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教工名录

袁媛

系所:材料科学系

职称:研究员

职务:

学位:博士

邮箱:yuanyuan17@cqu.edu.cn

电话:18223591217

地址:

学习工作经历

教育经历:

1999.09—2003.06     中南大学 伟德体育材料,工学学士

2003.09—2006.06     中南大学 伟德体育材料学,工学硕士

2006.09—2011.12     中南大学 粉末冶金研究学院材料学,工学博士

工作经历:

2017.06—至今           重庆大学 伟德体育,研究员

2017.06—至今           国家镁合金材料工程技术研究中心,研究员

2020.03—2020.09     德国卡尔斯鲁厄理工大学,访问教授

2012.10—2016.09     比利时 鲁汶大学 材料工程学院,飞马-玛丽居里博士后

2014.08—2017.06     德国 卡尔斯鲁厄理工学院 应用材料物理系,访问研究员

2012.03—2012.07     重庆大学 伟德体育,博士后工作

2008.09—2010.08   意大利 热那亚大学 无机化学工程学院, 联合培养公派博士生


社会兼职

重庆材料学会 理事


主讲课程

研究生课程:固态相变,材料热力学

本科生课程:材料设计


主要研究方向

1)材料热力学,动力学,相变和扩散

2)材料第一原理计算与材料结构多尺度演变模拟

3)合金设计与材料性能模拟

4) 镁合金结构功能材料设计

5)镁基储能材料的热动力学行为和离子电池电极的设计


科研项目

1)镁合金多元固溶特征模型与镁合金多元固溶强韧化设计的基础研究,2022-2025,国家自然科学基金面上项目,主持

2)基于镁铝合金纯化设计的Mg-Al-Fe-X体系富镁端端际相图的研究,2020-2023,国家自然科学基金面上项目,主持

3)镁铝复合板短流程轧制及其壳体构件一体化成形新方法新技术研究,2020-2023,国家自然科学基金重点项目,课题主持

4Study on the diffusion behavior of Gd+X (X=Y, Zn, Mn) in the Mg primary phase 2020,德国Helmholt研究中心项目,主持

5The characterization of alloying Li effect on the extension of the solubility of La and Mn in primary Mg phase2020,德国Helmholt研究中心项目,主持

6)集成关键实验,相图计算和结构模拟的多组分界面的组织结构演化的集成研究,2012-2016,欧盟和比利时荷兰语区自然研究基金会联合资助,金额约26万欧元,主持

7)冶金领域国际标准研究,2018-2021,科技部重点研发,骨干参研

8)超高强韧镁合金型材的均质制备,2016-2020,科技部重点研发,骨干参研


论文及专著

发表论文近四十余篇,部分论文如下:

[1] T. Chen, Q. Gao, Y. Yuan, T. Li, Q. Xi, T. Liu, A. Tang, A. Watson, F. Pan, Coupling physics in machine learning to investigate the solution behavior of binary Mg alloys, JMA, (2021).

[2] L. Yang, Y. Yuan, J. Liu, T. Chen, A. Tang, F. Pan, The investigation of Mg–Zn diffusion behaviour using Glow Discharge Optical Emission Spectroscopy (GD-OES) characterization method, Vacuum, 191 (2021) 110358.

[3] L. Yang, Y. Yuan, T. Chen, X. Dai, L. Zhang, D. Li, A. Tang, W. Yi, L. Zhang, F. Pan, Diffusion behaviour and mechanical properties of binary Mg–Gd system, Intermetallics, 133 (2021) 107171.

[4] J. Wu, Y. Yuan, X. Yu, T. Chen, D. Li, L. Wu, B. Jiang, A. Atrens, F. Pan, The high-temperature oxidation resistance properties of magnesium alloys alloyed with Gd and Ca, J. Mater. Sci., 56 (2021) 8745-8761.

[5] J. Wang, Y. Yuan, X. Chen, T. Chen, B. Jiang, D. Li, A. Tang, T. Boll, F. Pan, The High-Solution Design of Magnesium Alloys (Invited Speak), in: V.M. Mille (Ed.) TMS 2021, Magnesium Technology 2021, The Minerals, Metals & Materials Series, USA, 2021.

[6] T. Tu, X. Chen, T. Chen, Y. Yuan, F. Pan, New high-modulus and high-strength Mg-Gd-Ag-Mn-Ge alloys, Mater. Sci. Eng., A, 805 (2021) 140559.

[7] W. Luo, L. Wang, Y. Wang, L. Meng, Y. Yuan, L. Zhang, G. Wu, Microstructure and mechanical properties of a 2 wt% Nb bearing low carbon steel, Materials Science and Engineering: A, 826 (2021).

[8] N. Li, Y. Wang, S. Peng, Y. Yuan, J. Wang, Y. Du, W. Zhang, K. Han, Y. Ji, F. Dang, Ti3C2T MXene Cathode Catalyst with Efficient Decomposition Li2O2 and High-Rate Cycle Stability for Li-O2 Batteries, Electrochimica Acta, 388 (2021) 138622.

[9] Z. Jun, J. Bin, Y. Yuan, Q. Wang, M. Yuan, A. Tang, G. Huang, D. Zhang, P. Fusheng, Understanding the enhanced ductility of Mg-Gd with Ca and Zn microalloying by slip trace analysis, J. Mater. Sci. Technol., 95 (2021) 20-28.

[10] X. Cheng, Y. Yuan, T. Chen, Z. Zheng, L. Ma, B. Jiang, A. Tang, F. Pan, The effects of second-alloying-element on the formability of Mg-Sn alloys in respect of the stacking fault energies of slip systems, Materials Today Communications, 29 (2021).

[11] T. Chen, Y. Yuan, T. Liu, D. Li, A. Tang, X. Chen, R. Schmid-Fetzer, F. Pan, Effect of Mn Addition on Melt Purification and Fe Tolerance in Mg Alloys, Jom, 73 (2021) 892-902.

[12] T. Chen, L. Mo, Y. Yuan, J. Liu, J. Wang, D. Li, B. Jiang, F. Pan, Investigation on the Phase Relationship and Solidification Processes of Mg-rich Mg-Mn-Y Alloys, Journal of Phase Equilibria and Diffusion, (2021).

[13] J. Zhao, B. Jiang, Y. Yuan, A. Tang, Q. Wang, T. Yang, G. Huang, D. Zhang, F. Pan, Influence of Ca and Zn synergistic alloying on the microstructure, tensile properties and strain hardening of Mg-1Gd alloy, Mater. Sci. Eng., A, 785 (2020) 139344.

[14] J. Zhao, B. Jiang, Y. Yuan, A. Tang, H. Sheng, T. Yang, G. Huang, D. Zhang, F. Pan, Influence of Zn addition on the microstructure, tensile properties and work-hardening behavior of Mg-1Gd alloy, Mater. Sci. Eng., A, 772 (2020) 138779.

[15] D. Zhao, X. Chen, Y. Yuan, F. Pan, Development of a novel Mg–Y–Zn–Al–Li alloy with high elastic modulus and damping capacity, Mater. Sci. Eng., A, 790 (2020) 139744.

[16] T. Tu, X. Chen, C. Zhao, Y. Yuan, F. Pan, A simultaneous increase of elastic modulus and ductility by Al and Li additions in Mg-Gd-Zn-Zr-Ag alloy, Mater. Sci. Eng., A, 771 (2020) 138576.

[17] J. Liu, T. Chen, Y. Yuan, J. Wu, L. Yang, A. Tang, D. Li, F. Pan, Two-Stage Settling Approach to Purify Mg Alloy in: J.B. Jordon (Ed.) Magnesium Technology 2020, The Minerals, Metals & Materials Series, 2020, pp. 55-59.

[18] D. Li, W. Zhang, K. Chang, Y. Yuan, H.J. Seifert, Thermodynamic/Electrochemical Description of High-Voltage Spinels for Lithium-Ion Batteries, Journal of The Electrochemical Society, 167 (2020) 130511.

[19] D. Li, Y. Yuan, J. Liu, M. Fichtner, F. Pan, A review on current anode materials for rechargeable Mg batteries, JMA, 8 (2020) 963-979.

[20] T. Chen, X. Xiong, Y. Yuan, A. Tang, D. Li, A. Atrens, F. Pan, Effect of Steels on the Purity of Molten Mg Alloys, Advanced Engineering Materials, 20 (2020) 2000338.

[21] T. Zhao, Y. Hu, F. Pan, B. He, M. Guan, Y. Yuan, A. Tang, Effect of Zn Content on the Microstructure and Mechanical Properties of Mg–Al–Sn–Mn Alloys, Materials, 12 (2019) 3102.

[22] Y. Yuan, T. Chen, D. Li, U. Gerhards, F. Pan, H. Seifert, N. Moelans, Diffusion multiple study of the Co-Fe-Ni system at 800 °C, Calphad, 64 (2019) 149-159.

[23] T. Chen, Y. Yuan, J. Wu, T. Liu, X. Chen, A. Tang, F. Pan, Alloy Design Strategies of the Native Anti-corrosion Magnesium Alloy, in: V. Joshi (Ed.) Magnesium Technology 2019, The Minerals, Metals & Materials Series, 2019, pp. 169-173.

[24] Y. Yuan, L. Yang, D. Li, A. Tang, F. Pan, H. Seifert, N. Moelans, Diffusion multiple study of Co-Ni-Ti system at 1073 K, Calphad, 63 (2018) 156-163.

[25] X. Tao, P. Yao, W. Wei, H. Chen, Y. Ouyang, Y. Du, Y. Yuan, Q. Peng, An experimental study on the interdiffusion behaviors and mechanical properties of Ni-Zr system, J. Alloys Compd., 752 (2018) 412-419.

[26] Y. Yuan, D. Li, N. Moelans, Comments on “A numerical method to determine interdiffusion coefficients of Cu6Sn5 and Cu3Sn intermetallic compounds”, Intermetallics, 69 (2016) 95-97.

[27] Y. Yuan, D. Li, Y. Guan, H.J. Seifert, N. Moelans, Investigation of the diffusion behavior in Sn-xAg-yCu/Cu solid state diffusion couples, J. Alloys Compd., 686 (2016) 794-802.

[28] Y. Yuan, Y. Guan, D. Li, N. Moelans, Investigation of diffusion behavior in Cu–Sn solid state diffusion couples, J. Alloys Compd., 661 (2016) 282-293.

专利



表彰及奖励

欧盟玛丽居里研究员奖,2012-2016

德国卡尔斯鲁厄理工研究院,客座教授,客座教授奖金,2020


科研团队

现有客座德国教授一名,博士研究生四名,硕士研究生六名,本科创新团队两个

团队有齐备的材料计算软件和镁,铝,铁合金的热力学和动力学数据库

团队有齐备的材料熔炼设备和电池组装设备