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基本信息 The basic information
姓名: 王海鹏

学院: 物理科学与技术学院


学历: 博士研究生毕业

学位: 博士


职称: 教授

职务: 处长


学科: 材料科学与工程-材料物理与化学,物理学-凝聚态物理





工作经历 Work Experience
王海鹏，教授，博导，国家****科技领军人才，教育部新世纪优秀人才，国家优青，科技部中青年科技领军人才，多伦多大学访问****，中国青年科技奖、霍英东高校青年教师奖获得者，陕西省科技新星，西工大翱翔青年****。2004年4月留校工作，2012年遴选为材料物理与化学学科博士生导师。
西北工业大学校务委员会委员，一流大学建设领导小组办公室主任，学校发展规划领导小组办公室主任，第十一、十二、十三届党代会党代表，教代会代表。
CMS空间材料科学技术学会理事长、青年工作委员会副主任、凝固科学与技术学会副理事长。




教育教学 Education And Teaching
《液态金属结构与性质》——本科生课程
《空间实验原理与方法》——硕、博课程
《材料基因与纳米技术》——博士生课程
《国防材料技术概论》——硕士生课程
《纳米材料与技术》——本科生课程
《纳米材料物理》——硕士生课程
《亚稳材料物理》——硕士生课程
《非晶与准晶态物理》——本科生课程
《科学研究方法》——本科生课程
1.先进高温合金快速凝固与制备（航空航天用镍基高温合金、钛合金）
本方向主要面向航空航天领域核心高温合金，如镍基高温合金、钛合金等，设计并实现新型合金的快速凝固，从微观尺度入手，研究材料微观结构的演变规律，建立微观结构与宏观性质的物理图像，开发具有新型结构的合金。



图1 合金的微观结构，在深过冷条件下制备出细小初生相与共晶的复合结构

2. 新型金属材料的无容器处理
材料制备与成型过程对实验环境特别敏感，传统材料制备均在铸型中完成，铸型与材料的传热、传质、反应、浸润、异质形核等作用，使材料内部存在严重的微观偏析、内应力大等先天不足，严重制约了材料的应用。本方向采用超洁净环境，合成和制备新材料，实现材料微观组织的主动控制。




3. 液态合金的物理化学性质研究
液态合金的物理化学性质既是开展非平衡快速凝固理论的前提，又是开展液态理论研究的先决条件。由于深过冷液体在热力学上处于亚稳态，这些重要的热物理性质非常难以获取，致使快速凝固理论研究长期处于定性或半定量状态，亚稳液体理论建模工作也受到严重制约。本方向采用非接触测量技术，测定液态合金在深过冷条件下的表面张力、比热、粘度、扩散系数、密度等重要的性质，探索这些性质与温度合金成分的变化规律，揭示快速凝固过程中的热力学与动力学特征。

图2 液态金属镍的表面张力的实验测定与分子动力学计算

图3 亚稳液态镍硅的比热的实验测定与分子动力学计算



4. 亚稳液态合金的微观结构研究
亚稳液态合金的微观结构决定着宏观性质，而宏观性质则是微观结构的集中表现，二者之间存在非常紧密的联系，同时，微观结构的变化向下将遗传到固体结构，向上将延伸到过热的常规液态。本方向主要研究液态合金在深过冷亚稳条件下液态合金短程有序、团簇结构、原子堆积、配位分布、结构因子等特征，探索原子尺度特征对新材料制备与应用的作用机制。

图4 亚稳液态Fe-Cu合金偏双体分布函数的变化表征了两种原子偏聚规律

5. 计算材料科学
实验是获取液态合金物理化学性质的可靠且有效的途径，但是测定过程中存在的巨大实验难度，获取大的过冷度十分困难，这是目前物理化学性质缺乏的重要原因。凝固与制备材料过程中，由于材料不透明，且凝固速度快，无法实时观测相变与生长，只能通过最终凝固组织推测中间过程，致使人们很难认识真实的规律。采用有效的计算方法，建立合理的过冷液体计算模型，配合适当的实验，可以较为方便高效地解决上述问题。本方向采用分子动力学、相场理论等方法研究空间条件下液态合金的物理化学性质、快速凝固过程的微观组织演变、纳米尺度的原子分布与运动行为。

图5 深过冷条件下液态合金形成的团簇结构



招生信息 Admission Information
欢迎有志于在“材料物理与化学”（工科）、“物理学——凝聚态物理”（理科）领域实现人生梦想的青年才俊推免、报考研究生
招收类型：博士研究生（推免直博、硕博连读、考试录取）、硕士研究生（推免、考试录取）



荣誉获奖 Awards Information
19. 2019年，中国青年科技奖；
18. 2012年，教育部霍英东高校青年教师奖（2年评选一次，此次全国共102人获奖）；
17. 2011年，吴亚军优秀青年教师奖特等奖（当年全校共5人获特等奖）；
16. 2010年，陕西省科学技术一等奖（第2完成人）；
15. 2010年，全国优秀博士学位论文提名奖；
14. 2010年，第八届陕西青年科技奖；
13. 2010年，陕西省青年科技新星；
12. 2009年，国家教育部新世纪优秀人才；
11. 2006年，教育部自然科学二等奖（第2完成人）；
10. 2009年，西北工业大学青年****奖；
9. 2009年，西北工业大学优秀青年教师；
8. 2008年，西北工业大学“翱翔之星”；
7. 2008年，西北工业大学理学院优秀教师；
6. 自2013年，Applied Physics Letters、Philosophical Magazine Letters国际学术期刊的审稿人；
5. 自2010年，Nanotechnology、Int.J. Molecular Sci.国际学术期刊的审稿人；
4. 自2008年，Journal of Physics D: Applied Physics国际学术期刊的审稿人；
3. 自2008年，Journal of Physics: Condensed Matter国际学术期刊的审稿人；
2. 自2008年，陕西物理学会会员；
1. 研究生学习期间被授予“优秀研究生干部标兵”、“三好研究生标兵”、“十佳学生社会活动标兵”和陕西省“优秀毕业生”等称号。



科学研究 Scientific Research
11. 国家自然科学基金重点项目，高温多元合金的物理化学性质及其凝固过程主动控制研究，2018～2022，主持人；
10. 国家自然科学基金优青项目，金属材料深过冷与快速凝固研究，2016～2018，主持人；
9. 国家自然科学基金面上项目，电磁悬浮大体积镍基合金快速凝固机理与组织形成控制，2015～2018，主持人；
8. 国家自然科学基金面上项目，亚稳液态多元合金的物理化学性质与微观结构研究，主持人；
7. 国家教育部新世纪优秀人才支持计划，液态多元钛基合金的表面性质与表面结构研究，主持人；
6. 211工程三期新人新事新方向，液态Ni基高温合金的微观结构研究，主持人；
5. 陕西省自然科学基金，新型钛合金的无容器快速凝固研究，主持人；
4. 西工大翱翔之星人才计划，深过冷液态合金的热物理性质研究，主持人；
3. 921载人航天空间应用科学项目，XXXXXX，主要参与人；
2. 国家基金创新研究群体项目，金属材料空间环境地面模拟，主要完成人；
1. 国家自然科学基金重大项目，超常条件下材料凝固理论研究，主要完成人；



学术成果 Academic Achievements
发表论文情况
在Applied Physics Letters、Physical Review E、Journal of Chemical Physics、Metallurgical and Materials Transactions A/B、Scripta Materialia、Philosophical Magazine Letters、Physics Letters A、Journal of Physics D: Applied Physics、Science in China和Chinese Physics Letters国内外一流学报上发表SCI学术论文70余篇。

代表性论文
1.H. P. Wang, M. X. Li, P. F. Zou, X. Cai, L. Hu, and B. Wei*, “Experimental modulation and theoretical simulation of zonal oscillation for electrostatically levitated metallic droplets at high temperatures”, Physical Review E, 2018, 98: 063106. (SCI、EI)PDF
2.H. P. Wang, J. F. Zhao, W. Liu, and B. Wei*, “An anomalous thermal expansion phenomenon induced by phase transition of Fe-Co-Ni alloys”, Journal of Applied Physics, 2018, 124: 215107. (SCI、EI)PDF
3.P Lü, and H. P. Wang*, “Effects of Undercooling and Cooling Rate on Peritectic Phase Crystallization Within Ni-Zr Alloy Melt”, Metallurgical and Materials Transactions B, 2018, 49B: 499-508. (SCI、EI)PDF
4.P. Lü, H. P. Wang*, P. F. Zou, K. Zhou, L. Hu, and B. Wei，“Local atomic structure correlating to phase selection in undercooled liquid Ni-Zr peritectic alloy”，Journal of Applied Physics, 2018, 124(2): 025103. (SCI、EI)PDF
5.P. F. Zou, H. P. Wang*, S. J. Yang, L. Hu and B. Wei, “Density Measurement and Atomic Structure Simulation of Metastable Liquid Ti-Ni Alloys”, Metallurgical and Materials Transactions A, 2018, 49: 5488-5496. (SCI、EI)？PDF
6.H. P. Wang,J. Chang, and B. Wei, “Measurement and Calculation of Surface Tension for Undercooled Liquid Nickel and its Alloy”,Journal of Applied Physics, 2009, 106 (3) 033506. (SCI、EI收录，影响因子2.2)PDF

7.H. P. Wang,C. D. Cao and B. Wei, “Thermophysical Properties of a Highly Superheated and Undercooled Ni-Si Alloy Melt”,Applied Physics Letters, 2004, 84 (20) 4062-4064.(SCI、EI收录，影响因子4.0)PDF
8.H. P. Wang,W. J. Yao, and B. Wei, “Remarkable Solute Trapping Within Rapidly Growing Dendrites”,Applied Physics Letters, 2006, 89 (20) 201905. (SCI、EI收录，影响因子4.0)PDF
9.H. P. Wang,B. C. Luo, and B. Wei, “Molecular Dynamics Calculation of Thermophysical Properties for a Highly Reactive Liquid”,Physical Review E, 2008, 78 (4) 041204. (SCI、EI收录，影响因子2.5)PDF
10.H. P. Wang, S. J. Yang, and B. Wei, "Molecular Dynamics Prediction of Density for Metastable Liquid Noble Metals",Chemical Physics Letters, 2012, 539 30-34. (SCI收录，影响因子2.2)PDF

发表论文目录
2021年
94.P. C. Zhang, Y. J. Hu, J. Chang, H.P. Wang*, Microscopic hardness and dynamic mechanical analysis of rapidly solidified Fe-based amorphous alloys, Journal of Alloys and Compounds, 2021, in press.
93. P. F. Zou, H. P. Wang*, C.H. Zheng, L. Hu, J. Chang, B. Wei, Electrostatic levitation processing and microscopic hardness property of hyperperitectic Ti60Ni40 alloy, Intermetallics, 2021, 130, 106934.
92. P. F. Zou, C.H. Zheng, L. Hu, H. P. Wang*, Rapid Growth of TiNi intermetallic compound within undercooledTi50Ni50alloy under electrostatic levitation condition, Journal of Materials Science & Technology, 2021, 77, 82–89.


2020年


91.Q. Wang and H. P. Wang*, “Specific heat of ternary Ag-Si-Ge alloys from 123 K to high temperatures: experiment and prediction”, Journal of Thermal Analysis and Calorimetry, 2020, in press.
90.C. H. Zheng, H. P. Wang*, P. F. Zou, L. Hu, and B. Wei, “Determining thermophysical properties of normal and metastable liquid Zr-Fe alloys by electrostatic levitation method”, Metallurgical and Materials Transactions A, 2020 ,51, in press.
89.C. Liang, J. F. Zhao, J. Chang, and H. P. Wang*, “Microstructure evolution and nano-hardness modulation of rapidly solidified Ti–Al–Nb alloy”, Journal of Alloys and Compounds, 2020, 836, 155538.

88.Q. Wang, H. P. Wang*, D. L. Geng, and B. Wei, “Experimental determination of the Ni–Ni5Zr eutectic point for binary Ni–Zr alloy phase diagram”, Applied Physics A, 2020, 126, 375.
87.W. Liu, B. Zhai, J. F. Zhao, X. Cai, N. Yan, and H. P. Wang*, “Effect of High Undercooling on Dendritic Morphology and Mechanical Properties of Rapidly Solidified Inconel X750 Alloy” Metallurgical and Materials Transactions B, 2020,51.
86.X. Cai, and H. P. Wang*, “Heat transfer analysis of feedthrough flange under high alternating current condition”, Science China-Technological Sciences, 2020, 63(4) 686-692.
85.Z. C. Luo, and H. P. Wang*, “Combined effects of high undercooling and large cooling rate on microstructure evolution and hardening mechanism of rapidly solidified Ti-Al alloys”,Metallurgical and Materials Transactions A, 2020 ,51(3) 1242-1253.
84.Z. C. Luo, and H. P. Wang*, Primary dendrite growth kinetics and rapid solidification mechanism of highly undercooled Ti-Al alloys, Journal of Materials Science & Technology, 2020, 40, 47-53.
83. X. Cai, H. P. Wang*, and B. Wei, “Migration dynamics for liquid/Solid interface during levitation melting of metallic materials”, International Journal of Heat and Mass Transfer, 2020, 151, 110386.
82. H. P. Wang, P. Lü, X. Cai, B. Zhai, J. F. Zhao, B. Wei*, Rapid solidification kinetics and mechanical property characteristics of Ni–Zr eutectic alloys processed under electromagnetic levitation state, Materials Science Engineering A, 2020, 772, 138660.PDF
81. P. C. Zhang, J. Chang, and H. P. Wang*, “Transition from Crystal to Metallic Glass and Micromechanical Property Change of Fe-B-Si Alloy During Rapid Solidification”,Metallurgical and Materials Transactions B, (2019) doi:10.1007/s11663-019-01748-0.PDF
80. B. Zhai, K. Zhou, and H. P. Wang*, Coupling efect of undercooling and cooling on Ti–Al–V alloy, Solidifcation, Applied Physics A, 2020, 126,16. (SCI、EI)PDF



2019年

79. W. Liu, N. Yan, and H. P. Wang*, “Dendritic morphology evolution and microhardness enhancement of rapidly solidified Ni-based superalloys”, Science China Technological Sciences, 2019, 62(11) 1976-1986. (SCI、EI) PDF
78. J. Wu, C. Li？, Y. C. Liu？, X. C. Xia, Z. X. Zheng, and H. P. Wang*, “Precipitation of intersected plate-like γ’ phase in β and its effect on creep behavior of multiphase Ni3Al-based intermetallic alloy”, Materials Science & Engineering A, 2019, 767, 138439. (SCI、EI)PDF
77. J. Wu, C. Li？, Y. C. Liu？, X. C. Xia, Y. T. Wu, Y. F. Li, and H. P. Wang*, “Formation and widening mechanisms of envelope structure and its effect on creep behavior of a multiphase Ni3Al-based intermetallic alloy”, Materials Science & Engineering A, 2019, 763, 138158. (SCI、EI)PDF
76. J. Wu, C. Li？, Y. C. Liu？, X. C. Xia, Y. T. Wu, Z. Q. Ma, and H. P. Wang*, “Influences of solution cooling rate on microstructural evolution of a multiphase Ni3Al-based intermetallic alloy”, Intermetallics, 2019, 109, 48–59. (SCI、EI)PDF
75. M. X. Li, H. P. Wang*, and B. Wei, “Numerical analysis and experimental verification for heat transfer process of electrostatically levitated alloy droplets”, International Journal of Heat and Mass Transfer, 2019, 138, 109-116. (SCI、EI)PDF
74. X. Cai, H. P. Wang*, M. X. Li, Y. H. Wu and B. Wei, “A CFD Study Assisted with Experimental Confirmation for Liquid Shape Control of Electromagnetically Levitated Bulk Materials”, Metallurgical and Materials Transactions B, 2019, 50(2), 688-699. (SCI、EI)PDF
73. P. Lü, and H. P. Wang* and B. Wei, “Competitive Nucleation and Growth Between the Primary and Peritectic Phases of Rapidly Solidifying Ni–Zr Hypoperitectic Alloy”, Metallurgical and Materials Transactions A, 2019, 50(2), 789-803. (SCI、EI)PDF
72. Y. F. Si, and H. P. Wang*, P Lü, and B. Wei, “Peritectic solidification mechanism and accompanying microhardness enhancement of rapidly quenched Ni–Zr alloys”, Applied Physics A, 2019, 125(2), 102. (SCI、EI)PDF
71. J. Wu, C. Li*, Y. C. Liu*, Y. T. Wu, Q. Y. Guo, H. J. Li, and H. P. Wang*, Effect of annealing treatment on microstructure evolution and creep behavior of a multiphase Ni3Al-based superalloy, Materials Science and Engineering A, 2019, 743(16): 623-635. (SCI、EI)PDF
70.Q. Wang, J. Chang, and H. P. Wang*, “Thermophysical properties and atomic structure of liquid Si-Ge alloys”, Materials Chemistry and Physics, 2019, 221(1): 224-231. (SCI)PDF
2018年
69.H. P. Wang, M. X. Li, P. F. Zou, X. Cai, L. Hu, and B. Wei*, “Experimental modulation and theoretical simulation of zonal oscillation for electrostatically levitated metallic droplets at high temperatures”, Physical Review E, 2018, 98: 063106. (SCI、EI)PDF

68.H. P. Wang, J. F. Zhao, W. Liu, and B. Wei*, “An anomalous thermal expansion phenomenon induced by phase transition of Fe-Co-Ni alloys”, Journal of Applied Physics, 2018, 124: 215107. (SCI、EI)PDF
67.P Lü, and H. P. Wang*, “Effects of Undercooling and Cooling Rate on Peritectic Phase Crystallization Within Ni-Zr Alloy Melt”, Metallurgical and Materials Transactions B, 2018, 49B: 499-508. (SCI、EI)PDF
66.P. Lü, H. P. Wang*, P. F. Zou, K. Zhou, L. Hu, and B. Wei，“Local atomic structure correlating to phase selection in undercooled liquid Ni-Zr peritectic alloy”，Journal of Applied Physics, 2018, 124(2): 025103. (SCI、EI)PDF
65.X. Cai, H. P. Wang*, P Lü and B. Wei, “Optimized Electromagnetic Fields Levitate Bulk Metallic Materials”, Metallurgical and Materials Transactions B, 2018, 49: 2252-2260. (SCI、EI)PDF

64.P. F. Zou, H. P. Wang*, S. J. Yang, L. Hu and B. Wei, “Density Measurement and Atomic Structure Simulation of Metastable Liquid Ti-Ni Alloys”, Metallurgical and Materials Transactions A, 2018, 49: 5488-5496. (SCI、EI)PDF
63.H. P. Wang, C. H. Zheng, P. F. Zou, S. J. Yang, L. Hu and B. Wei*, “Density Determination and Simulation of Inconel 718 Alloy at Normal and Metastable Liquid States”, Journal of Materials Science & Technology, 2018, 34(3): 436-439. (SCI、EI)PDF
62.M. X. Li, H. P. Wang*, N. Yan and B. Wei, “Heat transfer of micro-droplet during free fall in drop tube”, Science China Technological Science, 2018 61(7): 1021-1030. (SCI、EI)PDF
61.W. Liu, J. Chang and H. P. Wang*, “Effect of Microstructure Evolution on Micro/Nano‐Mechanical Property of Fe–Co–Ni Ternary Alloys Solidified under Microgravity Condition”， Steel Research International, 2018, 89(7):**. (SCI、EI)PDF
60.Q. Wang, H. P. Wang*, D. L. Geng, M. X. Li and B. Wei, “A calorimetric study assisted with first principle calculations of specific heat for Si-Ge alloys within a broad temperature range”, Chinese Physics Letters, 2018, 35(12): 126501. (SCI、EI)PDF
59.翟斌, 周凯, 吕鹏，王海鹏*, “自由落体条件下Ti-6Al-4V合金微液滴的快速凝固”, 金属学报, 2018, 54(5): 824-830. (SCI、EI)PDF
58.蔡晓, 王海鹏*, 魏炳波, “三维大体积金属材料电磁悬浮过程的精准调控研究”, 中国有色金属学报, 2018, 28(11): 2288-2295. (EI)PDF

2014-2017年
57.H. P. Wang, S .J. Yang, L. Hu and B. Wei, “Molecular Dynamics Prediction and Experimental Evidence for Density of Normal and Metastable Liquid Zirconium”, Chemical Physics Letters, 2016, 653(1): 112-116. (SCI、EI）PDF
56.H. P. Wang, P. Lü, K. Zhou, and B. Wei, “Thermal Expansion of Ni3Al Intermetallic Compound: Experiment and Simulation”, Chinese Physics Letters, 2016, 33(4): 046502. (SCI)PDF
55.H. P. Wang, S. J. Yang, and B. Wei, “Predicting Macroscopic Thermal Expansion of Metastable Liquid Metals with Only One Thousand Atoms”, Science China-Physics, Mechanics & Astronomy, 2014, 57(12): 2235-2241. (SCI、EI)PDF
40.朱姜蕾, 王庆, 王海鹏*, “深过冷液态金属Cu的热物理性质和原子分布”, 金属学报, 2017, 53(8): 1018-1024. (SCI)PDF
54.K. Y. Zhou, Z. Y. Tang, Y. P. Lu*, T. M. Wang, H. P. Wang*, and T. J. Li, “Composition, Microstructure, Phase Constitution and Fundamental Physicochemical Properties of Low-Melting-Point Multi-Component Eutectic Alloys”, Journal of Materials Science & Technology, 2017, 33(2): 131-154. (SCI、EI)PDF
53.Y. T. Wu, Y. C. Liu, C. Li, X. C. Xia, Y. Huang, H. J. Li, and H. P. Wang, “Deformation Behavior and Processing Maps of Ni3Al-Based Superalloy during Isothermal Hot Compression”, Journal of Alloys & Compounds, 2017, 712: 687-695. (SCI)PDF
52.P. F. Zou, H. P. Wang*, S. J. Yang, L. Hu and B. Wei, “Anomalous Temperature Dependence of Liquid State Density for Ni50Ti50 Alloy Investigated Under Electrostatic Levitation State”, Chemical Physics Letters, 2017, 681(1): 101-104. (SCI、EI)PDF
51.P Lü, and H. P. Wang*, “Observation of the Transition from Primary Dendrites to Coupled Growth Induced by Undercooling within Ni-Zr Hyperperitectic Alloy”, Scripta Materialia, 2017, 137: 31-35. (SCI、EI)PDF
50.P Lü, K. Zhou, X. Cai and H. P. Wang*, “Thermophysical Properties of Undercooled Liquid Ni-Zr Alloys: Melting Temperature, Density, Excess Volume and Thermal Expansion”, Computational Materials Science, 2017, 135: 22-28. (SCI、EI)PDF
49.陈克萍, 吕鹏, 王海鹏*, “微重力条件下Cu-Zr共晶合金液固相变研究”, 物理学报, 2016, 66(6): 068101. (SCI)PDF
48.P Lü, K. Zhou and H. P. Wang*, “Evidence for the Transition from Primary to Peritectic Phase Growth during Solidification of Undercooled Ni-Zr Alloy Levitated by Electromagnetic Field”, Scientific Reports, 2016, 6: 39042. (SCI、EI)PDF
47.P Lü, and H. P. Wang*, “Direct Formation of Peritectic Phase but No Primary Phase Appearance in Ni83.25Zr16.75 Peritectic Alloy during Free Fall”, Scientific Reports, 2016, 6: 22641. (SCI、EI) PDF
46.P. Lü, Z. Y. Hong, J. F. Yin, N. Yan, W. Zhai, and H. P. Wang*, “Attenuation Motion of Acoustically Levitated Spherical Rotor”, Review of Scientific Instruments, 2016, 87:116103. (SCI)PDF
45.Y. Ruan, Q. Q. Gu, P. Lü, H. P. Wang and B. Wei, “Rapid Eutectic Growth and Applied Performances of Fe-Al-Nb Alloy Solidification Undercooled Electromagnetic Levitation Condition”, Materials and design, 2016, 112: 239-245. (SCI)PDF
44.K. Zhou, H. P. Wang, J. Chang, and B. Wei, “Experimental Study of Surface Tension, Specific Heat and Thermal Diffusivity of Liquid and Solid Titanium”, Chemical Physics Letters, 2015, 639: 105-108. (SCI、EI)PDF


2013年
43. X. B. Ma, H. P. Wang*, K. Zhou, J. Chang, and Z. Y. Hong, “Specific Heat Determination and Simulation of Metastable Ternary Ni₈₀Cu₁₀Si₁₀ Alloy Melt”, Applied Physics Letters, 2013, 103(10):104101. (SCI、EI)PDF
42.J. Chang,H. P. Wang, K. Zhou, and B. Wei, “Thermophysical properties and rapid solidification of an undercooled liquid hexabasic Ni-based alloy”,Philosophical Magazine Letters, 2013, 93 (4) 201-207. (SCI)PDF
41.K. Zhou,H. P. Wang, and B. Wei, “Thermophysical properties of substantially undercooled liquid Ti-Al-Nb ternary alloy measured by electromagnetic levitation”,Philosophical Magazine Letters, 2013, 93 (3) 138-141. (SCI)PDF
40.L. Hu,H. P. Wang, L. H. Li, and B. Wei, “Geometric optimization of electrostatic fields for stable levitation of metallic materials”,Science China Technological Sciences, 2013, 56 (1) 53~59. (SCI)PDF

2012年
39.H. P. Wang, S. J. Yang, and B. Wei, "Molecular Dynamics Prediction of Density for Metastable Liquid Noble Metals",Chemical Physics Letters, 2012, 539 30-34. (SCI收录，影响因子2.2)PDF
38.H. P. Wang, and B. Wei, “Ordered Structure Formation from Disordered Atoms Within Undercooled Liquid Rhodium”,Chemical Physics Letters, 2012, 521 (1) 55-58. (SCI收录，影响因子2.2)PDF
37.H. P. Wang, S. J. Yang and B. Wei, “Density and Structure of Undercooled Liquid Titanium”,Chinese Science Bulletin, 2012, 57 (7), 719-723. (SCI收录，影响因子1.1)PDF
36.L. Hu,H. P. Wang, L. H. Li, and B. Wei, “Electrostatic Levitation of Plant Seeds and Flower Buds”,Chinese Physics Letters, 2012, 29 (6) 064101~4. (SCI)PDF
35.J. Chang,H. P. Wang, K. Zhou, and B. Wei, “Surface Tension Measurement of Undercooled Liquid Ni-Based Multicomponent Alloys”,Philosophical Magazine Letters, 2012, 92 (9) 428-435. (SCI)PDF
34.J. Chang,H. P. Wang, K. Zhou, and B. Wei, “Rapid Dendritic Growth and Solute Trapping Within Undercooled Ternary Ni-5%Cu-5%Mo Alloy”,Applied Physics A, 2012, 109 (1) 139-143. (SCI)PDF
33.K. Zhou,H. P. Wang, and B. Wei, “Determining Thermophysical Properties of Undercooled Liquid Ti–Al Alloy by Electromagnetic Levitation”,Chemical Physics Letters, 2012, 521 (1) 52-54. (SCI收录，影响因子2.2)PDF

2011年
32.H. P. Wang, S. B. Luo, and B. Wei, “Measurement and Simulation of Specific Heat for Metastable Liquid Ni₈₀Fe₁₀Cu₁₀Alloy”,Applied Physics A-Materials Science & Processing, 2011, 105, 987-990. (SCI收录，影响因子1.8)PDF
31.H. P. Wang, and B. Wei, “Understanding Atomic-scale Phase Separation of Liquid Fe-Cu Alloy”,Chinese Science Bulletin, 2011, 56, 3416-3419. (SCI收录，影响因子1.1)PDF
30.K. Zhou,H. P. Wang, J. Chang, and B. Wei, “Surface Tension Measurement of Metastable Liquid Ti-Al-Nb Alloys”,Applied Physics A-Materials Science & Processing, 2011, 105 (1) 211-214. (SCI、EI收录, 影响因子1.8)PDF
29.K. Zhou,H. P. Wang,J. Chang, and B. Wei, “Specific Heat Measurement of Stable and metastable liquid Ti-Al alloys”,Applied Physics A-Materials Science & Processing, 2011, 103 (3) 135-137. (SCI、EI收录, 影响因子1.8)PDF
28.D. Y. Zang,H. P. Wang, F. P. Dai, D. Langevin, and B. Wei, “Solidification Mechanism Transition of Liquid Co-Cu-Ni Ternary Alloy”,Applied Physics A-Materials Science & Processing, 2011, 102 (2) 141-145.、EI收录, 影响因子1.8)PDF

2010年
27.H. P. Wang,and B. Wei, “Positive Excess Volume of Liquid Fe-Cu Alloys Resulting from Liquid Structure Change”,Physics Letters A, 2010, 374, 4787-4792. (SCI收录，影响因子2.2)PDF
26.H. P. Wang,J. Chang, and B. Wei, “Density and Related Thermophysical Properties of Metastable Liquid Ni-Cu-Fe Ternary Alloys”,Physics Letters A, 2010, 374: (24) 2489-2493. (SCI收录，影响因子2.2)PDF
25.H. P. Wang,and B. Wei, “Thermophysical Properties and Structure of Stable and Metastable Liquid Cobalt”,Physics Letters A, 2010, 374 (8) 1083-1087. (SCI收录，影响因子2.2)PDF
24.K. Zhou,H. P. Wang,J. Chang, and B. Wei, “Surface Tension of Substantially Undercooled Liquid Ti-Al Alloy”,Philosophical Magazine Letters, 2010, 90 (6) 455-462. (SCI、EI收录，影响因子1.9 )PDF
23.L. Hu,H. P. Wang, W. J. Xie and B. Wei, “Electrostatic Levitation Under theSingle-axis feedback Control Condition”,Science China, Physics, Mechanics & Astronomy,2010, 53 (8)1438-1444. (SCI、EI收录，影响因子1.2)PDF
22.L. Hu,H. P. Wang, W. J. Xie and B. Wei, “Electrostatic Levitation Under Single-axis Feedback Control Condition”,Chinese Science Bulletin，2010, 55 (24) 2755. (SCI、EI收录，影响因子1.1)PDF

2009年
21.H. P. Wang,and B. Wei, “Thermophysical Property of Undercooled Liquid Binary Alloy Composed of Metallic and Semiconductor Elements”,Journal of Physics D: Applied Physics, 2009, 42 (3) 035414. (SCI、EI收录，影响因子2.2)PDF
20.H. P. Wang,and B. Wei, “Thermophysical Properties of Stable and Metastable Liquid Copper and Nickel by Molecular Dynamics Simulation”,Applied Physics A-Materials Science & Processing, 2009, 95 (3) 661-665. (SCI收录、EI，影响因子1.8)PDF
19.H. P. Wang,J. Chang, and B. Wei, “Measurement and Calculation of Surface Tension for Undercooled Liquid Nickel and its Alloy”,Journal of Applied Physics, 2009, 106 (3) 033506. (SCI、EI收录，影响因子2.5)PDF
18.B. C. Luo,H. P. Wang,and B. Wei, “Specific Heat, Enthalpy, and Density of Undercooled Liquid Fe-Si-Sn Alloy”,Philosophical Magazine Letters, 2009, 89 (9) 527-533. (SCI、EI收录，影响因子1.9 )PDF
17.B. C. Luo,H. P. Wang,and B. Wei, “Phase Field Simulation of Monotectic Transformation for Liquid Ni-Cu-Pb Alloys”,Chinese Science Bulletin，2009, 54 (2) 183-188. (SCI收录，影响因子1.1)PDF
16.陈乐，王海鹏，魏炳波，液态三元Ni-Cu-Fe合金比热的实验与计算研究，物理学报，2009, 58 (1) 384-389. (SCI收录，影响因子1.3)PDF

2008年
15.H. P. Wang,and B. Wei, “Experimental Determination and Molecular Dynamics Simulation of Specific Heat for High Temperature Undercooled Liquid”,Philosophical Magazine Letters, 2008, 88 (11) 813-819. (SCI、EI收录，影响因子1.9)PDF
14.H. P. Wang,B. C. Luo, and B. Wei, “Molecular Dynamics Calculation of Thermophysical Properties for a Highly Reactive Liquid”,Physical Review E, 2008, 78 (4) 041204. (SCI、EI收录，影响因子2.5)PDF
13.H. P. Wang,B. C. Luo, T. Qin, J. Chang, and B. Wei, “Surface Tension of Liquid Ternary Fe-Cu-Mo Alloys Measured by Electromagnetic Levitation Drop Oscillating Method”,Journal of Chemical Physics, 2008, 129 (12) 124706-1. (SCI、EI收录，影响因子3.0)PDF
12.H. P. Wang,and B. Wei, “Theoretical Prediction and Experimental Evidence for Thermodynamic Property of Metastable Liquid Fe-Cu-Mo Ternary alloys”,Applied Physics Letters, 2008, 93 (17) 171904. (SCI、EI收录，影响因子4.0)PDF
11.J. Chang,H. P. Wang,and B. Wei, “Rapid Dendritic Growth Within an Undercooled Ni-Cu-Fe-Sn-Ge Quinary Alloy”,Philosophical Magazine Letters, 2008, 88 (11) 821-828. (SCI、EI收录，影响因子1.9 )PDF

2007年及以前
10.H. P. Wang,W. J. Yao, and B. Wei, “Remarkable Solute Trapping Within Rapidly Growing Dendrites”,Applied Physics Letters, 2006, 89 (20) 201905. (SCI、EI收录，影响因子4.0)PDF
9.H. P. Wang,W. J. Yao, C. D. Cao and B. Wei, “Surface Tension of Superheated and Undercooled Liquid Co–Si Alloy”,Applied Physics Letters, 2004, 85 (16)3414-3416. (SCI、EI收录，影响因子4.0)PDF
8.H. P. Wang,C. D. Cao and B. Wei, “Thermophysical Properties of a Highly Superheated and Undercooled Ni-Si Alloy Melt”,Applied Physics Letters, 2004, 84 (20) 4062-4064.(SCI、EI收录，影响因子4.0)PDF
7.H. P. Wang, C. D. Cao, and B. Wei, “Rapid Monotectic Solidification During Free Fall in Drop Tube”,Chinese Science Bulletin，2004, 49 (3) 220-225. (SCI收录)PDF
6.H. P. Wang, B. C. Luo, J. Chang and B. Wei, “Specific Heat and Related Thermophysical Properties of Liquid Fe-Cu-Mo Alloy”,Science in China G，2007, 50 (4) 397-406. (SCI、EI收录，影响因子1.2)PDF
5.H. P. Wang, J. Chang, B. C. Luo, and B. Wei, “Determination of the Surface Tension of Liquid Fe_77.5Cu₁₃Mo_9.5Ternary Monotectic Alloy”,Chinese Physics Letters，2007, 24 (2) 504-507. (SCI收录，影响因子1.1)PDF
4.H. P. Wang, and B. Wei, “Surface Tension and Specific Heat of Liquid Ni_70.2Si_29.8alloy”,Chinese Science Bulletin，2005, 50 (10) 945-949. (SCI收录)PDF
3.T. Qin,H. P. Wang,and B. Wei, “Simulated Evolution Process of Core-shell Microstructures”,Science in China G，2007, 50 (4) 546-552. (SCI、EI收录，影响因子1.2)PDF
2.臧渡洋，王海鹏，魏炳波，深过冷三元Ni-Cu-Co合金的快速枝晶生长，物理学报，2007, 56 (8) 4804-4809. (SCI、EI收录，影响因子1.3)PDF
1.X. Z. Song,H. P. Wang, Y. Ruan, and B. Wei, “Rapid Dendrite Growth in Quaternary Ni-based Alloys”,Chinese Science Bulletin，2006, 50 (8) 945-949. (SCI收录，影响因子1.1)PDF



团队信息 Team Information
材料物理与化学全国重点学科
凝聚态物理(物理学)
空间材料科学研究团队

2021年1月





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