冯艾寒-轻质高温结构材料课题组

冯艾寒

作者：thalenus 时间：2019-05-08 点击数：

职称	副教授	联系方式	aihanfeng@tongji.edu.cn
研究方向	轻质高温结构材料	个人主页链接	https://www.researchgate.net/profile/A_Feng
学习工作单位	同济大学材料科学与工程学院	联系电话	18621320401

冯艾寒

职称：副教授/博导

电子邮箱：aihanfeng@tongji.edu.cn

办公地点：德才馆452室

联系电话：18621320401

课题组主页：http://titanium.tongji.edu.cn

研究方向：

1、 Ti₂AlNb基合金微观组织调制及精密热成形(等温锻造、包覆轧制)研究

2、同步辐射、中子衍射、原位透射等技术在Ti₂AlNb、TiAl基合金、镁合金等材料相变过程中的应用

3、粉末冶金TiAl基合金微观组织演变与力学性能表征

4、搅拌摩擦焊接铝合金、镁合金、铝基复合材料、钛合金及Ti₂AlNb基合金微观组织与疲劳性能研究

工作经历：

2013.06-至今：同济大学副教授/博导

2010.05-2013.06：哈尔滨工业大学副教授/硕导

2008.05-2010.05：加拿大瑞尔森大学博士后

2005.08-2008.05：中国科学院金属研究所博士后

学习经历：

2001.03-2005.07：哈尔滨工业大学材料科学与工程学院材料学博士

1999.09-2001.03：哈尔滨工业大学材料科学与工程学院材料学硕士

1993.07-1997.09：哈尔滨工业大学材料科学与工程学院材料学学士

主持项目：

1、横向课题：“增材制造钛合金精细结构与疲劳性能研究”，项目起止：2019.09-2021.09.

2、横向课题：“3D打印钛基合金微观组织与力学性能研究”，项目起止：2019.03-2020.12.

3、横向课题：“TiAl基合金等温锻造晶粒细化机理研究”，项目起止：2018.10-2020.10.

4、同济大学重点科研项目培养基金：“Ti₂AlNb基合金典型高温结构部件制备研究”，项目起止：2017.06-2018.12.

5、横向课题：“细晶Ti₂AlNb基合金超塑性变形机理研究”，项目起止：2016.07-2018.12.

6、国家自然科学基金(青年)基金：“基于多相组织演化控制的Ti₂AlNb基金属间化合物合金搅拌摩擦焊接研究”，项目编号：51305304，项目起止：2014.01-2016.12.

7、国家科技重大专项课题：“难变形材料构件组织调制及精密热成形技术”，项目编号：2013ZX04011061，项目起止：2013.01-2017.12.

授课情况：

《金属成形原理》：博士研究生

《材料化学》：博士研究生(英文授课)

《材料现代研究方法》：博士/硕士研究生

《材料热力学》：博士/硕士研究生

《材料科学新进展》：本科生(英文授课)

《材料物理性能》：本科生(英文授课)

代表性论文与著作：

[1] B.Y. Hu,A.H. Feng*, H. Zhang*, R.S. Yang, Z.G. Hu. Corrosion rates of friction stir welded 2195-T8 Al-Li alloy in 3.5% NaCl solution with different pH values.Corrosion. Under review (2020).

[2] B.Y. Hu, H. Zhang, L.Y. Liu, D.B. Liu,A.H. Feng*, D.L. Chen*. Influence of precipitates on corrosion behavior of friction stir welded 2195-T8 joints.Mater. Character. Under review (2020).

[3] Y.L. Zhang, Z. Chen, S.J. Qu*,A.H. Feng, G.B. Mi, J. Shen, X. Huang, D.L. Chen*. Multiple a sub-variants and anisotropic mechanical properties of an additively-manufactured Ti-6Al-4V alloy,J. Mater. Sci. Technol.under review (2020).

[4] Y.L. Zhang, Z. Chen, S.J. Qu*,A.H. Feng, G.B. Mi, J. Shen, X. Huang, D.L. Chen*. Cyclic deformation behavior of a 3D-printed Ti-6Al-4V alloy.J. Alloys Compd.Revised (2020).

[5] Y.L. Zhang,A.H. Feng*, S.J. Qu, J. Shen, D.L. Chen*. Microstructure and low cycle fatigue of a Ti₂AlNb-based lightweight alloy.J. Mater. Sci. Technol.In press, (2020).

[6] Z.G. Zhang, S.J. Qu*, G.R. Cui*,A.H. Feng, J. Shen, D.L. Chen*. A new mechanism of dynamic phase transformations in an isothermal forged beta-gamma intermetallic alloy.Materials. 12 (2019) 2787.

[7] G.D. Wu, G.R. Cui, S.J. Qu*,A.H. Feng, G.J. Cao, B.H. Ge, H.P. Xiang, J. Shen, D.L. Chen*. High-temperature oxidation mechanisms of nano-/submicro-scale lamellar structures in an intermetallic alloy.Scripta Materialia. 171 (2019) 102-107.

[8] Y.X. Chen, J.C. Wang, Y.K. Gao*,A.H. Feng. Effect of shot peening on fatigue performance of Ti₂AlNb intermetallic alloy.International Journal of Fatigue. 127 (2019) 53-57.

[9] C.K. Yan, G.R. Cui*, S.J. Qu,A.H. Feng, J. Shen, D.L. Chen. Static recrystallization of pure titanium after cryo-deformation.Journal of Physics: Conference Series.IOP pubishing, 1270 (2019) 012040.

[10] K. Zhu, S.J. Qu,A.H. Feng*, J.L. Sun, J. Shen. Microstructural evolution and refinement mechanism of a beta-gamma TiAl-based alloy during multidirectional isothermal forging.Materials. 12 (2019) 2496.

[11] Y.J. Wu,A.H. Feng*, S.J. Qu, X. Hu, J. Shen. Macro-microscopic field evolution of Ti6Al4V alloy during isothermal upsetting based on deform platform.Materials Research Express. 6 (2019) 056505.

[12] Z.X. Zhang, S.J. Qu*,A.H. Feng, X. Hu, J. Shen. Microstructural mechanisms during multidirectional isothermal forging of as-cast Ti-6Al-4V alloy with an initial lamellar microstructure.J. Alloys Compd.713 (2019) 277-287.

[13] 朱凯，冯艾寒，曲寿江，沈军，铸态Ti-44Al-4Nb-(Mo,Cr,B)合金的热变形行为及热加工图，有色金属工程，9(9) (2019) 34-39.

[14] 闫辰侃，曲寿江，冯艾寒，沈军，钛及钛合金形变孪晶的研究进展，稀有金属，43(5) (2019) 449-460.(Cover page of the journal issue)

[15] 张胜雷，陈卓，曲寿江，冯艾寒，陆煦，沈军，陈道伦，热处理对电子束选区熔化制备的Ti-6Al-4V合金组织与力学性能的影响，热加工工艺，47(10) (2018) 226-231.

[16] S.J. Qu,A.H. Feng*, M.R. Shagiev, H. Xie, B.B. Li, J. Shen. Superplastic behavior of the fine-grained Ti-21Al-18Nb-1Mo-2V-0.3Si intermetallic alloy.Letters on Materilals.8 (4s), (2018) 567-571.

[17] J.M. Xiang, G.B. Mi, S.J. Qu*, X. Huang, Z. Chen,A.H. Feng, J. Shen, D.L. Chen**. Thermodynamic and microstructural study of Ti₂AlNb oxides at 800^oC.Scientific Reports. 8 (2018) 1276.

[18] Z.Y. Ma*,A.H. Feng**, D.L. Chen, J. Shen. Recent advances in friction stir welding/processing of aluminum alloys: microstructural evolution and mechanical properties.Critical Reviews in Solid State and Materials Sciences. 43(4) (2018) 269-333.(Highly cited paper as of 2019.10(Essential Science Indicators))

[19] K. Zhu, S.J. Qu,A.H. Feng, J.L. Sun, J. Shen*. Evolution of the microstructure and lamellar orientation of a beta-solidifying gamma-TiAl-based alloy during hot compression.Metals. 8 (2018) 445.

[20] C.K. Yan,A.H. Feng*, S.J. Qu, J.L. Sun, J. Shen. Hot deformation and grain refinement mechanisms of commercially pure titanium processed via three-directional cryo-compression.Mater. Sci. Eng. A731 (2018) 266-277.

[21] C.K. Yan,A.H. Feng*, S.J. Qu, G.J. Cao, J.L. Sun, J. Shen, D.L. Chen**. Dynamic recrystallization of titanium: Effect of pre-activated twinning at cryogenic temperature.Acta Mater. 154 (2018) 311-324.

[22] Z.X. Zhang, S.J. Qu,A.H. Feng, X. Hu, J. Shen*. The low strain rate response of as-cast Ti-6Al-4V alloy with an initial coarse lamellar structure.Metals. 8 (2018) 270-1-13.

[23] S.J. Qu*, S.Q. Tang,A.H. Feng, C. Feng, J. Shen, D.L. Chen**. Microstructural evolution and high-temperature oxidation mechanisms of a titanium aluminide based alloy.Acta Mater.148 (2018) 300-310.

[24] S.Q. Tang, S.J. Qu,A.H. Feng, C. Feng, J. Shen*, D.L. Chen**. Core-multishell globular oxidation in a new TiAlNbCr alloy at high temperatures.Scientific Reports. 7 (2017) 3483.

[25] Z.X. Zhang, S.J. Qu*,A.H. Feng, J. Shen, D.L. Chen*. Hot deformation behavior of Ti-6Al-4V alloy: Effect of initial microstructure.J. Alloys Compd.718 (2017) 170-181.

[26] Z.X. Zhang, S.J. Qu*,A.H. Feng, J. Shen. Achieving grain refinement and enhanced mechanical properties in Ti-6Al-4V alloy produced by multidirectional isothermal forging.Mater. Sci. Eng. A692 (2017) 127-138.

[27] A.H. Feng, D.L. Chen, Z.Y. Ma, W.Y. Ma, R.J. Song. Microstructure and strain hardening of a friction stir welded high-strength Al-Zn-Mg alloy.Acta Metall. Sin (Engl. Lett.)27(4) (2014) 723-729.

[28] 沈军*，冯艾寒. Ti₂AlNb基合金微观组织调制及热成形研究进展，金属学报，49(11) (2013) 1286-1294.

[29] M. Jafarzadegan, A.A. Zadeh,A.H. Feng, T. Saeid, J. Shen, H. Assadi. Microstructure and mechanical properties of a dissimilar friction stir weld between austenitic stainless steel and low carbon steel.J. Mater. Sci. Technol.29(4) (2013) 367-372.

[30] P. Lin,A.H. Feng, S.J. Yuan*, G.P. Li, J. Shen. Microstructure and texture evolution of a near-a titanium alloy during hot deformation.Mater. Sci. Eng. A563 (2013) 16-20.

[31] Q. Yang,A.H. Feng, B.L. Xiao, Z.Y. Ma*, Influence of texture on superplastic behavior of friction stir processed ZK60 magnesium alloy.Mater. Sci. Eng. A556 (2012) 671-677.

[32] M. Jafarzadegan,A.H. Feng, A.A. Zadeh, T. Saeid, J. Shen, H. Assadi. Microstructural characterization in dissimilar friction stir welding between 304 stainless steel and st37 steel.Mater. Characterization74 (2012) 28-41.

[33] X.J. Gu, C. Li,A.H. Feng, D.L. Chen. Application of flat-clad optical fiber bragg grating sensor in characterization of asymmetric fatigue deformation of extruded magnesium alloy.IEEE Sensors Journal. 11 (2011) 3042-3046.

[34] A.H. Feng, D.L. Chen*, Z.Y. Ma. Microstructure and cyclic deformation behavior of a friction-stir-welded 7075 Al alloy.Metall. Mater. Trans. A. 41A (2010) 957-971.

[35] A.H. Feng, D.L. Chen*, Z.Y. Ma. Microstructure and low-cycle fatigue of a friction-stir-welded 6061 aluminum alloy.Metall. Mater. Trans. A. 41A (2010) 2626-2641.

[36] A.H. Feng, D.L. Chen, C. Li, X.J. Gu. Flat-cladding fiber bragg grating sensors for large strain amplitude fatigue tests.Sensors10 (2010) 7674-7680.

[37] C. Li,A.H. Feng, X.J. Gu, D.L. Chen. Localized cyclic strain measurements of friction stir welded aluminum alloy using a flat-clad optical fiber sensor array.IEEE Sensors Journal10 (2010) 888-892.

[38] A.H. Feng, Z.Y. Ma*. Microstructure evolution of cast Mg-Al-Zn during friction stir processing and subsequent aging.Acta Materialia57 (2009) 4248-4260.

[39] A.H. Feng, B.L. Xiao, Z.Y. Ma*, R.S. Chen. Effect of friction stir processing procedures on microstructure and mechanical properties of Mg-Al-Zn casting.Metall. Mater. Trans. A. 40A (2009) 2447-2456.

[40] D.R. Ni, D. Wang,A.H. Feng, G. Yao, Z.Y. Ma*. Enhanced the high-cycle-fatigue strength of Mg-9Al-1Zn casting by friction stir processing.Scripta Mater.61 (2009) 568-571.

[41] A.H. Feng, B.L. Xiao, Z.Y. Ma*. Effect of microstructural evolution on mechanical properties of friction stir welded AA2009/SiCp composite.Compos. Sci. Technol.68 (2008) 2141-2148.

[42] A.H. Feng, B.L. Xiao, Z.Y. Ma*. Grain boundary misorientation and texture development in friction stir welded SiCp/Al-Cu-Mg composite.Mater. Sci. Eng. A497 (2008) 515-518.

[43] A.H. Feng, Z.Y. Ma*. Enhanced mechanical properties of Mg-Al-Zn cast alloy via friction stir processing.Scripta Mater.56 (2007) 397-400.(Scripta Materialia Top Cited Article 2007-2011:中国百篇最具国际影响力文章)

[44] A.H. Feng,Z.Y. Ma*. Formation of Cu₂FeAl₇phase in friction-stir-welded SiCp/Al-Cu-Mg composite.Scripta Mater.57 (2007) 1113-1116.

[45] S.J. Qu*,A.H. Feng, L. Geng, Z.Y. Ma, J.C. Han. DSC analysis of liquid volume fraction and compressive behavior of the semi-solid Si₃N₄w/Al-Si composite.Scripta Mater.56 (2007) 951-954.