

Mech090603.qxd


The Journal of Engineering Research   Vol. 7, No. 1, (2010) 53-61

1.  Introduction 

In recent years, the development of metal matrix com-
posites (MMCs) has been receiving worldwide attention
on account of their superior strength and stiffness in addi-
tion to high wear resistance and creep resistance com-
pared  to their corresponding wrought alloys. The ductile
matrix permits the blunting of cracks and stress concentra-
tions by plastic deformation and provides a material with
improved fracture toughness (Aigbodion. V.S, 2007).

The present trend, therefore, seems to be towards the
development of discontinuously reinforced metal matrix
composites which are gaining widespread acceptance pri-
marily because they have recently become  available at a 
__________________________________________
*Corresponding author’s e-mail: aigbodionv@yahoo.com

relatively low cost compared to uni-and multi-directional 
continuous-fiber reinforced MMCs and the availability of
standard or near-standard metal working methods which
can be utilized to form these MMCs (Aigbodion, V.S,
2007, and  Clyne, T. W, 2000).

Nowadays, research all over the globe is focusing
mainly on Aluminium (Aigbodion, V.S., 2007, and Yaro,
S.A., et al. 2006)  because of its unique combination of
good corrosion resistance, low density and excellent
mechanical properties. The unique thermal properties of
Aluminium composites such as metallic conductivity with
a coefficient of expansion that can be tailored down to
zero, add to their prospects in aerospace and avionics
(Sagail, A. and  Leisk, G., 1992).

Effect of Thermal Ageing Characteristics of Al-Si-Fe/Sic
Particulate Composite Synthesized by Double Stir Casting

V.S. Aigbodion* and S.B. Hassan

* Department of Metallurgical and Materials Engineering, Ahmadu Bello University, Samaru, Zaria, Nigeria

Received 3 June 2009; accepted 6 September 2009

Abstract :The  effect of thermal ageing  on the microstructure and properties  of 10wt% and 20wt%SiC partic-
ulate reinforced Al-Si-Fe matrix composite, produced by double stir casting route, have been studied. The com-
posite samples were solution heat-treated at 500oC for 3 hrs and aged at 100, 200, and 300oC with ageing time
between 60 and 660 minutes. The ageing characteristics of these grades of composite were evaluated using hard-
ness values, impact energy, tensile properties and microstructure. The tensile strength, yield strength, hardness
values increased as the percentage of silicon carbide increased in the alloy with decreased  impact energy in both
the as-cast and thermally age-hardened samples. The increases in hardness values and strength during thermal
ageing are attributed to the formation of coherent and uniform precipitation in the metal lattice. It was found
that both grades of composites showed acceleration in thermal ageing compared to the monolithic alloy.
However, the 20wt%SiC reinforced composite showed more acceleration compared to 10wt%SiC reinforced
composite.

Keywords: Al-Si-Fe/SiC, Thermal ageing, Composite, Mechanical properties, Microstructure and precipitation

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 ¿É°ùM.Ü .¢S , ¿ƒjOƒÑμjCG .¢S . ±

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IOÓ°üdG º«b IOÉjR ¿EG .ÉjQGôM áeOÉ≤àŸG êPÉªædG Ö∏°üJ h Ö°üdG øe πc ‘ ΩG~£°U’G ábÉW IOÉjõH áμ«Ñ°ùdG ‘ ¿ƒμ∏°ùdG ~«HQÉcG áÑ°ùf IOÉjõH OGOõJ IOÓ°ü ≈∏Y π°ü– ~°ûdG Iƒb

áfQÉ≤e …QGô◊G ΩOÉ≤àdG ‘ π«é©J âæ«H ~b ¬Øæ°üŸG äÉÑcôŸG øe πc ¿G ±É°ûàcG ” .¿~©ŸG áμÑ°T ‘ á∏°üàe h áª¶àæe äÉÑ°SôJ øjƒμJ ¤G iõ©J …QGô◊G ΩOÉ≤àdG AÉæKC’ Iƒ≤dG h

  ¿EÉa ∂dP ™eh .¬éàæŸG äÉμ«Ñ°ùdÉH20wt% Sic  :¤G áfQÉ≤dÉH ÌcCG π«é©J ÚÑj ÖcôŸG í∏°ùŸG  10wt% Sic .ÖcôŸG í∏°ùŸG

áá««MMÉÉààØØŸŸGG  ääGGOOôôØØŸŸGG   :Al-Si-Fe/Sic .Ö«°SôJ øjhôμj Ée Ö«côJ  ,á«μ«fÉμ«e ¢UGƒN ,Öcôe ,…QGôM ΩOÉ≤J ,


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The Journal of Engineering Research   Vol. 7, No. 1, (2010) 53-61

The age-hardening characteristics of an alloy are gen-
erally modified by the introduction of reinforcement.
These modifications are due to the manufacturing process,
the reactivity between the reinforcement and the matrix,
the size, the morphology and volume fraction of the rein-
forcement (Sagail, A., Leisk, G., 1992; Rajan, T.V. and
Sharma, C.P, 1988). 

In contrast to this extensive data available on the heat
treatment of Al-Si-Fe alloys with convectional alloying
elements (Yaro, S.A., et al. 2006). Relatively little is
demanded for their ageing hardening characteristics par-
ticularly in Silicon carbide reinforcement (Aigbodion,
V.S., 2007).  Hence, there is need for research to be car-
ried out in this very important area.  The aims of the pres-
ent research are to determine the microstructure and ther-
mal ageing characteristics of Al-Si-Fe/SiC particulate
composites with a view to obtaining the optimum thermal
age hardening procedure that would enable the achieve-
ment of the desired mechanical properties.

2.  Experimental Procedure 

2.1  Materials
The experimental materials used in this study includ-

ed: silicon carbide with an average particle size of 10µm,
ferrosilicon, high purity aluminium electrical wire
obtained from Northern Cable Company NOCACO
(Kaduna), moulding boxes, silica sand, and bentonite
obtained from National Metallurgical Development
Centre, Jos, Nigeria.

2.2  Equipment
The equipment used in this study included: pyrometer,

mechanical stirrer, a crucible, an electrical resistance fur-
nace, a Rockwell hardness tester, a Charpy impact
machine, a Tinus Olsen tensile machine and a
Metallurgical microscope with a built-in camera.

3.  Methods of Sample Production

The synthesis of the metal matrix composite that was
used in this research was achieved  using a double stir-
casting method at the Foundry Shop of the National
Metallurgical Development Center, Jos, Nigeria.  The
samples were produced by keeping the percentage of iron
and silicon constant, reinforced with Silicon carbide parti-
cles of 10wt% and 20wt%.  High-purity aluminium elec-
trical wires was charged in a graphite crucible kept in an
electric resistance furnace and 0.01%NaCl-KCl powder
were used as a cover for melting the alloy in order to min-
imize oxidation of aluminium by excluding oxygen and
creating a protective atmosphere inside the furnace. After
the melting of the pure aluminium, the temperature of the
furnace was raised to 720oC for the purpose of superheat-
ing the aluminium melt. The required quantity of 2.8% sil-
icon and 0.8%iron was added to the melt using ferrosili-
con, and the melt was thoroughly stirred (Aigbodion, V.S.,
2007;  Aigbodion,V.S. and Hassan, S.B., 2007).

With progressive melting, the furnace temperature was
raised to 780oC and the melt was held at this temperature
for 10 minutes. The melt was then skimmed to remove the
oxides and impurities. The molten metal was continuous-
ly stirred in order to ensure a near-uniform distribution of
alloying elements and prevent the elements from settling
at the bottom due to their higher density.  For each melt-
ing, 200g of charge materials was used to produce the
alloy.   The Silicon carbide particles were preheated to
1000oC, to make their surface oxidized (Aigbodion, V.S.
and Hassan, S.B., 2007). 

The alloy was then cooled down to a temperature just
below the liquidus point (580oC) to keep the slurry in a
semi-solid state. At this stage the preheated SiC particles
were added and mixed manually. Manual mixing was used
because it was very difficult to mix using automatic
device when the alloy was in a semi-solid state. After
manual mixing was done, the composite slurry was re-
heated to a temperature of 720oC and then automatic
mechanical mixing was carried out for about 20 minutes
at an average stirring speed of 150 rpm. In the final mix-
ing processes, the furnace temperature was controlled
between 730 and 740oC and the pouring temperature was
controlled to about 720oC (Aigbodion, V.S., 2007;
Aigbodio, V.S and Hassan, S.B., 2007).  A preheated sand
mould with diameter 18 mm and 300mm length was used
to produce cast bars.  After casting, the samples were
machined into tensile, impact and hardness test specimens
for the purpose of determining the mechanical properties. 

4.  Heat Treatment of the Samples

The test samples were solution heat-treated at temper-
ature of 500oC in an electrically heated furnace, soaked
for 3 hours at this temperature and then rapidly quenched
in warm water at 65oC.  Thermal ageing of the test sam-
ples was carried out at temperatures of 100, 200 and
300oC, for various ageing times of 60 to 660 minutes, and
then cooled in air. The thermal ageing characteristic of
these grades of composites was evaluated using hardness
values obtained from solution heat-treated samples of the
investigated composites subjected to the aforementioned
temperature conditions. The tensile and impact tests were
conducted at the peak ageing time of the various ageing
temperatures  (Aigbodion, V.S., 2007; Rajan, T.V. and
Sharma , C.P.,  1988).

5.  Determination of Hardness Values 

The hardness values of the samples were determined
according to the provisions in ASTM E18-79 using the
Rockwell hardness tester on "B" scale (Frank Well test
Rockwell Hardness Tester, model 38506) with a 1.56 mm
steel ball indenter, minor load of 10kg, major load of
100kg and hardness value of 101.2 HRB as the standard
block.  Before the test, the mating surfaces of the indenter,
plunger rod and test samples were thoroughly cleaned by
removing dirt, scratches and oil and  the testing machine


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The Journal of Engineering Research   Vol. 7, No. 1, (2010) 53-61

was calibrated using the standard block.  The samples
were placed on anvils, which acted as  support for the test
samples. A minor load of 10kg was applied to the sample
in a controlled manner without inducing impact or vibra-
tion and  the zero datum position was established. The
major load of 100 kg was then applied, and the reading
was taken when the large pointer came to rest or had
slowed appreciably and dwelled for up to 2 seconds. The
load was then removed by returning the crank handle to
the latched position and the hardness value read directly
from the semi automatic digital scale. Three indentations
were taken and the average represents the hardness values
(Aigbodion, V.S., 2007 and  Metal handbook., 1985).

6. Determination of the Tensile Properties

The tensile properties of the as-cast and peaking ther-
mal ageing samples were conducted on Tinus-Olsen ten-
sile testing machine with a strain rate of .002S-1.  The test
pieces were machined to the standard shape and dimen-
sions as specified by the American Society for Testing and
Materials (Annual Books of ASTM Standards, 1990). The
sample was locked securely in the grips of the upper and
lower crossbeams of the testing machine. A small load
was initially applied to seat the sample in the grips and
then the load was increased until failure occurred.

7.  Impact Strength Determination

The impact test of the as-cast and peaking thermal age-
ing samples was conducted using a fully instrumented
Avery Denison test machine. The mass of the hammer was
22 7 kg and the striking velocity was 3.5 m/sec. Charpy
impact tests were conducted on notched samples.
Standard square impact test sample measuring 75 x 10 x

10 mm with notch depth of 2 mm and a notch tip radius of
0. 02 mm at an angle of 45o was used (Annual Books of
ASTM Standards, 1990).

Before the test sample was mounted on the machine,
the pendulum was released to calibrate the machine.  The
test samples were then gripped horizontally in a vice and
the force required to break the bar was released from the
freely swinging pendulum. The value of the angle through
which the pendulum had swung before the test sample was
broken corresponded with the value of the energy
absorbed in breaking the sample and this was read from
the calibrated scale on the machine (Annual Books of
ASTM Standards, 1990).

8.  Microstructural Examination

Metallographic samples were cut from the produced
samples. The cut samples were then mounted in Bakelite,
and mechanically ground progressively on grades of SiC-
impregnated emery paper (80-600 grits) sizes using water
as the coolant. The ground samples were then polished
using one-micron size alumina polishing powder suspend-
ed in distilled water. Final polishing was done using 0.5
micron alumina polishing powder suspended in distilled
water. Following the polishing operation, etching of the
polished specimen was done using Keller's reagent. The
structure obtained was photographically recorded using an
optical microscope with built-in camera (Aigbodion, V.S.,
2007;  Aigbodion, V.S. and  Hassan. S.B., 2007).

9.  Results and Discussion

9.1   Results
The various microstructures developed for the two

grades of composites in the as-cast and thermally age-

wt%  SiC  As-cast Peak aged at 
100OC 

Peak aged at 
200OC 

Peak aged at 
300OC 

0 31.1 60.1 61.5 62.0 
10 57.2 75.0 74.5 84.0 
20 67.0 86.0 87.0 89.0 

Table 1.  Hardness (HRB) values for as-cast and thermal age-hardened with 10wt% and 20wt% of sili-
con carbide

Wt% SiC As-cast (N/mm2) Peak aged at 
100OC (N/mm2) 

Peak aged at 
200OC (N/mm2) 

Peak aged at 
300OC (N/mm2) 

0 45.60 59.90 56.40 52.40 
10 68.46 73.35 75.00 73.00 
20 79.98 80.75 82.50 80.34 

Table 2.  Yield strength of Al-Si/SiC composites with 10wt% and 20wt% of silicon carbide

Wt %  SiC  As-cast (N/mm2)   Peak aged at 100OC 
(N/mm2)   

Peak aged at 
200OC (N/mm2)   

Peak aged at 
300OC  (N/mm2)   

0 58.69 62.50 67.18 64.20 
10 96.06          98.50 98.50 100.20 
20 106.12 120.43 125.00 121.85 

Table 3.  Tensile strength of Al-Si-Fe/SiC composites with 10wt% and 20wt% of silicon carbide


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hardened condition are shown in Micrographs 1-12.  The
thermal ageing response measured by the variation of
hardness with time for two grades of composites is shown
in Figs. 1-3.  Table 1shows the hardness values of both the
thermally as-cast and age-hardened  Al-Si-Fe/SiC com-
posites.  The results of yield strength and ultimate tensile
strength with weight fraction of  Silicon  carbide at vari-
ous ageing temperatures are shown in Tables 2-3.  The
results of impact energy with weight fraction of Silicon
carbide (SiC) at various ageing temperatures are shown in
Table 4.

10.  Discussions

10.1  Thermal  Ageing Characteristics of Al-Si-Fe/
SiC Composites

From Figs. 1-3, it can be seen that there is a steep rise
in the hardness values of each grade of the composite at

initial stages for all ageing temperatures and then a fall
after reaching the various peak ageing times are reached,
corresponding to over-ageing.  However, at higher ageing
temperature the materials developed peak hardness at
shorter ageing time, because the rate of precipitation of
the second phase materials is faster and hence increases in
hardness values. The time to obtain peak hardness is
shorter according to the sequence: 100OC > 200OC >
300OC (See Figs. 1-3). 

The thermal age-hardening behavior of the Al-Si-
Fe/SiC particulate composites are similar to Al-Si-Mg/SiC
particulates as reported by Cottu et al. (1992) ie. hardness
continuously increases to a maximum during thermal age-
ing and then decreases later due to over ageing.  It is inter-
esting to note that in the reinforced aluminium alloy
metal-matrix, as the volume fraction of SiC increase to
20wt%  in the aluminium alloy there is a monotonic
reduction in the time required to reach peak hardness (See
Fig. 3). 

The 20wt%SiC addition, yielded the highest hardness
value.  As far as hardening behavior of the composites is
concerned, particle addition in the matrix alloy increases
the strain energy in the periphery of the particles in the
matrix and these tendencies may be due to the formation
of the dislocation at the boundary of the ceramic particles
by the difference in the thermo-expansion coefficient
between the matrix and ceramic particles during solution
treatment and quenching since a lot of dislocations gener-
ate in the main matrix/particle interface (Bedir, F., 2006).
Thus, dislocations cause the hardness increase in compos-
ite as well as residual stress increase because it acts as
non-uniform nucleation sites in the interface following the
age treatment.  It is thought that the higher the amount of
the ceramic particles in the matrix, the higher the density
of the dislocation, and as a result, the higher the hardness
of the composite.

10.2  Microstructural Analysis
Microstructures of the as-cast and heat-treated compos-

ites at various ageing temperatures and peaking ageing
time were examined by the use of a metallurgical micro-
scope. They were observed to contain primarily  -Al, sil-
icon eutectic and SiC particle as shown in Micrographs 1-
12. In the microstructure of the composites Si phase was
seen apparently in the eutectic regions, and intermetallic
compounds such as FeSiAl3, iron-containing phases due
to the secondary alloying elements (Aigbodion, V.S.,
2007; Rajan, T.V. and  Sharma, C.P, 1988).

The microstructure of the as-cast unreinforced Al-Si-
Fe alloy is shown in Micrograph 1, while Micrographs 2-
3 show the microstructure of the as-cast reinforced alloys
with SiC particles. 

The microstructure reveals that there are small discon-
tinuities and a reasonably uniform distribution of SiC par-
ticles. The ceramic phase is shown as dark phase, while
the metal phase is white. These structures are in agree-
ment with the co-continuous interlaced phases studied by
other researchers (Rohatgi, P.K., et al. 1988 and
Whitehouse, A.F., 1990). Micrographs 4-12, show the

0

2 0

4 0

6 0

8 0

1 0 0

0 2 0 0 4 0 0 6 0 0

A g e in g  

T im e ( M in u t e s )

H
a

r
d

n
e

s
s

 v
a

lu
e

s
(
H

0 w t% S i C

1 0 w t% S i C

2 0 w t% S i C

Ageing Time (Minutes)

H
ar

dn
es

s 
V

al
ue

s 
(H

R
B

)

Figure 1.  Variation  of  hardness   values  with ageing 
time at aageing temperature of 100oC

Ageing Time (Minutes)

H
ar

dn
es

s 
V

al
ue

s 
(H

R
B

)

Figure 2.  Variation  of  hardness  values  with  ageing
time at ageing temperature of 200oC

Ageing Time (Minutes)

H
ar

dn
es

s 
V

al
ue

s 
(H

R
B

)

Figure 3.  Variation  of  hardness  values  with  ageing 
time at ageing temperature of 300oC

0         200     400     600

100
80
60
40
20

0

0wt% SiC
10wt% SiC
20wt% SiC

0        200     400     600

100
80
60
40
20

0

0wt% SiC
10wt% SiC
20wt% SiC

0         200   400    600

100
80
60
40
20

0

0wt% SiC
10wt% SiC
20wt% SiC


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The Journal of Engineering Research   Vol. 7, No. 1, (2010) 53-61

microstructure of the thermally age-hardened Al-Si-
Fe/SiC composites. The microstructure reveals the disso-
lution and distribution of the SiC particles in the metal
matrix and the presence of precipitates at the particles
matrix interfaces with precipitation and dissolution of the
SiC particles and silicon eutectic phase (Aigbodio, V.S.,
2007; Aigbodion, V.S. and Hassan, S.B., 2007).

The formation and presence of precipitates at the par-
ticles- matrix interfaces may be appreciated by comparing
micrographs of the composite in the as-cast state micro-
graphs 1-3 and in the peak age-hardened state micro-
graphs 4-12. The micrographs in the peak age-hardened
state reveal precipitates covering the surface at the parti-
cles-matrix interfaces. Cottu  et al. (1992) reported a sim-
ilar behavior of increased precipitation at interfaces for
aluminum alloy 6061 reinforced with whiskers of silicon
carbide. 

10.3  Hardness Value
From Table 1, the hardness values for thermally as-cast

and age-hardened composite increases as the percentage
of Silicon carbide increases from 10wt% to 20wt% in the
alloy. This is due to an increase in the percentage of the
hard and brittle phase of the ceramics body in the alloy.

The hardness values of the thermally age-hardened
alloy are almost equal at various ageing temperatures with
percentage SiC additions (See Table 1), in line with the
earlier observation of  (Cottu et al. 1992 and Ikechukwuka
1997).

10.4  Yield and Tensile Strength
From Tables 2-3, the yield strength and ultimate tensile

strength of both the as-cast and age-hardened composites
increased with the increased percentage silicon carbide to
20 wt% SiC.  The as-cast samples have a value of 79.98
and 106.12N/mm2 for yield and tensile strength at 20%
SiC addition.   

For the thermally age-hardened samples, similar trends
were also observed as for the case of the as-cast samples,
in that the yield strength and ultimate tensile strength
increased to 20% wt of SiC. The ultimate tensile strengths
of the thermally age-hardened samples at 20 wt% SiC are
120.43, 125.00 and 121.85N/mm2 at peak ageing of 100,
200 and 300oC respectively. (See Table 3).  Also the yield
strengths of age-hardened samples at 20 wt% SiC addition
are 80.75, 82.50 and 80.34N/mm2 at peak ageing of 100,
200 and 300oC respectively (See Table 2). 

The higher values of both ultimate tensile strength and
yield strength obtained at 20 wt% SiC are attributed to the
uniform distribution of the SiC particles in the microstruc-
ture of the 20 wt% SiC (See Micrographs 3, 10-12).  It can

be seen that the inter-particle distance is smaller. The con-
tribution of inter-particle distance to strain hardening aris-
es from the fact that the space permitted a dislocation to
maneuver round obstacles limits the yield stress given by
the formula (Dieter, G.E., 1988): 

The smaller the values of  the greater the yield stress
as a result of strain hardening.  It therefore supports the
fact that (Micrographs 3,10-12) with smaller .

A substantial increase in both the yield strength and
ultimate tensile strength was obtained when compared
with the results of as-cast samples. For example the yield
strength of Al-Si-Fe/10SiC particles increased from 68.46
to 75.00N/mm2, while the ultimate tensile strength
increased from 96.06 to 98.50N/mm2 in the as-cast and
peak age-hardened at 200oC respectively.  The yield and
tensile strength of Al-Si-Fe/20SiC particles also increased
from 79.98 to 82.50 N/mm2 and 106.12 to 125.00 N/mm2
in the as-cast and thermally age-hardened at 200oC tem-
perature (See Tables 2-3). 

These results show that the Al-Si-Fe/10SiC particles
samples has 9.55% and 2.54% increases in yield strength
and ultimate tensile strength respectively over those of the
as-cast samples at peak ageing at 200oC, while for the Al-
Si-Fe/20SiC particles the respective increments were
3.15% and 17.79% for yield strength and ultimate tensile
strength. The increase in strength of the thermally age-
hardened samples over those of the as-cast are attributed
to the uniform distribution of SiC in the aged samples than
the as-cast samples respectively (See Micrographs 1 and 3
and Micrographs 4-12). 

Sagail and Leisk (1992) and Whitehouse et al. (1991)
attributed this to an increase in dislocation density at the
interfaces. An increase in dislocation density strain hard-
ens the metal-matrix locally and provides heterogeneous
nucleation sites for precipitation, thereby accelerating the
ageing response.  The modulated structures formed during
ageing in these grades of composites enhanced these prop-
erties and this is in agreement with the earlier works on
Al-Si-Mg/SiC (Cottu, J.P. et al. 1992  and Ikechukwuka.
N.A, 1997). The addition of SiC particles affects not only
the precipitation kinetics but also the relative amounts of
the various phases present in the microstructure. Besides
during quenching from the solution heat treatment tem-
perature, the SiC particles cool more slowly than the
matrix (since the particles have a lower thermal conduc-
tivity). This causes the matrix around the particles to be

Wt%   SiC As-cast Peak aged at 
100OC 

Peak aged at 
200OC 

Peak aged at 
300OC 

0 17.0J 28.0J 24.0J 22.0J 
10 14.5J 20.0J 19.0J 19.0J 
20 12.0J 17.0J 15.5J 16.0J 

Table 4.  Impact energy for as-cast and age-hardened with 10wt# and 20wt# of silicon carbide

    ô =
Gb


. ô  = Yield  stress, ë  = Inter -particle distance,  

G =  Shear energy of dislocation and b  = Burger vector.  


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The Journal of Engineering Research   Vol. 7, No. 1, (2010) 53-61

Micrograph 1.  Microstructure of the Al-Si-Fe  alloy,
showing silicon eutectic (black) conta-
ining FeAl3Si phases and Al (white)
(x200).  The structure reveals the eute-
ctic silicon  containing  FeSiAl3 phase 
in aluminium matrix.

Micrograph 2.  Microstructure  of  the  Al-Si-Fe  alloy
with  10 wt%  of SiC the the structure 
reveals  the  dissolution of  the eutectic 
silicon phase and uniform distribution 
of SiC  (black)  in Al matrix (white)
(x200).

Micrograph 3.  Microstructure of Al-Si  alloy reinfor-
ced with 20 wt% of SiC.  The structu-
re reveals  and dissolution of the eute-
ctic silicon  phase and uniform distri-
bution of  SiC  (black) in -Al matrix 
(white) (x200).

Micrograph 4.  Microstructure of  the  Al-Si-Fe  alloy
after peak aged at 100oC (x200).  The
structurre reveals dissolution and pre-
cipitation  of   the    silicon     eutectic 
(black) and the FeAl3Si phases in  
Al matrix (white).


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The Journal of Engineering Research   Vol. 7, No. 1, (2010) 53-61

Micrograph 5.  Microstructure  of  the  Al-Si-Fe alloy
after peak aged at 200oC (x200).  The
structure reveals  uniform dissolution
and precipitation of the silicon  eutec-
tic  (black) and the  FeAl3Sui  phases 
in  -al matrix (white).

Micrograph 6.  Microstructure   of  the   unreinforced 
alloy after peak aged at 300oC (x200).
The structure reveals dissolution and
precipitation  of  the  silicon eutectic
(black)  and the FeAl3Si phases with
some  segregation  of silicon eutectic
phases in -Al matrix (white).

Micrograph 7.  Microstructure of the reinforced alloy
(10 wt%  of SiC)  after peak  aged at
100oC (x200).  The  structure  reveals 
the dissolution of  the  eutectic silicon
phase  and  uniform   distribution  of
SiC (black) in  -Al matrix (white).

Micrograph 8.  Microstructure of the reinforced alloy
(10 wt%  after peak  aged  at  200oC 
(x200).   The   structure    reveals  the 
dissolution  of   the   eutectic    silicon 
phase and distribution of SiC (black)
in    -Al matrix (white).


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The Journal of Engineering Research   Vol. 7, No. 1, (2010) 53-61

Micrograph 9.  Microstructure of the reinforced alloy
(10 wt%  of   SiC  after peak  aged at
300oC  (x200).  The  structure  reveals
the  dissolution  of  the eutectic silicon
phase  and  uniform  distribution   of 
SiC (black)  with  precipitation of the
SIC particles.

Micrograph 10.  Microstructure   of   the   reinforced   
alloy  (20 wt%  of  SiC)  after peak 
aged at 100oC (x200).  The structure
reveals the dissolution of the eutectic
silicon  phase  and uniform distribu-
tion  of  SiC  (black)  with precipita-
tion covering.

Micrograph 11.  Microstructure  of   the    reinforced
alloy  (20 wt%  of  SiC)  after peak 
aged at 200oC (x200).  The structure
reveals the dissolution of the eutectic
silicon phase and well uniformly dis-
tribution of SiC (black) with precipi-
tation covering the aluminium phase
(white).

Micrograph 12.  Microstructure   of   the    reinforced 
alloy  (20 wt%  of   SiC)  after peak 
aged at 300oC (x200).  The structure
reveals the dissolution of the eutectic
silicon  phase  and  uniform distribu-
tion of SiC (black) with precipitation
covering.


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The Journal of Engineering Research   Vol. 7, No. 1, (2010) 53-61

warmer than the bulk matrix. The high dislocation densi-
ty and the high solubility centers (the warm particles-
matrix interfaces) in the composite are favorable condi-
tions for precipitation formation. This mechanism is a
possible explanation for the higher volume fraction of pre-
cipitates obtained in the composite of the age hardening
condition (Aigbodion, V.S., 2007;  Aigbodion, V.S. and
Hassan, S.B., 2007).

10.5  Impact Energy
From the Table 4, the impact energy of both the as-cast

and age-hardened samples, decreased as the percent SiC
addition increases in the alloy. The brittle nature of the
reinforcing materials (SiC) plays a significant role in
degrading the impact energy of the composite, since the
unreinforced alloy and the alloy with 10wt% SiC particles
have the highest impact energy, indicating that they are the
toughest of them all (Aigbodion, V.S., 2007).

11. Conclusions

From the results of the investigations, the following
conclusions have been made:

1)  The uniform distribution of the SiC particles in the
microstructure of both the as-cast and thermally age-
hardened Al-Si-Fe/SiC composites is the major factor
responsible for the improvement in the mechanical
properties.

2)  The addition of SiC particles affects not only the pre-
cipitation kinetics but also the relative amounts of the
various phases present in the microstructure, and that
during quenching from the solution heat treatment
temperature, the SiC particles cool more slowly than
the matrix (since the particles have a lower thermal
conductivity). This causes the matrix around the par-
ticles to be warmer than the bulk matrix. The high dis-
location density and the high solubility centers (the
warm particles-matrix interfaces) in the composite are
favorable conditions for precipitation formation. This
mechanism is a possible explanation for the higher
volume fraction of precipitates obtained in the com-
posite of the age-hardening condition.

3)  This research therefore, has established that these
grade of composites respond to precipitation-harden-
ing heat treatment.

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