13 results on '"Yu, Zijian"'
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2. Precipitate Characteristics and Mechanical Performance of Cast Mg–6RE–1Zn–xCa–0.3Zr (x = 0 and 0.4 wt%) Alloys
- Author
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Yu, Zijian, Xu, Xi, Du, Baotian, Shi, Kang, Liu, Ke, Li, Shubo, Han, Xiuzhu, Xiao, Tao, and Du, Wenbo
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- 2022
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3. Effect of Secondary Extrusion on the Microstructure and Mechanical Properties of Mg-12Gd-2Er-0.4Zr Alloy
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Mansoor, Adil, Du, Wenbo, Yu, Zijian, Ding, Ning, Fu, Junjian, Jia, Linyue, Liu, Ke, and Li, Shubo
- Published
- 2021
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4. Effects of deformation temperatures on microstructures, aging behaviors and mechanical properties of Mg-Gd-Er-Zr alloys fabricated by hard-plate rolling.
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Liu, Ke, Hu, Dalong, Lou, Feng, Yu, Zijian, Li, Shubo, Du, Xian, and Du, Wenbo
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TEMPERATURE effect ,MICROSTRUCTURE ,TENSILE strength ,ALLOYS ,PRECIPITATION hardening ,GRAIN size ,MAGNESIUM alloys - Abstract
• The high rolling temperature would impede the DRX occurrence for these final-rolled sheets. • The reduction of the volume fraction of this β phases led to the highest peak-aging hardness in R-450 °C sheet. • The precipitate chains in R-385 °C + A sheets were beneficial for strength and elongation. • The traditional precipitation characteristic in R-450 °C + A sheet was bad for elongation but good for strength. • The peak-aging R-450 °C sheet showed the highest strength, i.e. UTS of 518±17 MPa and YS of 438±18 MPa. In this investigation, a high-strength Mg-12Gd-1.0Er-0.5Zr (wt.%) alloy sheet was produced by hot extrusion (HE) and subsequent hard-plate rolling (HPR) at different temperatures. The results indicate that the microstructures of these final-rolled sheets are inhomogeneous, mainly including coarse deformed grains and dynamic recrystallized (DRXed) grains, and the volume fraction of these coarse deformed grains increases as the rolling temperature increases. Thus, more DRXed grains can be found in R-385 °C sheet, resulting in a smaller average grain size and weaker basal texture, while the biggest grains and the highest strong basal texture are present in R-450 °C sheet. Amounts of dynamic precipitation of β phases which are mainly determined by the rolling temperature are present in these sheets, and its precipitation can consume the content of Gd solutes in the matrix. As a result, the lowest number density of β phase in R-450 °C sheet is beneficial to modify the age hardening response. Thus, the R-450 °C sheet displays the best age hardening response because of a severe traditional precipitation of β' (more) and β Η / β Μ (less) precipitates, resulting in a sharp improvement in strength, i.e. ultimate tensile strength (UTS) of ∼ 518 ± 17 MPa and yield strength (YS) of ∼ 438±18 MPa. However, the elongation (EL) of this sheet reduces greatly, and its value is ∼ 2.7 ± 0.3%. By contrasting, the EL of the peak-aging R-385 °C sheet keeps better, changing from ∼ 4.9 ± 1.2% to ∼ 4.8 ± 1.4% due to a novel dislocation-induced chain-like precipitate which is helpful to keep good balance between strength and ductility. [ABSTRACT FROM AUTHOR]
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- 2024
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5. Development and characteristics of a low rare-earth containing magnesium alloy with high strength-ductility synergy.
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Yu, Zijian, Xu, Xi, Shi, Kang, Du, Baotian, Han, Xiuzhu, Xiao, Tao, Li, Shubo, Liu, Ke, and Du, Wenbo
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MAGNESIUM alloys ,HOT rolling ,RARE earth metals ,CRYSTAL grain boundaries ,EXTRUSION process ,COLUMNS ,ALLOYS - Abstract
In this study, we successfully developed a low RE containing Mg-3Y-2Gd-1Nd-0.5Zr (wt%) alloy with high strength-ductility synergy by combined processes of hot extrusion, hot rolling and ageing. This alloy exhibits an excellent strength-ductility balance (UTS of 345 ± 2.0 MPa, TYS of 301 ± 5.0 MPa and EL of 9.2 ± 1.9%), which is better than that of many Mg-RE wrought alloys with higher RE concentration and even comparable to that of 6061 Al wrought alloy. A long-range chain-like structure consisting of β′ phase, β H phase, β M phase and zig-zag atomic columns is observed for the first time in the studied alloy. The combined process of hot extrusion and hot rolling boosts the formation of deformed grains and low angle grain boundaries, and makes the deformed grains dominate in the alloy strengthening. Under this circumstance, the following ageing generates a novel heterogeneous structure comprising the long-range chain-like structure with broad interparticle spacing and the spacious precipitate-free zones in the deformed grains, which plays a key role in the concurrent strengthening and toughening of the alloy. The present study demonstrates that the deformed grains with long-range chain-like structures and precipitate-free zones is desirable microstructure for the low RE containing Mg alloys to achieve high strength-ductility synergy. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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6. Precipitate characteristics and their effects on the mechanical properties of as-extruded Mg-Gd-Li-Y-Zn alloy.
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Yu, Zijian, Xu, Xi, Mansoor, Adil, Du, Baotian, Shi, Kang, Liu, Ke, Li, Shubo, and Du, Wenbo
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SOLUTION strengthening ,ALLOYS ,DISPERSION strengthening ,MAGNESIUM alloys ,HIGH temperatures - Abstract
[Display omitted] • The TYS of the studied alloy is 295 MPa at 25℃ and 143 MPa at 200℃. • Theβ 1R phase is introduced in the studied alloy for the first time. • Theβ 1R phase forms by dislocation-assisted dynamic precipitation in hot extrusion. • Theβ 1R phase provides the alloy with a strong Orowan strengthening effect. In this work, a high-performance Mg-8.4Gd-4.4Li-3.5Y-1.4Zn (wt%) alloy was successfully prepared by low-temperature hot extrusion. The studied alloy has a TYS of 295 ± 1 MPa and an EL of 2.5 %±0.2 % at room temperature, 159 ± 8 MPa and 15.9 %±1.4 % at 150 °C, and 143 ± 4 MPa and 19.8 %±1.8 % at 200 °C. The high performance at temperatures up to 200 °C is attributed to the dispersion strengthening of three Mg 3 RE phase variants, the solid solution strengthening of alloying elements and the bimodal structure consisting of fine DRXed grains with random texture and coarse un-DRXed grains with basal texture. A novel island shaped β 1 R phase (FCC, a = 0.78 nm) with a size of 30 nm–100 nm is observed in the studied alloy. The β 1 R phase precipitates on the { 1 1 ¯ 00 } α prismatic planes. The strain-induced, dislocation-assisted dynamic precipitation during low-temperature hot extrusion is responsible for the formation of the β 1 R phase. The growth of the β 1 R phase is owing to the aid of the formation and transformation of zig-zag structures. The basal slip of < a > dislocations is the dominate deformation mechanism of the studied alloy in the early stage of tensile deformation at room temperature, while non-basal slip of < a > and < c + a > dislocations at 200 °C. Due to the strong interaction between β 1 R precipitates and dislocations, the densely distributed β 1 R precipitates significantly improve the mechanical properties via the Orowan strengthening both at room temperature and elevated temperatures. [ABSTRACT FROM AUTHOR]
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- 2021
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7. Microstructure evolution and mechanical properties of as-extruded Mg-Gd-Y-Zr alloy with Zn and Nd additions.
- Author
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Yu, Zijian, Xu, Chao, Meng, Jian, Zhang, Xuhu, and Kamado, Shigeharu
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MAGNESIUM alloys , *ZIRCONIUM alloys , *MECHANICAL properties of metals , *MICROSTRUCTURE , *RECRYSTALLIZATION (Metallurgy) - Abstract
The microstructure evolution and mechanical properties of as-extruded Mg-11.5Gd-4.5Y-0.3Zr (wt%) alloy with Zn and Nd additions were investigated. The addition of Zn inhibits the dynamic recrystallization (DRX) due to the presence of the long-period stacking ordered (LPSO) phase. The addition of Nd promotes the precipitation of the Mg 5 RE (RE: rare earth) phase. The existence of the densely distributed Mg 5 RE phase before hot extrusion promotes the DRX in subsequent hot extrusion process and leads to grain refinement. The increase in the number of Mg 5 RE phase particles degrades the mechanical properties of the resultant alloy. After hot extrusion, the studied alloys exhibit a bimodal microstructure consisting of fine dynamic recrystallized (DRXed) grains of several microns and strongly textured course un-DRXed grains. The as-extruded Mg-11.5Gd-4.5Y-1.5Zn-0.3Zr alloy exhibits an excellent balance of strength and ductility (tensile yield strength of 371 ± 3.0 MPa and elongation of 7.2 ± 0.8%). The alloy strengthening is attributed to the bimodal microstructure, the Mg 5 RE and LPSO phases, and the basal texture. The tensile yield strength of the as-extruded Mg-11.5Gd-4.5Y-1.5Zn-0.3Zr alloy can be further increased to 425 ± 2.5 MPa by precipitation hardening with the T5 treatment. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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8. Microstructural evolution and mechanical properties of Mg–11Gd–4.5Y–1Nd–1.5Zn–0.5Zr alloy prepared via pre-ageing and hot extrusion.
- Author
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Yu, Zijian, Huang, Yuanding, Mendis, Chamini Lakshi, Hort, Norbert, and Meng, Jian
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MICROSTRUCTURE , *MECHANICAL behavior of materials , *MAGNESIUM alloys , *HOT working of metals , *METAL extrusion - Abstract
The Mg–11Gd–4.5Y–1Nd–1.5Zn–0.5Zr (wt%) alloy was pre-aged prior to hot extrusion. Pre-ageing treatment introduced uniform distribution of plate-like Mg 5 RE precipitates, which transformed into nano-scale globular Mg 5 RE particles by split and spheroidization during hot extrusion. These globular Mg 5 RE particles contributed to continuous dynamic recrystallization by promoting the evolution of low misorientation sub-grain boundaries to high misorientation grain boundaries and caused grain refinement through grain boundary pinning. The improved mechanical properties were ascribed to the grain refinement, globular Mg 5 RE and LPSO precipitates. The ratio of compressive to tensile yield strength is 1.2. The yield strength asymmetry was attributed to the deformation asymmetry of LPSO phase and non-isotropic deformation behaviors of Mg matrix in tension and compression. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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9. Microstructures and mechanical properties of as-extruded Mg–8Gd–2Y–1Zn–6Li alloy.
- Author
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Yu, Zijian, Liu, Linlin, Mansoor, Adil, Liu, Ke, Li, Shubo, and Du, Wenbo
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INTERMETALLIC compounds , *ALLOYS , *DISPERSION strengthening , *MICROSTRUCTURE , *HEAT treatment , *MAGNESIUM alloys - Abstract
• A high-performance Mg-Li alloy with a TYS of 202 MPa is produced. • The studied alloy consists of deformed α-Mg grains and recrystallized β-Li grains. • Three Mg 3 RE variants form in the alloy and affect the mechanical properties differently. • A novel island-shape β 1R phase is firstly observed in the studied alloy. • The formation mechanism and strengthening mechanism of β 1R phase are clarified. In this study, a high-performance Mg–8Gd–2Y–1Zn–6Li (wt%) alloy having a TYS of 202 ± 2.6 MPa, UTS of 243 ± 2.1 MPa and EL of 10.7 ± 2.3% was successfully fabricated by casting, heat treatment and hot extrusion. The effects of intermetallic compounds on microstructure and mechanical properties were deeply investigated. The results show that the studied alloy consists of coarse deformed α-Mg grains with (0001) basal texture, fine recrystallized β-Li grains with (002) texture and three Mg 3 RE phase variants, which are bulk Mg 3 RE phase with a size range of 10–30 µm, spot Mg 3 RE phase with a size range of 1–2 µm and spherical Mg 3 RE phase with a size range of 0.3–1 µm, respectively. The spherical Mg 3 RE phase has a strong dispersion strengthening effect, while the bulk Mg 3 RE phase acts as crack resources and deteriorates the ductility. A novel island-like β 1 R phase (FCC, a = 0.78 nm) is found for the first time in the Mg-Gd-Li based alloys. It has a coherent (1 ̅ 12) β 1 R // (10 1 ̅ 0) α interface at the broad facet and a semi-coherent (1 ̅ 11) β 1 R // (11 2 ̅ 0) α interface at the end facet. The β 1 R phase transforms from β H phase at the semi-coherent interface by atomic shear of RE and Mg atoms. The β 1 R phase provides a significant precipitation strengthening effect to the studied alloy, while the dissolution of β 1 R phase results in the age-softening phenomenon. The high-performance of the studied alloy is mainly attributed to the α/β duplex structure, three Mg 3 RE phase variants, and β 1 R phase. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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10. Effects of extrusion ratio and temperature on the mechanical properties and microstructure of as-extruded Mg-Gd-Y-(Nd/Zn)-Zr alloys.
- Author
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Yu, Zijian, Xu, Chao, Meng, Jian, Liu, Ke, Fu, Jinlong, and Kamado, Shigeharu
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ALLOYS , *ALUMINUM alloys , *MICROSTRUCTURE , *MAGNESIUM alloys , *TEMPERATURE , *OSTWALD ripening - Abstract
This study investigates the effects of extrusion ratio and temperature on the microstructure and mechanical properties of as-extruded Mg-11.5Gd-4.5Y-(1Nd/1.5Zn)-0.3Zr (wt %) alloys. After hot extrusion the studied alloys exhibit a bimodal microstructure consisting of fine dynamic recrystallized (DRXed) grains with relatively random orientations and coarse un-DRXed grains with strong basal texture. The increase of extrusion ratio promotes the DRX, increases the volume fraction of Mg 5 RE phase, and refines the DRXed grains, whereas the increase of extrusion temperature decreases the volume fraction of Mg 5 RE phase and coarsens the DRXed grains. The increase of extrusion temperature suppresses the DRX of Mg-11.5Gd-4.5Y-0.3Zr (GW) and Mg-11.5Gd-4.5Y-1Nd-0.3Zr (GWN) alloys, but it has a limited effect on that of Mg-11.5Gd-4.5Y-1.5Zn-0.3Zr (GWZ) alloy. The increase of extrusion ratio improves the mechanical properties of GWZ and GWN alloys, while it deteriorates the mechanical property of GW alloy. The increase of extrusion temperature leads to a decreased strength and increased ductility of the studied alloys. The change of mechanical properties is a result of the competition between the "strengthening effect" of DRXed grains and the "hardening effect" of un-DRXed grains in the changing bimodal microstructure. The Mg 5 RE phase also contributes to the alloy strengthening, but the extensive Mg 5 RE precipitates acting as the crack resources are detrimental to the ductility, especially for the GWN alloy. With the optimum extrusion condition (temperature of 450 °C and ratio of 20:1) the GWZ alloy exhibits the best mechanical performance, which is superior to that of its competitor 6000 series aluminum alloys. • The studied Mg-Gd-Y-Zn-Zr alloy has a superior strength to 6000 series Al alloys. • Both Mg5RE phase and 18R-LPSO phase enhance the DRX behaviour. • The effect of bimodal microstructure on the mechanical properties was studied. • Three Mg–Gd based alloys were extruded using different extrusion parameters. • A big database (microstructural and mechanical) was obtained by quantitative statistics. [ABSTRACT FROM AUTHOR]
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- 2019
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11. Effects of grain refinement and precipitate strengthening on mechanical properties of double-extruded Mg-12Gd-2Er-0.4Zr alloy.
- Author
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Mansoor, Adil, Du, Wenbo, Yu, Zijian, Ding, Ning, Fu, Junjian, Lou, Feng, Liu, Ke, and Li, Shubo
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GRAIN refinement , *ALLOYS , *SCANNING electron microscopes , *DISPERSION strengthening , *MAGNESIUM alloys , *GRAIN size - Abstract
The Mg-12Gd-2Er-0.4Zr (GE122K) is fabricated by double extrusion, and the effects of grain refinement and precipitate evolution on the mechanical performance of the extruded alloys are deeply analyzed. Scanning electron microscope results spectacle that some bulky precipitates in the single extruded alloy are fragmented to fine precipitates during double extrusion and distribute linearly along the extrusion direction (ED). The fine precipitates exhibit the strongest dispersion strengthening effect, whereas the bulky precipitates act as crack resources and decrease the elongation. After double extrusion, a refined grain structure with an average grain size of 2.7 µm is achieved, which is attributed to dynamic recrystallization (DRX). Moreover, double extrusion boosts the content of rare-earth elements into the matrix by dissolving the fine precipitates. During aging, extensive β′ precipitates form in the double extruded alloy than in the single extrude alloy. As a result, refined grains and strong precipitation strengthening make a significant contribution to a high yield strength (YS) of 422 ± 1.59 MPa with an elongation (EL) of 6.5 ± 0.89% in the double extruded+peak-aged alloy (ACX2). The possible strengthening mechanisms are discussed, and it is found that grain refinement and precipitate strengthening are the main contributors to the high strength of the GE122K alloy. Fabrication of Mg-12Gd-2Er-0.4Zr (wt%) alloy via double extrusion+aging with excellent mechanical performance. [Display omitted] • A facile and robust fabrication mechanism is adopted to attain an excellent balance of yield strength and elongation. • Grain refinement and precipitates have different effects on the strength of Mg-12Gd-2Er-0.4Zr alloy. • The β′ precipitate strengthening is the dominate strengthening mechanism during aging treatment of the extruded alloys. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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12. Microstructures and mechanical properties of Mg-6Gd-1Er-0.5Zr alloy sheets produced with different rolling temperatures.
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Liu, Ke, Lou, Feng, Yu, Zijian, Wang, Zhaohui, Li, Shubo, Du, Xian, and Du, Wenbo
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TENSILE strength , *HONEYCOMB structures , *MICROSTRUCTURE , *PRECIPITATION hardening , *ALLOYS , *ROLLING friction - Abstract
• Rolling temperatures led to great variations in microstructure, aging behaviors and mechanical properties. • Dislocations left after rolling at 300 °C led to the formation of a novel chain-like precipitates. • Chain-like precipitates were composed of dominate β ', β ′ F phases et al. and improve age-hardening response greatly. • The good strength-ductility balance was mainly ascribed to the bimodal microstructure and chain-like precipitates. The sheet rolled at 300 °C exhibited the highest peak-aging hardness, which was ascribed to the precipitate chains comprising of the dominate β' , β′ F phase tail-like "hexagonal ring" layers, individual "zigzag" chain and individual "hexagonal ring" metastable phases. These precipitate chains could segregate the matrix into lots of nano-scale units forming honeycomb structures, which could improve the strength significantly without an obvious reduction of EL together with the bimodal microstructure. Thus, the GE61K-300 °C alloy sheet showed UTS of 367 ± 3 MPa, YTS of 349 ± 4 MPa and EL of 9.1 ± 1.5%, respectively. [Display omitted] In this study, we investigated the microstructures and mechanical properties of Mg-6Gd-1Er-0.5Zr (GE61K) sheets. The results show that the rolling temperature has a remarkable influence on microstructures, age-hardening responses and mechanical properties of GE61K sheets. The microstructures varies with the increase in rolling temperatures, i.e. microstructures were dominated by the mixture of dynamic recrystallized (DRXed) grains and un-DRXed grains at 300 °C, by DRXed grains at 350 °C, and by un-DRXed grains at 400 °C and 450 °C. Rolling at 300 °C leads to a formation of the bimodal microstructure which contains equilibrium Mg 5 (Gd, Er) precipitates and a large number of dislocations. These dislocations leads to a formation of novel chain-like precipitates which comprise dominant β ', β′ F (or β′ T), tail-like "hexagonal ring" layers, individual "zig-zag" chain and individual "hexagonal ring", eventually improving age-hardening responses. The chain-like precipitates are beneficial for achieving a good strength-ductility balance by dividing the matrix into nano-scale units and forming subsequent honeycomb structures. As a result, the R-300 °C sheet shows good mechanical properties, i.e. ultimate tensile strength (UTS) of 367 ± 3 MPa, yield strength (YS) of 349 ± 4 MPa and elongation (EL) of 9.1 ± 1.5%, respectively. However, such strength-ductility balance is destroyed sharply as soon as the rolling temperature increases to 400 °C because of the microstructure variations. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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13. Effects of 0.5 wt% Ce addition on microstructures and mechanical properties of a wrought Mg−8Gd−1.2Zn−0.5Zr alloy.
- Author
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Li, Baishun, Guan, Kai, Yang, Qiang, Niu, Xiaodong, Zhang, Dongdong, Yu, Zijian, Zhang, Xuhu, Tang, Zongmin, and Meng, Jian
- Subjects
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MICROSTRUCTURE , *MECHANICAL behavior of materials , *MAGNESIUM alloys , *RECRYSTALLIZATION (Metallurgy) , *CRYSTAL grain boundaries - Abstract
Effects of 0.5 wt% cerium (Ce) addition on microstructures and mechanical properties of a wrought Mg−8Gd−1.2Zn−0.5Zr alloy were thoroughly investigated in this work. The results indicate that 0.5 wt% Ce addition has slight refinement on the as-cast grains and results in a lattice expansion of the dominant intermetallic phase Mg 3 RE. After extrusion, 0.5 wt% Ce addition leads to higher level of recrystallization and finer dynamic recrystallization (DRX) grains and non-recrystallization stripes. In addition, there are much more dynamic precipitates on the DRX grain boundaries in the alloy with Ce addition, and the crystal structure (Mg 12 RE) is different from those (Mg 5 Gd) in the alloy with free Ce addition. Under peak-aging condition, 0.5 wt% Ce addition significantly changes the precipitates in the DRX grains from basal γ′ phase to prismatic β′ phase. As a result, the as-extruded Mg−8Gd−1.2Zn−0.5Zr alloy with 0.5 wt% Ce addition owns higher strength and more obvious precipitation hardening response than the alloy with free Ce addition. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
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