International Journal of Engineering Materials and Manufacture (2016) 1(1) 21-26 

https://doi.org/10.26776/ijemm.01.01.2016.05 

 

A. A. Adebisi
1
 , M. A. Maleque

1
 and M. B. Ndaliman

2,3
 

1
Department of Manufacturing and Materials Engineering, International Islamic University Malaysia. 

2
Scientific Equipment Development Institute (SEDI), Minna, Niger State Nigeria. 

3
Department of Mechanical Engineering, Federal University of Technology Minna, Niger State Nigeria. 

 E-mail: debisi1@yahoo.com 
 

Reference: Adebisi, A. A., Maleque, M. A. and Ndaliman, M. B. (2016). Influence of Stirring Speed on Microstructure and Wear 

Morphology of SiCp-6061Al Composite. International Journal of Engineering Materials and Manufacture, 1(1), 21-26. 

Influence of Stirring Speed on Microstructure and Wear Morphology of 

SiCp-6061Al Composite  

 

 

Adetayo Abdulmumin Adebisi, Md Abdul Maleque, and Mohammed Baba Ndaliman  

 

 

Received: 15 September 2016 

Accepted: 26 September 2016 

Published: 01 October 2016 

Publisher: Deer Hill Publications 

© 2016 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

The aim of this study is to investigate the influence of stirring speed on stir casting synthesis of 15 wt% silicon carbide 

particle reinforced aluminium alloy (SiCp-6061 Al) composite. The composite samples were produced at different 

stirring speed of 300, 500 and 700 rpm. However, the processing temperature and time are maintained at 800 °C 

and 180 secs processing condition. Dry reciprocating wear test is conducted using a ball on disc wear tester at a 

constant operating condition of 50N load, 10Hz frequency for 30 mins on the samples. The influence of stirring 

speed on the microstructure and wear morphology is examined using scanning electron microscope (SEM). The result 

reveals that the stirring speed influenced the processing condition including the microstructure and wear topography. 

Composite processed at 500 rpm attained homogeneity of the SiCp phase as observed from the microstructure. The 

worn surface experiences a relatively smooth mild wear without formation of cracks, porosity and craters. However, 

at 300 rpm the composite experiences micro cracks with formation of abrasive grooves due to insufficient distribution 

of the SiCp phase. Moreover, at 700 rpm high speed vortex formation is observed due to vigorous stirring which 

entraps gases and develops into large porosity, cracks and deep craters. This study establishes that stirring speed has 

a significant effect on the processing condition as well as the wear morphology of SiCp-Al6061 composite developed 

using stir casting technique. 

 

Keywords: Stir casting, Stirring speed, Wear morphology, SiCp-6061Al composite, Microstructure 

 

 

1 INTRODUCTION 

Silicon carbide particles reinforced aluminium alloy (SiCp-6061Al) composite is the most commonly used metal matrix 

composite due to its strength and stiffness, improved wear resistance and cost effective process technique [1]. These 

features makes them to emerge as an important category of materials that have potentials for structural applications 

in the automotive and aerospace industry. The processing of this attractive material plays a major role in determining 

the performance properties under operational condition [2, 3]. Among the variety of processing technique, the stir 

casting is generally accepted and commercially viable in developing the aluminium silicon carbide composite [4]. 

Moreover, the properties of SiCp-6061Al composites produced by stir casting depend on process parameters such as 

stirring speed. For instance, the homogenous distribution of reinforcement particulate is mostly dependent on the 

stirring speed of the composite melt. Uniform distribution is desired in order to maximize the composite properties. 

In achieving these properties, the stirring speed is of utmost concern.  

Several casting defects are obviously related to the extent and method in which the stirring occurred. Studies [2, 

4] have shown that porosity formation is attributed to gas entrapment during vigorous stirring leading to air bubbles 

in the slurry either independently or as air envelopes the reinforced particles. Very high stirring speed forms a vortex 

on the composite melt surface. The vortex mechanism is necessary in enveloping the particles into the matrix melt as 

the pressure difference between the inner and the outer surface of the melt sucks the particles into the melt [5]. 

However, vortex formation also traps inclusions which in turn develop into porosity formation. Therefore, the vortex 

process system needs to be properly controlled with the appropriate stirring speed.  

Naher et al., [6] studied the effect of different stirring speed on homogenous distribution of particle in fluids by 

simulation analysis. Experiments were examined on fluids with the same properties of liquid and semisolid aluminium 

condition. The use of fluid with viscosity similar to reinforced SiCp aluminium composite was used in the simulation 

of the mixtures with various stirring speed. It is concluded from the study that stirring speed has a significant effect 



Influence of Stirring Speed on Microstructure and Wear Morphology of SiCp-6061Al Composite 

22 

on particle distribution. Moreover, Prabu et al., [7] also investigated the effects of stirring speed on uniform 

distribution of SiCp in Al alloy matrix. This investigation considered the effect on the hardness value and 

microstructure. It was revealed that at higher stirring speed the porosity is observed to be more pronounced in the 

microstructure due to the vigorous stirring which enables oxide skins, gases and contaminations entrapped in the 

melt. Also, the hardness test indicates regions of both high and low value at lower stirring speed due to particle 

accumulation in some places and the non-inclusion of SiCp in other places. Similarly, higher stirring speed shows a 

non-uniform hardness value. This non uniformity is generated due to porosity, oxide skins, and formation of gases. 

Therefore, an optimum stirring speed is required in order to achieve uniform distribution in the matrix to attain 

uniform hardness.  

Based on the studies highlighted, the stirring speed is recognised as an important process parameter for processing 

aluminium composite. Though, there is no information available in the literature on the effect of this parameter on 

wear performance. Therefore, this study aims to investigate the influence of stirring speed on wear morphology of 

SiCp-Al composite using the stir casting process. 

 

2 METHODOLOGY 

2.1 Material Preparation 

AA6061 aluminium alloy is used as the matrix material and silicon carbide particles (SiCp) as the reinforcement phase 

material with an average size of 40 μm. Table 1 shows the properties of the matrix and reinforcement materials.  

 

 

Table 1. Properties of matrix (AA6061) and reinforcing (SiCp) phase. 

 

Property  Unit  Al (6061) SiCp 

Density g/cm
3
 2.7 3.22 

Melting point °C 660 2973 

Coefficient of thermal expansion µm/m°C 23.4 4 

Thermal conductivity W/mK 166 126 

Young’s modulus GPa 70 410 

 

 

2.2 Composite Processing Procedure 

The composite was developed using an electric resistance induction stir casting set up incorporated with a preheating 

furnace, vacuum chamber, stainless steel stirrer and attached die cavity. The melting furnace for Al alloy matrix has a 

heating capacity of 1000 °C while the reinforcement (SiCp) heating can be heated to 1200 °C. The temperature value 

is determined with a K- type thermocouple for sensing the temperature during the melting process until the desired 

temperature is attained on the indicator. The SiCp powder is preheated to 1100 °C for 2 hrs in order to initiate surface 

oxidation before incorporating into the aluminium melt [8].  

After melting of the aluminium alloy, dross formation is extracted from the melt surface with a coated skimmer 

which has been preheated. Moreover, before the addition of SiCp, 1 wt% magnesium was incorporated in the 

aluminium melt to improve the wettability between the matrix and reinforcement phase. Subsequently, the injection 

of SiCp was slowly added to the aluminium melt within an average of one (1) min as the stirrer (stainless steel) is 

gradually lowered into the furnace in order to perform stirring and pouring. The die steel is heated to 500 °C for 1 

hr and then positioned in a vacuum chamber of 350mmHg before pouring take place. Throughout this process, the 

composite melt is monitored to be in a molten state. 

 

2.3 Wear Testing 

Dry reciprocating wear test is conducted using a ball on disc high frequency reciprocating rig (HFRR) tester (as shown 

in Figure 1) according to ASTM D 6079-97/EN 590. The wear test is conducted at a constant operating condition of 

50 N load, 10 Hz frequency for 30 mins. Each of the composite produced at different stirring speed was tested against 

a 52100 chrome steel material with Ø6mm and 60-67 HRC hardness value. All the cast sample were cleaned with 

acetone prior and after testing and weighed using a micro scale weighing balance with an accuracy of 0.0001g. The 

wear rate is determined using the weight loss method as described in equation (1): 

 

r
m

w
t




 

 

Δm = mass loss, ρ = density, t = time 

(1) 



Adebisi et al., (2016): International Journal of Engineering Materials and Manufacture, 1(1), 21-26 

23 

 

 

Figure 1: Schematic view of wear testing machine. 

 

 

3 RESULTS AND DISCUSSION 

3.1 Microstructure 

Figure 2(a) shows the scanning electron microscope (SEM) of Al6061 alloy and the presence of magnesium and silicon 

in the Al alloy is confirmed from the energy dispersive x-ray spectroscopy (EDS) analysis as shown in Figure 2(b). The 

morphology of the SiCp powder is shown in Figure 3(a) with the EDS analysis in Figure 3(b). The average size of the 

SiCp is 40 μm.  
 

 

 

 

Figure 2: (a) Scanning electron micrograph (b) energy dispersive x-ray spectroscopy of 6061Al alloy. 

 

 

 

 

Figure 3: (a) Scanning electron micrograph (b) energy dispersive x-ray spectroscopy of SiCp. 

a 

a 

b 

b 



Influence of Stirring Speed on Microstructure and Wear Morphology of SiCp-6061Al Composite 

24 

3.2 Effect of Stirring Speed on the Microstructure of SiCp-Al Composite 

Homogenous distribution of the SiCp is desirable in order to optimize the properties of SiCp-Al composite. To achieve 

this, the processing condition of the stir casting technique is of utmost importance. Therefore, it is essential to examine 

the influence of stirring speed, a crucial parameter in stir casting, on the distribution of SiCp in Al alloy matrix. Samples 

from the cast composite processed at 300, 500 and 700 rpm were analysed through microstructure analysis. From 

the microstructural characterization it is observed that stirring speed significantly influenced the distribution of SiCp 

which is evident in Figure 4b.  

At 300 rpm, it is observed from the micrograph that regions of clustering and micro porosity is detected. 

Moreover, the distribution of SiCp is not uniformly dispersed as viewed in Figure 4(a). This indicates that 300 rpm is 

insufficient to achieve homogenous distribution of SiCp in the Al alloy matrix. With higher stirring speed of 500 rpm, 

an improved distribution of the SiCp is achieved as shown in Figure 4(b) indicating the SiCp is uniformly dispersed in 

the matrix alloy. Moreover, vortex formation is found to be minimized at 500 rpm stirring speed thereby stabilizing 

centrifugation which may lead to minimal stirring efficiency and potentially severe air entrainment at higher stirring 

condition. 

At higher stirring speed of 700 rpm, the porosity in the microstructure is more pronounced as observed from 

the micrograph in Figure 4(c). This condition is attributed to the vigorous vortex formation due to high stirring speed 

which enables oxide skins, gases and contaminants to be entrained in the melt. Furthermore, the distribution of the 

SiCp is not effective enough due to the formation of undesirable conditions such as large porosity and gas entrapment. 

 

3.3 Effect of Stirring Speed on Wear Morphology of SiCp-Al Composite 

Dry reciprocating wear test is conducted on the SiCp-Al composite processed at different stirring speed of 300, 500 

and 700 rpm. The surface wear morphology of these composites were evaluated based on the wear test condition 

of 50N load, 10 Hz frequency for 30 mins. Figure 5 shows the wear morphology of SiCp-Al composites considering 

the influence of stirring speed condition. Figure 5(a) examines the composite processed at 300 rpm. It is observed 

that the surface topography is characterized by both abrasive and adhesive wear mechanism as indicated with regions 

of groove formation and regions of particle clustering compaction respectively. Moreover, due to the insufficient 

distribution of the reinforced SiCp, the surface is characterised with micro cracks and regions of densely packed SiCp. 

As such abrasive grooves are observed in areas where the SiCp is absent which eventually formed abrasive grooves as 

shown in 5(a). 

 

 

 

  

 

  

 

Figure 4: Microstructure of 15 wt% SiCp Al composite processed at (a) 300 rpm (b) 500 rpm and (c) 700 rpm. The 

formation of composites, porosity, and micro cracks are indicated. 

 

Clustered SiCp 

Porosity 
Micro cracks 

SiCp 

SiCp 

SiCp 

SiCp 

Clustered SiCp 

Porosity 

Cracks 

a b 

c 



Adebisi et al., (2016): International Journal of Engineering Materials and Manufacture, 1(1), 21-26 

25 

   
 

 

 

Figure 5: Wear morphology of 15 wt% SiCp Al composite processed at (a) 300 rpm (b) 500 rpm and (c) 700 rpm. 

The formation of craters, cracks, and abrasive grooves are indicated. 

 

 

However, composite processed at 500 rpm shows that the topography of the worn surface is characterised with a 

relatively smooth mild wear without formation of cracks and porosity as shown in Figure 5(b). This is attributed to 

the uniform distribution of the SiCp attained with 500 rpm stirring speed and also the sufficient wettability between 

the reinforcement and Al alloy. This provides adequate rubbing and stable contact between the composite and the 

counter surface during the wear test. The stable interaction results to the formation of oxide layer on the wear surface 

which is viewed as the whitish scale profile on the SEM micrograph. This layer serves as a protective surface which 

improves the abrasion and adhesion resistance of the composite.  

Figure 5(c) describes the wear topography of composite processed at 700 rpm, the surface is characterized with 

numerous deep craters with crack formation due to the vigorous stirring speed used in the processing. This condition 

is ascribed to the high speed vortex formation which entraps inclusions such as gases which in turn develops into 

large porosity formation. 

 

 

6 CONCLUSIONS 

The influence of stirring speed on the microstructural and wear morphology of 15 wt% SiCp-Al composite was 

studied. It was found that the stirring speed has significant influence on the properties of composite. The following 

conclusions were drawn from the experimental results: 

 

1. The SiCp-Al composite was successfully processed and developed using the stir casting technique by varying 

the stirring speed.  

2. The composite achieved uniform particle distribution with 500 rpm stirring speed which in turn translates to 

improved microstructural and wear properties.  

3. From the microstructural analysis, it is found that at 300 rpm stirring speed, the composite experiences micro 

cracks with formation of abrasive grooves due to insufficient distribution of the SiCp phase. Moreover, at 700 

rpm high speed vortex formation is observed due to vigorous stirring which entraps gases and develops into 

large porosity, cracks and deep craters. 

4. The wear morphology of the composite processed at 500 rpm shows that the topography of the worn surface 

is characterised with a relatively smooth mild wear without formation of cracks and porosity. This feature is 

attributed to the uniform distribution of the SiCp in the matrix and also the sufficient wettability achieved 

between the reinforcement and Al alloy. 

S
l
i
d
i
n
g
 
d
i
r
e
c
t
i
o

n
 

Abrasive 

grooves 

Densely 

packed SiCp 

Crack 

formation 

Crack 

formation 

Deep 

craters 

a b 

c 



Influence of Stirring Speed on Microstructure and Wear Morphology of SiCp-6061Al Composite 

26 

5. The surface topography of the composite processed at 300 and 700 rpm is characterized with the formation 

of abrasive grooves, micro cracks and development of large porosity (deep craters) with cracks respectively. 

6. Achieving optimum stirring speed of 500 rpm during the processing of SiCp-Al composite improves and also 

maximise the microstructural and wear properties.  

 

 

ACKNOWLEDGEMENT 

The authors acknowledge the support of the Ministry of Education and International Islamic University Malaysia 

(IIUM) for the financial support to conduct this research under research project PRGS12-002-0002. The authors also 

appreciates the Foundry Workshop and Metallographic Laboratory at IIUM where the experimental studies were 

conducted. 

 

 

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