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Effect of Friction Stir Welding Parameters on the 
Microstructure and Mechanical Properties of 

AA2024-T4 Aluminum Alloy  
 

Abdel-Wahab El-Morsy Mohamed M. Ghanem Haitham Bahaitham 
Faculty of Engineering, Rabigh Branch 

King Abdulaziz University, Saudi Arabia and 
Faculty of Engineering, Helwan University 

Cairo, Egypt 

Central Metallurgical Research and 
Development Institute  

Cairo, Egypt 

Faculty of Engineering 
Rabigh Branch 

King Abdulaziz University 
Saudi Arabia 

 

 
Abstract—In this work, the effects of rotational and traverse 
speeds on the 1.5 mm butt joint performance of friction stir 
welded 2024-T4 aluminum alloy sheets have been investigated. 
Five rotational speeds ranging from 560 to 1800 rpm and five 
traverse speeds ranging from 11 to 45 mm/min have been 
employed. The characterization of microstructure and the 
mechanical properties (tensile, microhardness, and bending) of 
the welded sheets have been studied. The results reveal that by 
varying the welding parameters, almost sound joints and high 
performance welded joints can be successfully produced at the 
rotational speeds of 900 rpm and 700 rpm and the traverse speed 
of 35 mm/min. The maximum welding performance of joints is 
found to be 86.3% with 900 rpm rotational speed and 35 mm/min 
traverse speed. The microhardness values along the cross-section 
of the joints show a dramatic drop in the stir zone where the 
lowest value reached is about 63% of the base metal due to the 
softening of the welded zone caused by the heat input during 
joining. 

Keywords-friction stir welding; welding parameters; 2024-t4 
aluminum alloy; mechanical properties 

I. INTRODUCTION  
Due to many outstanding characteristics of Aluminum (Al) 

and its alloys, such as excellent corrosion resistance, high 
strength-to-weight ratio and ease of fabrication, Al-alloys are 
finding a wide range of application in aircrafts, ships, 
automobiles, storage facilities and heat exchangers building 
industries [1]. The utilization of Al-alloys in such industries is 
highly affected by their weldability factor. In order to achieve 
maximum joint efficiency, the Al-alloys weld joints should 
have exceptional levels of their mechanical properties while 
maintaining minimal levels of weld-defect density. The use of 
conventional fusion welding process in joining Al-alloys, 
especially the high-strength and heat-treatable ones, is 
considered less efficient due to the high possibility of forming 
hot cracks, segregation, and porosities welding defects during 
the fusion and solidification phases of the process [2]. In 
addition, the traditional welding process often leads to 
deterioration of mechanical properties and degradation of 
corrosion resistance in the joint because of phase 

transformations and the dissolution of strengthening 
precipitates during the fusion welding process [3-4]. 

To eliminate the distortions, particularly in thin sheets, and 
the problems associated with the traditional fusion welding 
processes, friction stir welding (FSW) has been developed. As 
a solid state joining process, FSW is a promising and a viable 
welding technique that can produce high-quality, defect-free, 
and low-cost joints particularly in the joining of high-strength 
Al-alloys such as highly alloyed 2xxx and 7xxx series [3, 5, 6]. 
In addition, FSW is considered to be the most remarkable and 
viable welding technique for several materials such as Al-
alloys [2-8], Mg-alloys [9-10], Ti-alloys [11], Ni-base alloys 
[12], Cu-alloys [13], and steels [14, 15]. Moreover, FSW has 
the possibility of creating dissimilar joints with excellent 
mechanical characteristics [16-17]. During FSW process, using 
an inappropriate level of welding parameters can cause defects 
in the joint and worsen its mechanical properties [18]. Thus, it 
is very important to choose the optimum levels of these 
welding parameters in order to get a weld of appropriate 
quality. The present study addresses the effect of traverse and 
rotational speeds on the quality of Al-alloys joints produced by 
FSW process through analyzing the microstructure and 
mechanical properties of 1.5 mm 2024-T4 Aluminum alloy. 
The mechanical properties that have been explored include 
microhardness distributions, bending, and tensile strength of 
the welded joints. 

II. EXPERIMENTAL PROCEDURE 
To study the effects of rotational speed and traverse speed 

on the quality of friction stir butt welded joints of Al-2024-T4 
Al-alloy, sheets with a thickness of 1.5 mm have been utilized. 
Chemical composition and mechanical properties of these 
sheets are presented in Table I. Using sawing machines, the 
sheets have been cut into 90×150×1.5 mm3 strips. The FSW 
process has been conducted by a vertical milling machine 
equipped with a high-speed stirring tool, which moves 
perpendicular to the rolling direction. In Table II the tool 
geometry is illustrated along with the ranges of rotational 
speeds and traverse speeds applied in the FSW process.  



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TABLE I.  CHEMICAL COMPOSITION AND MECHANICAL PROPERTIES OF 
AL-2024-T4  

Chemical composition 
Si Fe Cu Mn Mg Zn Ti Al 

0.5 0.5 4.1 0.6 1.2 0.25 0.15 Bal. 
Mechanical properties 

Hardness Tensile strength Yield stress 
160 HV 417 MPa 276 MPa 

TABLE II.  WELDING PARAMETERS AND TOOL GEOMETRY 

Rotational speed 
(rpm) 

Traverse speed 
(mm/min) Tool 

560 

35 

Cylindrical pin tool 
geometry 700 

900 
1400 
1800 

900 

11 
18 
28 
35 
45 

 
The joint performance has been determined by conducting 

optical microscopy and mechanical testing (microhardness, 
tensile and bend tests). The metallography samples for 
microstructural characterization have been taken perpendicular 
to the welding direction for each welded sheet. The samples 
have been etched using Killer’s reagent base with the following 
chemical composition: 1.5 ml HCl, 2.5 ml HNO3, 1 ml HF and 
95 ml distilled water. After being immersed for few seconds in 
the etching solution, the samples have been water-washed and 
dried in order to have them checked by the optical microscope. 
The hardness variation across the stirred zones of the joints has 
been obtained by conducting the Vickers Microhardness test on 
the traverse cross section of FSW samples joints. The 
mechanical performance of the joints has been determined 
through tensile testing where the ultimate tensile strength, the 
yield stress, and the percentage of elongation of several sets of 
specimens have been recorded and compared with those 
obtained from the base metal (BM) specimens. The specimens’ 
sets have been prepared according to ASTM E8M-13a standard 
[19] where each set contains three specimens made by the 
predetermined settings of rotational and traverse speeds 
considered in the study. The bending tests have been carried 
out as per ASTM E290 for welded specimens to check the 
joints performance and weld consolidation [20-21]. For each 
joint, bends have been checked with mandrel diameter. In order 
to conduct the test, 1.5×20×180 mm3 specimens have been bent 
around mandrel diameter 4T. The joint surface of the 
specimens has been examined for cracks and imperfections 
after reaching 180 bend by applying enough force to make the 
specimens’ legs parallel. Figure 1 shows schematic illustration 
of the FSW joints and the transverse testing specimens. 

III. RESULTS AND DISCUSSION 
The BM microstructure, presented in Figure 2, is mainly 

consisting of α-solid solution of Cu-Al (the bright contrast) and 
secondary phases with different morphologies precipitated in 
the matrix (the dark contrast). As shown in the Figure, the 

cladding layer of pure Al is rolled with the alloy to give high 
corrosion resistance by a layer of Al-oxide which cannot be 
penetrated by O2 and prevents further attack. 

 

 
Fig. 1.  Schematic illustration of the FSW and the traverse testing 
specimens. 

 

 
Fig. 2.  Optical microstructure of the base metal. 

Figures 3-6 show the morphology overviews of the traverse 
cross sections of FSW samples at different welding conditions 
covering the predetermined levels of rotational and traverse 
speeds. In all presented cases, the joints were split into several 
distinct regions: BM, stir zone (SZ), heat affected zone (HAZ) 
and the narrow transition region which is commonly called 
thermo-mechanically affected zone (TMAZ). Figure 3 shows 
the optical micrograph of SZ at 900 rpm rotational speed and 
11 mm/min traverse speed. It is observed that the clad layer has 
been damaged and forced into weld nugget. The indiscernible 
shape found in the SZ could be due to inadequate flow of 
metals and mixing in that zone. The improper heat applied 
during the FSW process has caused the void or groove-like 
defect to occur in both ZS and TMAZ in addition to causing 
some pinholes which have been observed at the bottom side of 
the joint. The observed kissing bond has been formed under the 
pin shoulder during the FSW process due to the severities of 
the oxide with some absorbed air on the specimens’ surface [9]. 

The optical micrograph of the welded sample at 900 rpm 
rotational speed and 35 mm/min traverse speed is shown in 
Figure 4. Despite the few microvoids observed in the SZ, it can 
be claimed that almost sound joints have been successfully 
produced by applying these levels of rotational and traverse 



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speeds. This is mainly because of the sufficient heat input 
applied during the FSW process which has elevated the 
temperature and promoted the plastic flow of materials around 
the pin tool in an effective manner. 

 

 
Fig. 3.  A micrograph of the joints at 11 mm/min traverse speed and  
900 rpm rotational speed. 

 

 
Fig. 4.  A micrograph of the joints at 35 mm/min traverse speed and  
900 rpm rotational speed. 

Optical micrograph of welded sample at 710 rpm rotational 
speed and 35 mm/min traverse speed is shown in Figure 5. As 
in the case of 900 rpm and 35 mm/min, few microvoids have 
been observed on the retreating side of SZ and TMAZ. The 
overall area percentage of the microvoids to the welding nugget 
is less than 1% indicating that the porosity level is still quite 
low. The cross-section of a typical FSW joint for the rotational 
speed of 1400 rpm and the traverse speed of 35 mm/min is 
shown in Figure 6. Voids have been obviously seen in the SZ 
and that could be attributed to the excess amount of heat 
generated by the high rotational speed of the pin tool. In 
addition, the excess heat input applied during the FSW has 
softened the metal and, as a result, has caused a large mass of 
flash to be ejected to the outside [22]. Figure 7 shows the 
ultimate tensile strength of the joints compared to the BM. 
Figure 7a presents the tensile strength of joints obtained at 
traverse speed of 35 mm/min and different rotational speeds, 
whereas part b of the figure presents the tensile strength of the 
joints obtained at rotational speed of 900 rpm and different 
traverse speeds. Both parts of this figure show that the tensile 
strength of the FSW joints is much lower than that of BM. The 

stated findings agree with findings in [23]. From the 
experimental results shown in Figure 7a, the tensile strength of 
the joints has a tendency to increase when rotational speed 
increases until it reaches 900rpm. Rotational speeds higher than 
this value cause the tensile strength to decrease due to the 
higher temperatures experienced in the SZ. Of the five 
rotational speeds shown, 700 rpm and 900 rpm rotational 
speeds enhanced the tensile strength of the joints substantially 
but the other rotational speeds (560, 1400, and 1800 rpm) 
deteriorated tensile strength of the joints analyzed. 

 

 
Fig. 5.  A micrograph of the joints at 35 mm/min traverse speed and  
700 rpm rotational speed. 

 

 
Fig. 6.  A micrograph of the joints at 35 mm/min traverse speed and  
1400 rpm rotational speed. 

When varying the traverse speed at constant rotational 
speed (900rpm), as shown in Figur 7b, the tensile strength is 
decreased but with a magnitude lower than the one observed 
when varying the rotational speed at constant traverse speed. 
This coincides with findings in [24, 25] as they report that 
temperature and rotational speed are significantly affecting the 
strength and microstructure of joints. Figure 8 shows the tensile 
strength performances of the joints obtained at different 
rotational and traverse speeds. The strength performances are 
defined as the ratios of the tensile strength of the joints to those 
of the BM. The tensile strength performances of the joints vary 
with the welding condition. For the joints obtained at a traverse 
speed (35 mm/min) and different rotational speeds, the strength 
performances are varying between 54.9% at 560 rpm and 
86.3% at 900 rpm. For the joints obtained at constant rotational 



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speed (900 rpm) and different traverse speeds, the strength 
performances are varying between 74.8% at 45 mm/min and 
86.3% at 35 min/min. The best results were obtained at a 
traverse speed of 35 mm/ min for all tool rotational speeds. 

 

 
 

 
Fig. 7.  Tensile strength of joints at different rotational and traverse speeds 
compared to BM. (a) at 35mm/min traverse speed and (b) at 900 rpm 
rotational speed. 

Figure 9 shows the microhardness profiles across the weld 
cross-section of the FSW joints at 35 mm/min traverse speed 
and various rotational speeds. As illustrated, the BM in the 
initial condition has an average microhardness value of about 
160 HV. This value is gradually decreasing in HAZ and TMAZ 
until it reaches its lowest level in the SZ. The minimum 
microhardness value observed in the SZ is 101 HV which is 
63% of the BM value at 560 rpm rotational speed. Such 
reduction of the microhardness value within the welded zone is 
attributed to the softening of the welded zone caused by the 
excess heat input during joining. Similar microhardness 
behavior of other friction stir-joined Al alloys has also been 
reported by other researchers [3, 24, 26]. However, the effect of 
the excess heat generated during the FSW process on the 
microhardness level is highly affected by the rotational speed 
applied. The microhardness value has increased to 119 HV in 
the SZ at 700 rpm and to 117 HV at 900 rpm while it has 
decreased at 1400 and 1800 rpm rotational speeds. This 
reduction in the microhardness value at higher rotational speeds 
is due to grain growth resulting from higher temperatures 
experienced during the FSW process [27]. Such observation 

coincides with findings in [21] which state that the rotational 
speed must be moderate enough to avoid grain growth. 

 
 

 
Fig. 8.  Tensile strength performances of joints at (a) at 35mm/min, and  
(b) at 900 rpm. 

Figure 10 shows the microhardness profiles across the 
weld cross-section of the FSW joints at 900 rpm rotational 
speed and two traverse speeds, 11 mm/min and 35 mm/min. 
As seen in the figure, the low traverse speed has decreased the 
microhardness value within the welded area by about 42.5% 
while the high traverse speed has decreased it by 26.8% of the 
BM microhardness value. With decreasing traverse speed, the 
time of exposure to the heat is increased and leads to grain 
growth. The mechanical resistance and the ductility of all joint 
specimens have been addressed using bending tests. These 
tests are very sensitive to defects near the surface of the 
welded zone. The welded specimens are loaded until they take 
a U-shape or a failure is observed. The bending tests were 
performed on the welded specimens obtained at different 
rotational and traverse speeds and the surface photographs of 
tested specimens are shown in Figure 11. As shown in Figure 
11a, the welds presented good ductility, allowing for very high 
bend angles and no cracks or failures were observed on the 
welded specimens at the rotational speeds of 560, 700, and 
900 rpm. On the other hand, cracks and failures are found in 
the welded zones on the specimens that have been welded at 
the rotational speeds of 1400 and 1800 rpm. The photographs 
of tested specimens in Figure 11b show that that the surface of 
most of the welded specimens seems to be good. Solely one 
specimen was observed to fail in the bend testing at the 

(a)

(a)

(b) 

(b) 



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traverse speed of 45 mm/min. Table III presents a summary of 
the conducted bend testing parameters and results 

 

 
Fig. 9.  Microhardness profile across the stirred zone at 35 mm/min 
traverse speed. 

 

 
Fig. 10.  Microhardness profile across the stirred zone at 900 rpm rotational 

speed and two different traverse speeds (11 mm/min and 35 mm/min). 

 
(a) 

 
(b) 

Fig. 11.  The bending results of joints at different traverse and rotational 
speeds. (a) at 35mm/min and (b) at 900 rpm. 

IV. CONCLUSIONS 
In this study, the friction stir butt weldability of AA2024-

T4 aluminum alloy was studied. The tensile, bending and 
microhardness tests, as well as microstructure analysis were 
conducted to determine the mechanical properties and the 

welding performances of joints. The following conclusions 
were drawn: 

 The almost sound joints were successfully produced at the 
rotational speeds of 900 rpm and 700 rpm and traverse 
speed of 35 mm/min. for the rotational speed of 1400 rpm.  

 As a result of the tensile test it was observed that the 
maximum welding performance of joints was found to be 
86.3% with a 900-rpm rotational speed and a 35 mm/min 
traverse speed. The tensile value is reached to 360 MPa in 
the welded sample. However, it is seen that the tensile 
strength values are decreased under the highest traverse 
speed (45 mm/min) and under the highest rotational speeds 
(1400 and 1800 rpm).  

 The microhardness profile of all the welded sheets clearly 
shows a dramatic drop in microhardness measurements 
within the SZ. The hardness increases relatively quickly 
from the SZ through the HAZ toward the BM. The welded 
sheet at low traverse speed (11 mm/min) demonstrates a 
more abrupt microhardness value compared with the 
welded sheet at high traverse speed (35 mm/min).  

 Most of the welds presented good ductility, allowing for 
very high bend angles and no cracks were observed.  

TABLE III.  EXPERIMENTAL BENDING RESULTS OF WELDED SAMPLES AT 
DIFFERENT TRAVERSE AND ROTATIONAL SPEEDS 

Traverse speed 
(mm/min) 

Rotational speed 
(rpm) Remarks 

35.5 

560 No cracks 
710 No cracks 
900 No cracks 
1400 Cracks 
1800 Cracks 

11.2

900 

No cracks 
18 No cracks 
28 No cracks 

35.5 No cracks 
45 Cracks 

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