**3. Joining of Mg to steel: state of the art**

In recent years, numerous techniques have been applied to bond Mg alloys to various grades of steels. These techniques can be broadly classified into solid-state joining (friction stir welding, ultrasonic spot welding, diffusion-welding processes) and fusion welding (resistance spot welding, laser welding brazing, laser hybrid welding, and arc welding). Review of the literature reveals that metallurgical bonding along the Mg/ steel interface can be achieved with addition of suitable interlayers (which possess a substantial solid solubility in both Mg and Fe) or inter-diffusion of the alloying element from the BM. Therefore, the joint quality is significantly influenced by the interlayer characteristics (forms, thickness, and compositions). Among the joining techniques, a variety of thin interlayers such as Zn, Cu, Al, Ni, Sn, Cu-Zn, and Ag has been reported to improve the interfacial reaction between magnesium alloys and steel. In this section, the potential of several methods for joining magnesium and steel will be discussed.

#### **3.1 Solid-state joining processes**

Solid-state joining technology has been applied to bond Mg alloys to steel and get high-quality joints than fusion-welding processes because of the added advantage of minimal oxidation because of the solid-state nature of the process. Solid-state joining processes, such as friction stir welding (FSW), ultrasonic spot welding (USW), and diffusion and eutectic bonding, have been used to join Mg alloys to steel. Generally, for solid-state bonded Mg alloys-interlayer-steel joints, the joint performance is influenced by the intimate contact between the dissimilar materials, and the microstructure, particularly the formation of IMCs [55, 56].

#### *3.1.1 Friction stir welding (FSW)*

FSW is a solid-state welding technique invented by Thomas et al. [57]. The combined action of pressure and stirring during the FSW led to mutual diffusion of the alloying elements from the BM, which promoted metallurgical bonding at the interface and improved the joint performance. Some of the unique advantages of FSW include low distortion and residual stresses due to low heat input and absence of melting, filler metal is not required and the heat efficiency is very high relative to traditional fusion-welding processes [58, 59]. Joining Mg alloys to steel by FSW has been extensively studied.

Watanabe et al. [60, 61] investigated the weldability of AZ31 Mg alloy to uncoated SS400 steel joints by FSW. Under optimum joining condition (0.1 mm tool pin offset toward steel plate, 1250 rpm pin rotation speed, and welding speed of 100 mm/ min), a joint with maximum strength of about 70% of the Mg BM was obtained. The low joint strength was associated with insufficient plasticization and presence of steel fragments in the Mg matrix. Considerable number of authors observed that the presence of zinc coating on the steel surface played an important role in the bond formation between the Mg alloys and steel [21, 27, 56, 62, 63]. For instance, Schneider et al. [63] and Jana et al. [27] joined AZ31B alloy to Zn-coated steel by FSW. It was found that the Zn coating enhanced the bondability of the Mg alloy/steel. The authors noted that the strength of the FSW welded AZ31B/galvanized steel was significantly superior to that of AZ31B/uncoated steel. The presence of Zn coating promoted the formation of liquid low melting Mg-Zn eutectic products at the interface. The liquid products, broken oxides, and other contaminants were forced out of the joining interface by the high pressure produced by the tool, exposing the fresh interfaces. As a result, mutual diffusion between magnesium alloy and steel was achieved.

Friction stir spot welding (FSSW) a variant of FSW, has also been used to join Mg alloys to steel. Liyanage et al. [29] joined AM60 to DP600 dual-phase steel by FSSW, and the welds showed no evidence of intermetallic formation. They reported that a Zn layer on DP600 steel resulted in melted eutectic material (αMg + MgZn) and cracking in the joints. The feasibility of joining 3 mm thick AZ31 Mg alloy to 1 mm 302 stainless steel by FSW was also reported [64]. The results showed that the combined action of pressure and stirring led to mutual diffusion of the alloying elements from the BM at

### *Challenges and Advances in Welding and Joining Magnesium Alloy to Steel DOI: http://dx.doi.org/10.5772/intechopen.101862*

the interface. Under optimum condition, the joints shear strength reached a maximum of 96.3 MPa. However, void and microtype defects at the interface were observed.

Joo et al. [65] reported that an acceptable AZ31B/SS400 steel joints with higher strength, sufficient material flow and tool wear reduction were obtained using hybrid gas tungsten arc welding (GTA) and friction stir welding. The tensile strength of the hybrid friction stir welds increased to 237 MPa about 91% of the Mg BM, compared to 226 MPa for conventional friction stir welds.

The prior research proved that refill friction stir spot welding (RFSSW) has many advantages for joining of Mg alloys/steel dissimilar welds [48, 66, 67]. Zhang et al. [67] joined 3 mm AZ31B to 1 mm galvanized steel joints by friction stir keyholeless spot welding (FSKSW) and reported that the stacking sequence of the workpieces played a significant role in determining the mechanical properties. Under optimum joining condition, the maximum joint strength of 8.7 kN was achieved. Furthermore, 1.53 mm ZEK100 Mg alloy was welded to 1 mm Zn-coated DP600 steel with 10 μm Zn coating by RFSSW [66]. The authors observed that the sleeve did not plunge into the bottom steel. A thin interfacial layer with thickness of <100 nm identified as FeAl2 by TEM was observed at the interface, which accommodates bonding between the immiscible Mg and Fe and appeared to have originated from Zn-based galvanized coating on steel. Under optimum process parameters (tool speed of 1800 rpm, welding time of 3.0 s, and penetration into the upper ZEK100 of 1.5 mm), the joints shear strength of 4.7 kN was achieved.

However, numerous studies focused on characterizing the Mg alloys to steel joints under dynamic loading condition [20, 48, 68]. For example, the fatigue behavior of FSW-produced by AZ31 and two types of Zn-coated steels (HSLA steel or mild steel (MS)) lap joints has been investigated [20]. It was found that the performance of friction stir welded joints under fatigue load is limited due to 'hook'-like features formed along the magnesium/steel interface, which act as stress raisers. Uematsu et al. [68] investigated the static and dynamic behavior of dissimilar lap joining of 2 mm AZ31 Mg alloy to 2 mm cold-rolled low carbon steel by FSSW. The results showed that fatigue crack grew through the interface, regardless of load levels. The authors noted that the effective nugget size could be the controlling factor of the fatigue strengths of dissimilar welds, and it is essential to increase the effective nugget size to improve the fatigue performance of dissimilar welds. Shen et al. [48] compared the static and dynamic behavior of 1.5 mm ZEK100 Mg alloy/0.9 mm galvanized DP600 steel dissimilar spot welds to Mg/Mg similar welds produced by RFSSW. It was observed that the static and dynamic behaviors of the magnesium/steel welds were superior to that of Mg/Mg similar spot welds. The higher joint performance observed for Mg to Zn-coated steel was associated with an increase in effective bonded area, compared to Mg/Mg spot welds due to the presence of displayed Zn-coated layer. Furthermore, the analysis of the dynamic behavior of the Mg alloys to galvanized steel joints revealed that the Zn brazing quality directly influences the fatigue life. Therefore, optimization of the welding parameters to facilitate this brazing to magnesium is necessary [48].

Comparison of the Mg alloys/steel joints maximum tensile shear strength produced by FSW and FSSW are shown in **Table 1**. In FSW welding, prior studies placed Mg alloys as the top sheet while the tool plunge depth was carefully controlled to avoid contacting the steel tool to the bottom ferrous substrate. However, this arrangement resulted in a low joint strength [64]. Interestingly, with recent RFSSW, the sleeve did not lunge into the bottom steel, which significantly increased the effective bond area and improved the joints performance [66–71]. During FSW and FSSW, the processing heads impose size and shape limitation, the process is best used with long and straight welds, and keeping the interlayer at the interface between the steel

and Mg alloy is very difficult due to the stirring action of the pin and material flow with high plasticity along the interface. Thus, limited the wide range of application of these techniques in industries [48, 72]. The comparison of the joint properties reveals that good static weld strength can be obtained between magnesium alloys to galvanized steel by a diffusion and braze-bonding mechanism [48, 66]. Most studies focused on using Zn interlayer, and there is a need to experiment with other interlayers. Furthermore, no study focused on the corrosion behavior of the joined parts.


#### **Table 1.**

*Comparison of the Mg alloys/steel joints maximum tensile shear strength produced by FSW and FSSW.*

*Challenges and Advances in Welding and Joining Magnesium Alloy to Steel DOI: http://dx.doi.org/10.5772/intechopen.101862*

### *3.1.2 Ultrasonic spot welding (USW)*

USW is also a solid-state welding technique that generates coalescence through a concurrent application of localized high-frequency vibratory energy and slight clamping force [73]. At present, the research conducted on joining magnesium alloys to steel using USW is limited.

Santella [74, 75] joined 1.6 mm thick AZ31B-H24 to 0.8 mm HDG mild steel by USW. The authors noted that the presence of Zn improved the bonding mechanism, but the Mg-Zn phases were completely squeezed from the spot weld and only thin Al5Fe5 phase was formed at the interface. Under optimum welding parameters, a joint with maximum lap shear strength of 4.2 kN was achieved. In another related study, Patel et al. [73] also noted that Mg and Zn combined to form Mg-Zn IMCs, while Fe and Zn combined to form a solid solution to create the weld joint. The results of these studies could suggest that no melting on the steel side occurs during USW. In comparison, Patel et al. [76] observed that the shear strength of the magnesium alloy/bare steel with the addition of Sn interlayer was higher than that of magnesium alloy/bare steel and magnesium alloy/galvanized steel joints, due to the solid solutions of Sn formed with magnesium and iron, as well as Sn and Mg2Sn eutectic.

On the other hand, it was demonstrated that corrosion could impair the mechanical performance of Mg alloy/steel USW joints [46]. However, the details of corrosion mechanisms required further study.

**Table 2** compares maximum tensile shear strength of the Mg alloys/steel joints produced by USW. The USW techniques involved the use of an interlayer to achieve interfacial reactions. The highest joint strength (about 88% of Mg/Mg ultrasonic spot weld) was obtained using Sn interlayer due to the solid solutions of Sn formed with magnesium and iron, as well as Sn and Mg2Sn eutectic structure. Therefore, using Sn interlayer resulted in better joining mechanism and mechanical performance and is thus more suitable [76]. Thus, choosing of suitable interlayer is essential for successful joining. The possibility of using different transition materials should be explored. Furthermore, studies on dynamic and corrosion behavior of the USW joint parts should be given attention.


**Table 2.**

*Comparison of the Mg alloys/steel joints maximum tensile shear strength produced by USW.*

#### *3.1.3 Diffusion and eutectic bonding*

Diffusion methods have been used to successfully join both similar and dissimilar materials combinations, including Mg alloys/steel [37, 78]. During the diffusion process, formation of uniform and thin IMC along the Mg alloy/steel interface is the key for successful bonding. The number of research suggested that interfacial bonding could be achieved by either addition of interlayer or some alloying elements in the Mg BM. The benefits of using Cu [78–80], Ni [37, 80], and Ag [44, 81] interlayers during diffusion bonding of Mg alloy/steel have been demonstrated.

Tachibana et al. [82] studied the influence of the Zn insert on the bondability of Mg/steel lap joints. It was found that the AZ31 and cold-rolled steel plate (SPCC) could not bond due to the oxide films formed on the AZ31 that prevented the bonding, while AZ31/Zn-coated steel (GI) was bonded successfully. The presence of zinc coating enhanced the bondability of Mg alloy/steel and removed the oxide films on AZ31. The weldability of 5 mm AZ31 Mg alloy to 1 mm thick 316 L steel joints using a diffusion brazing process with addition of Cu and Ni interlayers was also reported [37, 79, 80, 83]. Solid-state diffusion of the interlayer into the magnesium alloy, eutectic formation, and the formation of ternary IMCs was observed at the joint interface. The interfacial reaction was intense in the liquid state, inducing the excessive formation of brittle and thick IMC layers, which was detrimental to the joint strength. The maximum joint strength of 57 MPa (69% of that of AZ31 BM) with Cu interlayer was obtained compared to 32 MPa for Ni added joints. The high interfacial bond obtained for Cu-added joint was associated with confined intermetallics at the bonded interface compared to dispersed intermetallics for Ni added joint [80].

Some authors focused on bonding magnesium alloys to steel using reactive transient liquid phase bonding (rTLP) to improve the joints strength between dissimilar metals. During the rTPL process, eutectic melting and subsequent isothermal solidification occurred between the interlayer and the magnesium, while the formation of a thin continuous layer between the melt and the steels resulted in interfacial bonding of the steel with the magnesium substrate [44, 81]. The bondability of AZ31 to low carbon steel with the addition of Ag interlayer using rTPL process showed that isothermal solidification of the eutectic melt was formed at the Mg alloy side through the diffusion of Ag into the magnesium BM. Thin and uniform Fe2Al5 layer was observed at the steel side, which significantly improved the joint strength to 201 MPa [44, 81]. In contrast, coarse, non-uniform IMC intermittently formed at the interface without Ag interlayer, which deteriorates the joint performance.

**Table 3** gives a comparison of the Mg alloys/steel joints maximum tensile shear strength produced by diffusion and eutectic bonding. The literature reveals that the interlayer material has significant influence on the bondability of the Mg alloys to steel by diffusion and eutectic bonding process. The use of Cu, Ni, and Ag as intermediate elements has been studied. The major challenge associated with this technique is that the formation of ternary IMCs which could not be controlled and have detrimental effects on the joint performance [80]. A comparison of the joints strength shows that excellent static strength of Mg/steel joints has been achieved using rTPL techniques, even surpassing that of AZ31B Mg alloy BM with addition of Ag interlayer [44]. The rTPL unique qualities of short process time, coupled with forming a thin and continuous intermediate layer through the formation of a transient liquid interlayer, were responsible for the high joint performance obtained. The possibility of improving the joint performance using more interlayers should be explored.

*Challenges and Advances in Welding and Joining Magnesium Alloy to Steel DOI: http://dx.doi.org/10.5772/intechopen.101862*


#### **Table 3.**

*Comparison of the Mg alloys/steel joints maximum tensile shear strength produced by diffusion and eutectic bonding.*

#### **3.2 Fusion-welding processes**

Fusion welding involves joining the surface of the materials through melting and solidification to produce the bonding. Fusion-welding technologies based on resistance spot welding [4, 32, 84–86] laser braze [41, 43, 87–92], laser hybrid [33, 35, 36, 38–40, 47, 93–98] and arc welding [72, 99–102] have been investigated for joining magnesium alloys to steels. In general, the insertion of an interlayer or mutual diffusion of alloying elements from the BM has been adopted to improve interfacial bonding. The addition of suitable interlayer improves the spreadability and the nucleation of magnesium on steel.

### *3.2.1 Resistance spot welding (RSW)*

RSW is the most widely used welding technology in the auto industry [103] due its low cost, high speed, ease of operation, and automation [17, 32, 86]. Despite the inherent advantages of RSW, very limited work has been published in joining Mg alloy to steel. This include AZ31B Mg alloy/Zn-coated DP600 steel [32], AZ31 Mg alloy/ HDG steel with pre-coated nanoscale Fe2Al5 layer [34], AZ31B-H24 Mg alloy/HDG HSLA steel [4], AZ31B Mg alloy/HDG HSLA steel [84] and AZ31B Mg alloy/electrogalvanized DP600 steel [86].

Most of the works focused on joining magnesium alloys to galvanized steel. Liu and his co-workers developed a novel technique (asymmetric electrode) to lap weld 1.5 mm AZ31B to 1.2 mm HDG DP600 steel successfully by RSW [32]. It was found that the Zn interlayer was squeezed out of the bond region producing deal condition for intimate contact of fresh Mg and steel surfaces. The joining mechanism consisted of braze welding, solid-state bonding, and soldering. Under optimum parameters, a joint with tensile shear strength of 5.0 kN was obtained. Xu et al. [4] compared the microstructure and

mechanical performance of AZ31B to HDG HSLA steel joints by RSW and weld-bonding (WB), which combines the RSW and adhesive bonding. It was found that the peak shear load and energy absorption of the weld-bonded magnesium to steel joints were higher than that of resistance spot welded magnesium to steel joints. In another similar study, AZ31B was joined to HDG HSLA steel by RSW under dynamic loading [84]. It was found that the microstructure of the Mg/steel spot welds was different from that of Mg/Mg spot welds, but owing to similar crack propagation and failure mode, both welds had an equivalent fatigue resistance. Interestingly, Feng et al. [86] joined AZ31 to electro-galvanized DP600 steel by RSW process with and without HDG Q235 interlayer. Contrary to the previous studies [4, 32, 84] that used hot-dip Zn coating, the thin and compact features of electro-galvanized zinc layer prevented the zinc-coated layer on the steel to be squeezed out of the nugget. However, with insertion of HDG Q235 interlayer, the zinc-coated layer was squeezed out of the nugget and a peripheral soldered region was formed during the welding process, which significantly improved the joint tensile shear load from 4.14 kN to 5.49 kN. The feasibility of joining AZ31B Mg alloy to DP600 steel via pre-coated nano-scaled Fe2Al5 interlayer was also investigated [34]. The analysis of the interface characteristics revealed that metallurgical bonding was achieved due to the formation of the semi-coherent interfaces of Mg/Fe2Al5/Fe with well matching lattice.

However, RSW of Mg alloy to stainless steel is more challenging because of the absence of any Zn coating. However, Mg alloy to stainless steel joints has been reported [85, 104]. Min et al. [104] investigated the 0.4-mm thick AZ31B sheets, and 0.4-mm thick 443 ferritic stainless steel welded joints using the RSW with 443 ferritic stainless steel cover plates. It was found that Fe-Al IMC layer was formed at the interface, and the molten Mg could wet the surface of the interface layer. However, cracking was observed in the nugget. The crack was associated with the possible thermal behavior of various elements in the nugget during spot-welding process. Recently, Manladan [85] compared the microstructure and mechanical performance of 1.5 mm thick AZ31 Mg alloy/0.7 mm thick 316 L austenitic stainless steel joints by RSW and resistant element welding (REW). In comparison with two-zone FZ, consisting of peripheral FZ on the ASS side and main FZ observed for REW, the RSW joints were produced through welding-brazing mode, in which the Mg alloy melted and spread on the solid steel, forming the nugget only on the Mg side. The RSW produced the weak joint with a peak load of 2.23 kN and energy absorption of 1.14 J, whereas REW produced the strong joint with a peak load of 3.71 kN and energy absorption of 10.2 J.

Generally, in the RSW process of Mg alloys, large electric currents are always needed due to its high electrical and thermal conductivity, which commonly results in expulsion and electrode stick. In addition, RSW created only a localized joint, which may not be particularly strong [105].

A comparison of the Mg alloys/steel joints maximum tensile shear strength produced by RSW is shown in **Table 4**. It can be seen that limited research has been conducted on magnesium alloys/steel. The presence of zinc layer was crucial for successful welding of magnesium to steel. The predominant failure mode observed is interfacial (IF). This is the kind of failure mode commonly observed when conducting tensile shear tests on spot welds, in which the crack propagates through the nugget. A comparison of the joints performance shows that good static strength has been achieved, almost 95% Mg/Mg spot joint strength by RSW [32]. However, the research on the fatigue performance of Mg/steel dissimilar welds is still at its infancy due to the special geometry of the spot welds; it is hard to predict the crack initiation and propagation rate as reported by Liu et al. [84]. Among the RSW techniques, weld bonding produced the joint with highest mechanical resistance with joint failure on the Mg

*Challenges and Advances in Welding and Joining Magnesium Alloy to Steel DOI: http://dx.doi.org/10.5772/intechopen.101862*


#### **Table 4.**

*Comparison of the Mg alloys/steel joints maximum tensile shear strength produced by RSW.*

BM. Weld-bonding joining techniques has the advantages of low manufacturing costs, higher static and fatigue performance, and improved corrosion resistance [106, 107].

#### *3.2.2 Laser beam welding*

Laser beam welding presents a viable option for welding Mg alloys to steel due to its versatility, high specific heat input, and flexibility [55, 108–111]. Although fusion welding resulted in severe vaporization of Mg alloy at typical welding temperatures, the selection of optimum welding conditions is crucial for successful joining. Therefore, to control the severe vaporization of Mg, considerable number of authors concentrated on laser welding brazing and laser hybrid techniques.

Laser welding brazing (LWB) techniques offered additional advantages such as increased flexibility and adoptability when welding dissimilar metals [28, 91, 92, 112, 113]. To this end, LWB technique is suitable for joining dissimilar materials having large differences in melting points such as Mg/Ti [18, 114–116], Al/Ti [117], and Al/steel [118, 119]. In particular, welding of magnesium alloys to steel by LWB process was achieved with addition of third material or mutual diffusion of alloying elements. Thin interlayers such as Al [28, 120, 121], Ni [90, 113], Sn [31], Zn [41, 42, 87, 88, 91], and Fe-Al [41], have been used to improve the interfacial bonding between the immiscible Mg and Fe. Miao demonstrated the feasibility of joining 2.4-mm AZ31B Mg alloy to 1.7 mm Q235 steel by laser welding brazing process using high power CO2 laser without welding wire [122–124]. The analysis of the interface characteristics revealed that transition layer consisted mainly of IMCs, and metal oxides were observed at the interface. The compounds were identified by TEM as Al-rich phases, such as Mg17Al12, Mg2Al3, FeAl, and Fe4Al13 [124]. Although tensile strength of the butt joints could reach 182 MPa (81% of Mg alloy BM), but severe oxidation and vaporization of the magnesium alloy, coupled with immiscibility between magnesium and iron, led to weld defects such as spatters and porosity.

Therefore, to address the severe vaporization of the Mg, laser brazing or laser welding brazing with magnesium-based filler wire was proposed [28]. The benefits of using Al-12Si [28], Ni [113], Sn [31], and Zn [42] as transition material between Mg alloy to steel were explored by Nasiri and co-workers. It was found that the presence of the interlayer significantly improved the spreadability of the liquid magnesiumbased filler on steel surface but deteriorated the joint performance because of the weak bonding of IMCs products formed along the interface.

However, several authors observed mutual diffusion of alloying elements when joining Mg alloys to different grades of stainless steel [92, 125, 126]. For instance, [92] compared the joint performance of lap welded 1.5 mm-AZ31B/1.5 mm-mild steel (MS) joints and 1.5 mm-AZ31B/1.5 mm 201 stainless steel (SS) joints produced by LWB. Mechanical bonding was observed for Mg alloy to MS joints, whereas for Mg alloy to SS joints, thin reaction layer identified as FeAl by TEM as shown in **Figure 1**. The Al diffusion from magnesium BM to the interface was accelerated by

**Figure 1.** *Mg/201 stainless steel interface characteristics [73].*

### *Challenges and Advances in Welding and Joining Magnesium Alloy to Steel DOI: http://dx.doi.org/10.5772/intechopen.101862*

chemical potential induced by alloying elements of Cr and Ni was responsible for the interfacial reaction layer obtained.

A comparison of the Mg alloys/steel joints maximum tensile shear strength produced by LWB is shown in **Table 5**. The selection of suitable interlayer is crucial for successful bonding. For instance, using Ni and Sn interlayers, which led to formation of the Fe(Ni) and Al8Mn5-Fe(Al) reaction products along the α-Mg-Fe interface, respectively, resulted in formation of strong interfaces with low mismatch strain energy and strong bonds. Therefore, using both Ni and Sn interlayers is recommended for dissimilar joining of steel sheet to magnesium sheet. Furthermore, the diffusion of the alloying elements in BM and the bonding mechanism were extensively studied. A comparison of the joints properties reveals that relatively good static strength of magnesium alloy to steel joints has been obtained [126]. However, the behavior of the Mg alloys/steel joint under dynamic loading is yet to be explored. Among the LWB techniques, dual-beam mode with flux produced joint with an excellent mechanical resistance. To further enhance the reliability of the joint and improve its performance, the possibility of using different interlayers should be explored.

The excessive evaporation of magnesium during fusion welding can be overcome through the method of TIG-assisted laser process [33]. Generally, the addition of TIG could improve absorption of laser power and penetration of molten pool. During laser-TIG process, the TIG torch melts the magnesium, whereas, the laser is used to create deep penetration into the steel [36, 39]. Several authors reported that conventional fusion-welding technology such as TIG or laser welding alone could not be competent for joining of magnesium to steel [33, 89, 94]. For instance, [33, 89] demonstrated during TIG welding of Mg alloy to steel with higher heat input, either the magnesium alloys melt but the steel remained in solid state or the steel melt while blowholes formed in the magnesium alloys. In both cases, the bonding between the immiscible couple could not be obtained. Similarly, for conventional laser-welded magnesium alloys to steel joints, the immiscible materials could be joined with poor weld appearance and poor strength, coupled with large amount of electricity consumed by laser due to low absorptivity of magnesium alloys at room temperature [127]. For TIG-assisted laser process, the reflectivity of the magnesium to laser was reduced and thus the absorption of laser beam improved, creating a deeper penetration in the steel [33, 35, 128]. Consequently, laser-TIG process offers great potential for improving the joint performance for both similar and dissimilar metal welding [33, 39, 40, 89, 129, 130].

Like other joining techniques, interfacial bonding between magnesium alloy to steel could be achieved by insertion of third material or mutual diffusion of alloying elements from the BM [95]. Therefore, the benefits of using Cu [35, 39, 40], Ni [35, 36, 40, 93, 96], Sn [94], Zn [89], Cu-Zn [40, 97] to bond magnesium to steel had been extensively studied. These interlayers formed Mg2X IMC (where X is the interlayer elements) and a solid solution of interlayer in iron along the joint interface, which consequently enhanced the joints mechanical strength [40].

Liu examined the weldability of AZ31B/304 SS by laser-GTA process. A transitional zone consisting of Mg-Fe and magnesium diffusion into the matrix of iron in the form of oxide was observed at the interface. The formation of the complex MgO, ZnO, Fe2O3, or Al2O3 oxides deteriorates the joint strength [39, 94]. Furthermore, the use of laser-TIG techniques to join AZ31B and Q235 steel with Ni, Cu, Sn, and Cu-Zn interlayers was also explored [35, 36, 38–40, 93, 94]. These interlayers were heated and melted to react with magnesium and steel, and formed a transitional layer in the FZ and solid solution along the steel side. The analysis of the strengthening



**Table 5.** *Comparison of the Mg alloys/steel joints maximum tensile shear strength produced by laser welding brazing.*
