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Aging Effect on Microstructure and Machinability of 
Corrax Steel 

 

Ahmet Serdar Guldibi 
Faculty of Technology 
Karabuk University 
Karabuk, Turkey 

aserdarguldibi@karabuk.edu.tr 

Halil Demir 
Faculty of Technology 
Karabuk University 
Karabuk, Turkey 

hdemir@karabuk.edu.tr 
 

 

Abstract—In this paper, the influence of the aging process on the 

microstructure and machinability of Corrax Steel was 

investigated for four samples: a solution heat-treated (A0) and 

three samples aged at 400ºC (A4), 525ºC (A5.25) and 600ºC (A6) 

for four hours. The effect of aging temperature on hardness was 

examined. Machining tests were carried out using a CNC lathe 
with a multi-layer coated PVD (AlTiN) cutting tool, at various 

cutting speeds (50, 100, 150, 200, 250, 300, 350m/min) with 

constant feed rate (0.1mm/rev) and 1mm constant cutting depth. 

The microstructure was investigated using an optical microscope 

and EDS attached SEM. The effect of aging on reverted austenite 

formation was also evaluated. In order to understand the changes 

in surface topology, cutting forces and vibrations were measured. 

With increasing aging temperature, the lath martensite was 

transformed to plate martensite because of the formation of 

precipitates and reverted austenite. Aging at different 

temperatures increased hardness up to 58%, cutting forces up to 

117% and surface roughness up to 450%. The results describe 

the effect of the aging treatment on cutting forces, surface 
topology, tool wear and vibrations. 

Keywords-dry turning; corrax; cutting force, surface 

roughness; vibration 

I. INTRODUCTION  

Investigation of martensitic steels started in USA during the 
60’s. Martensitic steels have low carbon and have high strength 
and corrosion resistance [1]. These properties are reached by 
convenient composition and properly applied aging treatments. 
Corrax is a maraging steel appropriate for many applications 
such as plastics processing, extrusion dies, plastic extruder’s 
screws, guideways, landing gears, dental, and medical 
equipment [2-4]. The main goal of manufacturing companies is 
advanced productivity, improving surface finish and 
dimensional precision while reducing cost [5]. However, these 
goals are difficult to achieve especially during machining, as 
hardened maraging steels are as hard to machine materials [6]. 
Cutting forces, specific cutting energy, shear angle, shear 
stress, friction coefficient and shear stress rates for AISI 420 
steel at various cutting conditions and with various cutting 
tools have been investigated. According to test results, feed rate 
effects cutting forces, while cutting speed is the major effect of 
energy consumption. In [7], cutting forces and cutting energy 
reached maximum value at 60m/min and were reduced at 

higher cutting speeds. The machining of PH 15-5 maraging 
steel, aged at 482ºC to receive peak hardness value, was 
investigated in [8]. The machining tests were carried out using 
TiAlN coated tungsten carbide inserts with various nose 
radiuses (0.4, 0.8 and 1.2mm) at different cutting speeds and 
feed rates. Increasing feed rate increased cutting forces: 0.8mm 
nose radius caused higher cutting forces than 0.4mm and 
1.2mm. High cutting speed, low feed rate and middle tool nose 
(0.8mm) generated minimum surface roughness value 
(0.447µm). The heat formation during hard turning of 
chromium hardfacing materials was studied in [9]. Results 
showed that increasing cutting speed or feed rate increased 
cutting temperature. The temperature increase rates depended 
on the microstructure of the material. Machining finer 
structures cause higher temperature increment rate. The 
predicted temperature for fine structured materials is 650-
700ºC, while for coarser structured materials is 600ºC. The 
temperature and cutting forces during machining of SAE 4140 
steel was investigated in [10]. Results showed that increasing 
cutting speed increases the temperature on the rake face, 
enlarging the tool-chip contact area. 

The effects of hot turning on cutting forces, tool wear and 
surface topology, were examined in [11]. Experiments were 
carried out at room temperature, 300ºC and 600ºC. The 
outcomes showed that the increase of temperature decreased 
cutting forces, reduced tool wear, and improved surface 
topology. Machining Monel 400 at room temperature caused 
BUE formation, which enhanced tool’s life compared to 
Inconel 625 and Inconel 718. BUE formation increased tool’s 
life but also increased the surface roughness in the machining 
of Monel 400. Hot turning enhanced tool’s life, but this 
enhancement was poor for Inconel 625 and Monel 400 
compared to Inconel 718. The effects of different types of 
cutting fluid on cutting temperature, chip thickness, surface 
roughness, cutting forces and shear angle were investigated in 
[12]. Experiments were carried out under dry, conventional 
cutting fluid and cryogenic carbon dioxide at three different 
cutting speeds and four feed rates at 1mm cutting depth. 
Results showed that breakability was improved under 
cryogenic machining chips when compared to wet and dry 
machining. CO2 penetrated better the cutting zone improving 
lubrication. Improved lubrication reduced the cutting 
temperature and cut chip thickness. Increasing cutting speed 

Corresponding author: Ahmet Serdar Guldibi 



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decreased cutting forces because of the heat generated on the 
cutting zone. Under cryogenic cutting conditions, increasing 
cutting speed caused higher decrease in cutting forces, because 
of the improved lubrication. Increased cutting speed reduced 
surface roughness, cutting forces and vibration during 
machining. Increased feed rates also increased the surface 
roughness.  

There are several researches about the aging treatment, 
strength, hardness, fracture toughness, strength in high 
temperature, reverted austenite formation, and hydrogen 
embrittlement of maraging steels [13-16]. However, there is a 
lack of extensive study on the machining of Corrax steel. This 
study investigated the machinability of solution heat treated 
and aged at three different conditions Corrax steel, under 
different cutting speeds, in order to understand the effect of 
aging on its microstructure, hardness, and machinability. 

II. EXPERIMENTAL PROCEDURE 

A. Workpiece Materials 

Corrax steel was obtained from Uddeholm Turkey 
Corporation. The samples were solution heat treated at 850ºC 
for 0.5h and subsequently air-cooled. Table I shows the 
chemical composition of steel, analyzed by the GNR Atlantis 
optical emission spectrometry. 

TABLE I.  CHEMICAL COMPOSITION OF CORRAX STEEL 

Element C Si Mn P S 

% 0.048 0.203 0.253 0.012 0.026 
Element Cr Mo Ni Al  

% 12.24 1.388 9.064 1.582  
 

B. Heat Treatment and Microstructure 

The supplied Corrax steel had 350mm length and 35mm 
diameter. Four samples were obtained for the aging treatment. 
The samples were solution heat treated at 850ºC for 0.5h and 
then cooled at room temperature before the aging treatment. 
After the solution heat treatment all samples, except one (A0), 
were aged at three different temperatures (400, 525, 600ºC) for 
four hours and cooled in room temperature. At the end of the 
aging treatment, four sets of samples were obtained: (i) solution 
heat treated (A0), (ii) aged at 400ºC (A4), (iii) aged at 525ºC 
(A5.25) and (iv) aged at 600ºC (A6). Conventional 
metallographic methods such as grinding, polishing and 
etching were used for microstructural investigation. Kalling’s 
reagent was used for etching at various etching times, 
depending on material’s hardness. Etching time depended on 
the hardness of each sample. The microstructure of the samples 
was examined using a Nikon Epiphot 200 optical microscope 
and an EDS equipt Carl Zeiss Ultra Plus Gemini Fesem 
scanning electron microscopy (SEM). XRD investigations were 
carried out using a Rigaku Ultima IV. XRD, SEM and EDS 
examinations were carried out in Iron and Steel Institute 
(MARGEM) at Karabuk University. Microhardness testing was 
conducted using a Shimadzu Vickers microhardness testing 
machine, with an HV1 (9,807N) load and 15s holding time. At 
minimum five hardness measurements were made on each 
sample and their average was accepted as hardness value. 

C. Machine and Cutting Tool 

Machining tests were accomplished using a Fanuc Control 
unit equipped with a Johnford TC-35 Lathe having 10KW 
power. The turning tests were carried out using PVD 
multilayer-coated cementite carbide inserts with a 
CNMG120408RP geometry. The cutting inserts were designed 
by Kennametal. The inserts were mechanically fixed on a tool 
holder with a DCLNR2525 geometry. The inserts were 
designated by KC5010 Kennametal which is equivalent to P10-
20. 

D. Cutting Parameters 

Machining tests were performed under dry cutting 
conditions without any cooling liquid. Cutting parameters were 
determined into the recommended, by the manufacturer, limits 
in order to observe the performance of the cutting inserts. The 
cutting parameters are exposed in Table II. 

TABLE II.  CUTTING PARAMETERS 

Workpiece samples Vc (m/min) f (mm/rev) ap (mm) 

A0 
A4 

A5.25 
A6 

50 

0.1 1 

100 
150 
200 
250 
300 
350 

 

Cutting forces were measured using Kistler 9257B 
piezoelectric 3-axes dynamometer. The Mutitoyo Surftest 211 
surface roughness tester was used for measuring the surface 
roughness. Three different measurements were made on each 
surface and their average was accepted as the surface 
roughness value. Vibration measurements were performed 
using iDynamic application [17] with an MTK sensor having 
0.00390625 m/s2 resolution. 

III. RESULTS AND DISCUSSION 

A. Workpiece Materials 

Optical micrographs of A0, A4, A5.25 and A6 are shown in 
Figure 1, while similar microstructure investigations for PH 13-
8 Mo were carried out in [18, 19]. As it can be observed, the 
microstructure of the sample A0 has large and irregular 
massive martensite blocks. Increasing aging temperature 
transforms the martensite structure from lath to plate. While 
massive martensite structures are seen in Figure 1(a)-1(c), 
Figure 1(d) shows the plate martensite structure. Figure 1(c) 
shows the microstructure of the A5.25 sample with 
molybdenum carbides in the aged martensite structure [20]. 
The martensitic structure is smaller, compared to A0 and A4 
samples. The microstructure of the A6 sample, seen in Figure 
1(d), has the highest amount of reverted austenite, indicated by 
white areas [21]. The transformation of massive to plate 
martensite with the increase of aging temperature can be 
explained by the formation of reverted austenite on the 
martensite borders [15, 22]. The growth of reverted austenite 
into martensite reduced massive martensite to plate martensite. 
In addition, the Al content allows NiAl precipitations through 
aging which caused resistance to coarsening, even at high 
temperatures [23]. 



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(a) (b) 

  
(c) (d) 

Fig. 1.  Microstructure of: a) solution heat treated (A0), b) aged at 400℃ 
(A4), c) aged at 525℃ (A5.25). d) aged at 600℃ (A6) 

Maraging steels are designed to form a martensitic structure 
and austenite transforms completely into martensite during 
cooling [29-32]. The XRD patterns of the samples, presented in 
Figure 2, indicate that the dominant microstructure consisted of 
martensite phase. The significant intensity peaks of bcc(110) 
with small intensity of bcc(200) and bcc(211) show the 
martensite phase formation. The aging treatment causes a 
reverted austenite formation in the microstructure. Increasing 
the aging temperature also increases the amount of reverted 
austenite in the microstructure, as seen in Figure 2. 

 

 
Fig. 2.  XRD patterns of samples 

Figure 3 shows the EDS analysis with the spectrum points 
1-6 white marked on the microstructure of the A5.25 sample. 
The selected points contain different percentages of C, Cr, Ni, 
Mn, Fe and Al elements. The existence of these elements 
demonstrates a small amount of NiAl, CrC, MoC, Fe3C and 
NiMn precipitates, which affect the strength of steels [13, 24-
26]. The precipitations in the martensite structure hinders the 
dislocation motion that enhances the strength of steel [27, 28]. 
Aging at temperatures over 525ºC causes a significant amount 
of reverted austenite [14]. Reverted austenite nucleates at the 
martensite lath boundary and low amounts of reverted austenite 
are not visible under a light microscope [33]. This austenite 
formation is the result of an uncompleted transformation of 
austenite into martensite. The aging process causes an inverse 

transformation from martensite to austenite [34, 35], while 
similar results were reported for Corrax [36, 37]. The solution 
heat treated sample (A0) has less than 2% retained austenite 
[38]. Increasing aging temperature and time, increased the 
reverted austenite formation [39, 40]. Retained austenite, which 
is free of precipitates, decreased toughness and strength as 
reported in [41]. The reason for this decrease in toughness and 
strength can be explained by the brittle character of the matrix, 
in which the overaged particles serve as crack nucleation sites 
[42-44]. 

 

 
Fig. 3.  SEM Image of A5.25 sample aged at 525ºC 

TABLE III.  EDS OF INDICATED PARTICLES IN A5.25 

Spectrum C Al Cr Mn Fe Ni Mo 

1 17.22 1.35 20.20 2.11 51.72 6.26 1.14 
2 6.95 1.11 23.16 2.82 54.00 10.64 1.32 
3 2.07 1.88 19.11 6.01 60.49 9.14 1.30 
4 2.74 1.54 19.17 3.81 62.13 9.50 1.12 
5 3.89 1.55 18.67 1.02 62.50 11.19 1.19 
6 2.50 1.48 18.83 4.41 62.43 9.89 0.46 

Mean value 5.89 1.49 19.86 3.36 58.88 9.44 1.09 
Sigma 5.82 0.25 1.71 1.77 4.77 1.73 0.32 

Sigma mean 2.38 0.10 0.70 0.72 1.95 0.71 0.13 
 

B. Micro Hardness 

Micro hardness tests were carried out at room temperature 
and the results are shown in Figure 4. Hardness was affected by 
aging temperature. The lowest hardness was measured for the 
A0 sample. Increasing aging temperature up to 525ºC increased 
hardness and its highest value was obtained at aging 
temperature of 525ºC. The increase on hardness can be 
explained by the diffusion assisted mechanism that hinders the 
dislocation movements. The principle of the particle 
strengthening is hindered by the dislocation movement of 
nanometer-sized particles precipitation [45, 46]. Higher aging 
temperatures decrease hardness, because of the growth of 
precipitations and reverted austenite formation in the 
microstructure [16, 47-49]. 

C. Cutting Forces 

Turning experiments were carried out at seven different 
cutting speeds (50, 100, 150, 200, 250, 300, 350m/min), at a 
constant feed rate of 0.1mm/rev and 1mm cutting depth. 



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Cutting forces are shown in Figure 5. Aged samples cause 
higher cutting forces than the solution heat treated sample A0, 
e.g. the cutting forces increased by 85% for A4, 103% for 
A5.25 and 96% for A6 samples respectively, compared to those 
of the A0 sample. The highest cutting force was measured 
during the machining of the A5.25 sample, which is attributed 
to its highest material hardness. The lowest cutting force was 
measured in A0, which had the lowest hardness (332Hv). The 
results showed that the aging treatment has a great influence on 
cutting forces because of the precipitation formation in the 
microstructure. Precipitations hinder the movement of 
dislocations, reducing the cutting forces increment. However, 
overaging causes a decrease of cutting forces and hardness 
because of the overgrowth of precipitations. These reasons 
explain the decrease of cutting forces during the machining of 
the A6 sample. 

 

 
Fig. 4.  Hardness of the samples 

 
Fig. 5.  Cutting forces versus cutting speed 

The effect of cutting speed on the cutting forces was also 
investigated for each sample. The lowest cutting forces were 
measured at 200m/min, for all samples with the exception of 
A6. The lowest cutting forces for A6 sample were obtained at 
350m/min. Machining A0 sample at different cutting speeds 
caused irregular cutting forces, which can be attributed to 
vibrations as seen in Figure 6 [50]. The cutting forces of aged 
samples, except from A5.25 decrease for cutting speeds up to 
200m/min. This can be explained by the temperature 
increments on the cutting zone [51]. While machining materials 
harder than 45HRc (hard turning) the temperature on the 
cutting zone reaches an austenization temperature softening the 
material while machining [52-56]. Machining of A5.25 caused 
high cutting forces at cutting speeds higher than 200m/min 
because of serious tool wear. Tool wear changes the shape of 
the rake angle and the tool-chip interface. A small decrease at 
350m/min can be noted in Figure 5. This can be explained by 
the extreme tool wear, as seen in Figure 7, which changes the 

cutting depth. The cutting forces depend on the material’s 
hardness: increasing hardness increases cutting forces. The A6 
sample has the lowest cutting forces, compared to the other 
samples. This can be explained by its lowest hardness value 
and the retained austenite formation in its microstructure. 
Retained austenite decreases strength and hardness. In general, 
increasing cutting speed decreases cutting forces. This can be 
explained by the decreased on tool-chip interface and the 
increased heat on cutting zone that soften shear strength [57]. 

 
Fig. 6.  Root mean squaer values at different cutting forces 

Tool wear changes tool’s geometry, affecting the cutting 
process. This is the reason why cutting forces and vibrations 
are high at excessive cutting speeds, as seen in Figures 5 and 6. 
A small increment of vibrations, as seen in Figure 6 at 
150m/min cutting speed for A0, can be explained by the 
continuous chip formation. The increment of vibrations at 
150m/min caused the increase of cutting forces. The lowest 
vibrations were measured in the A6 sample, which can be 
explained by the reverted austenite in the microstructure that 
reduced hardness and toughness. As a result, it can be noted 
that vibrations have great effect on cutting forces. 

 

  

(a) (b) 

  

(c) (d) 

Fig. 7.  SEM images of worn cutting tools for A5.25 samples after 
machining at: a) 200m/min, b) 250m/min, c) 300m/min, and d) 350m/min 

D. Surface Roughness 

Figure 8 shows the workpiece surface roughness values for 
A0 (332Hv), A4 (426Hv), A5.25 (525Hv) and A6 (404Hv) 



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samples. The measured surface roughness value for each 
sample is the average of three measurements. Cutting speed has 
great influence on the produced surface roughness. Increasing 
cutting speed decreases surface roughness. However, 
increasing cutting speed for the hardest sample, A5.25, caused 
serious tool wear, which disrupted the surface topology. 
Machining of the A0 and A6 samples showed the lowest 
surface roughness. This is explained by the lowest hardness 
value of A0 and the reverted austenite formation in the 
microstructure of A6, which decreased toughness and hardness. 
Low hardness and toughness ease the cutting process, 
enhancing surface roughness. 

 

 
Fig. 8.  Surface roughness versus cutting speed 

Machining A0 at a 50m/min cutting speed showed an 
increase of surface roughness comparing to the A6 sample. 
This is explained by the continuous chip formation, as seen in 
Figure 9, which damaged the machined surface. 

 

  

(a) (b) 

  

(c) (d) 

Fig. 9.  Chip formation at 50m/min for: a) A0, b) A4, c) A5.25, and d) A6 

The lowest surface roughness was obtained at 350m/min, as 
0.51µm for both A0 and A6 samples. However, surface 
roughness values for the A4 sample were not usual. The peak 
surface roughness value for A4 sample was obtained at a 
100m/min cutting speed, which is explained by the vibration 
peak, as it can be noted in Figure 6 [58]. Machining A5.25 
(525Hv) at 50m/min caused a tool overhang and the highest 
vibration, as it can be noted in Figure 6, being the reason of the 

high surface roughness [59]. Extreme high surface roughness 
values for A5.25 were obtained at 250, 300 and 350m/min 
cutting speeds because of serious tool wear, which also caused 
vibrations, as it can be noted in Figure 6. As a conclusion, the 
vibration has great effect on surface topology. There are many 
reasons for cutting forces and surface roughness correlation. 
One of the main is the effect of the vibrations while machining. 
The rise of vibrations depends on cutting speed, tool wear, and 
the samples’ microstructure. The increase of vibrations caused 
an increase of cutting forces. Serious tool wear also increased 
vibration formation. The lowest vibrations were obtained 
during the machining of the A6 sample, something that can be 
explained by the reverted austenite formation that reduced 
hardness and toughness. 

IV. CONCLUSION 

This study investigated the influence of precipitation and 
reverted austenite formation on cutting forces and surface 
roughness of Corrax steel. Machining tests were carried out for 
A0 (332Hv), A4 (426Hv), A5.25 (525Hv) and A6 (404Hv) 
samples. The results showed that: 

• The aging treatment has a major effect on the formation of 
precipitation that causes an increase on hardness. The 
highest hardness was measured for the sample aged at 
525ºC for four hours. Hardness increase is a result of 
precipitation formation in the microstructure. Aging 
temperatures higher than 525ºC decreased hardness due to 
overaging which caused reverted austenite formation and 
the growth of precipitations in the microstructure.  

• Aging treatment improves the mechanical properties and 
makes the cutting process more difficult. Machining of the 
hardest sample (A5.25) caused serious tool wear at high 
cutting speeds such as 250, 300 and 350 m/min. Cutting 
forces were increased by sample’s aging temperature up to 
525ºC. Aging at 600ºC caused a cutting forces decrease 
because of the reverted austenite formation and the growth 
of precipitations.  

• Cutting speed, vibration and tool wear affected seriously 
surface roughness. The lowest surface roughness values 
were measured for A0 and A6 samples. Vibration and tool 
wear have a serious effect on the surface roughness values, 
as well as cutting forces. Reverted austenite formation also 
reduced vibrations and improved surface roughness. 

ACKNOWLEDGMENT 

This research was supported by the Scientific Research 
Projects Department of Karabuk University (BAP) with Project 
No KBÜBAP-18-KP-145. 

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