Journal of Mechanical Engineering Science and Technology ISSN 2580-0817 

Vol. 6, No. 1, July 2022, pp. 9-22  9 

                 DOI: 10.17977/um016v6i12022p009 

Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Automotive 

Alloys under Up-milling and Down-milling Operation                                         

Akib Abdullah Khan1, Mashiur Rahman Shoummo1, Mohammad Salim Kaiser2* 

1Department of Mechanical Engineering, Bangladesh University of Engineering and Technology, 
Dhaka-1000, Bangladesh 

2Directorate of Advisory, Extension and Research Services, Bangladesh University of Engineering 

and Technology, Dhaka-1000, Bangladesh 

*Corresponding author: mskaiser@iat.buet.ac.bd 

Article history: 

Received: 26 March 2022 / Received in revised form: 25 April 2022 / Accepted: 25 May 2022  

ABSTRACT  

Effect of the elements Fe, Ni, and Cr on the surface quality under machining of hyper-eutectic aluminium-

based Al-Si automotive alloys has been carried out as the elements improve the properties of this alloy. 

Machining is done on a horizontal type milling machine using a high-speed steel slab milling cutter in dry 

condition. Only the cutting speed varies throughout the experiment, while the machining feed and depth of 

cut remain fixed. The experimental results show that the addition of these alloying elements increases the 

roughness and hardness specially due to formation of Fe-rich intermetallic 𝛽−𝐴𝑙5𝐹𝑒𝑆𝑖. However, the 
needle-like 𝛽−𝐴𝑙5𝐹𝑒𝑆𝑖 has been refined with the addition of Cr, as seen by the microstructure. The SEM 
fractography shows a huge cleavage of the brittle 𝛽−𝐴𝑙5𝐹𝑒𝑆𝑖 phase, which initiates the crack propagation 
for Fe added alloys. The downward force causes compressive stress exerted in down-milling operation, so 

the results depict higher hardness and better surface finish.  Besides, shorter chips are formed in down-

milling than up-milling process, which rather causes the brittleness of the alloys. When the cutting speed is 

raised, the surface quality deteriorates due to high temperature, while the hardness improves initially due to 

formation of precipitates then decreases due to coarsening of precipitates. 

Copyright © 2022. Journal of Mechanical Engineering Science and Technology. 

Keywords: Chips, hardness, microstructure, roughness, surface 

I.  Introduction

Al-Si alloys are used to manufacture connecting rods, pistons, cylinder liners, engine 

blocks, etc., components of engine construction in automotive applications, as they are light 

in weight and have high strength [1]-[5]. To develop the diverse properties of this alloy, 

several other components are added. When minor elements Cu and Mg are alloyed, it 

improves the involuntary properties. Moreover, the alloy offers the quick response to heat 

treatment [4], [5]. Iron is found in aluminum as the most common impurity. Small amount 

of iron into pure alloys provides slightly higher strength [6], [7]. The addition of Ni 

effectively increases the properties associated with the elevated temperature of the Al-Si 

alloy. A number of complex thermally stable intermetallic are formed, which enhance the 

mechanical properties of the alloys, especially at higher temperatures ahead of 250 °C [8], 

[9]. The acceptance of higher amount of Fe in Al-Si alloy can be effectively enhanced by 

adding Ni [10]. Chromium is alloyed to aluminium alloys for controlling the grain structure, 

preventing the grain growth and to slow down the recrystallization during heat treatment. 

Chromium reduces aluminum susceptibility and stress corrosion improving the toughness 

mailto:mskaiser@iat.buet.ac.bd


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Khan et al. (Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Alloys under Milling Operation) 

property [11]. Iron forms intermetallic phases, which are brittle and hard, so the amount of 

iron in Al-Si alloys should not be high. Addition of adapt elements such as manganese, 

nickel, zinc, lead, vanadium, chromium, magnesium, copper etc. modifies the morphology 

of the harmful platelet iron intermetallic compounds to harmless shapes [10]-[12]. The 

inclusion of Cr accelerates the transformation of Fe-containing phases from β-AlFeSi to α-

Al(Fe,Cr)Si. β-AlFeSi has a needle-like shape, while α-Al(Fe,Cr)Si has a fishbone-like 

morphology [13]. A brief literature review also has been made on the morphological change 

of different aluminum alloys under machining [14].  

However, for manufacturing or repairing the final product, the alloy is machined using 

several methods and machine tools to produce the desired shape. It can also be observed that 

the internal structure of the alloys is dramatically affected by the machinability [15]. This 

structure can be modified through adding alloying elements, process selection, or heat 

treating subsequently [15]. One of the methods of machining is milling, which is done on 

milling machines. Milling is a machining operation that removes material from a workpiece 

by combining the rotation of a multiple-point cutting tool with the advancement (or feeding) 

of the workpiece at an angle to the tool's axis [16]. Milling can be divided into two types: 

traditional (or up) milling and climb (or down) milling. The relationship between the cutter's 

rotation and the feed direction is the distinction between these two approaches. "Up-milling" 

is when the cutter rotates in the opposite direction of the workpiece, while "down-milling" 

is when the cutter rotates in the same direction as the workpiece. This machining method 

affects various properties of the surface being machined. Experimental studies reveal that 

the quality of the machined surface not only depends on the cutting parameters applied but 

also the composition and conditions of the alloy samples [17]-[19]. 

As there is little information in the literature, this study is to find out the effect of the 

alloying elements like Fe, Ni, and Cr on the machinability using milling machine in terms 

of roughness, hardness, chips formation, surface quality and microstructural observation of 

the automotive Al-Si alloys. A comparison also has been made between both the processes 

of up-milling and down-milling. 

II. Material and Methods 

A 390 grade aluminium engine block was melted as master alloy. No alloying element 

was added to the first alloy. Then some Fe was added while casting the second alloy. Ni and 

Cr were further added to cast the third and fourth alloys, respectively. The prepared alloys 

are analysed by spectrochemical methods, as shown in Table 1. 

Table 1. Values of wt.% composition for the experimental alloys 

Alloy Si Fe Ni Cr Cu Mg Zn Mn Ti Al 

1 19.209 0.795 0.089 0.040 2.826 0.245 1.117 0.214 0.099 Bal 

2 17.947 5.910 0.091 0.086 2.881 0.186 1.139 0.183 0.071 Bal 

3 18.913 6.256 0.567 0.057 2.889 0.193 1.124 0.178 0.090 Bal 

4 19.363 5.501 0.621 1.267 3.112 0.232 1.085 0.217 0.076 Bal 

The melting was carried out in a ceramic fiber type laboratory-scale resistance heating 

furnace where degasser and borax were used as suitable flux cover. The chamber of the 

furnace was sized at 450 × 450 × 450 millimeters with a maximum working temperature of 



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Khan et al. (Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Alloys under Milling Operation) 

930 °C. Four heats were taken to develop an Al-Si-based alloy for engine construction. The 

master alloy was remelted to prepare Alloy 1. Then, to prepare Alloy 2, which mainly 

contained Fe, mild steel chips were added to the master alloy. Next, chips created from mild 

steel and some Ni were added to prepare Alloy 3, which mainly contained Fe and Ni. Finally, 

Alloy 4 was developed through the some stainless-steel chips addition in to the master alloy 

to full fill the requirement of the level of Fe and Ni along with Cr. For casting, the furnace 

temperature was always maintained at 750±15 °C with the help of electronic controller. Iron 

metal moulds were preheated to 200 °C, and casting was done into them. Mould sizes were 

20 × 150 × 300 millimeters. The cast alloy was kept in a muffle furnace at 400 °C for 18 

hours of homogenization and was air-cooled. Afterward, the homogenized samples were 

solutionized at 530 °C for 2 hours, and then the samples were salt ice water quenched to get 

a supersaturated single-phase region. Next, the alloys were isothermally aged at 175 °C for 

240 minutes, as the peak hardness of the alloys is achieved at that condition [19], [20]. The 

samples were wet sanded mechanically with SiC papers of 120, 320, and 1200 grit. The 

machining operation was done with an HSS (high-speed steel) slab milling cutter mounted 

on a horizontal milling machine on 300 × 50 × 20 millimeters bars of the four alloys. The 

experimental setup is shown in Figure 1. The feed was 9.5 mm and kept constant throughout 

the experiment. Machining parameters, including cutting speed, feed rate, and depth of cut 

are crucial in terms of the workpiece's process-structure-performance relationship, so they 

must be chosen carefully [21]. So, the experiment was carried out by varying the cutting 

speed without the influence of any cutting fluids. The cutter was frequently being cleaned 

with a brush during the milling operation so that chips were removed from the cutter, which 

was spoiling the machined surface. A Tylor Hubson surface roughness tester was used to 

measure surface roughness. An average of five measurements was taken to calculate 

roughness. A Zwick Rockwell hardness tester with 1/8 inch ball was used to get hardness 

values in the B scale. A USB microscope was used for observing the machined surfaces, and 

a DSLR camera was used to capture digital photographs of the generated chips. Table 2 

shows the tool geometry and cutting conditions used in the experiment. The specimens were 

polished with alumina and etched with Keller’s reagent for scanning electron microscopy as 

well as fractographic observations of the surfaces of the alloys using the Jeol Scanning 

Electron Microscope JSM-5200.  

 

Fig. 1. Experimental setup. 

HSS slab milling cutter 

Specimen 

Chips collection 



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Khan et al. (Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Alloys under Milling Operation) 

Table 2. Tool geometry and cutting condition. 
 

Cutter Diameter  76.2 mm 

Cutter Height  101.6 mm 

Cutter Helix Angle  20 

Cutter Rake Angle  8 

Cutter Teeth  16 no. 

Feed  9.5 mm/min 

Depth of Cut  1.0 mm 

Cutting Speed  7.9, 12.9, 14.8, 18.9, 23.9 m/min 

Cutting Condition Dry 

 

III. Results and Discussions 

A. Surface Roughness 

Surface roughness variation with the cutting speed of the cast and aged hypereutectic 

different experimental Al-Si automotive alloys is shown in Figures 2 and 3 under up-milling 

and down-milling machining processes, respectively. From both figures, it can be noted that 

base Alloy 1 be evidence for lower roughness, whereas Fe added Alloy 2 has rougher 

surface, and the roughness increases accordingly as Ni and Cr are added too. Common 

needle-like 𝛽−𝐴𝑙5𝐹𝑒𝑆𝑖 intermetallic phases are formed due to the presence of Fe in the 
hypereutectic based alloys, which strongly degrades the mechanical and physical properties 

of Alloy 2 and 3. Because intermetallic compounds are brittle and rigid, they can operate as 

stress raisers and sources of weakness, reducing the alloy's strength and ductility. In the alloy 

matrix, the compounds behave as distinct particles having a highly faceted character. As a 

result, it has a poor bonding within the matrix, resulting in the lowest impact strength [22]. 

When the cutter in a milling machine is worked upon, these needle-like brittle intermetallic 

compounds break down into smaller particles, resulting in an uneven surface finish. It can 

be seen that when Ni is added, AlSiFeNi and Chinese script intermetallics develop. 

According to the Ni content, these intermetallic structures are more common in Al dendrites 

[23]. These intermetallics are long needle-like, making the alloy more prone to blow-holes 

and porosity. As a result, the bond strength with the matrix is lower, resulting in a rougher 

surface. When Cr is added, the morphology of the platelet iron intermetallic complex 

changes to innocuous forms, improving the mechanical capabilities but lowering the surface 

quality [11], [23]. An earlier investigator has discovered a similar result in Cr added Al-Si 

alloy with 0.52 wt% Fe [24]. The intermetallic compound is broken down into tiny bits and 

disseminated throughout the matrix [23].  

An interesting fact can be observed from the figures that the surface quality of down-

milled surfaces is superior than that of up-milled surfaces. The cause for this could be Al 

has a tendency to form the built-up edge through the attachment with cutting tool during 

machining. It has an unfavorable outcome on the surface finish, making it undesirable [24], 

[25]. During up-milling, the cutter applies outward force to the material, shearing it and 

increasing BUE. Down-milling, on the other hand, exerts an inward force on the alloy, 

compressing it and smoothing the surface. From Figures 2 and 3, it is also evident that the 

surface quality reduces while the cutting speed is gradually increased. Increase in cutting 

speed increases the surface temperature, and at high temperature grains are coarsed, the 



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Khan et al. (Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Alloys under Milling Operation) 

intermetallics are broken into pieces and brittle state of the intermetallics appears at the 

surface, creating rougher surface. The heat is generated by the friction between the cutting 

tool and workpiece interface during chip removal since it raises the temperature in the 

cutting zone which reduces the cutting tool material's hardness [26]. Many studies have 

found that as the cutting tool hardness decreases, the wear of cutting tool goes faster, 

changing the cutting edge and shape of the broken chip. As a result, this wear has an 

undesirable effect on surface roughness and dimensional accuracy [26], [27].  

6 8 10 12 14 16 18 20 22 24 26
0.8

1.2

1.6

2.0

2.4

2.8

3.2

3.6

R
o

u
g

h
n

e
s
s
, 

m

Cutting speed, m/min

 Alloy 1

 Alloy 2

 Alloy 3

 Alloy 4

 
Fig. 2. Surface roughness variation with cutting speed of the experimental 

alloys under up-milling process. 

6 8 10 12 14 16 18 20 22 24 26
0.8

1.2

1.6

2.0

2.4

2.8

3.2

3.6

R
o

u
g

h
n

e
s
s
, 

m

Cutting speed, m/min

 Alloy 1

 Alloy 2

 Alloy 3

 Alloy 4

 
Fig. 3. Surface roughness variation with cutting speed of the experimental 

alloys under down-milling process. 

 



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Khan et al. (Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Alloys under Milling Operation) 

B. Hardness 

Figures 4 and 5 show the hardness of the machined surfaces of the experimental alloys 

for up-milling and down-milling operations at various cutting speeds. It is clear that Alloys 

2, 3, and 4 have higher hardness ratings than Alloy 1. The higher amount of Fe produced 

iron rich intermetallic during solidification and ageing, which increases the hardness of the 

alloys [27]. There are the five main Fe-rich phases: 𝐴𝑙3𝐹𝑒, 𝛼 − 𝐴𝑙8𝐹𝑒2𝑆𝑖, 𝛽 − 𝐴𝑙5𝐹𝑒𝑆𝑖, 𝛿 −
𝐴𝑙4𝐹𝑒𝑆𝑖2 𝑎𝑛𝑑 𝛾 − 𝐴𝑙3𝐹𝑒𝑆𝑖. Among them, 𝛽 − 𝐴𝑙5𝐹𝑒𝑆𝑖 phase is usually accountable for the 
higher hardness. It can be seen that the same intermetallics which are responsible for 

degrading surface quality are also responsible for improving hardness rating. Alloy 3 shows 

a further improvement of the hardness. Adding Ni after age hardening increases the 

hardness, which could be related to the development of harder precipitated phases such 

as 𝑁𝑖3𝐴𝑙 𝑎𝑛𝑑 𝑁𝑖3𝑆𝑖 during the aging process [28], [29]. Conversely, Cr alters the 
morphology and type of Fe-rich intermetallic phases in cast aluminum alloys, resulting in a 

loss of hardness in Alloy 4 [11].   

However, another intriguing finding is that down-milling produces superior quality in 

terms of hardness than up-milling. The reason for this could be that when down-milling, the 

cutter provides compressive force, which is similar to cold rolling, and cold rolling improves 

hardness by reducing defects such as pinholes and porosity, and increasing dislocation 

density [30]. 

0 2 4 6 8 10 12 14 16 18 20 22 24 26
70

75

80

85

90

95

100

105

H
a

rd
n

e
s
s
, 

H
R

B

Cutting speed, m/min

 Alloy 1

 Alloy 2

 Alloy 3

 Alloy 4

 

Fig. 4. Rockwell hardness variation with cutting speed of the experimental 

alloys under up-milling process. 

 

Figures 4 and 5 depict again that the Rockwell hardness number increases as cutting 

speed is raised up to a certain speed, then the hardness starts to fall again. The surface 

temperature rises as the speed of the cutter increases, and after a certain point, the 

precipitates grow coarser, and coarse precipitates are less effective at resisting dislocation 

movement than finely dispersed precipitates. It is possible that the softening of the alloys at 

higher temperatures is related to particle coarsening. It can be seen from Figures 2 to 5 that 

the surface roughness and hardness variation with cutting speed are opposite to each other. 



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Khan et al. (Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Alloys under Milling Operation) 

As the speed is increased, the surface roughness rises, whereas the hardness is improved. 

Previous research suggests that the harder the ductile material, the higher the surface 

roughness values. However, in the case of brittle material, it was discovered that the 

variation was very closer between them. It was also stated that the porous-like defects into 

the alloy play a significant task on machinability of brittle materials, with the higher level 

of porous material recording higher roughness values owing to such microstructure of the 

alloy [31]. 

0 2 4 6 8 10 12 14 16 18 20 22 24 26
70

75

80

85

90

95

100

105

H
a

rd
n

e
s
s
, 

H
R

B

Cutting speed, m/min

 Alloy 1

 Alloy 2

 Alloy 3

 Alloy 4

 
Fig. 5. Rockwell hardness variation with cutting speed of the experimental 

alloys under down-milling process. 

 

C. Chips Photo Micrographs 

Figure 6 shows photomicrographs of chips produced as a result of machining. In the 

case of up-milling, the chips are longer. Down-milling, on the other hand, results in shorter 

chips. When down-milling, a compressive force is applied to the surface, and due to high 

amount of force, the bonds between molecules are frequently broken. As a result, the chips 

are shattered during down-milling and got shorter in length. The chip size decreases from 

Figures 6(a) to 6(c) for up-milling and from 6(e) to 6(g) for down-milling. As previously 

discussed, the intermetallics which are formed due to alloy addition are responsible for this 

result. As intermetallic compounds with Fe and Ni are formed, the alloys become more 

brittle. The intermetallics are broken into pieces as machining force is applied and are 

dispersed throughout the material and the surface. Thus, the mechanical property decreases 

[21], [22]. Hence, the chips are broken in short segments. On the other hand, from Figure 

6(d) for up-milling and Figure 6(h) for down-milling, it is noticeable that the chips are rather 

longer relatively. When Cr is added, however, the morphology of the intermetallic 

compound changes to a more favorable state, improving mechanical properties [11], [23]. 

 



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Khan et al. (Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Alloys under Milling Operation) 

  

  

  

  

Fig. 6. Optical images of the machined chips at cutting speed 23.9 m/min and depth of cut 

1 mm, under up-milling (a) Alloy 1 (b) Alloy 2 (c) Alloy 3 (d) Alloy 4 and under down-

milling (e) Alloy 1 (f) Alloy 2 (g) Alloy 3 (h) Alloy 4.  

(

e

) 

(

a

) 

(

b

) 

(

f

) 

(

g

) 

(

c

) 

(

d

) 

(

h

) 

(f) 

(a) (e) 

(b) 

(h) (d) 

(g) (c) 



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Khan et al. (Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Alloys under Milling Operation) 

D. Microstructural Observations 

Before machining, polished surfaces are smooth, and no plastic deformation is observed 

on the surface, which can be seen from the optical images in Figure 7. Much information 

cannot be extracted from this type of optical micrographs. However, for polished surfaces 

of Alloy 1 to 4, as alloying elements (Fe, Ni, Cr) are added, the tone becomes slightly 

different. The variation in the amount of elements present into the alloys is responsible for 

some variation in terms of different levels of tones in different alloys. The similar variation 

of tone was observed in previous studies of Al-Si alloy, too [32].  

 

    Unmachined     Up-milling  Down-milling 

Alloy 1 

   

Alloy 2 

   

Alloy 3 

   

Alloy 4 

   

Fig. 7. Optical images of the machined surface at cutting speed 23.9 m/min and depth of 

cut 1 mm of the experimental alloys under up-milling and down-milling conditions. 

 

150m 

Smooth surface Crack Compressed  

surface 

Crack 

Crack 

Crack 

Compressed  

surface 

Compressed  

surface 

Compressed  

surface 

Smooth surface 

Smooth surface 

Smooth surface 



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Khan et al. (Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Alloys under Milling Operation) 

After machining under up-milling condition, the micrographs consist of different cracks 

and more uneven surfaces than those created by down-milling. It is due to the tensile shear 

occurring during up-milling operation. Micrograph of Alloy 1 displays relatively the 

minimum cracks on the surface. But Fe added Alloy 2 shows more cracks due to presence 

of higher level of Fe-rich intermetallic followed by Fe and Ni added Alloy 3 which is due to 

both Fe and Ni rich needle-like intermetallics. However, Cr Added Alloy 4 can reduce this 

phenomenon by changing the morphology of Fe-rich intermetallic phases [11], [23]. In case 

of down-milling operation, lower cracks and pinholes are observed due to compressive 

stress, which occurs like cold rolling. On the other hand, the uneven surfaces are produced 

similarly as up-milling operation, but in different intensity, due to presence of different hard 

intermetallics. 
 

E. Scanning Electron Microscopy 

The SEM in Figure 8 shows the microstructure of experimental automotive alloys at 

peak aged condition. The microstructures as usual consist of primary Al dendrites with 

eutectic Si phases and a number of intermetallic phases in the matrix. Mixtures of 

intermetallic compounds are formed in the matrix due to the presence of Fe, Ni, Cr, Cu, and 

Mg in the alloys. Platelets and acicular morphologies can be seen in eutectic Si particles. 

Voids and hollow space can be noticed in the microstructure as a casting defect of cast alloys 

[28].  

 

 

 

Fig. 8. SEM images of the peak aged (a) Alloy 1, (b) Alloy 2, (c) Alloy 3, and (d) Alloy 4.  

 

The microstructure in Figure 8(a) shows of the base alloy as it contains 0.85 wt% Fe. 

As the percentage of iron is low, it has a small amount of 𝛽 − 𝐴𝑙5𝐹𝑒𝑆𝑖 phase, which can be 

(

a

) 

(c) 

(b) (a) 

(d) 

Distributed  

intermetallics 

Modified  

intermetallics 

Niddle-like  

intermetallics 

Large 

intermetallics 



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Khan et al. (Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Alloys under Milling Operation) 

witnessed in Figure 8(a). Figure 8(b) shows that the microstructure of Fe accompanying 

Alloy 2 has a higher amount of 𝛽 − 𝐴𝑙5𝐹𝑒𝑆𝑖 phase than Alloy 1 in Figure 8(a) due to the 
excess Fe in the alloy. Because Alloy 3 contains a considerable quantity of Ni, there are two 

types of 𝐴𝑙3𝑁𝑖 phases: plate-like and needle-like. The long needle-like structures can be 
seen in Figure 8(c), which covers most of the area. As previously discussed, these structures 

are responsible for blow-holes, pinholes, and porosity, which again is responsible for the 

degraded quality of surface. Figure 8(d) shows SEM micrographs of Cr-added Alloy 4, 

which has a changed structure with plate-like and needle-like morphologies missing. 

Figure 9 shows the SEM fractographs of the tensile tested peak aged alloys. The SEM 

fractograph of Alloy 1 is shown in Figure 9(a), which indicates a cleavage fracture. It occurs 

due to the high deformation rates during loading. Every grain has different orientation of the 

fracture plane. As secondary cracks, intergranular cleavage is visible too. Crack initiation 

occurs by significant cleavage of the brittle 𝛽 − 𝐴𝑙5𝐹𝑒𝑆𝑖 phase, according to the SEM 
fractograph of Alloy 2 (Figure 9(b)). At such Fe levels, a proliferation of β-platelets is 

expected in the alloy microstructure. The crack propagates from one β-platelet to the next, 

which can be seen in the Figure 9(b). In comparison to Si particles, the plate-like 𝛽 −
𝐴𝑙5𝐹𝑒𝑆𝑖 phase has substantially greater dimensions, making it more vulnerable to crack 
initiation. Increased number of secondary cracks is visible in Figure 9(c), because during 

age-hardening, the alloy becomes more brittle due to more precipitation hardening of the 

Ni-rich phases. As Cr changes, the 𝛽 − 𝐴𝑙5𝐹𝑒𝑆𝑖 phases in the alloy, no cracks propagating 
between the matrix and β-particles are detected in the SEM picture of Alloy 4 (Figure 9(d)) 

[33]. 

 

  

  

Fig. 9. SEM fractograph of peak aged (a) Alloy 1, (b) Alloy 2, (c) Alloy 3 and (d) Alloy 4.  

(b) 

(d) 

(a) 

(c) 

Brittle cleavage 

 fracture 

Massive brittle 

cleavage fracture 

Massive brittle 

cleavage fracture 

Modified brittle 

cleavage fracture 



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Khan et al. (Surface Quality of Fe, Ni, and Cr added Hyper-eutectic Al-Si Alloys under Milling Operation) 

IV. Conclusion 

From this study following results may be concluded regading the alloying elements’ 

effect on the surface quality of discussed Al-Si hyper-eutectic automotive alloy under up-

milling and down-milling conditions.  

Surface quality degrades as Fe, Ni, and Cr are added in subsequent alloys, because of 

intermetallic formation as well as creation of porosity and blow holes. The better surface 

quality and hardness can be achieved through down-milling operation due to compressive 

force and minimized BUE than for up-milling, acting as tensile-like force. The surface 

roughness and hardness both are found to be proportional to cutting speed for producing 

higher temperature at higher speed. The fractured surfaces of Fe and Ni added alloys show 

more cracks than the base alloy for the formation of different brittle intermetallics, whereas 

Cr added alloy shows lesser cracks for better morphology of the intermetallic precipitates. 

The chips produced are shorter in case of down-milling as compressive force acts on the 

brittle materials unlike of up-milling. The shorter chips are found for Fe and Ni added alloys 

as increased brittleness, but relatively longer chips are created in case of Cr added alloy due 

to intermetallic modification. 

Acknowledgement 

The authors thank to the GCE Department as well as DAERS office of Bangladesh 

University of Engineering and Technology, Dhaka for providing the equipment for this 

study. 

References 

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