Your search keyword '"Sun, Yuqiao"' showing total 6 results

1. Microstructure and properties of novel Al-Ce-Sc, Al-Ce-Y, Al-Ce-Zr and Al-Ce-Sc-Y alloy conductors processed by die casting, hot extrusion and cold drawing.

Author

Wang, Weiyi, Pan, Qinglin, Lin, Geng, Wang, Xiaoping, Sun, Yuqiao, Wang, Xiangdong, Ye, Ji, Sun, Yuanwei, Yu, Yi, Jiang, Fuqing, Li, Jun, and Liu, Yaru

Subjects

DIE castings, TENSILE strength, ALLOYS, ALUMINUM alloys, ELECTRIC conductivity, ELECTRICAL conductors, MAGNESIUM alloys, SILICON alloys

Abstract

In order to overcome the trade-off between the strength and electrical conductivity of aluminum alloy conductors, the new Al-Ce-Sc, Al-Ce-Y, Al-Ce-Zr and Al-Ce-Sc-Y alloys were prepared by die casting, high temperature homogenization treatment, hot extrusion and cold drawing. Adding Sc and Y eliminated the dendrite segregation of the as-cast Al-0.2Ce alloy and promoted the formation of equiaxed grains with the average grain size of 142.5 μm. The Al-0.2Ce-0.2Sc-0.1Y alloy inherited the great tensile properties of Al-0.2Ce-0.2Sc alloy and the high electrical conductivity of Al-0.2Ce-0.1Y alloy simultaneously. After cold drawing and annealing at 200 °C for 5 h, the ultimate tensile strength of Al-0.2Ce-0.2Sc-0.1Y alloy reached 200 MPa and 198 MPa, the elongation reached 6.8 % and 8.5 %, and the electrical conductivity reached 61.01 % and 61.77 %, respectively. The main second phase of Al-0.2Ce-0.2Sc-0.1Y alloy after hot extrusion were Al 13 Fe 3 Ce containing a few Y and Si atoms. The larger size and proportion of the second phase greatly reduced the concentration of solute Fe and Si atoms and the addition of Y significantly decreased the density of defects after cold drawing compared to Al-0.2Ce-0.2Sc alloy, which improved electrical conductivity of the alloy. Furthermore, the dispersed and coherent nano-size Al 3 Sc precipitions of Al-0.2Ce-0.2Sc-0.1Y alloy greatly improved strength, elongation and heat resistance. Compared with Al-0.2Ce-0.2Sc alloy, the lower density of dislocation, stacking fault and subgrain boundary and the larger size of Al 3 Sc precipitions with enrichment of Y atoms enable the Al-0.2Ce-0.2Sc-0.1Y alloy to maintain high strength, elongation and electrical conductivity after annealing. [ABSTRACT FROM AUTHOR]

Published

2020

2. The effects of scandium heterogeneous distribution on the precipitation behavior of Al3(Sc, Zr) in aluminum alloys.

Author

Sun, Yuqiao, Pan, Qinglin, Luo, Yuhong, Liu, Shuhui, Wang, Weiyi, Ye, Ji, Shi, Yunjia, Huang, Zhiqi, Xiang, Shengqian, and Liu, Yaru

Subjects

*DISCONTINUOUS precipitation, *SCANDIUM, *FACTOR structure, *ALLOYS, *ALUMINUM alloys

Abstract

Sc-containing Al alloys have excellent mechanical properties, which provide the foundation for their applications. The precipitation of the Al 3 Sc/Al 3 (Sc, Zr) is generally considered to be a key factor for the performance boost. However, the performances of the alloy in different production batches often exhibit unstable and fluctuation, which may be related to the heterogeneous of scandium. Herein, we investigated the precipitation behaviors of Al 3 Sc/Al 3 (Sc, Zr) phases in the Al-0.5Sc and Al-0.5Sc-0.25Zr alloys at 340 °C. Results shown that the high scandium‑zirconium ratio not only lead to the discontinuous precipitation, but also contribute to the abnormal continuous Al 3 (Sc, Zr) precipitation in Al-0.5Sc-0.25Zr alloy. The morphology of abnormal Al 3 (Sc, Zr) is similar to the common secondary Al 3 (Sc, Zr) phase with a coffee-bean like morphology. With the aid of Three-Dimensional Atomic Probe (3DAP), the core-shell structures of Al 3 (Sc, Zr) phases are quantitatively analyzed. In the shell layer of abnormal Al 3 (Sc, Zr) phase, the atomic concentration ratio of Sc to Zr is much higher than the common continuous precipitated Al 3 (Sc, Zr) phase. The abnormal Al 3 (Sc, Zr) phase may be one of the key factors for the structure heredity of Sc-containing Al alloys. [Display omitted] • The discontinuous precipitated Al 3 Sc phases are related to the partial high ratio of Sc/Zr (at.%) in Al alloys. • The discontinuous precipitated Al 3 Sc phases form at the casting process and gradually decompose at annealing process. • The high scandium-zirconium ratio leads to the decrease of coarsening resistance of the secondary Al 3 (Sc, Zr) phase. [ABSTRACT FROM AUTHOR]

Published

2021

3. Study on the primary Al3Sc phase and the structure heredity of Al-Zn-Mg-Cu-Sc-Zr alloy.

Author

Sun, Yuqiao, Pan, Qinglin, Luo, Yuhong, Liu, Yaru, Sun, Yuanwei, Long, Liang, Li, Mengjia, Wang, Xiaoping, and Liu, Shuhui

Subjects

*HYPEREUTECTIC alloys, *HEREDITY, *EUTECTIC reactions, *ALLOYS, *MECHANICAL alloying

Abstract

The morphology of primary Al 3 Sc phase in Al-2.2Sc(wt%) was found to be influenced by melting condition. Some representative morphology appeared in large quantities at specific melting temperatures, holding times, and cooling rates. Crystallography of primary phases with various morphologies was researched, and the growth processes of the primary phase were investigated. Deformed cubes and dendrite can be developed from cubes, the butterfly-like particles had multiple layers inside, and repeated eutectic reactions were the main reason for the formation of multilayer structures. Al-2.2Sc(wt%) master alloys with different morphologies of primary Al 3 Sc phase can lead to different refining effects, and the mechanical properties of alloys were consequently influenced. The structure heredity of Al Sc master alloy was proved to be existed, and not influenced by prolonging insulation time and sufficient stirring. Unlabelled Image [ABSTRACT FROM AUTHOR]

Published

2020

4. Hardening behavior of Al-0.25Sc and Al-0.25Sc-0.12Zr alloys during isothermal annealing.

Author

Luo, Yuhong, Pan, Qinglin, Sun, Yuqiao, Liu, Shuhui, Sun, Yuanwei, Long, Liang, Li, Xinyu, Wang, Xiaoping, and Li, Mengjia

Subjects

*TERNARY alloys, *ALLOYS, *ALUMINUM alloys, *ANNEALING of metals, *OSTWALD ripening, *ISOTHERMAL temperature

Abstract

The hardening behavior of Al-0.25Sc and Al-0.25–0.12 (wt.%) alloys during isothermal annealing were studied by transmission electron microscopy (TEM), scanning electron microscopy (SEM), optical microscopy (OM), and hardness measurements. The results show that Sc-containing aluminum alloy contained fine dispersion of spherical secondary Al 3 Sc particles, which developed during the annealing process. Al 3 (Sc, Zr) precipitates in the Al-0.25Sc-0.12Zr alloys are core-shell structure. Different isothermal annealing temperatures can lead to different strengthening effects on the alloys. Al-0.25Sc and Al-0.25Sc-0.12Zr alloys both exhibit obvious annealing hardening behavior, and the ternary Al-0.25Sc-0.12Zr alloy shows better thermal stability than Al-0.25Sc alloy. • The diffusion rate of Sc atoms is inhibited by Zr atoms, which can prevent the coarsening of Al 3 (Sc, Zr). • The hardness decrease in Al–Sc alloy is mainly caused by the coarsening of Al 3 Sc particle. • The radius of the Al 3 (Sc,Zr) particles can maintain their value when annealed at higher temperature (>340 °C) for longer time (∼24 h). [ABSTRACT FROM AUTHOR]

Published

2020

5. The role of trace Sc and Y in the corrosion resistance of cold drawn Al-0.2Ce based alloys with high electrical conductivity.

Author

Lin, Geng, Pan, Qinglin, Wang, Weiyi, Liu, Bing, Huang, Zhiqi, Xiang, Shengqian, Liu, Yaru, Sun, Yuqiao, and Ye, Ji

Subjects

*ELECTROLYTIC corrosion, *CORROSION resistance, *KELVIN probe force microscopy, *ELECTRIC conductivity, *PEARLITIC steel, *CORROSION in alloys, *ALLOYS

Abstract

The effects of trace Sc and Y on the corrosion behaviors of cold-drawn Al-0.2Ce alloys were revealed by scanning Kelvin probe force microscopy (SKPFM), transmission electron microscopy (TEM), scanning electron microscopy (SEM), Electron Probe Micro-analyzer (EPMA), and electrochemical measurements. The results showed that the Al 3 Sc particles not only enable the increase of subgrain boundaries in the modified alloy after cold drawing but also improve the morphology and size of the Al 13 Fe 3 Ce phase. SKPFM analysis showed that the enrichment of Y around the Al 13 Fe 3 Ce phase in the modified alloy can decrease its electrochemical inertness and thus reduce the micro-galvanic corrosion susceptibility of the alloy. The results of the electrochemical analysis showed that the individual and composite addition of Sc and Y can improve the corrosion resistance of the cold-drawn Al-0.2Ce alloy. The corrosion potential and current of Al-0.2Ce-0.2Sc alloy are −0.892 V and 0.91 μA·cm−2, while the corrosion potential and current of Al-0.2Ce-0.1Y alloy are −0.918 V and 1.08 μA·cm−2, respectively. It is obvious that Sc element improves the corrosion resistance of Al-0.2Ce alloy more effectively than Y element. The corrosion depth of Al-0.2Ce-0.2Sc-0.1Y alloy was the smallest tested by immersion under the same conditions, and its corrosion potential and corrosion current were −0.842 V and 0.79 μA·cm−2, respectively, corresponding to the best corrosion resistance. The formal mechanism of pitting corrosion in the alloys is also discussed. [Display omitted] • Effect of Sc on microstructure and corrosion of Al-0.2Ce alloy was revealed. • The enrichment of Y atoms around Al 13 Fe 3 Ce can reduce the potential difference. • The corrosion behaviors of pitting corrosion induced by Al 13 Fe 3 Ce was discussed. • The equivalent circuit of the studied alloys was identified. [ABSTRACT FROM AUTHOR]

Published

2021

6. Investigation of microstructure evolution and quench sensitivity of Al–Mg–Si–Mn–Cr alloy during isothermal treatment.

Author

Liu, Shuhui, Wang, Xiangdong, Pan, Qinglin, Li, Mengjia, Ye, Ji, Li, Kuo, Peng, Zhuowei, and Sun, Yuqiao

Subjects

*AVRAMI equation, *HETEROGENOUS nucleation, *MICROSTRUCTURE, *SUPERSATURATED solutions, *ALLOYS

Abstract

The quench sensitivity of Al–Mg–Si–Mn–Cr alloy was studied through time-temperature-transformation (TTT) and time-temperature-property (TTP) curves. The high quench sensitive region ranges from 250 °C to 430 °C with nose temperature at about 350 °C, where the quenching rate is required to higher than 9 °C/s for avoiding the formation of quench-induced precipitates. B′(Al 3 Mg 9 Si 7) precipitates from the supersaturated solid solution, and gradually transforms to equilibrium β (Mg 2 Si) and excess Si phase with increasing isothermal time at 350 °C. The loss of the solute atoms in matrix results in the reduction of the aging hardening precipitation and the formation of the precipitate-free zones (PFZs) during artificial aging. The nucleation rate of the quench-induced precipitation is studied by nucleation theory, and the phase transformation kinetics is analyzed through Avrami equation. The Al(MnCrFe)Si dispersoids, (sub)grain boundaries and dislocations are the preferential heterogeneous nucleation sites for quench-induced precipitation. • The quench sensitivity of the alloy was studied by time-temperature-transformation and time-temperature-property curves. • The microstructure evolution of the quench-induced precipitate and its effect on mechanical properties were analyzed. • The nucleation rate and phase transformation kinetics of the precipitation were investigated. • The preferential heterogeneous nucleation site for quench-induced precipitation was discussed. [ABSTRACT FROM AUTHOR]

Published

2020