Zhang Zhaohui, male, professor, doctoral supervisor, winner of Beijing Outstanding Talent Support Program. Carbon, Acta Materialia, Scripta Materialia, Composite Science and Technology, Materials & Design, Materials Science and Engineering A, Journal of Alloys and Compound and other international academic journal reviewer; Guest Editor (Contributing Editor), Journal of American Ceramic Society; Member of Mold Professional Committee of China Mechanical Engineering Society; National Natural Science Foundation of China Fund Project newsletter (network) reviewer; China Machine Press external editor. He is mainly engaged in the research of new ceramic protective materials, advanced cermet composite materials, nanomaterials, and the preparation technology of new materials by discharge plasma sintering. The main course of materials science and engineering undergraduate courses "Hydraulic transmission and Control", "Foundation of Casting Engineering", "Composite Materials", "Professional English"; Master program "Principles of Elastoplastic Mechanics"; Doctoral program "Computational Materials Science". He has presided over more than 20 scientific research projects such as National Natural Science Foundation, installation and development application transformation, National Defense 973 Program topic, installation and development pre-research, National Defense Science and Technology Foundation, installation and development Pre-Research Fund, and National Defense Science and Technology Key Laboratory Fund. He has published more than 100 academic papers, of which more than 80 are included in SCI, and he has cited more than 1,000 SCI papers. He edited 1 national planning textbook, wrote 2 monographs funded by the National Defense Science and Technology Books Publishing Fund, and published 6 finite element works, with a total print run of 100,000 copies. As the first inventor, he has applied for more than 40 national and national defense invention patents, and has authorized 31. He has won 1 first prize for excellent textbooks in Ordning-engineering universities (ranking 1st), 1 second prize for National defense science and technology inventions, and 1 Top Reviewer (Annual Best Reviewer) award each by Elsevier Publishing and Meitao.

New ceramic protective material; Advanced metal ceramic composite materials; Nanomaterials; Preparation technology of new materials by discharge plasma sintering.

From September 1990 to July 1994, he studied at Luoyang Institute of Technology and obtained a bachelor's degree in Mechanical design. From September 1994 to July 1997, he studied at Luoyang Institute of Technology and obtained a master's degree in composite materials. From September 1997 to July 2000, he studied at Beijing Institute of Technology and obtained his doctorate degree in Mechanical Manufacturing and Automation.

Since 2000, he has been working in the School of Materials, Beijing Institute of Technology.

[1] 张朝晖 著，《放电等离子烧结技术及其在钛基复合材料制备中的应用》，国防工业出版社，2018
[2] 张朝晖 主编，《ANSYS16.1结构分析工程应用及实例解析.第4版》，机械工业出版社，2016
[3] 张朝晖 主编，《ANSYS12.0热分析工程应用》，中国铁道出版社 2010
[4] 张朝晖 编著，《ANSYS有限元理论与工程应用.2版》，电子工业出版社，2008
[5] 王富耻，张朝晖 著，《静液挤压技术》，国防工业出版社，2008
[6] 张朝晖 主编，《计算机在材料科学与工程中的应用》，2008，中南大学出版社
[7] 张朝晖，蔡玉强 编著，《Pro/ENGINEER野火2版精彩实例教程》， 北京大学出版社，2006
[8] 张朝晖，姜开宇，赵丹阳 编著，《SolidWorks 2005精彩实例教程》，北京大学出版社，2006
[9] 张朝晖，王富耻，王鲁，李树奎 编著，《ANSYS工程应用范例入门与提高》，清华大学出版社，2004
[10] Q. Wang, Z.H. Zhang*, T.J. Su, X.W. Cheng*, X.Y. Li, S.Z. Zhang, J.Y. He. A TiB whisker-reinforced titanium matrix composite with controllable orientation: A novel method and superior strengthening effect, Materials Science and Engineering: A, 2022, 830: 142309.
[11] X.Y. Li, Z.H. Zhang*, X.W. Cheng*, G.J. Huo, Q. Song, Y. Xu. Direct achievement of ultra-high strength and good ductility for high CoNi secondary hardening steel by combining spark plasma sintering and deformation, Materials Letters, 2021, 290: 129465.
[12] Z.Y. Hu, Z.H. Zhang*, X.W. Cheng*, F.C. Wang, Y.F. Zhang, S.L. Li. A review of multi-physical fields induced phenomena and effects in spark plasma sintering- Fundamentals and applications, Materials and Design, 2020, 191: 108662.
[13] Q. Song, Z.H. Zhang*, Z.Y. Hu, S.P. Yin, H. Wang, X.Y. Li, X.W. Cheng*. Influences of the pre-oxidation time on the microstructure and flexural strength of monolithic B4C ceramic and TiB2-SiC-B4C composite, Journal of Alloys and Compounds, 2020, 831: 154852.
[14] Q. Song, Z.H. Zhang*, Z.Y. Hu, H. Wang, Y.F. Zhang, X.Y. Li, X.W. Cheng*. Mechanical properties and pre-oxidation behavior of spark plasma sintered B4C ceramics using (Ti3SiC2+CeO2/La2O3) as sintering aid, Ceramics International, 2020, 46: 22189-22196.
[15] Q. Song, S.P. Yin, Z.H. Zhang*, Z.Y. Hu. Microstructure and mechanical properties of super-hard B4C ceramic fabricated by spark plasma sintering with (Ti3SiC2+Si) as sintering aid. Ceramics International. 2019, 45: 8790-8797.
[16] Z.Y. Hu, Z.H. Zhang*, X.W. Cheng. Microstructure evolution and tensile properties of Ti-(AlxTiy) core-shell structured particles reinforced aluminum matrix composites after hot-rolling/heat-treatment, Materials Science and Engineering: A, 2018, 737: 90-93.
[17] S.P. Yin, Z.H. Zhang*, X.W. Cheng. Spark plasma sintering of B4C-TiB2-SiC composite ceramics using B4C, Ti3SiC2 and Si as starting materials. Ceramics International. 2018, 44: 21626-21632.
[18] Z.Y. Hu, Z.H. Zhang*, X.W. Cheng. A rapid route for synthesizing Ti-(AlxTiy/UFG Al) core-multishell structured particles reinforced Al matrix composite with promising mechanical properties. Materials Science & Engineering A. 2018, 721: 61-64.
[19] H. Wang, Z.H. Zhang*, Z.Y. Hu. Improvement of interfacial interaction and mechanical properties in copper matrix composites reinforced with copper coated carbon nanotubes. Materials Science & Engineering A. 2018, 715: 163-173.
[20] Z.Y. Hu, X.W. Cheng, H.M. Zhang, Z.H. Zhang*. Investigation on the microstructure, room and high temperature mechanical behaviors and strengthening mechanisms of the (TiB+TiC)/TC4 composites. Journal of Alloys and Compounds, 2017, 726: 240-253.
[21] H. Wang, Z.H. Zhang*, H.M. Zhang, Z.Y. Hu. Novel synthesizing and characterization of copper matrix composites reinforced with carbon nanotubes. Materials Science & Engineering A, 2017, 696: 80-89.
[22] Z.Y. Hu, X.W. Cheng, Z.H. Zhang*, H. Wang. The influence of defect structures on the mechanical properties of Ti-6Al-4V alloys deformed by high-pressure torsion at ambient temperature. Materials Science and Engineering: A. 2017, 684: 1-13.
[23] F.C. Wang, Z.H. Zhang*, Y.J. Sun, Z.Y. Hu. Rapid and low temperature spark plasma sintering synthesis of novel carbon nanotube reinforced titanium matrix composites, Carbon. 2015, 95: 396-407.
[24] Z.F. Liu, Z.H. Zhang*, J.F. Lu, F.C. Wang. Effect of sintering temperature on microstructures and mechanical properties of spark plasma sintered nanocrystalline aluminum. Materials & Design. 2014, 64: 625-630.
[25] Z.F. Liu, Z.H. Zhang*, F.C. Wang. A novel and rapid route for synthesizing nanocrystalline aluminum. Materials Science and Engineering: A. 2014, 615: 320-323.
[26] Z. H. Zhang*, F.C. Wang, Y.D. Wang. The sintering mechanism in spark plasma sintering – Proof of the occurrence of spark discharge. Scripta Materialia. 2014, 81: 56-59.
[27] S. Wei, Z.H. Zhang*, F.C. Wang. Effect of Ti content and sintering temperature on the microstructures and mechanical properties of TiB reinforced titanium composites synthesized by SPS process. Materials Science and Engineering A. 2013, 560(10-11): 249-255.
[28] Z.H. Zhang*, X.B. Shen, F.C. Wang. Microstructure characteristics and mechanical properties of TiB/Ti-1.5Fe-2.25Mo composites synthesized in situ using SPS process. Transactions of Nonferrous Metals Society of China. 2013, 23(9): 2958-2604.
[29] Z.H. Zhang*, X.B. Shen, F.C. Wang. A new rapid route to in-situ synthesize TiB-Ti system functionally graded materials using spark plasma sintering method. Materials Science and Engineering A. 2013, 565: 326-332.
[30] Z.H. Zhang*, L. Qi, X.B. Shen, F.C. Wang. Microstructure and mechanical properties of bulk carbon nanotubes compacted by spark plasma sintering. Materials Science and Engineering A. 2013, 573: 12-17.