[5] Pokorny, Z., Dobrocky, D., Kadlec, J., Studeny, Z. (2018). 
Influence of alloying elements on gas nitriding process of high-
stressed machine parts of weapons. Metallic Materials, vol. 
56, no. 2, p. 97-103, DOI:10.4149/km_2018_2_97.
[6] Totten, G., Colas, R. (2016). Encyclopedia of Iron, Steel, and 
Their Alloys. CRC Press, Boca Raton, DOI:10.1081/E-EISA.
[7] Gawroński, Z., Sawicki, J. (2006). Technological surface layer 
selection for small module pitches of gear wheels working 
under cyclic contact loads. Materials Science Forum, vol. 513, 
p. 69-74, DOI:10.4028/www.scientific.net/MSF.513.69.
[8] Nguyen, D.N., Nguyen, A.X., Nguyen, V.B., Le, T.N., Le, T.Ch. 
(2019). Control Gas Nitriding Process: A Review. Journal of 
Mechanical Engineering Research and Developments, vol. 42, 
no. 1, p. 17-25, DOI:10.26480/jmerd.01.2019.17.25.
[9] Maldzinski, L., Liliental, W., Tymowski, G., Tacikowski, 
J. (1999). New possibilities for controlling gas nitriding 
process by simulation of growth kinetics of nitride 
layers. Surface Engineering, vol. 15 no. 5, p. 377-384, 
DOI:10.1179/026708499101516740.
[10] Mittemeijer, E. J., Somers, M. A. J. (1997). Thermodynamics, 
kinetics, and process control of nitriding. Surface Engineering, 
vol. 13, no. 6, p. 483-497, DOI:10.1179/sur.1997.13.6.483.
[11] Aghajani, H., Behrangi, S. (2017). Plasma Nitriding of Steels. 
Springer International Publishing, Berlin, DOI:10.1007/978-3-
319-43068-3.
[12] Chen, F. F. (2012) Introduction to Plasma Physics. Springer 
Science & Business Media, Berlin.
[13] Binienda, M. (2013). Research on the Nitriding of the Small 
Diameter Drills in High-Frequency Ring Discharge Plasma. 
Ph.D. thesis, University of Lodt, Lodz. (in Polish)
[14] Kim, H. S., Kim, J. H., Kim, W. Y., Lee, H. S., Kim, S. Y., Khil, 
M. S. (2017). Volume control of expanded graphite based on 
inductively coupled plasma and enhanced thermal conductivity 
of epoxy composite by formation of the filler network. Carbon, 
vol. 119, p. 40-46, DOI:10.1016/j.carbon.2017.04.013.
[15] Delzeit, L., McAninch, I., Cruden, B. A., Hash, D., Chen, 
B., Han, J., Meyyappan, M. (2002). Growth of multiwall 
carbon nanotubes in an inductively coupled plasma reactor. 
Journal of Applied Physics, vol. 91, no. 9, p. 6027-6033, 
DOI:10.1063/1.1465101.
[16] Global Industry Analysts. (2021). High Speed Steel (HSS) 
Metal Cutting Tools - A Global Market Report, from https://
strategyr.com, accessed on 2021-04-30.
3.  For samples made of HS6-5-2 steel with a 
diameter of 4 mm, it is best to conduct the process 
with a generator power of 2 kW.
4.  The maximum hardness obtained on the raw 
material is about 1100 HV; hardness increases by 
350 % in relation to the starting material.
5.  Layers with functional properties of 100 µm 
thickness are obtained in a very short process 
lasting 45 min.
4  ACKNOWLEDGMENTS
The work has been done under Measure 1.2—Sectoral 
Research & Development programs of “Program 
Operacyjny Inteligentny Rozwój” 2014–2020 (Smart 
Growth Operational Program 2014–2020) co-funded 
by the European Regional Development Fund. The 
project: “Development of nitriding technology for 
machine parts and tools in inductively coupled 
plasma together with a device for its implementation.” 
Contract Number: POIR.01.01.01-00-0088/17.
5  REFERENCES
[1] Pye, D. (2003). Practical Nitriding and Ferritic Nitrocarburizing. 
ASM International, Russell Township, DOI:10.31399/asm.
tb.pnfn.9781627083508.
[2] Bilger, P., Dulcy J., Gantois M., Torchane L. (1996). Control of 
iron nitride layers growth kinetics in the binary Fe-N system. 
Metallurgical and Materials Transactions: A, vol. 27A, p. 1823-
1835, DOI:10.1007/BF02651932.
[3] Sawicki, J., Siedlaczek P., Staszczyk A. (2018). Fatigue life 
predicting for nitrided steel - finite element analysis. Archives 
of Metallurgy and Materials, vol. 63 no. 2, p. 921-927, 
DOI:10.24425/122423.
[4] Sawicki, J., Siedlaczek P., Staszczyk A. (2018). Finite-element 
analysis of residual stresses generated under nitriding 
process: a three-dimensional model. Metal Science and Heat 
Treatment, vol. 59, no. 11-12, p. 799-804, DOI:10.1007/
s11041-018-0229-y.