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张海龙

 

张海龙

教授,博士生导师

 

北京科技大学新金属材料国家重点实验室

北京市海淀区学院路30号

邮编:100083

电话:010-62332258

传真:010-62333447

 

E-mail:hlzhang@ustb.edu.cn

 

个人简介

2003年6月在西安交通大学获博士学位,2003年10月—2005年8月在清华大学做博士后,2005年8月进入北京科技大学工作。2011年4月—2012年4月在德国达姆施塔特工业大学(Technische Universitӓt Darmstadt)访问研究,2016年7月—9月在美国德克萨斯大学达拉斯分校(University of Texas at Dallas)访问研究。主持国家863计划、国家自然科学基金等4项国家级课题和7项省部级课题;发表论文130多篇,SCI他引1600多次,H指数21;获授权专利22项。

 

研究兴趣

1.导热复合材料

2.电子封装材料

 

研究概述

随着器件集成度和功率密度的急剧增加,CPU芯片、LED照明、半导体激光器等高功率器件的有效散热成为微电子技术发展的瓶颈。本课题组利用高热导率金刚石颗粒或石墨烯与金属铜或铝制备导热复合材料,研究金属/非金属纳米多层结构的微尺度传热机制,为高功率器件的散热问题提供解决方案。

 

荣誉与奖项

  1. 2007年,北京市科技新星
  2. 2010年,教育部新世纪优秀人才

 

学术服务

  1. 美国矿物金属材料学会(TMS)会员,美国陶瓷学会会员,中国化工学会会员
  2. 多种学术期刊审稿人,包括Journal of the American Ceramic Society, Journal of Alloys and Compounds, Journal of Materials Science, Composites Part B, Diamond and Related Materials等

 

在研项目

  1. 国家自然科学基金,铜/碳化物/金刚石纳米多层结构的微尺度传热机制(51571015),2016年—2019年
  2. 国家重点研发计划课题,用于激光晶体冷却的新型散热材料及散热机制(2016YFB0402102),2016年—2020年

 

获授权专利22项

 

代表性论文

  1. L.H. Wang, J.W. Li, Z.F. Che, X.T. Wang, H.L. Zhang*, J.G. Wang*, M.J. Kim*: Combining Cr pre-coating and Cr alloying to improve the thermal conductivity of diamond particles reinforced Cu matrix composites, Journal of Alloys and Compounds, 749: 1098-1105 (2018)
  2. G.Z. Bai, N. Li, X.T. Wang, J.G. Wang, M.J. Kim, H.L. Zhang*: High thermal conductivity of Cu-B/diamond composites prepared by gas pressure infiltration, Journal of Alloys and Compounds, 735: 1648-1653 (2018)
  3. Z.F. Che, J.W. Li, Q.X. Wang, L.H. Wang, H.L. Zhang, Y. Zhang, X.T. Wang, J.G. Wang, M.J. Kim: The formation of atomic-level interfacial layer and its effect on thermal conductivity of W-coated diamond particles reinforced Al matrix composites, Composites Part A, 107: 164-170 (2018)
  4. Z.F. Che, Q.X. Wang, L.H. Wang, J.W. Li, H.L. Zhang, Y. Zhang, X.T. Wang, J.G. Wang, M.J. Kim: Interfacial structure evolution of Ti-coated diamond particle reinforced Al matrix composite produced by gas pressure infiltration, Composites Part B, 113: 285-290 (2017)
  5. Z.F. Che, J.W. Li, L.H. Wang, Y.X. Qi, Y. Zhang, H.L. Zhang, X.T. Wang, J.G. Wang, M.J. Kim: Effect of diamond surface chemistry and structure on the interfacial microstructure and properties of Al/diamond composites, RSC Advances, 6: 67252-67259 (2016)
  6. C.X. Li, X.T. Wang, L.H. Wang, J.W. Li, H.X. Li, H.L. Zhang*: Interfacial characteristic and thermal conductivity of Al/diamond composites produced by gas pressure infiltration in a nitrogen atmosphere, Materials & Design, 92: 643-648 (2016)
  7. J.W. Li, H.L. Zhang, L.H. Wang, Z.F. Che, Y. Zhang, J.G. Wang, M.J. Kim, X.T. Wang: Optimized thermal properties in diamond particles reinforced copper-titanium matrix composites produced by gas pressure infiltration, Composites Part A, 91: 189-194 (2016)
  8. Z.F. Che, Y. Zhang, J.W. Li, H.L. Zhang, X.T. Wang, C. Sun, J.G. Wang, M.J. Kim: Nucleation and growth mechanisms of interfacial Al4C3 in Al/diamond composites, Journal of Alloys and Compounds, 657: 81-89 (2016)
  9. J.W. Li, X.T. Wang, Y. Qiao, Y. Zhang, Z.B. He, H.L. Zhang*: High thermal conductivity through layer optimization in diamond particles dispersed Zr-alloyed Cu matrix composites, Scripta Materialia, 109: 72-75 (2015)
  10. J.W. Li, H.L. Zhang, Y. Zhang, Z.F. Che, X.T. Wang: Microstructure and thermal conductivity of Cu/diamond composites with Ti-coated diamond particles produced by gas pressure infiltration, Journal of Alloys and Compounds, 647: 941-946 (2015)
  11. B. Lin, X.T. Wang, Y. Zhang, J. Zhu, H.L. Zhang*: Interface characterization of a Cu-Ti-coated diamond system, Surface and Coatings Technology, 278: 163-170 (2015)
  12. H.L. Zhang, J.H. Wu, Y. Zhang, J.W. Li, X.T. Wang, Y.H. Sun: Mechanical properties of diamond/Al composites with Ti-coated diamond particles produced by gas-assisted pressure infiltration, Materials Science and Engineering A, 626: 362-368 (2015)
  13. J.S. He, X.T. Wang, Y. Zhang, Y.M. Zhao, H.L. Zhang*: Thermal conductivity of Cu-Zr/diamond composites produced by high temperature-high pressure method, Composites Part B, 68: 22-26 (2015)
  14. J.S. He, H.L. Zhang, Y. Zhang, Y.M. Zhao, X.T. Wang: Effect of boron addition on interface microstructure and thermal conductivity of Cu/diamond composites produced by high temperature-high pressure method, Physical Status Solidi A, 21: 587-594 (2014)
  15. L.L. Chen, X.T. Wang, W.J. Gong, H.L. Zhang*: Effect of yttrium addition on microstructure and orientation of hydride precipitation in Zr-1Nb alloy, International Journal of Hydrogen Energy, 39: 21116-21126 (2014)
  16. J.H. Wu, H.L. Zhang, Y. Zhang, J.W. Li, X.T. Wang: The role of Ti coating in enhancing tensile strength of Al/diamond composites, Materials Science and Engineering A, 565: 33-37 (2013)
  17. W.J. Gong, H.L. Zhang, C.F. Wu, H. Tian, X.T. Wang: The role of alloying elements in the initiation of nanoscale porosity in oxide films formed on zirconium alloys, Corrosion Science, 77: 391-396 (2013)
  18. W.J. Gong, H.L. Zhang, Y. Qiao, H. Tian, X.D. Ni, Z.K. Li, X.T. Wang: Grain morphology and crystal structure of pre-transition oxides formed on Zircaloy-4, Corrosion Science, 74: 323-331 (2013)
  19. J.H. Wu, H.L. Zhang, Y. Zhang, J.W. Li, X.T. Wang: Effect of copper content on the thermal conductivity and thermal expansion of Al-Cu/diamond composites, Materials & Design, 39: 87-92 (2012)
  20. Y. Zhang, H.L. Zhang, J.H. Wu, X.T. Wang: Enhanced thermal conductivity in copper matrix composites reinforced with titanium-coated diamond particles, Scripta Materialia, 65: 1097-1100 (2011)
  21. H.B. Qin, H.L. Zhang*, B.P. Zhang, L.H. Xu: Hydrothermal synthesis of perovskite BiFeO3–BaTiO3 crystallites, Journal of the American Ceramic Society, 94: 3671-3674 (2011)
  22. H.L. Zhang*, S. Yang, S. Yang, D.C. Kong, B.P. Zhang, Y.J. Zhang: Reliability enhancement in nickel-particle-dispersed alkaline niobate piezoelectric composites and actuators, Journal of the European Ceramic Society, 31: 795-800 (2011)
  23. S.W. Zhang, H.L. Zhang*, B.P. Zhang, S. Yang: Phase-transition behavior and piezoelectric properties of lead-free (Ba0.95Ca0.05)(Ti1-xZrx)O3 ceramics, Journal of Alloys and Compounds, 506: 131-135 (2010)
  24. S.W. Zhang, H.L. Zhang*, B.P. Zhang, G.L. Zhao: Dielectric and piezoelectric properties of (Ba0.95Ca0.05)(Ti0.88Zr0.12)O3 ceramics sintered in a protective atmosphere, Journal of the European Ceramic Society, 29: 3235-3242 (2009)
  25. H.L. Zhang, J.F. Li, B.P. Zhang, W. Jiang: Enhanced mechanical properties in Ag-particle-dispersed PZT piezoelectric composites for actuator applications, Materials Science and Engineering A, 498: 272-277 (2008)
  26. H.L. Zhang, J.F. Li, B.P. Zhang: Microstructure and electrical properties of porous PZT ceramics derived from different pore-forming agents, Acta Materialia, 55: 171-181 (2007)
  27. H.L. Zhang, J.F. Li, B.P. Zhang, K.F. Yao, W.S. Liu, H. Wang: Electrical and thermal properties of carbon nanotube bulk materials: Experimental studies for the 328K-958K temperature range, Physical Review B, 75: 205407 (2007)
  28. H.L. Zhang, J.F. Li, B.P. Zhang: Sintering and piezoelectric properties of co-fired PZT/Ag composites, Journal of the American Ceramic Society, 89: 1300-1307 (2006)
  29. H.L. Zhang, J.F. Li, K.F. Yao, L.D. Chen: Spark plasma sintering and thermal conductivity of carbon nanotube bulk materials, Journal of Applied Physics, 97: 114310 (2005)
  30. H.L. Zhang, P.Z. Huang, J. Sun, H. Gao: Morphological healing evolution of penny-shaped fatigue microcracks in pure iron at elevated temperatures, Applied Physics Letters, 85: 1143-1145 (2004)
  31. H.L. Zhang, J. Sun, H. Gao: Morphological healing evolution of intragranular penny-shaped microcracks by surface diffusion: Part II. Experiments, Metallurgical and Materials Transactions A, 34: 287-294 (2003)

 

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