International Journal of Engineering Materials and Manufacture (2018) 3(1) 63-67 
https://doi.org/10.26776/ijemm.03.01.2018.08 

 
Umma Abdullahi1, Md Abdul Maleque2  and Mohammad Yeakub Ali2 
1Center for Energy Research and Training 
Ahmadu Bello University, Zaria 
Kaduna State, 810261 Nigeria 
E-mail: ummaabdullahi@abu.edu.ng 
 

2Department of Manufacturing and Materials Engineering,  
International Islamic University Malaysia 
PO Box 10, 50728 Kuala Lumpur, Malaysia 
E-mail: maleque@iium.edu.my 
 
Reference: Umma, A., Maleque, M. A. and Ali, M. Y. (2018). Characterization of Carbon Nanotube Reinforced Aluminium Nano-
composite Using Field Emission Scanning Electron Microscope. International Journal of Engineering Materials and Manufacture, 
3(1), 63-67. 

 
 

Characterization of Carbon Nanotube Reinforced Aluminium Nano-
composite using Field Emission Scanning Electron Microscope 
 
 
Umma Abdullahi, Md Abdul Maleque and Mohammad Yeakub Ali 
 

 

Received: 21 March 2018 
Accepted: 27 March 2018 
Published: 30 March 2018 
Publisher: Deer Hill Publications 
Creative Commons: CC BY 4.0 

 
 
ABSTRACT 
Carbon nanotubes (CNT) is a promising fibrous materials for development of nanocomposite especially aluminium 
(Al) matrix nanocomposites as CNT exhibited extraordinary mechanical properties and high aspect ratios. The 
dispersion is the main factor for a quality CNT-Al nanocomposite that affects the uniformity in mixture leading to 
the enhanced mechanical and wear behaviour. The present study emphasizes on the characterization of carbon 
nanotube dispersion by means of field emission scanning electron microscope after synthetization of new 
nanocomposite. The mixing of the reinforcement and matrix powders was performed in ball mill for 2 hours at 250 
rpm. The result shows the homogeneous distribution of CNT in Al-matrix. The morphological characterization under 
FESEM provides insight features of CNT-Al nano-composite with the ball milling parameter on the sintering. 
 
Keywords: Carbon nanotube; Aluminium powder; Dispersion; Characterisation; FESEM 
 
 
1 INTRODUCTION 
Aluminium (Al) matrix composite can be used for many applications including aviation, aircraft and automotive 
industries due to the lower density as many components require weight reduction for less fuel consumption which in 
turn can save the environment. Advancement of the research in the carbon nanotube was embarked after finding of 
carbon nanotubes (CNTs) by rolling a graphene sheets [1]. A multiwalled carbon nanotube (MWCNT) is consisting 
of multiple rolled layers or concentric tubes of carbon or graphite material. Past research revealed that MWCNTs 
have extraordinary properties compared to carbon fibres, such as rigidity is approximately 1000 GPa and thermal 
conductivity of up to 6000 W mK [2]. Different processing routes are available for development of Carbon nanotube 
reinforced metal matrix composites (CNT-MMC). Powder metallurgy (PM) is cost-effective, robust and energy saving 
process. Hot deformation behavior of a 2.0 wt% CNT/2024Al nanocomposite was studied via high-temperature 
compression over a temperature and strain rate range of 200–400 °C and 0.001–0.1 s−1, respectively [3]. They found 
that microstructural examinations at a high strain rate, within the upper and lower temperature limits, revealed the 
occurrence of second-phase particle shearing, refinement, re-precipitation, and re-orientation. Mahmood et al. [4] 
have studied the time-dependent formulation of slightly weakened interface (SWI) model for an embedded carbon 
nanotube (CNT) in a polymer matrix with the aim to predict viscoelastic properties of CNT/polymer nanocomposites. 
In generally, the viscoelastic properties of CNT/polymer are lower than CNT-metal nanocomposites. 
Ball milling is a technique to mix up the reinforcement and matrix materials before it goes through powder metallurgy 
process for nanocomposite development. In order to achieve targeted properties of nanocomposite, different 
combination of materials is formulated [5], [6], [7]. Thermal conductivity, mechanical and tribological property 
enhance significantly with different graphite shape. It is very important to successfully dispersed CNTs with the matrix 
material to attain desirable properties [6], [7]. Previous works done on the ball milling of CNT and aluminium 



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64 

mixtures with different speed and time for dispersion and homogenization of the CNT and aluminium. The effect of 
process variable such as milling time, control agent and CNT wt % on the morphology of alloy powder was 
investigated by Esawi and Borady [8]. Another study was done by others on the CNT particle size and milling time 
and they concluded that the particle size and morphology changed significantly due to the parameter [9]. They also 
found that the addition of methanol as process control agent affect the mechanically alloyed powder mixture 
characteristic. 
However, no information is available in literature on the characterisation of CNT dispersion with wide range of CNT 
into Al matrix in terms of mapping and line analysis. Therefore, this research studied and characterised carbon 
nanotube dispersion in ball milled CNT-Al nano-composite which was performed in a planetary ball mill equipment 
using FESEM. 
 
2 FEATURES OF FESEM 
A field emission scanning electron microscope (FESEM) is microscope that works with electrons (particles with a 
negative charge) instead of light. These electrons are liberated by a field emission source having the smallest probe 
diameters (~ 1.2 nm) and with higher resolution. A FESEM is used to visualize very small topographic details on the 
surface or entire or fractioned objects. Researchers in materials, biology, chemistry and physics apply this technique 
to observe structures that may be as small as 1 nanometer. The main advantage of the FESEM is that high resolution 
imaging can be performed with very low accelerating voltages [10]. 
By using FESEM, topography, morphology, composition, mapping, crystallographic information, higher lateral 
resolution, onset field strength and investigation of the long-term stability can be measured.  
The FESEM can be classified as a high vacuum instrument (less than 1x10-7 Pa or 10-10 mbar). The vacuum allows 
electron movement along the column without scattering and helps to prevent discharges inside the instrument. Under 
vacuum, electrons generated by a field emission source (electron gun) are accelerated in a field gradient. The electron 
beam passes through electromagnetic lenses, focusing onto the specimen. As a result of the electrons bombardment, 
different types of electrons or signals (such as secondary electrons (SE), Backscattered electrons (BSE), AE, X-rays, 
light) are emitted from the specimen. The image is formed based on the detection and intensity of the secondary 
electrons. The applications of FESEM are semiconductor device cross section analyses for gate widths, gate oxides, 
film thicknesses, and construction details; advanced coating thickness and structure uniformity determination and 
small contamination feature geometry and elemental composition measurement [11]. 
 
3 MATERIALS AND METHOD 
The matrix material in this investigation was Al powder (99.7% purity) and the particle size was 78 µm with the 
spherical shape. The reinforced material was multi-walled carbon nanotubes (MWCNTs) with a nominal diameter of 
10nm, length of 5-15µm and surface area of 40-300 m2g-1. The morphology of Al powder and MWCNT was 
investigated using FESEM and shown in Figure 1. There are four formulations with, 1, 1.5, 2 and 2.5 wt% CNT for 
development of CNT-Al nanocomposite. Initially, CNT-Al powders were mixed by hand shaking inside the tube using 
10 mm diameter stainless steel ball for 10-15 mins. Then, this hand shacked mixture was placed in a stainless steel jars 
with the same ball. The ball milling was performed using high energy planetary ball mill equipment at a constant 
speed of 250 rpm for 2 hours in presence of argon gas.The sample was compacted at a pressure of 2500 psi and 
sintered using hot isostatic press (HIP) machine (HP630) at 500oC and the argon gas was supplied at the pressure of 
2500psi for 60mins to control the atmosphere in the process. The CNTs dispersion was analysed using FESEM. 
 
 

  
(a) (b) 

 

Figure1: Photo-micrograph of (a) aluminium powder and (b) CNT [3]. 
  



Characterization of Carbon Nanotube Reinforced Aluminium Nano-composite using Field Emission Scanning Electron Microscope 

65 

4 RESULTS AND DISCUSSIONS 
From the FESEM image at higher magnification, the CNT was observed to be a long and thin tube like structure and 
appeared as individual molecules as expected. Figure 2 to 5 shows that the particles are plastically deformed due to 
effect of ball milling parameters resulting a typical flake structures of the nanocomposite.  
With the increasing the milling time, the flake structure nanocomposite start changing to the sandwich structure up 
to the first few minutes of the milling time followed by welding of the particles together, and finally turns to the 
rough surface with course particle size. This is happen due to collision during grinding of the particles. The progressive 
welding of the particles continued due to effect of the milling time. 
Fig. 3 shows the microstructure of 1.5 wt% CNT at 250 rpm for different ball milling time. From the figure, it can be 
seen that both reinforcement and matrix particles are flattened because of the collision during ball milling. Spherical 
shape of CNT and Al mixtures was observed with increasing milling time. Similar observation was made from Fig. 2 
and 4 for 1 and 2 wt% CNT respectively; while for 2.5 wt% some cluster was observed on the morphology (Fig. 5). 
However, similar result was observed by others but with different and higher milling time [6]. In terms of 
homogenization 1.5 wt% CNT was assume to have better and uniform CNT dispersion and it was attained in a short 
time at 250 rpm milling speed. Higher CNT percentage into Al matrix demanded more milling time to 
homogeneously dispersed the mixture compared to when using a lower CNT percentage mixture. Uniform and 
homogeneously dispersed CNT has a significant effect in a light weight CNT-Al nanocomposite. 
Hence, the dispersion and homogenous distribution of CNT in Al can significantly affected by the ball milling time 
and preliminary mixing of the powders.  It can be said that the appropriate amount of bonding agent like process 
control agent and hand mixing of CNT and Al powder before ball milling are the main contributing factors toward 
the uniform dispersion and distribution of CNT powder in Al matrix. 
 
 
 

   
(a) (b) (c) 

 
Figure 2: Microstructure of 1 wt% of CNT at 250 rpm for different ball milling time. 

 
 
 
 

  
 

(a) (b) (c) 
 

Figure 3: Microstructure of 1.5 wt% of CNT at 250 rpm for different ball milling time. 
 
  

1 wt%, 1hr 1 wt%, 2hr 1 wt%, 3hr 

1.5 wt%, 1hr 1.5 wt%, 2hr 1.5 wt%, 3hr 



Abdullahi, Maleque and Ali (2018): International Journal of Engineering Materials and Manufacture, 3(1), 63-67 

66 

   
(a) (b) (c) 

 
Figure 4: Microstructure and morphology of 2 wt% CNT at 250 rpm for different ball milling time 

 
 
 
 

   
(a) (b) (c) 

 
Figure 3: Microstructure of 2.5 wt% of CNT at 250 rpm for different ball milling time. 

 
 
5 CONCLUSION 
The morphological characterization of the developed nanocomposite using different CNT weight percentage are 
presented and compared while the choice of the best CNT percentage in the development of CNT-Al nanocomposite 
was made based on the analysis of FESEM and the results showed homogeneous dispersion and distribution of CNTs 
in aluminium matrix. Ball milling time during the mixing of the powder and controlled atmosphere with argon in the 
furnace play important role on the sintered product of the CNT-Al nano-composite. 
 
 
ACKNOWLEDGEMENTS 
The authors would like to express their thanks to the Department of Manufacturing and Materials Engineering, IIUM 
for the support to carry out this research work. 
 
 
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