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基本信息 The basic information
姓名: 王海丰

学院: 材料学院


学历: 博士研究生毕业

学位: 博士


职称: 教授

职务:


学科:





工作经历 Work Experience
2010/06-2012/04 西北工业大学材料学院 讲师
2012/05-2015/04 西北工业大学材料学院 副教授
2015/05-至今 西北工业大学材料学院 教授
2011/10-2013/09 德国宇航院空间材料物理研究所 洪堡****
2014/01-2014/03 德国宇航院空间材料物理研究所 访问****
2015/08-2015/09德国宇航院空间材料物理研究所 访问****




教育经历 Education Experience

2000/09-2004/07 西北工业大学材料学院本科 材料成型及控制工程
2004/09-2010/06 西北工业大学材料学院硕士、博士 材料加工工程



教育教学 Education And Teaching
☆ 研究生课程
《热力学极值原理及其应用》（40学时）

☆ 本科生课程
《材料热力学》（60学时）
《Thermodynamics of Materials & Phase transformations》（58学时）



荣誉获奖 Awards Information
2011年 陕西省科学技术一等奖（排名第三）；德国洪堡****
2012年 学校顶级论文专项资助
2013年 学校顶级论文专项资助
2014年 学校首批“翱翔新星”
2015年 学校“翱翔青年****”；陕西省“青年科技新星”
2017年 陕西省****基金



科学研究 Scientific Research
☆ 研究方向
非平衡理论：多元多相合金非平衡凝固理论及固态相变理论
非平衡材料：耐磨及润滑材料设计、制备及其性能表征；亚稳金属材料设计、制备及其力学性能研究
☆ 研究项目
主持国家自然科学基金面上项目、青年项目等10余项，参与国家自然基金重点项目、国家“973”计划、总装预研共用技术项目等多项。主要主持国家基金情况如下：
[1] 2012/01-2014/12，国家自然基金青年项目（**）：“基于宏观-微观方法的多元合金枝晶非平衡凝固动力学研究”
[2] 2014/01-2017/12，国家自然基金面上项目（**）：“二元共晶凝固中三相交界线热力学与动力学研究”
[3] 2016/03-2018/02，霍英东青年教师基金（151048）：“损伤容限型钛基非晶-枝晶复合材料制备及力学性能研究”
[4] 2020/01-2023/12，国家自然基金面上项目（**）：“超高温长寿命耐磨难熔高熵合金设计、制备及摩擦学机理研究”




学术成果 Academic Achievements
在非平衡凝固理论，非平衡相变理论，热力学极值原理应用、块体非晶材料、耐磨及自润滑材料方面取得了一些研究成果，累计发表学术论文70余篇，其中本学科TOP期刊Acta Materialia论文20篇。
☆ 2019年学术论文
[1] Jianbao Zhang, Haifeng Wang*, Fan Zhang, Xinlei Lü, Yachan Zhang, Qing Zhou. Growth kinetics and grain refinement mechanisms in an undercooled melt of a CoSi intermetallic compound. Journal of Alloys and Compounds 781 (2019) 13-25
[2]Qing Zhou, Yue Ren, Yin Du, Weichao Han, Dongpeng Hua, Haimin Zhai, Ping Huang, Fei Wang, Haifeng Wang*. Identifying the significance of Sn addition on the tribological performance of Ti-based bulk metallic glass composites. Journal of Alloys and Compounds 780 (2019) 671-679
[3]Qing Zhou , Yin Du , Yue Ren, Wangwang Kuang, Weichao Han, Haifeng Wang*, Ping Huang, Fei Wang, Jian Wang*. Investigation into nanoscratching mechanical performance of metallic glass multilayers with improved nano-tribological properties. Journal of Alloys and Compounds 776 (2019) 447-459.
[4] Qing Zhou, Yin Du,Weichao Han, Yue Ren, Haimin Zhai, Haifeng Wang*. Identifying the origin of strain rate sensitivity in a high entropy bulk metallic glass. Scripta Materialia 164 (2019) 121–125.
[5] Zhaowu Tang, Shang Zhang, Ruipeng Cai, Qing Zhou, Haifeng Wang*. Designing High Entropy Alloys with Dual fcc and bcc Solid-Solution Phases: Structures and Mechanical Properties. Metallurgical and Materials Transactions A 50 (2019) 1888-1901.
[6] Fan Zhang, Haifeng Wang*,M. Koble, Jianbao Zhang, Qing Zhou, D.M. Herlach*. A Transition from Fine to Coarse Lamellar Eutectics in the Undercooled Ni-29.8 At. Pct Si Eutectic Alloy: Experiments and Modeling. Metallurgical and Materials Transactions A 50A (2019) 2847-2859.
[7] Qing Zhou, Weichao Han, Yin Du, Hongxing Wu, Andrew Bird, Xiaoxing Zhao, Xianzong Wang, Haifeng Wang*, Ben D. Beake. Enhancing fatigue wear resistance of a bulk metallic glass via introducing phase separation: A micro-impact test analysis. Wear 436-437 (2019) 203037.
☆ 2018年学术论文
[1] Jianbao Zhang, Haifeng Wang*, Wangwang Kuang, Yachan Zhang, Shu Li, Yuhong Zhao*, D.M. Herlach*. Rapid solidification of non-stoichiometric intermetallic compounds: Modeling and experimental verification. Acta Materialia, 2018, 148: 86-99.
[2] Wangwang Kuang, Haifeng Wang *, Xin Li, Jianbao Zhang, Qing Zhou,Yuhong Zhao*. Application of the thermodynamic extremal principle to diffusion controlled phase transformations in Fe-C-X alloys: Modeling and applications. Acta Materialia 2018, 159: 2018 16-30.
[3] Yuhao Xu, Qing Zhou*, Yin Du, Yue Ren, Haimin Zhai*, Qiang Li, Jialin Chen*, Haifeng Wang*, Modulating mechanical properties of Ti-based bulk metallic glass composites by tailoring dendrite composition with Sn addition. Journal of Alloys and Compounds, 2018, 745: 16-25.
[4] Yin Du, Qing Zhou*, Yue Ren, Wangwang Kuang, Weichao Han, Shang Zhang, Haimin Zhai, Haifeng Wang*. Tailoring shear banding behaviors in high entropy bulk metallic glass by minor Sn addition: A nanoindentation study. Journal of Alloys and Compounds 2018, 762: 422-430.
[5] Xin Li, Wangwang Kuang*, Jianbao Zhang, Qing Zhou, Haifeng Wang*. Application of the Thermodynamic Extremal Principle to Massive Transformations in Fe-C Alloys. Metallurgical and Materials Transactions A 2018, 49: 4484-4494.
[6] Fan Zhang, Cun Lai, Jianbao Zhang, Yachan Zhang, Qing Zhou, Haifeng Wang*. Anomalous eutectics in intermediately and highly undercooled Ni-29.8at.%Si eutectic alloy. Journal of Crystal Growth 2018, 495: 37-45.

☆ 2017年学术论文
[1]Xiao Zhang, Haifeng Wang*, Wangwang Kuang, Jianbao Zhang. Application of the thermodynamic extremal principle to phase-field modeling of non-equilibrium solidification in multi-component alloys. Acta Materialia 128, 2017: 258-269.
[2] Haimin Zhai, Yuhao Xu, Fan Zhang, Yue Ren, Haifeng Wang*, Feng Liu*. Effect oftransition metal elements (Cu, Ni, Co and Fe) on the mechanical properties ofTi-based bulk metallic glass composites. Journal of Alloys and Compounds. 2017,694: 1-9.
[3] Cun Lai, Jianbao Zhang, Fan Zhang, YachanZhang, Haifeng Wang*, Wei Yang, FengLiu*. Growth velocities and growth orientations in an undercooled melt ofNi31Si12 intermetallic compound. Journal of Alloys and Compounds. 2017, 712:241-249.
[4] Haimin Zhai, Yuhao Xu, Yin Du, Haifeng Wang*, Feng Liu*. Strain ratesensitivity and deformation behavior in a Ti-based bulk metallic glasscomposite. Journal of Non-Crystalline Solids 2017, 471: 128-136.
[5] R. Kobold, W.W. Kuang, H. Wang, W. Hornfeck, M. Kolbe, Dieter M. Herlach*. Dendrite growthvelocity in the undercooled melt of glass forming Ni50Zr50 compound.Philosophical Magazine Letters 2017, 97:249-256.
☆ 2016年学术论文
[1] Cun Lai, HaifengWang*, Qian Pu, Tingting Xu, Jinsong Yang, Xi Zhang, Feng Liu*. Phaseselection and re-melting-induced anomalous eutectics in undercooled Ni–38 wt%Si alloys. Journal of Materials Science, 2016, 51: 10990–11001.
[2] Wangwang Kuang, Haifeng Wang*, Jianbao Zhang, Feng Liu. Application of thethermodynamic extremal principle to diffusion-controlled phase-transformationsin multi-component substitutional alloys: Modeling and applications. Acta Materialia 2016, 120: 415-425.
[3] Haimin Zhai, Haifeng Wang*, Feng Liu*. Effects of Sn addition on mechanicalproperties of Ti-based bulk metallic glass composites. Materials and Design2016, 110: 782-789.
[4] Haimin Zhai, Haifeng Wang*, Feng Liu*. A strategy for designing bulk metallicglass composites with excellent work-hardening and large tensile ductility.Journal of Alloys and Compounds 2016, 685: 322-330.
[5] Wangwang Kuang, Haifeng Wang*, Feng Liu, S. L. Sobolev. Modeling of eutecticdendrite growth in undercooled binary alloys. Journal of Materials Science2016, 51: 2141-2152.
☆ 2016年以前主要学术论文
[1] H.F. Wang*, P.K. Galenko et al.Phase-field modeling of an abrupt disappearance of solute drag in rapidsolidification. Acta Materialia2015, 90: 282-291.
[2] W.W.Kuang, K. Christian, H.F. Wang* etal. Eutectic dendrite growth in undercooled Fe83B17 alloy: Experiments andmodeling. Scripta Materialia 2015,105: 34-37.
[3] K.Wang, H.F. Wang et al. Morphological stability analysis for planar interface duringrapidly directional solidification of concentrated multi-component alloys. Acta Materialia2014, 67: 220~231.
[4] H.F. Wang*, F.Liu, G.J. Ehlen et al. Application of the maximal entropy production principleto rapid solidification: A multi-phase-field model. Acta Materialia 2013, 61: 2617~2627.
[5] K. Wang, H.F. Wang et al. Modeling dendrite growth in undercooledconcentrated multi-component alloys. ActaMaterialia 2013, 61: 4254~4265.
[6] K. Wang, H.F. Wang et al. Modeling rapid solidification of multi-component concentrated alloys. Acta Materialia 2013, 61: 1359~1372.
[7] H.F. Wang*, F.Liu et al. Application of the maximal entropy production principle to rapidsolidification: A sharp interface model. ActaMaterialia 2012, 60: 1444~1454.
[8] H.F. Wang, F.Liu et al. Modeling grain refinement for undercooled single-phasesolid-solution alloy melt. ActaMaterialia 2011, 59: 4787~4797.
[9] H.F. Wang, F.Liu et al. Oscillatory morphological stability for rapidly directionalsolidification: Effect of nonlinear liquidus and solidus. Acta Materialia 2011, 59: 5859~5867.
[10] H.F. Wang, F.Liu et al. Modeling the overall solidification kinetics for undercooledsingle-phase solid-solution alloys-I: Model derivation. Acta Materialia. 2010, 58: 5402~5410.
[11] H.F. Wang, F.Liu et al. Modeling the overall solidification kinetics for undercooledsingle-phase solid-solution alloys-II: Model application. Acta Materialia. 2010, 58: 5411~5419.
[12] H.F. Wang, F. Liu et al. Kinetics ofdiffusion-controlled transformations: Application of probability calculation. Acta Materialia. 2009, 57: 3072~3083.
[13] H.F.Wang, F. Liu et al. Solute trapping model incorporating diffusive interface. Acta Materialia. 2008, 56: 746~753.
[14] H.F. Wang, F.Liu et al. An extended morphological stability model for a planar interfaceincorporating the effect of nonlinear liquidus and solidus. Acta Materialia. 2008, 56, 2592~2601.
[15] H.F. Wang, F.Liu et al. Analysis of non-equilibrium dendrite growth in bulk undercooledalloy melt; model and application. Acta Materialia. 2007, 55: 497~506.
[16] H.F. Wang, F.Liu et al. Effect of non-linear liquidus and solidus in undercooled dendritegrowth: A comparative study in Ni-0.7 at.% B and Ni-1 at.% Zr systems. Scripta Materialia. 2007, 57: 413~416.



团队信息 Team Information

本人隶属于先进润滑与密封材料研究中心刘维民院士团队。
西北工业大学先进润滑与密封材料研究中心成立于2017年3月，以中国科学院院士、“摩擦学最高成就奖”获得者刘维民教授为首席科学家，按照西北工业大学人才特区政策进行建设管理。中心依托学校材料科学与工程国家一级重点学科，以“建设一流科研环境，培养一流科技人才，做出一流科研成果”为最高目标。中心瞄准润滑材料及密封材料研究的国际前沿，面向国家重大需求，围绕材料学的基础科学问题，将材料学与润滑密封结合在一起，重点开展四个方向的研究：先进润滑材料、特种密封材料、材料表面/界面、功能纳米材料及应用。以期建设成为在国际润滑与密封领域具有重要影响、引领国际润滑与密封材料研究、支撑国家高技术装备及工业发展的润滑与密封材料及技术的研究中心。



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