刘剑 - 四川大学 - 机械工程学院

个人简介

教育背景及工作经历 2003.09～2007.07，四川大学材料成型及控制工程专业学士学位 2007.09～2010.07，四川大学钢铁冶金专业获硕士学位 2010.10～2014.12，英国伯明翰大学机械工程专业获博士学位 2005.01～至今，四川大学机械工程学院副教授 2017.08～2017.09，牛津大学访问学者担任四川大学机械工程学院副院长，主要从事先进制造和材料加工领域的研究，先后入选四川省“特聘专家”及四川省学术与技术带头人后备人选，获四川省科技进步奖三项(一项排名第一)，获四川大学青年科技人才奖，入选川大“双百B”人才计划。先后主持国家重点研发计划子课题、自然科学基金面上和青年项目以及主持四川省科技厅重点研发项目及其他纵横项项目10余项。在ACS Applied Materials & Interfaces、Metallurgical and Materials Transactions A、Journal of Alloys and Compounds、Journal of the European Ceramic Society、Journal of Manufacturing Processes、Materials Science and Engineering: A、International Journal of Refractory Metals and Hard Materials、International Journal of Advanced Manufacturing Technology、Materials and Manufacturing Processes、Manufacturing Review等杂志上发表学术论文近50余篇，其中以第一作者或通讯作者发表SCI论文近30篇， SCI他引次数近600次，2篇论文为期刊most cited articles,单篇SCI文章他引次数最高213次，次高160次。担任《精密成型》杂志通讯编委，担任中国机械工程学会极端制造分会会员。开设课程材料力学性能（全英文）；材料成型装备及智能化在研项目： 1. 国人数据人工智能建模分析技术与专家基础模板库构建，国家重点研发计划子课题 2. 高性能长寿命硬质合金刀具的脉冲磁场快速再制造技术关键机理研究，国家科学自然基金面上项目 3. 基于工业互联网的数控刀具协同设计制造及应用技术，横向 4. 高性能钛合金零部件的关键制造技术研究，横向 5. PSP复合技术制备Sialon陶瓷微型零件的尺寸精度控制研究，国家科学自然基金青年项目 6. 长寿命低成本粉末成型刀具产业化的外场再制造关键技术研究，四川省重点研发项目 7. 高性能钛合金液态成型关键技术研究，横向项目 8. 基于长寿命液压件的石墨烯耐磨耐蚀复合涂层的关键制备技术研究，横向项目 9. 叶片检测与失效分析，横向项目

研究领域

1. 金属零部件的特种能场制造（改性）与再制造（修复）技术 2. 增材制造(3D打印、应力分析)、智能制造（智能装备、智能加工、数字化工厂）、工业互联网（设备互联、信息传输、智能诊断等） 3. 生物医疗器械(医学+制造)、石墨烯衍生产品 4. 材料加工仿真技术（铸、锻、焊模流分析、结构设计分析等）

近期论文

查看导师最新文章（温馨提示：请注意重名现象，建议点开原文通过作者单位确认）

[1] Hanlin Fei, Jian Liu*, Sintering of the WC-6%Co cemented carbides for improved mechanical and cutting performance using Micro-FAST, International Journal of Refractory Metals and Hard Materials,Volume 98, August 2021, 105545[2] Zhe chen,Jian Liu*. The effect of the electric pulse treatment on the microstructure and mechanical performance of the Al–Zn alloy, Materials Science and Engineering: A,Volume 796, 7 October 2020, 140016. [3] K. Huang, W. Chen, M. Wu, J. Wang, K. Jiang, J. Liu*, Microstructure and densification of the Ti6Al4V–70%TiB2 metal-ceramic by coupled multi-physical fields-activated sintering, Journal of Alloys and Compounds, 820 (2020) 153091. [ [4] L. Zhang, J. Liu*, Y. Yang, G. Yang, K. Jiang, Sintering of BN/cemented carbide composites under an electric field for improved mechanical performances, Materials Science and Engineering: A, 761 (2019) 138018. [5] M. Wu, Z. Chen, C. Huang, K. Huang, K. Jiang, J. Liu*, Graphene platelet reinforced copper composites for improved tribological and thermal properties, RSC Advances, 9 (2019) 39883-39892. [6] J. Liu, M. Wu, Y. Yang, G. Yang, H. Yan, K. Jiang, Preparation and mechanical performance of graphene platelet reinforced titanium nanocomposites for high temperature applications, Journal of Alloys and Compounds, 765 (2018) 1111-1118. [7] J. Liu, C. Wei, G. Yang, L. Wang, L. Wang, X. Wu, K. Jiang, Y. Yang, A Novel Combined Electromagnetic Treatment on Cemented Carbides for Improved Milling and Mechanical Performances, Metallurgical and Materials Transactions A, 49 (2018) 4798-4808. [8] M. Li, J. Liu*#, X. Zhang, Y. Tian, K. Jiang, Fabrication of graphene/nickel composite microcomponents using electroforming, The International Journal of Advanced Manufacturing Technology, 96 (2018) 3191-3196. [9] Y. Zhou, W. Jiang, Y.T. Chen, Y. Yang, G. Yang, D.G. Yin, J. Liu*, Fabrication of Ultrafine WC-Ni Cemented Carbide by Coupled Multi-physical Fields Activated Sintering, Rare Metal Mat. Eng., 46 (2017) 561-564. [10] S. Ying, Z. Qian, Y. Gang, Y. Yi, W. Can, W. Ling, L. Jian*, Compressive Properties of the Grahpene Reinforced Titanium Composites, Rare Metal Mat. Eng., 46 (2017) 3882-3886. [11] G. Yi, Z. Dan, L. Jian*, Y. Yi, Y. Gang, Effects of Processing Parameters on Porous NiTi Alloys Prepared by Micro-FAST, Rare Metal Mat. Eng., 46 (2017) 2190-2196. [12] J. Liu*, H. Hassanin, Z.Y. Ni, Y. Yang, G. Yang, K. Jiang, Production of high-precision micro metallic components by electroforming process, Mater. Manuf. Process., 32 (2017) 1325-1330. [13] J. Liu*, H. Guo, Y. Su, L. Wang, L. Wei, G. Yang, Y. Yang, K. Jiang, Spark plasma sintering of graphene platelet reinforced zirconia composites with improved mechanical performance, Materials Science and Engineering: A, 688 (2017) 70-75. [14] M. Li, J. Liu*, X. Zhang, C. Zhou, S.P. Munagala, Y. Tian, J. Ren, K. Jiang, Graphene Platelet (GPL)/Nickel (Ni) Laminate Coatings for Improved Surface Properties Advanced Engineering Materials, 19 (2017) 1600795. [15] J. Liu, Y. Yang, H. Hassanin, N. Jumbu, S.A. Deng, Q. Zuo, K.L. Jiang, Graphene-Alumina Nanocomposites with Improved Mechanical Properties for Biomedical Applications, Acs Appl Mater Inter, 8 (2016) 2607-2616. [16] Qiao Lan..,Jian Liu*, 2016 3RD INTERNATIONAL CONFERENCE ON INFORMATION AND COMMUNICATION TECHNOLOGY FOR EDUCATION (ICTE 2016), Failure Analysis of Cracking Defect in Engine Cylinder Block. [17] Y. Zhou, Y. Yang, G. Yang, D.Q. Yin, Y. Qin, J. Liu*, Effects of sintering temperature on the densification of WC-6Co cemented carbides sintered by coupled multi-physical-fields activated technology, Manuf. Rev., 2 (2015) 5. [18] K. Jiang, J. Li, J. Liu*, Spark Plasma Sintering and Characterization of Graphene Platelet/Ceramic Composites, Advanced Engineering Materials, 17 (2015) 716-722. [19] J. Liu, Z. Li, H. Yan, K. Jiang, Spark Plasma Sintering of Alumina Composites with Graphene Platelets and Silicon Carbide Nanoparticles, Advanced Engineering Materials, 16 (2014) 1111-1118. [20] K. Jiang, J. Li, J. Liu*, Electrochemical codeposition of graphene platelets and nickel for improved corrosion resistant properties, RSC Advances, 4 (2014) 36245-36252. [21] J. Liu, H. Yan, K. Jiang, Mechanical properties of graphene platelet-reinforced alumina ceramic composites, Ceramics International, 39 (2013) 6215-6221. [22] J. Liu, H. Yan, M.J. Reece, K. Jiang, Toughening of zirconia/alumina composites by the addition of graphene platelets, Journal of the European Ceramic Society, 32 (2012) 4185-4193. [23] J. Liu, Y. Yang, K. Feng, D. Lu, Study on the effect of current on reactive sintering of the W–C–Co mixture under an electric field, Journal of Alloys and Compounds, 476 (2009) 207-212. [24] H. Hassanin, F. Modica, M.A. El-Sayed, J. Liu, K. Essa, Manufacturing of Ti–6Al–4V Micro-Implantable Parts Using Hybrid Selective Laser Melting and Micro-Electrical Discharge Machining, Advanced Engineering Materials, 18 (2016) 1544-1549. [25] S. Deng, P. Penchev, J. Liu, Y. Wang, K. Jiang, S. Dimov, Z. Zhang, Y. Liu, J. Leng, H. Butt, Laser directed writing of flat lenses on buckypaper, Nanoscale, 7 (2015) 12405-12410. [26] L. Zhang, J. Liu*, Y. Yang, G. Yang, K. Jiang, Reprint of: Sintering of BN/cemented carbide composites under an electric field for improved mechanical performances, Materials Science and Engineering: A, 766 (2019) 138411.