A Parametric Study on Dissimilar Metal Welding of Aluminum and Copper using Pulsed Fiber Laser

DOI: https://doi.org/10.21203/rs.3.rs-907751/v1

Abstract

Joining dissimilar metals is critically challenging due to the difference in properties of the metals themselves which leads to the formation of brittle intermetallic compounds (IMCs). Aluminum (Al) and copper (Cu) are well-known materials for electrical application as they attribute to various advantageous characteristics. In lithium-ion batteries, to obtain most of the features of the metals, combinations of these metals are highly recommended. However, with such high reflective metals and heat-sensitive characteristics in the battery, the joint of these metals needs to be processed with an advanced method. In this study, a pulsed fiber laser source that suits to process for heat-sensitive components is utilized to weld two overlap configurations of Al/Cu and Cu/Al, separately. Different ranges of laser power are designated for each welding configuration separately. Thus, the quality of the two welds is evaluated in terms of microstructure and mechanical properties. Consequently, it is found that the growth of IMCs with dendritic structure towards the Al side is observed in both cases. Moreover, the weld of Al/Cu shows a better connection strength as well as fewer imperfections than the weld of Cu/Al.

1. Introduction

Being a crucial part of electronic devices and electric vehicles, lithium-ion batteries have been attracting global attention recently [1]–[3]. To meet up global desire, manufacturers now are making great efforts to achieve a better battery with various features in safety, durability, power performance, etc. However, during the production of lithium-ion batteries, multiple welding processes are required [4]. As the welded connection in the battery would have a significant impact on the electrical flow which in turn affects the battery performance between connected parts, the weld would be one of the key factors to improve the battery performance.

In the battery industry, aluminum (Al) and copper (Cu) are the materials with the most consumption as they feature high conductivity. Besides, Al is also well known for a lightweight and easy forming material, while Cu owns great tensile strength. Therefore, the combination of these materials provides great benefits to improve the performance of the batteries. However, joining for these dissimilar metals originally makes special demand to the joining technique since the common unforeseen formation of Intermetallic Compounds (IMCs) [5]–[8]. The formation of IMCs in the dissimilar weld of Al and Cu occurs due to the low solubility of the metals. According to the phase diagram of Al and Cu, as shown in Fig. 1, the maximum solubility of Cu in Al is 2.5% and Al in Cu is about 19.7%. Therefore, the interdiffusion of the metals during welding easily leads to the formation of the brittle Al-Cu IMCs. These IMCs are generally brittle [9]. Therefore, the growth of IMCs results in significant degradation of the weld properties and the formation of several weld defects such as porosities and cracks [10]–[13]. Moreover, the increase of the IMCs thickness induces a significant increase in contact resistance of Al-Cu joints [14]. Besides, the metals show very different physical and metallurgical properties such as density, melting point, boiling point, and thermal conductivity shown in Table 1.

Over the past years, many researchers have been proposed different joining methods for Al-Cu joint including solid-state and fusion welding. In particular, friction-stir welding has been attempted to joint dissimilar metals of Al and Cu by many researchers [15]–[17]. Meanwhile, scholars also reported several critical issues attributed to the friction-stir welding such as tool matters [18], failures at the interface, or nugget zone during mechanical testing [19], [20]. Next, ultrasonic spot welding which has the merit of less energy consumption and relatively short weld time has been utilized to weld Al and Cu [21]–[24]. Nevertheless, the dissimilar weld of Al and Cu conducted by ultrasonic spot welding also revealed several issues. As the welding method also require welding tool, tool matters such as tool wear and tool-material contact will adversely affect the weld quality [25]. The feasibility of dissimilar joining for Al and Cu using resistance spot welding was also investigated [26]. However, studies also pointed out limitations of the weld with resistance spot welding including materials, welding configuration, and welding tools. Therefore, it is necessary to develop a tool-free welding method. Fortunately, researchers and manufacturers have recently been employing the use of laser beam in manufacturing processes including welding for various materials. Laser beam welding (LBW) attributes with unique features such as non-contact processing, high energy intensity, and ease to control energy input so that LBW has successfully joined both similar and dissimilar thermal plastic materials [27]–[29]. Furthermore, LBW for dissimilar metals of Al and Cu has been investigating by many researchers. For instance, Xue et al. [30] used ANSYS FLUENT to create a 3D finite volume simulation for the molten pool behavior for the weld of dissimilar metals of Al and Cu using a continuous wave laser source. The study concluded that an extensive interdiffusion of Cu and Al took place in the molten state with the given welding condition. Thus, different varieties of Al-Cu IMCs were formed in the weld. Meanwhile, Fetzer et al. [31] and Dimatteo et al. [32] have developed the laser welding for Al and Cu with continuous-wave laser source using beam oscillation technique. Both studies have reported that the weld with beam oscillation techniques has been significantly improved, and the element mixing in the fused zone is enhanced. Moreover, the penetration depth of the weld could be controlled by the adjustment of the oscillation amplitude. To provide more options in laser welding for Al and Cu, Wang et al. [33] described a study on an advanced welding technique in which he utilized a laser beam with a focal spot size of 6000 \({\mu }\)m to create laser shock welding. The study has proved the feasibility of laser shocking in joining the dissimilar metals of Al and Cu and achieved a nearly flat interface in the weld. Moreover, laser welding for Al and Cu with the use of the laser with a focal spot size of 800 \({\mu }\)m and 635 \({\mu }\)m was also performed by Zuo et al. [10] and Lerra et al [34], respectively. In summary, it can be seen that most studies are focusing on the use of laser beam with the focal spot size of hundreds of micrometers for laser welding of the dissimilar metals. Dissimilar metals of Al and Cu joint using a pulsed wave laser and focused spot size is less being investigated. Using pulsed wave laser produces a peak power for each pulse, thus the weld can obtain a deep penetration with shorter interaction time. As short interaction time is required, the pulsed wave laser is suitable for heat-sensitive components as well as reflective materials (e.g., Al and Cu).

Therefore, we aim to investigate the weld of dissimilar of Al and Cu using a pulsed wave laser beam with a focused spot size (40 \({\mu }\)m). Moreover, two opposite lap welding configurations (Al/Cu and Cu/Al) will be performed and compared. The weld will be analyzed in terms of microstructure characteristics and mechanical properties. The microstructure of the weld will be revealed mainly through cross-section observation, while mechanical properties of the weld will be evaluated with hardness distribution and mechanical strength.  

Table 1

Physical and mechanical properties of Al and Cu [35].

Material

Density

(g/\({\mathbf{c}\mathbf{m}}^{3}\))

Melting point

(\(^\circ \mathbf{C}\))

Boiling point

(\(^\circ \mathbf{C}\))

Thermal conductivity

(W/m K)

Modulus of Elasticity

(GPa)

Poisson’s Ratio

Aluminum

2.7

660

2470

205

68

0.36

Copper

8.96

1085

2562

385

0.33

0.35


2. Experiment

Figure 2 shows the schematic of the experimental setup. The laser source used in the experiment is an ytterbium pulsed fiber laser (IPG-YLPM, IPG photonics, Southbridge, Massachusetts USA). The specification of the laser source is indicated in Table 2. The welding experiment of Al and Cu are conducted in two overlap configurations of Al/Cu and Cu/Al. The laser power for the experiment varies according to the welding configuration. Firstly, preliminary experiments are performed on both welding configurations. After the preliminary experiments, the variation of the laser power for the investigation is set. The selection of laser power range for each welding configuration is done based on the weldability. The laser power range is from the lowest laser power required to form a joint between materials. The variation of the laser power for each weld are shown in Table 3. Besides, the wobbling technique is applied in this study as it has been proved to enhance the weld quality in literature [31], [32]. The thin sheets of Al and copper having thickness of 0.27∽0.3 mm has been employed as welding specimens in the experiment. The welds are conducted in overlap configuration with the dimension shown in Fig. 2b).

The observation of the welded specimen is firstly implemented with a Dino-lite microscope for top and bottom view. Next, Scanning Electron Microscope (SEM) is employed for further observing the microstructure of the weld in cross-section view. To identify mechanical properties, hardness in the weld zone is measured with Vickers hardness measurement, while a shear strength test is applied for the welded specimen to evaluate the mechanical strength of the weld.

  
Table 2

Specifications of the laser source

Laser type

Pulsed fiber laser

Maximum laser power

300 W

Wavelength

1064 nm

Pulse duration

20 ns

Spot size

40\({\mu }\text{m}\)

Frequency

2000 kHz

Welding speed

5 mm/s

 

Table 3

Laser power and wobbling specification

Configuration

Laser power range (W)

Wobbling

Amplitude (mm)

Frequency (kHz)

Al/Cu

80–160

0.5

100

Cu/Al

180–260


3. Result And Discussion

3.1 Microstructure

The morphology of the top and bottom surface of the weld in both configurations are observed and shown in Fig. 3. In the weld of Al/Cu, the top surface reveals a clean weld surface without visible spatters on the weld surface. In contrast, a visible heat-affected zone tends to enlarge at the end of the welding line in the weld of Cu/Al. From the bottom view, heat-affected evidence is visible from the laser power of 120 W when Al is on top of Cu. Meanwhile, in the weld of Cu/Al, full penetration can be observed from the laser power of 180 W. Overall, with the growth of the visible defect on the bottom view as the laser power increases, one can be withdrawn that the penetration increases with increasing laser power.

Figure 4 exhibits the observation of cross-section view in both welds of Al/Cu and Cu/Al. In the case of Al/Cu, the observation result demonstrates an increase of penetration depth when laser power increases. Moreover, dense porosities are observed at the laser power of 140 W and 160 W mainly in the upper material (Al). At the laser power of 140 W, porosities are found to lie on the interface line of the welded materials, while pores are formed around visible cracks initiated from the Al material when laser power of 160 W is used. In the case of Cu/Al weld, the cross-section reveals fluctuated weld surface as well as loss of material in the weld zone. As the laser power increases, the loss of material rises. A reliable explanation for this is the high reflectance of Cu [36] together with high energy input (i.e., laser power). Besides, porosities are also detected mainly in the Al side.

The microstructure of the interface in the weld of Al/Cu and Cu/Al is shown in Fig. 5. In both welds, the dendritic structure is observed to form and expand towards the Al side. The chemical composition of the dendritic structure has been examined and shown in Table 4. The result reveals that the dendritic structure reveals the structure for the IMCs of Al2Cu. Meanwhile, a thicker layer of dendritic structure can be detected in the case of Al on top in comparison with the weld of Cu/Al. To understand the behaviour of microstructures in the weld zone Kirkendall effect has been considered [37]. A reliable explanation for the expansion of dendritic structure into the Al side relates to the phenomenon of the Kirkendall effect which is demonstrated by Smigelskas and Kirkendall [37]. The Kirkendall effect expresses the motion of the interface between two metals due to the difference in the diffusion rate of the metal atoms. The illustration for the effect is indicated in Fig. 6. During the welding process, the atoms of Al and Cu start to diffuse to each other. The diffusion rate of Cu is generally five times higher than that of Al, and the diffusion rate of Cu is linearly proportional to temperature shown in Fig. 6(a) [38]. The interdiffusion of Al and Cu leads to the formation of Al-Cu intermetallic compounds shown in Fig. 6 (b). Together with the low diffusion rate of Al, the spread of IMCs will tend to be on the Al side shown in Fig. 6(c).  

 Table 4
 Chemical composition on the cross-section of the points in  Figure 5.

Point

Al (at%)

Cu (at%)

Possible phase

1

61.16

38.84

Al2Cu

2

83.88

16.12

Al + IMCs

3

87.52

12.48

Al + IMCs

4

69.86

30.14

Al2Cu

5

83.65

16.35

Al + IMCs

6

89.55

10.45

Al + IMCs

3.2 Mechanical properties

a. Hardness profile

Vickers hardness measurement is conducted vertically in the cross-section of the weld from the upper material to the lower material. The hardness measurement of the weld of Al/Cu is shown in Fig. 7. Within the upper material (Al) in the weld configuration of Al/Cu, the hardness increases as the distance is close to interface. Meanwhile, the hardness distribution in the weld with the laser power of 80 W remains similar to the base materials (Al: 60 HV, Cu: 117 HV). At the laser power of 100 W, a sharp increase of hardness takes place at the interface. Meanwhile, a significant rise in hardness happens at the distance of 50 \({\mu }\text{m}\) from the interface when the laser powers of 120 W, 140 W, and 160 W are used. In other words, the peak hardness at each laser power shifts towards the Al side when the laser power increases. Furthermore, with the increment of the laser power, the peak hardness of individual laser power rises. In particular, the maximum hardness at the laser power of 100 W and 120 W are 625.9 HV and 880 HV, respectively. Meanwhile, the peak hardness obtained at the laser power of 140 W is 890 HV and at the laser power of 160 W is 995.7 HV. In the lower material (Cu), the hardness decreases significantly at the distance of 50 \({\mu }\text{m}\) and 100 \({\mu }\text{m}\) from the interface. From the distance of 150 \({\mu }\text{m}\) towards the bottom, there is an insignificant variation of the hardness among different laser powers.

Figure 8 indicates the hardness profile of the weld with Cu on top of Al. Overall, the material surrounding the interface is reported with high hardness. Within the upper material (Cu) at all laser powers, hardness increases as the distance is close to the interface. Peak hardness values at the laser power of 180 W and 200 W are measured at the interface of Al and Cu. Meanwhile, the maximum hardness values at the laser power of 220 W and 240 W are detected in the Al side at the distance of 50 \({\mu }\text{m}\) and 100 \({\mu }\text{m}\) from the interface, respectively. On the Al side, it is noticed that the high hardness zone expands together with the increase of the laser power. In particular, at the laser power of 200 W, the material with the hardness exceeding 300 HV remains till the distance of 50 \({\mu }\text{m}\) from the interface. In comparison, at the laser power of 220 W and 240 W, the high hardness zone remains within the distances of 200 \({\mu }\text{m}\) and 250 \({\mu }\text{m}\) from the interface, respectively.

b. Mechanical strength

The mechanical strength of the weld is evaluated by the shear strength test. Figure 9 expresses the ultimate loading forces of each weld according to laser powers. It is clear that the weld of Al/Cu achieves higher weld strength than the weld of Cu/Al. Furthermore, an optimal laser power at which the maximum mechanical strength can be achieved is also recognized in both cases. In particular, in the weld of Al/Cu, the weld attains the average shear loading force of 246.82 N at the laser power of 80 W. The low strength of the weld with the laser power of 80 W can be explained by the lack of penetration in the weld. The ultimate loading force of 297.59 N which is higher than the shear strength of base Al (260 N) and lower than the strength of base Cu (490 N) is recorded at the weld with the laser power of 100 W. As for laser power of 120 W, 140 W, and 160 W, the recorded loading forces declines, respectively. The downturn of the shear strength of the weld when the laser power increase is related to the increase of the IMCs formation in the weld. As shown in Fig. 10, the intermixture of Al and Cu in the interface of the weld Al/Cu increases with the increase of laser power.

When the weld is conducted with the configuration of Cu/Al, the shear strength of the weld is obtained with a similar tendency as in the weld of Al/Cu with the given laser power range. At the laser power of 180 W, the average ultimate loading force recorded is 64.85 N. When the weld is conducted with the laser power of 200 W, the average strength reaches 83.8 N. Afterward, the average of the ultimate loading force reduces as the laser power increases. The lowest strength of the weld is found at the laser power of 260 W with the average loads that the weld can endure is 57.64 N. It is important to note that the explanation for the reduction of the weld strength in Cu/Al welds relies on the loss of the weld metal in the weld zone due to evaporation. As shown in Fig. 4, the loss of the weld metal in the cross-section view increases as the laser power increases. The loss of the weld metal will weaken the connection strength.

Moreover, the fracture behavior of Al/Cu and Cu/Al welds are significantly different. Figure 11 demonstrates the shear strength test result for the weld of Al/Cu and Cu/Al with the presence of elongation. Overall, the weld of Al/Cu results in a longer elongation before it fractures than the weld of Cu/Al. Moreover, the fracture of most of the weld in the configuration of Cu/Al happens at the ultimate load points, while there is elongation after the ultimate load in the case of Al/Cu weld. In short, the weld of Al/Cu is more ductile than the weld of Cu/Al.

4. Conclusion

In this study, the weld of dissimilar metals of Al and Cu is performed with the use of a pulsed fiber laser. Using the pulsed wave laser provides many benefits for joining heat-sensitive components due to concentrated laser beam and short pulse duration which leads to less interaction time. In the present study, the welding result is evaluated through microstructure observation and mechanical behavior. Overall, the weld of Al/Cu required less laser energy to be welded (e.g., laser power). The weld with Al on top also reveals significant beneficial characteristics in comparison with the weld of Cu/Al. Through the study, several considerations can be concluded as follows:

- The formation of Al2Cu with dendritic structure expands towards Al in both cases of Al on top and Cu on top. This occurs due to the difference in the diffusion rate of the base metals explained by the Kirkendall effect.

- The weld metal on the aluminum side is obtained with higher hardness than that on the Cu side. Cu/Al weld produces a deeper extension of high-hardness weld metal in Al side than Al/Cu weld.

- With the given welding condition, the highest shear strength of the weld Al/Cu and Cu/Al are obtained at the laser power of 100 W and 200 W, respectively. Meanwhile, Al/Cu weld has higher strength and more ductile than the weld of Cu/Al.

Overall, a clear comparison between two welding configurations for dissimilar metals of Al and Cu has been clarified in the study. However, to have a further understanding of the interaction of the pulsed fiber laser to Al and Cu, another study will be conducted aiming at investigating the microstructure characteristics of the joints. Thus, the relationship between the microstructure of the joint and its effect on mechanical behavior can be established.

Declarations

Acknowledgment

The research described herein was sponsored by the National Research Foundation of Korea (NRF) grant funded by the Korean government (MSIP; Ministry of Science, ICT, and Future Planning) (No. 2019R1A2C1089644) and by the KOREA INNOVATION FOUNDATION grant funded by the Korea government (MSIP) (No. 2020-DD-SB-0159). 

The opinions expressed in this paper are those of the authors and do not necessarily reflect the views of the sponsors.

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