吉林大学研究生导师教师简介-马志超

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马志超
(教授)赞
的个人主页 http://teachers.jlu.edu.cn/Mazhichao/zh_CN/index.htm教授博士生导师硕士生导师主要任职 : 吉林省材料服役性能测试产业公共技术研发中心副主任
性别 : 男毕业院校 : 吉林大学学历 : 博士研究生毕业学位 : 博士在职信息 : 在职所在单位 : 机械与航空航天工程学院学科 : 机械制造及其自动化办公地点 : 长春市人民大街5988号吉林大学南岭校区个人简介马志超，1986年10月生，教授，博士生导师，教育部青年****。
2013 年提前毕业获工学博士学位，2015年被破格聘任为副教授，同年进入工程仿生教育部重点实验室从事博士后研究，2018年通过学术委员会的教授职称评审，同年被遴选为博士生导师，2019年被破格聘任为教授。2019年受吉林大学“培英工程计划”支持，赴新加坡国立大学机械工程系和麻省理工学院材料科学与工程系开展合作研究。
主要从事原位力学测试技术和工程仿生方面的研究。现任吉林省材料服役性能测试产业公共技术研发中心副主任，是国际仿生工程学会（ISBE）会员、中国机械工程学会高级会员、中国仪器仪表学会试验机分会委员、国家自然科学基金委员会项目通讯评阅人。主持国家自然科学基金面上、青年基金、重点项目课题、国家重大科学仪器设备开发专项子课题、国家重点研发计划子课题、全国博士后基金特别资助、吉林省重点科技研发项目、中国科协青年人才托举工程项目等，获国家自然基金委优秀结题项目（机械类当年全国4项目)。
发表SCI 收录论文50余篇，其中ESI高被引论文一篇（1%）。合著原位力学测试领域的英文专著 2 部，成果被国际科技新闻网站 Vertical News、Space Mart 等专题报道，被加拿大工程院院士 Y. Sun、美国科学促进会会士 P. Ferreira、英国皇家工程院外籍院士 S. Fatikow、美国工程院院士 Kumar等学者正面引用和好评；授权美国发明专利1件，公开欧、欧洲发明专利 2 件，授权中国发明专利近 30 件，4 件专利在国机集团等企业转化实施；制定原位力学测试仪器的机械行业标准 2 项。负责起草《大百科全书》原位力学测试相关词条。
入选2018年教育部青年****、2017-2019年度中国科协青年人才托举工程，获教育部技术发明一等奖（排名第二）、吉林省技术发明一等奖（排名第二）、2017年中国仪器仪表学会青年科技人才奖（当年全国4人），入选国家优秀青年科学基金人才培育计划和优秀青年教师培养计划（重点阶段）。主要奖励荣誉：
（1）入选2018年教育部青年****
（2）入选2017-2019年度中国科协青年人才托举工程
（3）获教育部技术发明一等奖（排名第二）
（4）吉林省技术发明一等奖（排名第二）
（5）2017年中国仪器仪表学会青年科技人才奖（当年全国4人）
（6）2015、2017年中国有色金属科技论文奖
（7）入选吉林大学“培英工程计划”
（8）入选吉林大学国家优秀青年科学基金人才培育计划
（9）入选优秀青年教师培养计划（重点阶段）
（10）吉林大学优秀博士后
（11）吉林大学优秀博士学位论文
（12）国家自然基金“变温条件下材料复合应力疲劳性能原位测试新技术的研究”获国家自然基金委优秀结题项目（机械类当年全国4项目）

English edition:q Personal Information
§ Name: Zhichao Ma
§ Country: People's Republic of China
§ Email: zcma@jlu.edu.cn
§ Current job: Professor, Jilin University
§ Address: Renmin Street 5988, Jilin University, Changchun, 130025, Chinaq Academic Background
§ 2009/09-2013/12, School of Mechanical Sci & Eng, Jilin University, Doctoral Student
(Graduate in advance)
§ 2005/09-2009/07, School of Mechanical Sci & Eng, Jilin University, Undergraduate Student
q Work Experience
§ 2019/09-Current, National University of Singapore, Visiting Professor
§ 2018/12-Current, School of Mechanical and Aerospace Engineering, Jilin University,
Bionic Engineering Key Laboratory, Ministry of Education,
Nominated as Professor by President
§ 2017/06-Current, Secretary of the Academician Luquan Ren, Jilin University
§ 2015/10-Current, Jilin Province Material Service Performance Testing Center, Executive Director
§ 2015/09-Current, School of Mechanical Sci & Eng, Jilin University, Associate Professor
(Accelerated Promotion)
§ 2015/04-2016/05, Bionic Engineering Key Laboratory, Ministry of Education, Postdoctoral Fellow
§ 2014/06-2015/09, School of Mechanical Sci & Eng, Jilin University, Lecturer
q Research Interests
§ In situ Mechanical Testing Instruments
§ Mechanics of Materials at Micro/Nano scale
§ Multi Physical Field Coupling Driving/Testing
§ Bionic Design/Fabrication
q Scientific Research Projects as Leader
§ Young Elite Scientists Sponsorship, China Science and Technology Association
§ Decoupling of constitutive relation on basis of combined stresses----Special Project for Development of National Major Scientific Instruments
§ Design principle and mathematical model of biomimetic microstructural array----National Natural Science Foundation of China
§ Bionic construction of high entropy alloy artificial joints based on in-situ testing of failure mechanism ----National Natural Science Foundation of China
§ Multifunctional in-situ monitoring system----National Key R&D Program
§ PeiYing Project----Top Young Elite Program of Jilin University
§ Research on novel in situ test technologies of combined stresses fatigue properties of materials under variable temperature conditions----National Natural Science Foundation of China
§ In situ materials testing technology and equipment development for mechanical properties of high temperature and high frequency----Key Research and Development Projects in Jilin Province
§ Service performance evolution and coupled bionic design of high entropy alloy coating----Special Funding for the Post-Doctoral Science Fund of China
§ National Excellent Youth Science Fund Cultivation Plan of Jilin University
q Awards and Prizes
§ Young Yangtze River Scholar of the Ministry of Education, 2018
§ Science and Technology Award by Ministry of Education of China, 1st Prize, 2018, Second author
§ Young Elite Scientists Sponsorship by China Science and Technology Association, 2017
§ Youth Science and Technology Award by ChinaInstruments and Control Society, 2017
§ Technology Invention Award by Jilin Province, 1st Prize, 2016, Second author
§ Candidate of “Outstanding Young Science Foundation of China” of Jilin University, 2016
q Journal Reviewer
§ Advanced Engineering Materials
§ Materials & Design
§ Measurement Science & Technology
§ Journal of Alloys and Compounds
§ Review of Scientific Instruments
§ Materials
§ Experimental Techniques
§ Science China Technological Sciences
§ Nanoscale Research Letters
§ International Tribology
§ Mechanical Systems and Signal Processing
§ Sensor and Actuator A
q Memberships of Academic Societies
§ Member of International Society of Bionic Engineering
§ Senior Member of Chinese Mechanical Engineering Society
§ Invited Reviewer of National Natural Science Foundation of China
§ Senior Member of Nonferrous Metals Society of China
§ Member of Youth Committee, ChinaInstruments and Control Society
§ Council member of Jilin Provincial Society of Additional Materials Manufacturing
q Established Industrial Standards
[1] Ma, Z. C., Zhao, H. W., et al. (2016): In situ testing systems of tensile-bend combined mechanical properties for solid materials. (Chinese Industrial Standard, JB/T 13224-2017)
[2] Zhao, H. W., Zhang, J. W., Dong, J. S., Wang, X. Z., Xu, Z. G., Zhu, M., Ren, L. Q., Ma, Z. C. (2015): In situ tensile testing instruments for solid materials-Technical specification. (Chinese Industrial Standard, No JB/T 12720-2016)
q Monograph
[1] Zhao, H. W., Huang, H., Ji, J.B., Ma, Z. C. (2012): Design and analysis of key components in the nanoindentation and scratch test device, as a chapter published in book "Human Musculoskeletal Biomechanics", InTech OPEN ACCESS Publisher. 185-208.
[2] Zhao, H. W., Huang, H., Fan, Z. Q., Yang, Z. J., Ma, Z. C. (2012): Design, Analysis and Experiments of a Novel in situ SEM Indentation Device, as a chapter published in book "Nanoindentation in Materials Science", InTech OPEN ACCESS Publisher. 287-308.
q Publications
[1]Ma, Z. C., et al. (2020): Differences in surface mechanical properties of Zr-based bulk metallic glass related to stress condition. Materials Letters, In press.
[2] Ma, Z. C., et al. (2020): Mechanical properties of cortical bones related to temperature and orientation of Haversian canals. Materials Research Express, In press.
[3] Ma, Z. C., *Zhao, H. W., et al. (2019): Effective method to simultaneously release residual stress and promote planarization of surface indentation achieved by secondary indentation. Applied Surface Science, In press.
[4] Ma, Z. C., *Zhao, H. W., et al. (2019): Cyclic stress induced surface nanocrystallization adjacent to indentation edge of Zr-based bulk metallic glass at room temperature. Applied Surface Science, In press.
[5] Ma, Z. C., Zhang, W., *Zhao, H. W., et al. (2019): Enhanced strength and slightly reduced ductility in a high entropy alloy via cold rolling and annealing. Journal of Alloys and Compounds, In press.
[6] Ma, Z. C., *Zhao, H. W., Ren. L. Q., et al. (2019): Fatigue device driven by a three degree of freedom tripodal piezoelectric actuator. Review of Scientific Instruments, 90, 036102.
[7] Ma, Z. C., *Zhao, H. W., Ren. L. Q., et al. (2019): Static and cyclic mechanical behaviours and fracture mechanisms of Zr-based metallic glass at elevated temperatures. Philosophical Magazine, 7, 835-852.
[8] Ma, Z. C., *Zhao, H. W., Ren. L. Q., et al. (2019): Novel crystallization behaviors of Zr-based metallic glass under thermo-mechanical coupled fatigue loading condition. Acta Metallurgica Sinica, Published Online.
[9] Zhou, L. M., M., Ren, S. H., *Ma, Z. C. (2019): Node-based smoothed radial point interpolation method for electromagnetic-thermal coupled analysis. Applied Mathematical Modelling, 78, 841-862.
[10] Zhou, L. M., Li, M., Ma, Z. J., Ren, S. H., Li, X. L., Tang, J. H., *Ma, Z. C. (2019): Steady-state characteristics of the coupled magneto-electro-thermo-elastic multi-physical system based on cell-based smoothed finite element method. Composite Structures, 211, 111-128.
[11] Zhou, L. M., Ren, S. H., Liu, C. Y., *Ma, Z. C. (2019): A valid inhomogeneous cell-based smoothed finite element model for the transient characteristics of functionally graded magneto-electro-elastic structures. Composite Structures, 208, 298-313.
[12] Ma, Z. C., *Zhao, H. W., Ren. L. Q., et al. (2018): Evaluation of nanoindentation load-depth curve of MEMS bridge structures by calculating the critical elastic-plastic bending deflections. Applied Surface Science, 434, 1-10.
[13] Zhou, L. M., Ren, S. H., Liu, C. Y., *Ma, Z. C. (2019): A valid inhomogeneous cell-based smoothed finite element model for the transient characteristics of functionally graded magneto-electro-elastic structures. Composite Structures, 208, 298-313.
[14] Liu, C. Y., Ma, Z. C., Ren. L. Q., et al. (2018): Correction method for mechanical performance testing instrument with Tension–torsion coupling loading. Measurement Science & Technology, Published Online.
[15] Ma, Z. C., *Zhao, H. W., Ren. L. Q., et al. (2018): Motor-piezoelectricity coupling driven high temperature fatigue device. Review of Scientific Instruments, 89, 016102.
[16] Liu, C. Y., H.W. Zhao*, Ma, Z. C., et al. (2017): Novel instrument for characterizing comprehensive physical properties under multimechanical loads and multi-physical field coupling conditions. Review of Scientific Instruments, 89, 025112.
[17] Zhou, M.X., Fan, Z.Q., Ma, Z. C., et al. (2017): Effects of Flotage on Immersion Indentation Results of Bone Tissue: An Investigation by Finite Element Analysis, Advances in Materials Science and Engineering, 2017, 4569351.
[18] Zhou, M.X., Fan, Z.Q., Ma, Z. C., et al. (2017): Design and Experimental Research of a Novel Stick-Slip Type Piezoelectric Actuator, Micromachines, 8, 150.
[19] Zhong, Y. X., Zhao, H. W., Ma, Z. C., et al. (2017): A study on the effect of double-tip inclined angle on micro-scratching process using smooth particle hydrodynamic method, Advances in Mechanical Engineering. 9, 1-7.
[20] Ma, Z. C., *Zhao, H. W., Ren. L. Q., et al. (2016): Elastic-plastic bending properties of an AZ31B magnesium alloy based on persistent tensile preloads. Journal of Alloys and Compounds, 708 (2017) 594-599
[21] Ma, Z. C., *Zhao, H. W., Ren. L. Q., et al. (2016): Thermo-mechanical coupled in situ fatigue device driven by piezoelectric actuator. Precision Engineering, 46, 349-359.
[22] Ma, Z. C., *Zhao, H. W., Ren. L. Q., et al. (2016): Fracture criterion on basis of uniformity of plastic work of polycrystalline ductile materials under various stress states. Acta Mechanica, 227, 2053-2059.
[23] Zhao, H. W., Zhong, Y. X., *Ma, Z. C. (2016): Effects of indentation depth on micro hardness and scratch behavior. Journal of Alloys and Compounds, 680, 105-108.
[24] Sun, X. D., *Zhao, H. W., Yu, Y., Zhang, S. Z., Ma, Z. C., et al. (2016): Variations of mechanical property of out circumferential lamellae in cortical bone. AIP Advances, 6, 115116.
[25] Ma, Z. C., *Zhao, H. W., Ren. L. Q., et al. (2016): Measurement error of Young’s modulus considering the gravity and thermal expansion of thin films. Measurement Science & Technology, 27, 127001.
[26] Hou, P. L., *Zhao, H. W., Ma, Z. C., et al. (2016): Influence of punch radius on elastic modulus of three-point bending tests. Advances in Mechanical Engineering. 8, 1-8.
[27] Ma, Z. C., *Zhao, H. W., et al. (2016): Method for determining of true stress of cross-shaped specimens subjected to biaxial tensile loads. Instruments and Experimental Techniques, 59, 287-293.
[28] Ma, Z. C., *Zhao, H. W., Ren. L. Q., et al. (2015): Evaluation of equivalent accumulation area of internal defects based on statistical law of yield loads. Journal of Alloys and Compounds, 649, 500-504.
[29] Ma, Z. C., *Zhao, H. W., et al. (2015): Deformation behavior of micro-indentation defects under uniaxial and biaxial loads. Review of Scientific Instruments, 86, 095112.
[30] Ma, Z. C., *Zhao, H. W., et al. (2015): A novel tensile device for in situ scanning electron microscope mechanical testing. Experimental Techniques, 39, 3-11.
[31] Ma, Z. C., *Zhao, H. W., et al. (2015): Modular correction method of bending elastic modulus based on sliding behavior of contact point. Measurement Science & Technology, 26, 087001.
[32] Ma, Z. C., *Zhao, H. W., et al. (2015): Critical Fracture Behavior of a Cu/Al Composite Laminate via the Observation of Scanning Electron Microscope. Materials Transactions, 56, 813-818.
[33] Ma, Z. C., *Zhao, H. W., et al. (2015): Prediction Method of Low Cyclic Stress-Strain Curve of Structural Materials. Materials Transactions, 56, 1067-1071.
[34] Ma, Z. C., *Zhao, H. W., et al. (2015): Effects of zinc on the static and dynamic mechanical properties of copper-zinc alloy. Journal of Central South University, 22, 2440-2445.
[35] Li, J. P., Zhao, H. W., Qu, X. T., Qu, H., Zhou, X. Q., Fan, Z. Q., Ma, Z. C. et al. (2015): Development of a compact 2-DOF precision piezoelectric positioning platform based on inchworm principle. Sensors and Actuators A, 222, 87-95.
[36] Ma, Z. C., *Zhao, H. W., et al. (2014): Influences of tensile pre-strain and bending pre-deflection on bending and tensile behaviors of an extruded AZ31B magnesium alloy. Materials & Design, 64, 566-572.
[37] Ma, Z. C., *Zhao, H. W., et al. (2014): Decomposition method based on a modified Arcan fixture and its application in an in situ combined load tester. Measurement Science & Technology, (2014) 25, 127001.
[38] Ma, Z. C., *Zhao, H. W., et al. (2014): Effects of 2D misalignment on tensile results and corresponding correction methods to obtain the true tress-train curve. Measurement Science & Technology, 25, 115011
[39] Zhang, L., *Zhao, H. W., Ma, Z. C., et al. (2014): Molecular dynamics simulation of linearly varying cutting depth of single point diamond turning on Cu (111). International Journal of Nanomanufacturing, 10, 33-357.
[40] Zhang, L., *Zhao, H. W., Yang, Y. H., Huang, H., Ma, Z. C., et al. (2014): Evaluation of Repeated Single Point Diamond Turning on the Deformation Behavior of Monocrystalline Silicon via Molecular Dynamic Simulations. Applied Physics A, 116, 141-150.
[41] Zhang, L., *Zhao, H. W., Guo, W. C., Ma, Z. C., et al. (2014): Quasicontinuum Analysis of the Effect of Tool Geometry on Nanometric Cutting of Single Crystal Copper. Optik, 125, 682-687.
[42] Ma, Z. C., *Zhao, H. W., et al. (2013): Novel in situ device for investigating the tensile and fatigue behaviors of bulk materials. Review of Scientific Instruments, 84, 045104.
[43] Ma, Z. C., *Zhao, H. W., et al. (2013): Note: Investigation on the influences of gripping methods on elastic modulus by a miniature tensile device and in situ verification. Review of Scientific Instruments, 84, 066102.
[44] Ma, Z. C., *Zhao, H. W., et al. (2013): Novel correction methods on a miniature tensile device based on a modular non-standard layout. Measurement Science &Technology, 24, 085901.
[45] Zhang, L., *Zhao, H. W., Huang, H., Ma, Z. C., et al. (2013): The evolution of machined-induced surface of single crystal FCC copper via nanoindentation. Nanoscale Research Letters, 8, 211.
[46] Huang, H., *Zhao, H. W., Fan, Z. Q., Zhang, H., Ma, Z. C., et al. (2013): Analysis and experiments of a novel and compact 3-DOF precision positioning platform. Journal of Mechanical Science and Technology, 27, 1-11.
[47] Zhang, L., *Zhao, H. W., Ma, Z. C., et al. (2013): A Study on Size Effect of Indenter in Nanoindentation via Molecular Dynamics Simulation. Key Engineering Materials, 562-565, 802-808.
[48] Ma, Z. C., *Zhao, H. W., et al. (2012): A miniaturized in situ tensile platform under microscope. Telkomnika, 10, 524-530.
[49] Zhang, L., *Zhao, H. W., Ma, Z. C., et al. (2012): A study on phase transformation of monocrystalline silicon due to ultraprecision polishing by molecular dynamics simulation. AIP ADVANCES, 2, 042116.
[50] Huang, H., *Zhao, H. W., Ma, Z. C., et al. (2012): Design and analysis of the precision-driven unit for nanoindentation and scratch test. Journal of Manufacturing Systems, 31, 76-81.
[51] Shi, C. L., *Zhao, H. W., Huang, H., Wan, S. G., Ma Z. C., et al. (2013): Effects of probe tilt on nanoscratch results: An investigation by finite element analysis, Tribology International, 60, 64-69.
[52] Huang, H., *Zhao, H. W., Zhang, Z. Y., Yang, Z. J., Ma, Z. C. (2012): Influences of Sample Preparation on Nanoindentation Behavior of a Zr-Based Bulk Metallic Glass, Materials, 5, 1033-1039.
[53] Huang, H., *Zhao, H. W., Yang, Z. J., Mi, J., Fan, Z. Q, Wan, S. G, Shi, C. L., Ma, Z. C. (2012): A novel driving principle by means of the parasitic motion of the microgripper and its preliminary application in the design of the linear actuator, Review of Scientific Instruments , 83, 055002.
[54] Huang, Hu., *Zhao, H. W., Mi, J., Yang, J., Wan, S. G., Xu, L. X., Ma, Z. C. (2012): A novel and compact nanoindentation device for in situ nanoindentation tests inside the scanning electron microscope, AIP ADVANCES , 2, 012104.
[55] Huang, H., *Zhao, H. W., Yang, Z. H., Fan, Z. Q., Wan, S. G, Shi, C. L., Ma, Z. C. (2012): Design and analysis of a compact precision positioning platform integrating strain gauges and the piezoactuator, Sensors, 12, 9697-9710.
[56] Huang, H., *Zhao, H. W., Mi, J., Yang, J., Wan, S. G., Yang, Z. J., Yan, J. W., Ma, Z. C. et al. (2011): Experimental research on a modular miniaturization nanoindentation device, Review of Scientific Instruments, 82(9), 095101.
[57] Ma, Z. C., *Ren. L. Q., et al. (2018): Miniaturized piezoelectric driven fatigue device inside SEM. Academic Conference on Measurement Control and Metrology Technology at Guangzhou, China, September 2018.
[58] Ma, Z. C., *Zhao, H. W., et al. (2012): Calibration methods based on stress-strain curve for a novel tensile platform inside SEM. Proc. 10th Int. Conf. on Frontiers of Design and Manufacturing at Chongqing, China, July 2012.
[59] Ma, Z. C., *Zhao, H. W., et al. (2012): Analysis and experiment of a novel miniature driven unit for in situ fatigue test based on tensile preload. Proc. 10th Int. Conf. on Frontiers of Design and Manufacturing at Chongqing, China, July 2012.
[60] Huang, H., Shi, C. L., *Zhao, H. W., Ma, Z. C. (2012): An Integrated Nanoindentation Module: Design and Experiments. Proc. 10th Int. Conf. on Frontiers of Design and Manufacturing at Chongqing, China, July 2012.
[61] Zhang, L., *Zhao, H. W., Huang, H., Ma, Z. C., (2012): Effects of the Deformation of Indenter in Nanoindentation–Molecular Dynamics Simulation. Proc. 10th Int. Conf. on Frontiers of Design and Manufacturing at Chongqing, China, July 2012.
[62] Huang, H., *Zhao, H. W., Ma, Z. C., et al. (2011): Development of a novel nanoindentation device for in situ test in SEM, 2nd Nano today conference at Hawaii USA, 2011.
[63] Ma, Z. C., *Zhao, H. W., et al. (2011): In situ tensile test platform design and experimental research under microscopes. 9th National Doctoral Student Conference at Changsha, China, September 2011.
[64] Ma, Z. C., Hu, L. L., *Zhao, H. W., et al. (2010): Theoretical and experimental research on machine tool servo system for ultra-precision position compensation on CNC lathe. Proceedings of SPIE, (2010) 7544.
[65] Ma, Z. C., *Zhao, H. W., Ren, L. Q. (2017): Motor-piezoelectricity coupling driven high temperature fatigue device based on adjustable monotonic and cyclic loading. 2017 Development Forum of test machine and Test Technology. 12-16.
q Patents
[1]Ma, Z. C.; Zhao, H. W., et al.: In situ mechanical testing method and system for materials subjected to static and dynamic load spectrum. U. S. patent, WO**
[2] Ma, Z. C.; Zhao, H. W., et al.: Macroscopic/microscopic rotating driving platform based on biomimetic tentacle and thermalexpansion. (Authorized Chinese invention patent, Patent No **4.9)
[3] Ma, Z. C.; Zhao, H. W., et al.: Fatigue performance testing device of microstructure under combined stresses and high temperature. (Authorized Chinese invention patent, Patent No **1.4)
[4] Ma, Z. C.; et al.: Flexible driving bionic massage manipulator based on pneumatic artificial muscle. Submitted as: Chinese invention patent (Application No **6.0, application date 06.03.2018)
[5] Ma, Z. C.; et al.: Electromagnetic experimental device for measuring impact mechanical properties of biomaterials. Submitted as: Chinese invention patent (Application No **4.9, application date 06.03.2018)
[6] Ma, Z. C.; et al.: Electromechanical thermal coupling stress corrosion in-situ fatigue test device. Submitted as: Chinese invention patent (Application No **4.6, application date 20.01.2018)
[7] Ma, Z. C.; et al.: Piezoelectric driven three jaw bionic micro size clamping mechanism based on flexure hinge. Submitted as: Chinese invention patent (Application No **6.X, application date 24.08.2017)
[8] Ma, Z. C.; et al.: Multi stage static and dynamic coupling mechanical loading device for high frequency fatigue test. Submitted as: Chinese invention patent (Application No **8.X, application date 24.08.2017)
[9] Ma, Z. C.; et al.: High temperature heating chamber for in-situ optical monitoring and synchrotron radiation. Submitted as: Chinese invention patent (Application No **4.6, application date 11.07.2017)
[10] Ma, Z. C.; et al.: Bionic construction method of high entropy alloy artificial joint based on in-situ test. Submitted as: Chinese invention patent (Application No **0.6, application date 11.07.2017)
[11] Ma, Z. C.; et al.: Calibration method of micro bridge indentation load depth curve for MEMS. Submitted as: Chinese invention patent (Application No **8.3, application date 15.03.2017)
[12] Ma, Z. C.; et al.: In situ testing system and method for mechanical properties of materials under static and dynamic load spectrum. Submitted as: Chinese invention patent (Application No **0.2, application date 08.07.2016)
[13] Qian, Q. M.; Gao, Y. X.; Ma, Z. C.; et al.: Automatic dispensing device on basis of macro/micro driving and accuracy control. Submitted as: Chinese invention patent (Application No **1.0, application date 29.04.2016)
[14] Zhao, H. W.; Liu, C. Y.; Ma, Z. C.; et al.: In situ testing instrument for testing mechanical-electrical-magnetic coupling properties of materials under combined loads. U. S. patent, WO**
[15] Dong, J. S.; Zhou, Y. C.; Ma, Z. C.; et al.: Miniature and precise nanoindentation and nanoscratch testing device. Submitted as: Chinese invention patent (Application No **3.5, application date 29.07.2015)
[16] Zhao, H. W.; Shi, C. L.; Liu, H. D,; Lu, S.; Huang, H.; Tian, Y.; Ma, Z. C.; et al. (2015): Precise in situ torsional platform for materials’ performance testing. (Authorized Chinese invention patent, Patent No **4.8)
[17] Zhao, H. W.; Cheng, H. B.; Shao, M. K,; Zhang, P.; Ma, Z. C.; et al. (2015): In situ three-point bending platform for materials’ performance testing on basis of adjustable environment temperature. (Authorized Chinese invention patent, Patent No **1.1)
[18] Li, H. L.; Zhao, H. W.; Ma, Z. C.; et al. (2015): A kind of testing instrument of materials’ properties. (Authorized Chinese invention patent, Patent No **8.X)
[19] Ma, Z. C.; Zhao, H. W., et al. (2015): Fatigue performance testing device of microstructure under combined stresses and high temperature. (Authorized Chinese invention patent, Patent No **1.4)
[20] Ma, Z. C.; Zhao, H. W., et al. (2015): In situ static and dynamic performance biaxial testing platform under service temperature. (Authorized Chinese patent for utility model, Patent No **2.0)
[21] Ma, Z. C.; Zhao, H. W., et al. (2015): Machining equipment of aspherical concave lens based on adjustable curvature radius. (Authorized Chinese invention patent, Patent No **7.8)
[22] Ma, Z. C.; Zhao, H. W., et al. (2014): Fatigue mechanical performance testing device of materials driven by piezoelectric actuator. (Authorized Chinese invention patent, Patent No **9.4)
[23] Zhao, H. W.; Li, J. P.; Ren, L. Q.; Qu, H.; Ma, Z. C.; et al. (2014): Bionic multi-degrees of freedom actuator at micro/nano scale under microscope. (Authorized Chinese invention patent, Patent No **3.9)
[24] Zhao, H. W.; Ren, L. Q.; Li, J. P.; Huang, H.; Zhang, P. F.; Hu, X. L.; Cheng, H. B.; Fang, D. N.; Ma, Z. C.; et al.: Micromechanical performance in situ test instrument for multi-load and multi-physical field coupling material. Submitted as: Euro and U. S. patent (NO PTC/CN2014/072805, application date 03.03.2014)
[25] Zhao, H. W.; Cheng, H. B.; Ma, Z. C.; et al. (2014): Miniature mechanical properties testing device based on tensile-bending combined loading mode. (Authorized Chinese invention patent, Patent No **3.3)
[26] Zhao, H. W.; Ma, Z. C.; et al. (2013): Cross-scale in situ combined loading testing device at micro/nano scale. (Authorized Chinese invention patent, Patent No **3.9)
[27] Zhao, H. W.; Ma, Z. C.; et al. (2013): Material mechanical properties testing device on basis on tensile/compressive and bending combined loading under microscope. (Authorized Chinese invention patent, Patent No **2.9)
[28] Zhao, H. W.; Ma, Z. C.; et al. (2013): In situ high-frequency fatigue mechanical properties testing device based on tensile/compressive mode under scanning electron microscope. (Authorized Chinese invention patent, Patent No **3.9)
[29] Zhao, H. W.; Ma, Z. C.; et al. (2013): In situ torsional mechanical properties testing device at micro-radian scale under scanning electron microscope. (Authorized Chinese invention patent, Patent No **1.X)
[30] Zhao, H. W.; Ma, Z. C.; et al. (2013): In situ tensile/compressive testing device based on quasi-state loading under scanning electron microscope. (Authorized Chinese invention patent, Patent No **2.4)
[31] Zhao, H. W.; Hu, X. L.; Ma, Z. C.; et al. (2013): Cross-scale in situ three-point bending testing device at micro/nano scale. (Authorized Chinese invention patent, Patent No **7.3)
[32] Zhao, H. W.; Ma, Z. C.; et al. (2013): Biaxial tensile/compressive mechanical testing device under scanning electron microscope. (Authorized Chinese patent for utility model, Patent No **2.3)
[33] Zhao, H. W.; Yuan, Y. K.; Li, S.; Zou, Q.; Ma, Z. C.; et al. (2013): In situ nanoindentation device on basis of adjustable tensile and bending preloads. (Authorized Chinese invention patent, Patent No **6.X)
[34] Zhao, H. W.; Huang, H.; Yuan, Y. K.; Mi, J.; Yang, J.; Wan, S. G.; Ma, Z. C.; et al. (2013): Miniature nanoindentation testing device. (Authorized Chinese invention patent, Patent No **4.9)
[35] Zhao, H. W.; Huang, H.; Shi, C. L.; Hu, L. L.; Yang, J.; Wan, S. G.; Ma, Z. C.; et al. (2013): In situ nanoindentation testing device at micro/nano scale on basis of double displacement detection. (Authorized Chinese invention patent, Patent No **5.X)
[36] Zhao, H. W.; Zhang, L.; Shi, C. L.; Hu, X. L.; Ma, Z. C.; et al. (2013): Cross-scale in situ tensile/compressive testing device at micro/nano scale under microscope driven by hydraulic actuator. (Authorized Chinese invention patent, Patent No **3.4)
[37] Zhao, H. W.; Zhang, L.; Huang, Hu.; Hu, X. L.; Shi, C. L.; Ma, Z. C.; et al. (2013): Cross-scale in situ three/four point testing device at micro/nano scale under microscope. (Authorized Chinese invention patent, Patent No **5.8)
[38] Zhao, H. W.; Ma, Z. C.; et al. (2012): Mechanical testing device of materials on basis of combined loading mode driven by hydraulic actuator. (Authorized Chinese patent for utility model, Patent No **9.7)
[39] Zhao, H. W.; Ma, Z. C.; et al. (2012): Cross-scale in situ tensile/ compressive testing device at micro/nano scale. (Authorized Chinese invention patent, Patent No **8.9)
[40] Zhao, H. W.; Ma, Z. C.; et al. (2011): In situ tensile/compressive testing device under scanning electron microscope driven by hydraulic actuator. (Authorized Chinese patent for utility model, Patent No **5.9)
[41] Zhao, H. W.; Ma, Z. C.; et al. (2011): Servo compensation drive system of cutting tool at micro/nano level. (Authorized Chinese patent for utility model, Patent No **0.1)教育经历
[1]2009.9--2013.12 吉林大学机械工程硕博连读（提前毕业）
[2]2005.9--2009.7 吉林大学机械工程本科生
工作经历
[1]2014.1--2014.6中国电子科技集团公司
[2]2014.6--至今吉林大学机械科学与工程学院2014/06-2015/09 讲师
2015/04-至今工程仿生教育部重点实验室博士后
2015/09-2018/12 副教授（破格）
2018/11至今博士生导师
2018/12至今教授（破格，公示，通过学术委员会评审）
2019/11至今教育部青年****

社会兼职
[1]国际仿生工程学会会员
[2]中国机械工程学会高级会员
[3]中国仪器仪表学会试验机分会会员
[4]国家自然科学基金委员会项目通讯评阅人评阅人
[5]中国有色金属学会会员
[6]吉林省材料服役性能测试产业公共技术研发中心副主任
[7]吉林大学青年科技工作者协会会员
研究方向
[1] 材料服役性能测试技术与仪器[2] 仿生材料设计与制备[3] 极端材料材料性能教师其他联系方式
[1] 邮箱 : [2] 电话 :

吉林大学研究生导师教师简介-马志超

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