姓名:王翠萍
职称:教授,博士生导师
电话:0592-2180606 (实验室)
传真:0592-2187966
个人简历
教育经历:
工学博士:1998.4-2001.3,日本东北大学,材料科学
工学硕士:1996.4-1998.3,日本东北大学,材料科学
工学学士:1982.8-1986.7,中国东北大学,金属材料
工作经历:
2004.04至今:厦门大学,教授,博士生导师
2006.01-2017.12:厦门大学特聘教授
2001.04-2004.03:日本东北大学,研究员
1986-1994:中国黑色金属材料东北公司,职员
兼职情况:
中国物理学会相图专业委员会委员
全国材料新技术发展研究会常务理事
研究领域
相图与相变,材料热力学与动力学,计算材料学、材料设计及其新材料研发等,研究兴趣涉及金属基复合材料、高温合金、电子封装材料、高性能铜合金、核材料等。
主要科研成果
主要代表学术论著与论文
(1)C.P. Wang, X.J. Liu, I. Ohnuma, R. Kainuma and K. Ishida, Formation of immiscible alloy powders with egg-type microstructure, Science, Vol.297 (2002), pp.990-993.
(2)Yuechao Chen, Cuiping Wang*, Jingjing Ruan, Shuiyuan Yang, Toshihiro Omori, Ryosuke Kainuma, Kiyohito Ishida, Jiajia Han*, Yong Lu, Xingjun Liu*, Development of low-density γ/γʹ Co-Al-Ta-based superalloys with high solvus temperature, Acta Materialia, 188 (2020), 652-664.
(3)Jingjing Ruan, Weiwei Xu, Tao Yang, Jinxin Yu, Shuiyuan Yang*, Junhua Luan, Toshihiro Omori, Cuiping Wang*, Ryosuke Kainuma, Kiyohito Ishida, Chain Tsuan Liu, Xingjun Liu*, Accelerated design of novel W-free high-strength Co-base superalloys with extremely wide γ/γʹ region by machine learning and CALPHAD methods, Acta Materialia, 186 (2020) 425-433.
(4)Yuechao Chen, Cuiping Wang*, Jingjing Ruan, Toshihiro Omori, Ryosuke Kainuma, Kiyohito Ishida, Xingjun Liu*, High-strength Co-Al-V-base superalloys strengthened by γ′-Co3(Al,V) with high solvus temperature, Acta Materialia, 170(2019), 62-74.
(5)Yong Lu, Cuiping Wang, Yipeng Gao, Rongpei Shi, Xingjun Liu,and Yunzhi Wang, Microstructure map for self-organized phase separation during film deposition, Physical Review Letters, Vol. 109(2012), pp. 086101-1-5..
(6)Rongpei Shi, Cuiping Wang, Daniel Wheeler, Xingjun Liu, Yunzhi Wang, Formation Mechanisms of Self-Organized Core/Shell and Core/Shell/Corona Microstructure in Liquid droplets of Immiscible Alloys, Acta Materialia, Vol. 61 (2013) pp.1229-1243.
(7)Weiwei Xu, Jiajia Han, Yi Wang, Cuiping Wang, Xingjun Liu, Zi-Kui Liu, Investigation of electronic, mechanical and thermodynamic properties of L12 ordered Co3(M, W) (M = Al, Ge, Ga) phases using first-principles, Acta Materialia, Vol. 61(2013), pp. 5437-5448.
(8)98)Yuheng Liu, Xingjun Liu, Xinren Chen, Shuiyuan Yang, Cuiping Wang*, Hydrogen Generation from Hydrolysis of Activated Al-Bi, Al-Sn Powders Prepared by Gas Atomization Method, International Journal of Hydrogen Energy, Vol.42(2017), pp. 10943-10951.
(9)Cuiping Wang, Ke Li, Jiajia Han*, Yuechao Chen, Youheng Chen, Yichun Wang, Xingjun Liu*, Temperature dependence of thermodynamic stability and mechanical property of alloying Co3Ta compounds, Journal of Alloys and Compounds, 808(2019), 151068.
(10)Hengxing Jiang, Shuiyuan Yang, Cuiping Wang* Yanqing Zhang, Xiao Xu, Yuechao Chen, Toshihiro Omori, Ryosuke Kainuma, Xingjun Liu*, Martensitic transformation and shape memory effects in Co-V-Al alloys at high temperatures. Journal of Alloys and Compounds, Vol.786 (2019), 648-654.
(11)Cuiping Wang, Lihui Yan, Jiajia Han*, Weiwei Xu, Bin Deng, Xingjun Liu*, Effects of alloying elements on the structural, elastic and thermodynamic properties of Co3Ta compounds from first-principles calculations, Journal of Alloys and Compounds, Vol.726 (2017) , 490-497.
(12)Cui Ping Wang, Xing Jun Liu, and Rong Pei Shi, Chen Shen and Yunzhi Wang, Ikuo Ohnuma, Ryosuke Kainuma, and Kiyohito Ishida, Design and formation mechanism of self-organized core/shell structure composite powder in immiscible liquid system, Applied Physics Letters, Vol. 91(2007), p.141904-1-3.
(13)R.P. Shi, Y. Wang, C.P. Wang, X.J. Liu, Self-organization of core-shell and core-shell-corona structures in small liquid droplets, Applied Physics Letters, vol. 98(2011), p.204106-1-3
(14)Cui Ping Wang, Xing Jun Liu, and Rong Pei Shi, Chen Shen and Yunzhi Wang, Ikuo Ohnuma, Ryosuke Kainuma, and Kiyohito Ishida, Design and formation mechanism of self-organized core/shell structure composite powder in immiscible liquid system, Applied Physics Letters, vol. 91(2007), p.141904-1-3.
(15)Cuiping Wang, Tao Yang, Yuheng Liu, Jingjing Ruan, Shuiyuan Yang, Xingjun Liu*, Hydrogen generation by the hydrolysis of magnesium-aluminum-iron material in aqueous solutions, International Journal of Hydrogen Energy, Vol. 39 (2014), pp. 10843-10852.
(16)C.P. Wang, X.J. Liu, I. Ohnuma, R. Kainuma and K. Ishida, “Formation of core-type macroscopic morphology in Cu-Fe base alloy with liquid miscibility gap”, Metallurgical and Materials Transactions A, Vol.35A (2004), pp.1243-1253.
(17)X.J. Liu, C.P. Wang, I. Ohnuma, R. Kainuma and K. Ishida, “Experimental investigation and thermodynamic calculation of the Cu-Sn and Cu-Sn-Mn systems”, Metallurgical and Materials Transactions A, Vol.35A (2004), pp.1641-1654.
(18)C.P. Wang, J.F. Luo, J.J. Ruan, C.C. Zhao, S.Y. Yang, X.J. Liu, Experimental determination of phase equilibria in the Ni-Hf-Si ternary system, Intermetallics, Vol.42 (2013), pp.14-22.
(19)Z.S. Li, X.J. Liu, C.P. Wang, Thermodynamic modeling of the Pb-U and Pb-Pu systems, Journal of Nuclear Materials, Vol. 403 (2010), pp.1-6.
(20)C.P. Wang, Y. He, H.L. Zhang, X.J. Liu, Thermodynamic assessments of the U-Ni and Th-Ni systems, Journal of Alloys and Compounds, Vol. 487 (2009), pp. 126-131
主要发明专利(20项):
(1)一种稳定γ′相强化的Co-Ni-V-Al基高温合金,ZL201811056585.3
(2)镍锰基无硼钎料及其制备方法,ZL201610352127.9
(3)一种具有低杨氏模量的Ti-Mn-Nb三元合金,ZL201710025653.9
(4)一种镍基无硼钎料及其制备方法,ZL201610008886.3
(5)低膨胀高导热铜-不锈因瓦合金复合材料及其制备方法,ZL201610268433.4
(6)一种基于调幅分解的铜镍合金作为强化恒电阻率合金的应用,ZL201610023279.4
(7)一种含高温有序γ'强化相的Co-V基高温合金及其制备方法,ZL201510029465.4
(8)一种抗氧化的水解制氢复合粉及其制备方法,ZL201410426701.1
(9)一种晶体/非晶复合粉体及其制备方法,ZL201210395732.6
(10)一种核/壳结构的铝铟锡合金粉体及其制备方法,ZL200810071575.7
(11)一种铜基合金/铁基马氏体合金复合粉体及其制备方法,ZL200810070989.8
(12)一种核/壳型锡铋铜合金粉体及其制备方法,ZL 200810071417.1
(13)一种Ni-Cu-Fe-Si多孔合金及其制备方法,ZL 201010283559.1
(14)一种锡银金无铅焊接材料及其制备方法,ZL200810070673.9
(15)一种银镍复合材料的制备方法,ZL200710009688.X
(16)一种无铅焊接材料及其制备方法,ZL200810070577.4
(17)一种锡铋铜自包裹复合粉的焊膏及其制备方法,ZL 201010610621.3
(18)高強度・低抵抗のCu-Fe系焼結体、それに用いる粉末、およびその焼結体の製造方法,特開2005-290461 (P2005-290461A)(日本专利)
(19)はんだおよびその製造方法,特開2005-161397 (P2005-161397A) (日本专利)
(20)熱電変換モジュール,特開2005-161318 (P2005-161318A) (日本专利)
