Mech080510b.qxd


The Journal of Engineering Research  Vol. 7, No. 1 (2010)  1-10

1.  Introduction 

Wear may be defined as the progressive loss of a sub-
stance from the operating surface of a body occurring as a
result of relative motion of the surface with respect to
another body (Stan Grainger, 1994).  The concept
embraces metal to metal, metal to other solids and metal
to fluid contact. This definition is clearly associated with
the surfaces of materials. It must be recognized that wear
and friction are not intrinsic properties of a material but
are characteristic of the total engineering system and its
operating environment Any change in stress, temperature,
speed can have a significant effect on the type of wear or
the wear-rate of a component (Askwith, 1980).
Aluminum-Silicon (Al-Si) castings are considered the
most commercially used (Bolten, 1998 and Mustafa
1995),  because of their engineering significance accepted
mechanical  properties, good   corrosion  resistance,  rela- 
___________________________________________
* Corresponding author’s e-mail: mukeab2005@yahoo.com

tively low thermal expansion coefficient and high fluidity-
during  melting and casting (Bolten, 1998).  Therefore
these alloys are often used in many tri-bological and bear-
ing applications, pistons, cylinder heads in combustion
chamber zones, camshaft bearings, spark plug bosses and
bolt bosses  (Dana, 2001).  There are three families of alu-
minum-based bearing alloys in common use. They are Al-
Pb, Al-Sn and Al-Si-Cd.  Cadmium is used in bearing
alloys, due to a low coefficient of friction and very good
fatigue resistance.

Abbas  and Ibrahim (2003) studied the effect of Cu and
Mg adding on wear behavior of (Al-8%Si) under dry slid-
ing conditions and they concluded that the hardness and
wear resistance increase because of formations of hard
second-phase particles such as Al2Cu () and CuMgAl.
Israa (2005)  studied the effect of lead addition on sliding
wear resistance and friction coefficient of Al-16%Si alloy

Effect of Cd on Microstructure and Dry Sliding Wear
Behavior of (Al-12%Si) Alloy

Muna K. Abbass

Department of Production Engineering and Metallurgy, University of Technology, Baghdad, Iraq

Received  10 May 2008; accepted 1 April 2009

Abstract: The aim of the present research is to study the effect of cadmium addition on microstructure and wear
behavior of the alloy (Al-12%Si) under dry sliding conditions. Wear behavior was studied by using the Pin-On-
Disc technique under different conditions at applied loads 5-20 N, at constant sliding speed and in  constant
time. The steel disc hardness was  35HRc. All alloys were prepared with different percentages of cadmium (1.0,
2.0, 3.0) wt%.  Also the base alloy was prepared by melting and pouring the molten metal in a metallic mold. It
was found that the cadmium addition to Al-Si matrix decreases the wear rate and improves the wear properties
for alloys containing -Cd under loads above 10N.  It was also found that the alloy Al-12%Si containing 3%Cd
is the best alloy in wear resistance and friction coefficient. This is due to presence of the Cd-phase as cuboids
or hard particles distributed in a eutectic matrix which reduces the friction coefficient at high loads (20N).

Keywords:  Wear resistance, Al-Si alloy, Cadmium, Friction coefficient 

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¢SÉÑY Ò° N ≈æe

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 ∂àμJƒÑdG á«°VQG ¤G Ωƒ«eOÉμdGAl-12%Si∂dòc .øJƒ«f 10 øe ÈcG »àdG á£∏°ùŸG ∫ɪM’G ~æY h  çÓãdG ∂FÉÑ°ù∏d h ≈∏ÑdG ¢UGƒN ø°ù– h ≈∏ÑdG ∫~©e π«∏≤J ¤G …ODƒJ

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 .(øJƒ«f 20) á«dÉ©dG ∫ɪM’G ~æY ∑ÉμàM’G πeÉ©e øe π∏≤J »àdGh

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The Journal of Engineering Research  Vol. 7, No. 1 (2010)  1-10

under varying loads and sliding speed conditions. She
concluded that the wear rate of an alloy increases with
speed and applied load. It has been observed that the wear
rate and friction coefficient decrease noticeably with
increasing wt% of lead. The influence of calcium on the
microstructure and properties of an Al-7%Si-0.3%Mg-
xFe alloy has been studied by Sreeja Kumarl, et al.
(2006),  who concluded that the addition of calcium mod-
ifies the eutectic microstructure and also reduces the size
of intermetallic  Fe-platelets, causing improved ductility
and impact strength.   

Basavakumar,  et al. (2007) studied the microstructures
and dry sliding wear behavior of Al-7Si and Al-7Si-2.5Cu
cast alloys after various melt treatments like grain refine-
ment and modification. Results indicate that the combined
grain refined and modified Al-7Si-2.5Cu cast alloys which
have microstructures consisting of uniformly distributed
-Al grains, eutectic Al-silicon and fine CuAl2 particles in
the interdendritic region. These alloys exhibited better
wear resistance in the cast condition compared with the
same alloy subjected to only grain refinement or modifi-
cation.

The aim of present work was  to study the effect of cad-
mium addition on the wear rate and friction coefficient of
Al-12%Si alloy under dry sliding conditions.

2.  Experimental Work 

2.1 Specimens Preparation   
The Al-12%Si alloy (base alloy) was melted and dif-

ferent percentages of cadmium (1.0, 2.0, and 3.0) wt%
were added to the melt of Al-Si separately. Cadmium
metal was enveloped with aluminum foil before being
added to the melt. For each experiment about 300gm of
prealloyed (Al-12%Si) in alumina crucible was placed in
an electric resistance furnace at a temperature 700ºC
which is below the boiling temperature  of  cadmium
metal Tp =767ºC. A small amount of flux (2% CaF2) was

added to the melt to remove the impurities (as slag) from
the melt. The melt was poured into a metallic mold which
was dried before the casting operation at 120ºC by using
the Heracus drier type. The castings were left to cool
down in the air.  The specimens of prepared alloys had
100mm length and 13mm diameter. 

2.2  XRD Measurement

2.3 Wear Specimens 
Wear specimens were machined from an ingot and cut

according to ASTM specification D2625-83 to 20mm
length and 10mm diameter (ASTM, 1989).  Then one sur-
face of each specimen was ground by using emery paper
of SiC in different grits (220,320,500 and 1000). The pol-
ishing  was applied to the specimens by using diamond
paste of size 1.0µm with a special polishing cloth and
lubricant to obtain a clean and smooth surface. The initial
surface roughness of the wear pins was Ra = 0.20µm. 

2.4 Wear Apparatus 
A Pin-On-Disc wear apparatus was used, which was

designed according to ASTM specification F732-82
(ASTM, 1989) as shown in Fig. 1.  The pin (specimen)
was fixed and the disc (carbon steel) was  rotating at a
speed of 510 rpm. The tangential force (friction force) was
rotating  between the pin and the disc through their inter-
face sliding.  The main features of the test specimens and
loading system are described below.

2.5 Test Specimen and Loading System 
The test specimen and loading system shown in Fig. 1

consist of:

Figure 1.  The Pin-On-Disc wear appratus

        The X-Ray diffraction measurements have been 
carried out using Shimadzu-labx X-ray diffraction unit 
model XRD-6000, kV = 40, Cu k , and XRF 
(EDXRF) type, Twin-X, Oxford co. England. These 
measurements include; base alloy and the Al-12%Si-
3%Cd alloy to identify and estimate of the phases in an 
alloy. 



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The Journal of Engineering Research  Vol. 7, No. 1 (2010)  1-10

1. a squirrel-cage type electrical motor (3-phase, and
constant rotational speed of 940 rpm).

2. aluminum pulleys and a V-belt to transmit the speed.
3. a carbon steel rotating disc with a 24 cm diameter and

a hardness of 35HRc and a surface finish of 0.8 µm.
4. a mechanism for loading the specimen which is drawn

in detail in Fig. 1.  Loading is applied by load weights
representing normal force on pin and disc  transmitted
to the specimen by a lever system and holder. The ful-
crum is 36cm and 7cm from disc center  3.7 m/sec rel-
ative speed of pin and disc  from the point of loading
or 34cm and 5cm from disc center  2.7 m/sec relative
speed) as the load is applied directly to the holder.

5. four sensitive strain gages fixed on the inner and outer
walls of a steel ring taken from TQ calibration appara-
tus (attachment set) of S6072-E-31 Techequipment
strain meter shown in Fig. 2.   (The system is fixed on
the holder and the force is transmitted directly from
the lever to the ring by a 5mm diameter and of 3cm
long pin.  The whole system was leveled and placed on
a heavy steel table to minimize vibration). 

2.6 Wear Test 
The weight method was used to determine the wear rate

of specimens.  The specimens were weighted before and
after the wear test with a sensitive balance type DENVER
instrument Max-210gm with an  accuracy  of 0.0001 gm.
The weight loss  W was divided by the sliding distance
and the wear rate was obtained  by using the following
equation (UNIDO, 1990).

Wear rate = w/SD (1) 

w = w2 - w1 (2)  

SD = SS . t                                                              (3)

Wear rate (W.R) = W / D.N.t                          (4)

where:

W.R = wear rate (gm/ cm)
SD = sliding distance (m)
Ss = linear sliding speed(m/sec.)
D = sliding circle diameter (cm)
SS = sliding distance (cm)
t = sliding time (min)
N = steel disc speed (rpm)
Hardness of       = 35 HRc

steel disc 
Diameter of =  10 mm

specimen
Length of =  20 mm

specimen 

2.7  Measurement of Friction Coefficient 
Friction coefficient (μ) is found by dividing the fric-

tional force (F) by the applied  load (N)  according to the
equation as follows: 

µ = F / N                                                              (5) 

Frictional force is found by a specially designed steel
ring taken from a calibration apparatus of a TQ strain
meter mounted on a U-angle block, fixed on the bench and
aligned with the left-side of the lever arm. The force is
transmitted from the left side of the fulcrum lever to the

Figure 2.  Four strain gages mounted on steel ring in addition to strain gage calibration system



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The Journal of Engineering Research  Vol. 7, No. 1 (2010)  1-10

ring by a 5mm diameter and 3cm long sliding rod. Two
half bridges were formed on the inside and outside ring
surfaces by means of four strain gauges with a gage factor
of 2.065. These strain gages were then connected to a TQ-
S6072 digital bridge strain meter as shown in  Fig. 3.
Before running the experiment, the digital strain microm-
eter display cathode ray screen was calibrated to record
the micro-strain reading before and after running.  The
reading from the strain meter was taken and the calibra-
tion curve of load (force) versus strain was plotted in Fig.
4 at a constant sliding time (20 min) and sliding speed 2.7
m/sec and the steel  disc hardness was  35HRc.

2.8  Measurement of Microhardness 
Small specimens of base alloy  Al-12%Si (alloy A) and

of Cd-containing alloys alloys B, C & D were prepared by
turning processes in the dimensions of 12mm in length
and 10mm in diameter. A wet grinding operation with
water was done by using emery paper of SiC in the differ-
ent grits (220, 320, 500, and 1000). Polishing  was done to
the specimens by using diamond paste of size (1µm) and
special polishing cloth and lubricant. They were cleaned
with water and alcohol and dried with hot air. Etching
process was done to the specimens by using an etching
solution which was composed of (99% H2O+1%HF).

Figure 3.  Micro strain meter aparatus used in this study

y = 33.473x

0

200

400

600

800

1000

1200

0 5 10 15 20 25 30 35

micro strain   μ?

Figure 4.  The calibration curve of load versus strain at a constant sliding time of 20 min,
sliding speed of 2.7 m/sec. and steel disc hardness of 35 HRc

micro strain 

lo
ad

 (
gm

)



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Then the specimens were washed with water and alcohol
and dried. The Vickers hardness test was carried out by
using Vickers hardness tester type Einsingenbei  U/M,
Model Z323.  A diamond indenter was forced into the sur-
face of the  specimen being tested under a static load of
300 mg for 10 to 15 sec.  Measurements of the indentation
diagonal were made in 3 to 5 readings and the average
hardness  HV was found as shown in Table 1.

3.  Results and Discussion

3.1   Microstructure Results
Primary silicon has a cuboidal form which can be seen

in the micrograph (Fig. 5a) of an alloy Al-12%Si.  The
eutectic mixture, though, is non-lamellar in form and
appears, in section, to consist of separate flakes of silicon
(grey) and alpha Al-phase (white) (Basavakumar, et al.
2007).   A coarse platelet of the crystals of the Al-Si eutec-
tic phase was formed in the casting during solidification.
These particles are brittle and tend to reduce the mechan-
ical properties of the casting (Lidman, 2005 ).  During the
solidification of the cast Al-Si alloys in a primary -phase
start to separate from the liquid. After nucleation when the
temperature decreases the primary phase grows as solid
crystals have a dendrite shape.  On the polished surface
two phases can be distinguished and the secondary arms
of the dendrites cut on the sample phase clearly appear
Zhang, et al. 2003).  Figure (5b-5d) shows the microstruc-
tures of alloys B, C and D containing cadmium 1%, 2% &
3% respectively.  It is seen that the particles of Cd are dis-
tributed as small particles in the matrix and Al-Si eutectic
phase, because it is probable that there is only an extreme-
ly small solubility of Al in solid Cd as indicated in Al-Cd
phase diagram (Davis and Associates, 1982),  see Fig. 6. 

Modification and grain refinement in microstructure of
Al-Si alloy have been achieved due to the presence of cad-
mium particles in the matrix of the eutectic phase. Fig. 7
indicates X-Ray diffraction analysis results of an alloy
(Al-12%Si-3%Cd) and the presence of Si and Al phases in
the microstructure of the alloy. 

3.2 Wear Results

3.2.1  Effect of Cd on Wear Rate
The addition of Cd to the base alloy (Al-12 %Si) leads

to a decrease in wear rate as shown in Fig. 8. The wear
behavior of base alloy (A) is mild wear (oxidative wear)
at low loads 5-10 N, and when the load increases the wear
rate increases and transforms to metallic wear at high
loads 10-20 N. These results are in agreement with  those

of other researchers (Israa, 2005 and Jawdat, 2002).
In case of Al-12%Si containing 1%Cd (alloy B) and

2%Cd  (alloy C) respectively, Fig. 8, it can be seen that the
wear rate reaches maximum value at load 10 N and then
decreases as the applied load increases to 20 N. This is due
to work-hardening of the matrix by plastic deformation
which helped in reducing the extent of wear of the sam-
ples at high loads. During wear at high loads, the temper-
ature increases appreciably, thus  lowering the strength of
the materials in contact and resulting in an increased con-
tact area and coefficient of friction.  The stronger grain-
refined and modified alloys recorded the lowest wear rate.
This is due to the presence of Cd phase as hard particles
(the hardness of pure cadmium is 203MPa) distributed in
matrix of  (Al-Si), which reduces the contact area between
the steel disc and the specimen surface in addition to the
role of silicon phase which increases wear resistance.  In
Fig. 8 shows  that the wear rate decreases to lower values
as  Cd addition  increases to 3%Cd in an Al-12%Si alloy.
These results are due to the increase in hardness of the
alloy alloy D to 103 HV in comparison with the base alloy
(alloy A) which is 70HV, see Table 1 which gives the
hardness results of the studied alloys (See Table 1).

3.2.2  Effect of Cd on Friction Coefficient 
When two surfaces slide together, most of the work

done against friction is turned into heat. The resulting rise
in temperature may modify the mechanical and metallur-
gical properties of the sliding surfaces, and it may make
them oxidize or even melt.  All these things influence the
wear rate and friction coefficient.

In order to minimize friction forces we must use lubri-
cants. These contaminate the surface preventing adhesive
contact and obviously lowering the coefficient of friction
(µ) (Mikell Groover, 1999).

In this work, friction coefficient can be reduced, under
dry sliding conditions by increasing the surface hardness
of the alloy (A1-12%Si) through the addition of cadmium
to a matrix of eutectic phase (Al-Si).  Figure 9 shows the
relationship between the coefficient of friction (µ) and
sliding time at a constant load of 20N for different alloys
(A, B, C & D).  In the first sliding time the µ increases
with time until it reaches a steady state and then continu-
ing for longer periods (20 minutes or more).  This is due
to the presence of cuboids or hard cadmium particles dis-
tributed in the matrix which resists the large applied forces
normal to the surface and hence separate the asperity tips
very effectively, while the two surface layers can shear
over each other  quite easily.  This  can  reduce the coeffi-
cient of friction (µ).  It was found that as the Cd% increas-
es the grains becomes smaller and finer.   The stronger
grain-refined and modified alloys recorded the lowest
coefficient of friction. These results are similar to those of
references  (Basavakumar, et al. 2007 and  ASM
Materials, 2002).

3.2.3  Worn Surface Results
There are two main types of wear abrasive wear and

adhesive wear. The present work studied the former one.

Specimen 
No. 

Cd ( wt%)  HV (Kg/mm 2) 

A 0% (base alloy)  70 
B 1.0 85 
C 2.0 97 
D 3.0 103 

Table 1.  Hardness results of the studied alloys



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The Journal of Engineering Research  Vol. 7, No. 1 (2010)  1-10

 

(Al-Si) 
eutectic 

Cd  particle  

50 μm 
b 

50 μm 
c 

Cd  particle  

 

(Al-Si) 
eutectic 

alpha phase  

  a 
50 μm 

50 μm 

(Al-Si) 
eutectic 

Cd  particle  

d 

Al-12% Si alloy

Al-12% Si alloy
1% Cd

Al-12% Si alloy
2% Cd

Al-12% Si alloy
3% Cd

a

Si phase

Figure 5.  The microstructures of the studied alloys (as cast)



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The Journal of Engineering Research  Vol. 7, No. 1 (2010)  1-10

Adhesive wear is often called frictional wear since it aris-
es from the same basic mechanism of friction that comes
from welding and subsequent shearing of minute surface
asperities. When two nominally flat surfaces, no matter
how smooth are brought into contact, they will only touch
at relatively few isolated points. When sliding occurs
these welds are sheared. When operating under heavy
loads (or high speeds), the wear debris will appear as large

mainly metallic particles (severe wear).  On the other hand
operation under light loads (or low speeds) will produce
fine oxide wear debris (mild wear) (Ashby and Jones,
1980).

Figures 10a-10d show micrographs of the worn sur-
faces of specimens (A, B, C & D) at an applied load of
20N during wear test. 

Figure 6.  Phase diagram of Al-Cd alloys (Davis, J.R. and Associates, 1982)

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

 
2 è  

  A l 

S i 

S i  

S i 

A l 

Fig.7   XRD results of an alloy ( Al -12%Si -3%Cd Figure 7.  XRD results of an alloy (Al-12%Si - 3%Cd)

In
te

ns
it

y 
(C

.P
.S

)

2

Al-Cd



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The Journal of Engineering Research  Vol. 7, No. 1 (2010)  1-10

The worn or damaged surface shows continuous
grooves and cracking of a long wear track. In some places,
some plastic deformation, together with presences of fine
oxides debris particles are also observed in case of base
alloy Al-12%Si.  While it is seen as smooth and with
glassy finish and faint wear lines in the direction of slid-
ing on worn surfaces, this  indicates that a mild abrasion
wear mode is present in case of Al-12%Si alloys contain-
ing cadmium especially alloy D. 

4.  Conclusions

1. Modification and grain refinement in the microstruc-
ture of Al-Si alloy have been achieved by the presence
of cadmium particles in the alloy matrix.

2. The wear behavior of base alloy A1-12%Si changes
from mild wear (oxidative wear) at low loads 5-10 N
to metallic wear at high loads 10-20 N. 

3. The cadmium added to alloy  Al-12%Si changes the
wear behavior at higher loads than  5-10 N.

Figure 8.  The  effect  of  applied load  on  wear rate  of  different alloys  at a sliding 
speed of 2.7 m/sec, sliding time of 20 min and steel disc hardness of 35 HRc

Figure 9.  The effect of cadmium adding on friction coefficient () of different alloys
at a applied load of 20N and sliding speed of 2.7 m/sec

Sliding Time, min

F
ri

ct
io

n 
C

oe
ff

ic
ie

nt

Applied Load, N

W
ea

r
R

at
e,

 (
m

g/
cm

) 
*1

0-
8



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The Journal of Engineering Research  Vol. 7, No. 1 (2010)  1-10

4. The alloy A1-12 % Si containing 3% Cd shows the
highest wear resistance in comparison with other
alloys at a high load 20 N.

5. The cadmium added to alloy Al-12 % Si reduces the
friction coefficient at high loads.

6. The addition of cadmium at different ratios leads to an
increase in the hardness of the aluminum silicon based
alloy.

References

Abbas, M.K. and  Ibrahim, E.K., 2003, "Effect of Copper
and Magnesium Adding on Wear Behavior of (Al-Si)
Alloy," Engineering and Technology Journal,
University of Technology, Baghdad - Iraq, Vol. 22(1),
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Ashby, M.F. and Jones, D.R.H., 1980, "Engineering
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Askwith T.C., 1980, "The Basic Mechanisms of Wear,"
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Wear Behavior of Al-7Si and Al-7Si-2.5Cu Cast
Alloys,"  Journal of  Material  Science,  Vol. 42,  pp.
7882-7893.

Bolten, W., 1998, "Engineering Materials Technology,"
Butterworth's, 3rd ed.

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

(a)  Al-12%Si (Base alloy ) (b)  Al-12%Si-1%Cd 
 

( c)  Al-12%Si-2%Cd 
(d)  Al-12%Si- 3%Cd 
 

Fig.10   Micrographs of the worn surfaces of different alloys at a applied load  of 
20N , sliding speed  of 2.7m/sec and steel  disc har dness of 35HRc  

sliding direction                                     

100ì m 100ì m 

100ì m 100ì m 

Figure 10.   Micrographs of the worn surfaces of different alloys at a applied load  of 20 N,  
                     sliding speed  of 2.7m/sec and steel  disc har dness of 35HRc   
                     sliding direction                                      

(c) Sl-12% Si-2% Cd
(d) Al-12% Si-3% Cd

(a) Al-12% Si (Base alloy) (b) Al-12% Si-1% Cd



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