Effect of Equal Channel Angular Pressing on the Microstructure and Mechanical Properties of an Mg–5Sn Alloy

: An Mg–5Sn alloy was processed by equal channel angular pressing (ECAP) for different passes (4P, 8P, and 12P), and the microstructure evolution and mechanical properties were investigated. The grain size, amount of Mg 2 Sn precipitates, and texture of ECAP alloys depend on the number of passes. The ECAP 8P alloy has the ﬁnest grains and largest area fraction of Mg 2 Sn particles, followed by the ECAP 12P alloy. The ECAP 4P and 8P alloys exhibit basal textures tilted towards transverse direction (TD), whereas the ECAP 12P alloy shows basal texture with the c -axis of the grains parallel to the extrusion direction (ED). ECAP alloys show superior strengths compared to the as-cast alloy, mainly attributed to ﬁne grain strengthening, precipitation strengthening, texture strengthening, and dislocation strengthening. The ultimate tensile strength (UTS) increases while the elongation (EL) decreases with increasing ECAP pass.


Introduction
The crises of global warming, environmental deterioration, and resource shortage drive the growing demand for light-weight materials [1,2]. Mg alloys are potential lightweight structural materials for applications in various industrial sectors such as rail traffic, automobiles, and aircraft due to their high specific strength, excellent damping capacity, and good castability [3][4][5]. However, the development of high-performance Mg alloys has heavily relied on rare earth (RE) elements [6,7]. The addition of RE elements boosts the cost of Mg alloys, severely limiting their application. Therefore, the development of RE-free Mg alloys is of huge significance.
Analogous to RE elements, Sn possesses a very high solubility in Mg at high temperatures, but a negligible solubility at room temperature. In addition, the Mg 2 Sn phase has a high melting temperature of 770 • C [8]. Mg-Sn alloys are deemed as promising RE-free Mg alloys by researchers and have attracted considerable research interest over the past two decades [9][10][11][12]. Nonetheless, cast Mg-Sn alloys exhibit inferior mechanical properties. Thermomechanical processing techniques have been applied to tailor the microstructure and enhance their mechanical performance. Cheng et al. investigated the influence of hot extrusion on the microstructure and mechanical properties of Mg-xSn (x = 6, 8, 10) alloys. They reported that hot-extruded alloys exhibit enhanced yield strength (YS), mainly due to grain refinement and the presence of fine Mg 2 Sn precipitates [12,13]. Zhao et al. found that the YS and UTS of hot-extruded Mg-xSn (x = 1, 3, 5, 7) alloys increase, but EL decreases with increasing Sn content [14]. The strain hardening ability of hot-extruded Mg-Sn alloys also decreases with increasing Sn content [15]. A hot-extruded Mg-5Sn alloy processed by coupling twinning, aging, and detwinning (TAD) exhibits higher strength compared to its counterpart without TAD [16].
ECAP is an effective severe plastic deformation (SPD) technique to improve the mechanical properties of metallic materials. ECAP has been broadly employed to process Mg alloys [17][18][19][20]. However, surprisingly, the effect of ECAP on the mechanical performance of Mg-Sn alloys has rarely been reported. In this work, the influence of ECAP on the microstructure and mechanical properties of an Mg-5Sn alloy was examined. The results presented in this work may provide guidance for the development of high-performance Mg-Sn alloys.

Materials and Methods
To fabricate the targeted Mg-5Sn (in weight percent, wt.%) alloy, pure Mg (99.9%) and pure Sn (99.99%) ingots were melted in a graphite crucible placed in an electric resistance furnace (Nanjing, China) and then cast in a steel mold pre-heated to 300 • C, under CO 2 (99% in volume) and SF 6 (1% in volume) mixed atmosphere. The crucible and mold were coated with zirconia before being used. To dissolve intermetallic phases in Mg-5Sn ingots, solid solution treatment was conducted at 480 • C for 12 h, followed by water quenching. Subsequently, Mg-5Sn ingots were cut into small pieces with a dimension of 20 mm × 20 mm × 45 mm by wire electrical discharge machining, which were then ECAP processed for 4, 8, and 12 passes at 390 • C. The corresponding processed ECAP pieces are denoted by ECAP 4P, ECAP 8P, and ECAP 12P alloys, respectively.
Room temperature tensile tests were performed with a CMT5105 electronic universal testing machine(Tianjin, China) with a loading rate of 0.5 mm/s. Tensile test specimens are dog-bone-shaped with a gauge size of 2 mm × 2 mm × 7 mm, as shown in Figure 1.
At least 3 samples were tested for each alloy state to render reliable results. For ECAP alloys, the tensile direction is along ED. Microstructures of specimens were characterized by X-ray diffraction (XRD, Bruker D8 DISCOVER, Bruker, MA, USA), optical microscopy (OM, Olympus BX51M, Olympus, Tokyo, Japan), and scanning electron microscopy (SEM, ZEISS G300, Zeiss, Oberkochen, Germany) equipped with electron backscatter diffractions system (EBSD) and energy dispersive spectroscopy (EDS). OM, SEM, and EBSD specimens were prepared following the procedure described in [19]. The average size and area fraction of particles in ECAP alloys were obtained with the Image-Pro Plus. EBSD data were post-processed with the Channel 5 software. All EBSD results presented in this work were obtained by using this software.
Metals 2022, 12, x FOR PEER REVIEW 2 of 10 5Sn alloy processed by coupling twinning, aging, and detwinning (TAD) exhibits higher strength compared to its counterpart without TAD [16]. ECAP is an effective severe plastic deformation (SPD) technique to improve the mechanical properties of metallic materials. ECAP has been broadly employed to process Mg alloys [17][18][19][20]. However, surprisingly, the effect of ECAP on the mechanical performance of Mg-Sn alloys has rarely been reported. In this work, the influence of ECAP on the microstructure and mechanical properties of an Mg-5Sn alloy was examined. The results presented in this work may provide guidance for the development of high-performance Mg-Sn alloys.

Materials and Methods
To fabricate the targeted Mg-5Sn (in weight percent, wt.%) alloy, pure Mg (99.9%) and pure Sn (99.99%) ingots were melted in a graphite crucible placed in an electric resistance furnace (Nanjing, China) and then cast in a steel mold pre-heated to 300 °C, under CO2 (99% in volume) and SF6 (1% in volume) mixed atmosphere. The crucible and mold were coated with zirconia before being used. To dissolve intermetallic phases in Mg-5Sn ingots, solid solution treatment was conducted at 480 °C for 12 h, followed by water quenching. Subsequently, Mg-5Sn ingots were cut into small pieces with a dimension of 20 mm × 20 mm × 45 mm by wire electrical discharge machining, which were then ECAP processed for 4, 8, and 12 passes at 390 °C. The corresponding processed ECAP pieces are denoted by ECAP 4P, ECAP 8P, and ECAP 12P alloys, respectively.
Room temperature tensile tests were performed with a CMT5105 electronic universal testing machine(Tianjin, China) with a loading rate of 0.5 mm/s. Tensile test specimens are dog-bone-shaped with a gauge size of 2 mm × 2 mm × 7 mm, as shown in Figure 1. At least 3 samples were tested for each alloy state to render reliable results. For ECAP alloys, the tensile direction is along ED. Microstructures of specimens were characterized by Xray diffraction (XRD, Bruker D8 DISCOVER, Bruker, MA, USA), optical microscopy (OM, Olympus BX51M, Olympus, Tokyo, Japan), and scanning electron microscopy (SEM, ZEISS G300, Zeiss, Oberkochen, Germany) equipped with electron backscatter diffractions system (EBSD) and energy dispersive spectroscopy (EDS). OM, SEM, and EBSD specimens were prepared following the procedure described in [19]. The average size and area fraction of particles in ECAP alloys were obtained with the Image-Pro Plus. EBSD data were post-processed with the Channel 5 software. All EBSD results presented in this work were obtained by using this software.     Figure 2 as insets. EDS was conducted to determine the composition of the intermetallic phase, the results of which are shown in Figure 3. The intermetallic phase was identified to be the Mg 2 Sn phase. XRD analysis shown in Figure 4 confirms that the as-cast Mg-5Sn alloy is composed of α-Mg and Mg 2 Sn phases. Mg 2 Sn particles in the as-cast alloy are very coarse and plate-like, with a size of around tens of microns. Mg 2 Sn particles were mostly dissolved by solid solution treatment, but a few of them remained near grain boundaries (Figure 2), consistent with previous studies [11,21]. The remaining Mg 2 Sn particles are smaller than that in the as-cast alloy. The peak for the Mg 2 Sn phase cannot be observed from the XRD results for the SS alloy shown in Figure 4. This is because of the tiny amount of Mg 2 Sn phase remaining in the SS alloy.

Microstructure Evolution
Metals 2022, 12, x FOR PEER REVIEW 3 of 10 phase are presented in Figure 2 as insets. EDS was conducted to determine the composition of the intermetallic phase, the results of which are shown in Figure 3. The intermetallic phase was identified to be the Mg2Sn phase. XRD analysis shown in Figure 4 confirms that the as-cast Mg-5Sn alloy is composed of α-Mg and Mg2Sn phases. Mg2Sn particles in the as-cast alloy are very coarse and plate-like, with a size of around tens of microns. Mg2Sn particles were mostly dissolved by solid solution treatment, but a few of them remained near grain boundaries (Figure 2), consistent with previous studies [11,21]. The remaining Mg2Sn particles are smaller than that in the as-cast alloy. The peak for the Mg2Sn phase cannot be observed from the XRD results for the SS alloy shown in Figure 4. This is because of the tiny amount of Mg2Sn phase remaining in the SS alloy.   Metals 2022, 12, x FOR PEER REVIEW 3 of 10 phase are presented in Figure 2 as insets. EDS was conducted to determine the composition of the intermetallic phase, the results of which are shown in Figure 3. The intermetallic phase was identified to be the Mg2Sn phase. XRD analysis shown in Figure 4 confirms that the as-cast Mg-5Sn alloy is composed of α-Mg and Mg2Sn phases. Mg2Sn particles in the as-cast alloy are very coarse and plate-like, with a size of around tens of microns. Mg2Sn particles were mostly dissolved by solid solution treatment, but a few of them remained near grain boundaries (Figure 2), consistent with previous studies [11,21]. The remaining Mg2Sn particles are smaller than that in the as-cast alloy. The peak for the Mg2Sn phase cannot be observed from the XRD results for the SS alloy shown in Figure 4. This is because of the tiny amount of Mg2Sn phase remaining in the SS alloy.     shows SEM micrographs of the ECAP alloys. Noticeably, numerous fine Mg2Sn precipitates exist in the ECAP alloys. They were mainly generated during ECAP by dynamic precipitation. Plastic deformation inducing dynamic precipitation is a common phenomenon in Mg-Sn-based alloys, which are aging-hardenable, as extensively reported by previous studies [11,14,22,23]. In addition, some coarse and blocky Mg2Sn particles can be observed. Recalling that a few coarse Mg2Sn particles were undissolved after solid solution treatment, it is obvious that these undissolved particles were fragmentized by ECAP and changed to be blocky-shaped. ECAP inducing the fragmentation of secondphase particles was also observed by other studies [24]. Interestingly, the size and amount of Mg2Sn particles depend on the extent of deformation. Specifically, as ECAP passes increase from 4P to 8P, the average size and area fraction of the Mg2Sn particles increase from 0.79 μm and 8.52% to 2.20 μm and 35.57%,  Figure 5 shows SEM micrographs of the ECAP alloys. Noticeably, numerous fine Mg 2 Sn precipitates exist in the ECAP alloys. They were mainly generated during ECAP by dynamic precipitation. Plastic deformation inducing dynamic precipitation is a common phenomenon in Mg-Sn-based alloys, which are aging-hardenable, as extensively reported by previous studies [11,14,22,23]. In addition, some coarse and blocky Mg 2 Sn particles can be observed. Recalling that a few coarse Mg 2 Sn particles were undissolved after solid solution treatment, it is obvious that these undissolved particles were fragmentized by ECAP and changed to be blocky-shaped. ECAP inducing the fragmentation of secondphase particles was also observed by other studies [24].  Figure 5 shows SEM micrographs of the ECAP alloys. Noticeably, numerous fine Mg2Sn precipitates exist in the ECAP alloys. They were mainly generated during ECAP by dynamic precipitation. Plastic deformation inducing dynamic precipitation is a common phenomenon in Mg-Sn-based alloys, which are aging-hardenable, as extensively reported by previous studies [11,14,22,23]. In addition, some coarse and blocky Mg2Sn particles can be observed. Recalling that a few coarse Mg2Sn particles were undissolved after solid solution treatment, it is obvious that these undissolved particles were fragmentized by ECAP and changed to be blocky-shaped. ECAP inducing the fragmentation of secondphase particles was also observed by other studies [24]. Interestingly, the size and amount of Mg2Sn particles depend on the extent of deformation. Specifically, as ECAP passes increase from 4P to 8P, the average size and area fraction of the Mg2Sn particles increase from 0.79 μm and 8.52% to 2.20 μm and 35.57%, Interestingly, the size and amount of Mg 2 Sn particles depend on the extent of deformation. Specifically, as ECAP passes increase from 4P to 8P, the average size and area fraction of the Mg 2 Sn particles increase from 0.79 µm and 8.52% to 2.20 µm and 35.57%, respectively. With the further increase in ECAP passes to 12P, the change in the average size is negligible, but the area fraction reduces slightly to 32.56%. This phenomenon can be rationalized by considering the competition between dynamic precipitation and dissolution of the Mg 2 Sn phase. Dynamic precipitation is closely related to dislocations which are potential nucleation sites for Mg 2 Sn precipitates [25]. Dissolution of the Mg 2 Sn phase depends on temperature, and higher temperatures promote dissolution. In the early stage of ECAP, the dislocation density is relatively low and dynamic precipitation is in an early stage. Therefore, Mg 2 Sn precipitates in the ECAP 4P alloy are very fine, and their distribution is sparse. As ECAP passes increase to 8P, more dislocations were accumulated in the alloy, providing more nucleation sites. Moreover, Mg 2 Sn precipitates precipitated in the early stage provide additional nucleation sites. Consequently, the sizes of the Mg 2 Sn precipitates in ECAP 8P are larger than that in the ECAP 4P alloy, and their area fraction rises sharply to 35.57%. In other words, in the cases of the ECAP 4P and 8P alloys, dynamic precipitation is dominant over dissolution of the Mg 2 Sn phase because of the abundance of Sn solute atoms in the Mg matrix and relatively low temperature. In contrast, with the further increase in ECAP passes to 12P, the actual temperature of the deformation zone is relatively high due to the heat produced by plastic deformation and friction during ECAP [26][27][28]. Meanwhile, Sn solute atoms in the Mg matrix may have been depleted after ECAP 8P. Therefore, in the case of the ECAP 12P alloy, dissolution of the Mg 2 Sn phase is dominant over dynamic precipitation due to the relatively high temperature and depletion of Sn solute atoms. The area fraction of Mg 2 Sn precipitates decreases slightly.
Inverse pole figure (IPF) maps and grain size distribution of ECAP alloys are shown in Figure 6. Grains are colored by orientation according to the color code (shown as the inset in Figure 6). Compared to the as-cast alloy, ECAP alloys show significantly refined grains, with an average grain size (AGS) of 3-5 µm. Grain refinement is due to dynamic recrystallization (DRX) during ECAP. Interestingly, AGS decreases from 4.61 to 3.03 µm as ECAP pass increases from 4P to 8P but increases to 3.95 µm with the further increase in ECAP pass to 12P. The grain growth is due to the high deformation temperature (390 • C) and the heat generated during ECAP. respectively. With the further increase in ECAP passes to 12P, the change in the average size is negligible, but the area fraction reduces slightly to 32.56%. This phenomenon can be rationalized by considering the competition between dynamic precipitation and dissolution of the Mg2Sn phase. Dynamic precipitation is closely related to dislocations which are potential nucleation sites for Mg2Sn precipitates [25]. Dissolution of the Mg2Sn phase depends on temperature, and higher temperatures promote dissolution. In the early stage of ECAP, the dislocation density is relatively low and dynamic precipitation is in an early stage. Therefore, Mg2Sn precipitates in the ECAP 4P alloy are very fine, and their distribution is sparse. As ECAP passes increase to 8P, more dislocations were accumulated in the alloy, providing more nucleation sites. Moreover, Mg2Sn precipitates precipitated in the early stage provide additional nucleation sites. Consequently, the sizes of the Mg2Sn precipitates in ECAP 8P are larger than that in the ECAP 4P alloy, and their area fraction rises sharply to 35.57%. In other words, in the cases of the ECAP 4P and 8P alloys, dynamic precipitation is dominant over dissolution of the Mg2Sn phase because of the abundance of Sn solute atoms in the Mg matrix and relatively low temperature. In contrast, with the further increase in ECAP passes to 12P, the actual temperature of the deformation zone is relatively high due to the heat produced by plastic deformation and friction during ECAP [26][27][28]. Meanwhile, Sn solute atoms in the Mg matrix may have been depleted after ECAP 8P. Therefore, in the case of the ECAP 12P alloy, dissolution of the Mg2Sn phase is dominant over dynamic precipitation due to the relatively high temperature and depletion of Sn solute atoms. The area fraction of Mg2Sn precipitates decreases slightly. Inverse pole figure (IPF) maps and grain size distribution of ECAP alloys are shown in Figure 6. Grains are colored by orientation according to the color code (shown as the inset in Figure 6). Compared to the as-cast alloy, ECAP alloys show significantly refined grains, with an average grain size (AGS) of 3-5 μm. Grain refinement is due to dynamic recrystallization (DRX) during ECAP. Interestingly, AGS decreases from 4.61 to 3.03 μm as ECAP pass increases from 4P to 8P but increases to 3.95 μm with the further increase in ECAP pass to 12P. The grain growth is due to the high deformation temperature (390 °C) and the heat generated during ECAP.    in the ECAP 4P and 8P alloys are mostly tilted towards TD, away from ED. In contrast, the c-axis of the grains in the ECAP 12P alloy is parallel to ED. In addition, texture intensities of the three alloys are different. The ECAP 4P alloy has the strongest texture intensity of 50.38, while the ECAP 8P alloy possesses the weakest texture intensity of 18.76. It has been reported that unDRXed grains have a stronger basal texture than DRXed grains [26,29,30]. Thus, it is speculated that the variation in texture intensity is related to the change in the fraction of unDRXed grains. Figure 8 shows different types of grains and their fractions in ECAP alloys. The ECAP 4P alloy has the largest frequency of unDRXed grains, followed by the ECAP 12P alloy. The variation in the frequency of unDRXed grains with ECAP passes is consistent with that of texture intensity.
Metals 2022, 12, x FOR PEER REVIEW 6 of 10 the c-axis of the grains in the ECAP 12P alloy is parallel to ED. In addition, texture intensities of the three alloys are different. The ECAP 4P alloy has the strongest texture intensity of 50.38, while the ECAP 8P alloy possesses the weakest texture intensity of 18.76. It has been reported that unDRXed grains have a stronger basal texture than DRXed grains [26,29,30]. Thus, it is speculated that the variation in texture intensity is related to the change in the fraction of unDRXed grains. Figure 8 shows different types of grains and their fractions in ECAP alloys. The ECAP 4P alloy has the largest frequency of unDRXed grains, followed by the ECAP 12P alloy. The variation in the frequency of unDRXed grains with ECAP passes is consistent with that of texture intensity.   the c-axis of the grains in the ECAP 12P alloy is parallel to ED. In addition, texture intensities of the three alloys are different. The ECAP 4P alloy has the strongest texture intensity of 50.38, while the ECAP 8P alloy possesses the weakest texture intensity of 18.76. It has been reported that unDRXed grains have a stronger basal texture than DRXed grains [26,29,30]. Thus, it is speculated that the variation in texture intensity is related to the change in the fraction of unDRXed grains. Figure 8 shows different types of grains and their fractions in ECAP alloys. The ECAP 4P alloy has the largest frequency of unDRXed grains, followed by the ECAP 12P alloy. The variation in the frequency of unDRXed grains with ECAP passes is consistent with that of texture intensity.    Figure 9 shows kernel average misorientation (KAM) maps of ECAP alloys. The ECAP 8P alloy has the lowest average KAM value of 0.363, while the ECAP 8P alloy has the largest average KAM value of 0.389. KAM value can be regarded as an indication of dislocation density in alloys. A higher KAM value indicates a higher dislocation density [19]. DRX consumes dislocations and can thus lead to a reduction in dislocation density. The lowest KAM value of the ECAP 8P alloy is associated with its highest frequency of DRXed grains. Figure 9 shows kernel average misorientation (KAM) maps of ECAP alloys. The ECAP 8P alloy has the lowest average KAM value of 0.363, while the ECAP 8P alloy has the largest average KAM value of 0.389. KAM value can be regarded as an indication of dislocation density in alloys. A higher KAM value indicates a higher dislocation density [19]. DRX consumes dislocations and can thus lead to a reduction in dislocation density. The lowest KAM value of the ECAP 8P alloy is associated with its highest frequency of DRXed grains.   Table 1. ECAP alloys possess significantly enhanced strength compared to the as-cast alloy. The strength enhancement is mainly attributed to grain refinement strengthening, precipitation strengthening, dislocation strengthening, and texture strengthening. As ECAP passes increase from 4P to 12P, the UTS increases continuously from 208 to 275 MPa. The SS alloy has the best ductility due to the absence of coarse Mg2Sn particles and dislocations.   Table 1. ECAP alloys possess significantly enhanced strength compared to the as-cast alloy. The strength enhancement is mainly attributed to grain refinement strengthening, precipitation strengthening, dislocation strengthening, and texture strengthening. As ECAP passes increase from 4P to 12P, the UTS increases continuously from 208 to 275 MPa. The SS alloy has the best ductility due to the absence of coarse Mg 2 Sn particles and dislocations. Figure 9 shows kernel average misorientation (KAM) maps of ECAP alloys. The ECAP 8P alloy has the lowest average KAM value of 0.363, while the ECAP 8P alloy has the largest average KAM value of 0.389. KAM value can be regarded as an indication of dislocation density in alloys. A higher KAM value indicates a higher dislocation density [19]. DRX consumes dislocations and can thus lead to a reduction in dislocation density. The lowest KAM value of the ECAP 8P alloy is associated with its highest frequency of DRXed grains.   Table 1. ECAP alloys possess significantly enhanced strength compared to the as-cast alloy. The strength enhancement is mainly attributed to grain refinement strengthening, precipitation strengthening, dislocation strengthening, and texture strengthening. As ECAP passes increase from 4P to 12P, the UTS increases continuously from 208 to 275 MPa. The SS alloy has the best ductility due to the absence of coarse Mg2Sn particles and dislocations.  To explain the variation in strength with ECAP passes, we need to recall the microstructure evolution during ECAP. Compared to the ECAP 4P alloy, the ECAP 8P alloy has finer grains, much higher area fraction of Mg 2 Sn precipitates, and almost the same KAM value but lower texture tensity. Fine grain strengthening and precipitation strengthening are stronger, but texture strengthening is weaker in the ECAP 8P alloy than in the ECAP 4P alloy. The higher UTS in the ECAP 8P alloy indicates that the increase in fine grain strengthening and precipitation strengthening is larger than the reduction in texture strengthening. In comparison with the ECAP 8P alloy, the ECAP 12P alloy possesses larger grains, slightly lower area fraction of Mg 2 Sn precipitates, higher KAM value, and much stronger texture intensity, induing weaker fine grain strengthening and precipitation strengthening, but stronger dislocation strengthening and texture strengthening. The higher UTS in the ECAP 12P alloy implies that the increase in dislocation strengthening and texture strengthening is higher than the reduction in fine grain strengthening and precipitation strengthening.

Mechanical Properties
In contrast to UTS, EL shows a descending trend with the increase in ECAP passes. Ductility is related to grain size, texture, dislocation density, and precipitates. Larger grains provide more room for dislocation storage than finer grains and thus are good for ductility [31,32]. Strong basal texture along the tensile direction is detrimental to ductility [31,[33][34][35][36][37]. Dislocations [32,35] and precipitates [38,39] of high density can inhibit dislocation movements and thus promote stress concentration, deteriorating the ductility of alloys. Among all ECAP alloys, the ECAP 4P alloy has relatively large grains, low dislocation density, low area fraction of Mg 2 Sn precipitates, and tilted basal texture, leading to its largest EL. Compared to the ECAP 4P alloy, the ECAP 8P alloy has finer grains and much more Mg 2 Sn precipitates. Therefore, the ECAP 8P alloy exhibits poorer ductility than the ECAP 4P alloy. Although the ECAP 12P alloy possesses slightly larger grains and slightly less Mg 2 Sn precipitates than the ECAP 8P alloy, it has a larger dislocation density. More importantly, the ECAP 12P alloy is featured by strong basal texture with the c-axis of the grains parallel to the ED. Thus, it has a lower EL than the ECAP 8P alloy.

Conclusions
The effect of ECAP on the microstructure and mechanical properties of an Mg-5Sn alloy was investigated. Compared to the as-cast alloy, ECAP alloys show significantly refined grains. The ECAP 8P alloy has the smallest average grain size of 3.03 µm, followed by the ECAP 12P alloy with an average grain size of 3.95 µm. As ECAP pass increases from 4P to 8P, the area fraction of Mg 2 Sn precipitates rises from 8.52% to 35.57%, but decreases to 32.56% with the further increase in ECAP passes to 12P. The ECAP 4P and 8P alloys have basal textures tilted towards TD, while the ECAP 12P alloy shows a basal texture with the c-axis of the grains parallel to ED. The ECAP alloys possess significantly enhanced strengths compared to the as-cast alloy, mainly due to fine grain strengthening, precipitation strengthening, texture strengthening, and dislocation strengthening. UTS shows an increasing trend with increasing ECAP pass, whereas EL exhibits a decreasing trend.