张嘉振，入选国家级高层次人才计划，浙江师范大学杰出教授，博士/博士生导师。第五，六，七，八届国际结构材料的疲劳和损伤大会执委（中国地区唯一执委），英国机械工程师协会成员，英国航空工程师协会成员，欧洲先进材料和加工协会工程师协会成员。发表论文60多篇，其中SCI检索收录30余篇，EI收录10余篇，ISTP收录（特邀）：4篇。国际SCI他人检索150多次。承担的国外科研项目总计15项，科研经费总计800多万英镑；国内科研项目包括多项工信部项目、中国商飞研究项目，国家自然科学基金、黑龙江省自然科学基金重点项目，黑龙江省教育厅海外学人项目，科研经费总计8000多万人民币。

（研究生招生：要求有较深的力学功底，熟悉有限元分析软件（abaqus）的优先，报考研究生的同学，请先联系我的团队成员：赵元，zhaoyuan@zjnu.edu.cn；手机号（Wechat）：18846454124）

研究领域：

     增材制造，金属材料疲劳，断裂问题，复合材料结构强度研究和飞行器结构设计

代表性项目：

     (1) 国家重点研发计划,  复杂精密结构的成形工艺优化与应用研究, 2017-07 至 2021-06, 265万元, 结题, 主持
     (2) 国家重点研发计划项目, 大型客机和民用航天高强铝合金构件增材制造结构优化设计方法, 2018-05 至 2021-04, 254万元, 结题, 参与
     (3) 国家重点研发计划项目,大型客机高强铝合金增材制造典型构件应用验证及评价, 2018-05 至 2021-04, 655万元, 结题, 参与

代表性著作：

     (1) 增材制造与航空应用, 冶金工业出版社, 2021，主编

     (1) 民机结构分析手册, 北京航空航天大学出版社 ，2017，参编

部分代表性论文：

[1]  Zhang J Z（张嘉振） . “A shear band decohesion model for small fatigue crack growth in an ultra-fine grain aluminum alloy”. Engineering Fracture Mechanics, 2000, 65(6): 665-681.

[2]  Zhang J Z, （张嘉振） Zhang J Z, Meng Z X. “Direct high resolution in situ SEM observations of very small fatigue crack growth in the ultra-fine grain aluminium alloy IN 9052”.Scripta Materialia, 2004, 50(6):825-828.

[3]  Zhang J Z, （张嘉振） He X D, Tang H, et al. “Direct high resolution in situ SEM observations of small fatigue crack opening profiles in the ultra-fine grain aluminium alloy”. Materials Science & Engineering A, 2008, 485(1-2):115-118.

[4]  M.D. Halliday, J.Z. Zhang（张嘉振）, P. Poole and P. Bowen. “In situ SEM observations of the contrasting effects of an overload on small fatigue crack growth at two different load ratios in 2024-T351 aluminium alloy”. International Journal of Fatigue, 1997, 19(4):273-282.

[5]  Zhang J Z（张嘉振）, X.D.He and S.Y.Du. “Analyses of the fatigue crack propagation process and stress ratio effects using the two parameter method”. International Journal of Fatigue,2005,27(10-12): 1314-1318.

[6]  J. Z. Zhang（张嘉振） et al. “Crack closure in small fatigue cracks-A comparison of finite element predictions and scanning microscope measurements”. Fatigue & Fracture of Engineering Materials 1997:20.

[7]  J. Z. Zhang（张嘉振）, X.D. He, S. Y. Du. “Elastic–plastic finite element analysis and experimental study of short and long fatigue crack growth”. Engineering Fracture Mechanics, 2001:1591-1605.

[8]  Zhang J Z（张嘉振），Bowen P. “On the finite element simulation of three-dimensional semi-circular fatigue crack growth and closure”. Engineering Fracture Mechanics, 1998, 60(3):341-360.

[9]  J.Z. Zhang （张嘉振）, X.D. He , Y. Sha , S.Y. Du. “The compressive stress effect on fatigue crack growth under tension–compression loading”. International Journal of Fatigue, 2010, 32:361–367.

[10] J.Z. Zhang（张嘉振）, X.D. He , B. Suo , S.Y. Du . “Elastic–plastic finite element analysis of the effect of compressive loading on crack tip parameters and its impact on fatigue crack propagation rate”. Engineering Fracture Mechanics, 2008,75:5217–5228.

[11] J.Z. Zhang（张嘉振）, X.D. He , S.Y. Du . “Analysis of the effects of compressive stresses on fatigue crack propagation rate”. International Journal of Fatigue, 2007,29: 1751–1756.

[12] Jiazhen Zhang（张嘉振）, Xiaodong He, Shanyi Du. A simple engineering approach in the prediction of the effect of stress ratio on fatigue threshold[J]. International Journal of Fatigue, 2003, 25: 935-938.

[13] J. Z. Zhang（张嘉振）, M.D. Halliday , P. Bowen, P. Poole. “Three dimensional elastic-plastic finite element modelling of small fatigue crack growth under a single tensile overload”. Engineering Fracture Mechanics, 1999: 229-251.

[14] J. Zhang（张嘉振）, X.D He , Y. Sha , S.Y. Du. “The compressive stress effect on fatigue crack growth under tension–compression loading”. International Journal of Fatigue,2010,32:361–367.

[15] J. Zhang（张嘉振）, X.D. He , Y. Sha , S.Y. Du. “The compressive stress effect on fatigue crack growth under tension–compression loading”. International Journal of Fatigue,2010,32:361–367.

[16] Bai S , Sha Y , Zhang J（张嘉振） . “The effect of compression loading on fatigue crack propagation after a single tensile overload at negative stress ratios”. International Journal of Fatigue, 2018, 110:162-171.

    [17] Dawei Wang, Huili Han , Bo Sa , Kelin Li , Jujie Yan , Jiazhen Zhang（张嘉振）, Jianguang Liu ,

    Zhengdi He , Ning Wang and Ming Yan. A review and a statistical analysis of porosity in metals

    additively manufactured by laser powder bed fusion[J]. Opto-Electronic Advances Review 2022,

    Vol. 5, No. 10.

[18] Xiping Li, Jiawen He, Zhonglue Hu*, Xin Ye, Sisi Wang, Yuan Zhao, Bin Wang, Yuhui Ou, Jiazhen Zhang* (张嘉振). High strength carbon-fiber reinforced polyamide 6 composites additively manufactured by screw-based extrusion[J]. Composites Science and Technology, 2022, 229: 109707. (共同通讯)

[19] Xin Ye, Zhonglue Hu, Xiping Li, Sisi Wang, Bin Wang, Yuan Zhao, Jiawen He, Jianguang Liu, Jiazhen Zhang* （张嘉振）. Effect of annealing and carbon nanotube infill on the mechanical and electrical properties of additively manufactured polyether-ether-ketone nanocomposites via fused filament fabrication[J] Additive Manufacturing, 2022, 59:103188. (共同通讯）

[20] Yue Wang, Jipeng Zhang, Guodong Fang, Jiazhen Zhang（张嘉振）, Zhengong Zhou, Shiyu Wang. Influence of temperature on the impact behavior of woven-ply carbon fiber reinforced thermoplastic composites[J]. Composite Structures, 2017, 185: 435-445.（第一作者为指导的博士研究生）

[21] Jipeng Zhang, Yue Wang, Jiazhen Zhang（张嘉振）, Zhengong Zhou, Guodong Fang, Yuan Zhao, Shiming Zu. Characterizing the Off-Axis Dependence of Failure Mechanism in Notched Fiber Metal Laminates[J]. Composite Structures, 2018, 185: 148-160. （第一作者为指导的博士研究生）

[22] Che L, Zhou Z, Fang G, Ma Y, Dong W, Zhang J（张嘉振）. Cured shape prediction of fiber metal laminates considering interfacial interaction[J]. Composite Structures, 2018, 194: 564-574. （第一作者为指导的博士研究生）

[23] Wang Y, Zhang J, Zhang J（张嘉振）, Zhou Z, Fang G, Wang S. Compressive behavior of notched and unnotched carbon woven-ply PPS thermoplastic laminates at different temperatures[J]. Composites Part B: Engineering. 2018; 133: 68-77. （第一作者为指导的博士研究生）

[24] Zhao Y, Alderliesten R, Zhou ZG, Fang GD*, Zhang JZ（张嘉振）, Benedictus R. On the physics of applying finite width and geometry correction factors in fatigue crack growth predictions of GLARE. International Journal of Fatigue, 2018, 117:189-195. （第一作者为指导的博士研究生）

[25] Zhao Y, Alderliesten R, Wu ZW, Zhou ZG, Fang GD*, Zhang JZ（张嘉振）, Benedictus R. Determining finite-width-correction factors for fatigue crack growth prediction in GLARE using the equivalent compliance method. International Journal of Fatigue, 2019,127:74-81. （第一作者为指导的博士研究生）

通讯/办公地址 : 0b3163c5bbc5429c02cad478a6734d6989c7eb9586bb037758a6422e3ea58b5b5e821514f6cc4357cc2e7777a94de790f7e14ef557ec3dd17443ece9cc38db8f7efbdb373bd508ff8b8ba965d87aa98c7b447582dbbd57194080083738f4c85c0f4d3a9584c41169169060977a0eb0c1604bbf6a0bf36a9948ce98033b291dbc

邮箱 : 4d59c8c3376c276a48547df0ea99dcccc7008e967af71135bf76794aa7cf0d17f9d312719a91735b69585e53f144da8c77d5f4d40be2f330424c664e19d0e8de6b8452d764cb3e1c6d0153f1ed72d23272ef3118ed824aa84c16ba30b46142d2e231c97289ae5bfe5baea0183d933cf3dfdf882f376b8305ddcdb1012e75397c

1988.9 -- 1991.7
英国伯明翰大学       工程力学       博士研究生毕业       博士学位

1986.9 -- 1988.7
哈尔滨工业大学       工程力学       硕士研究生毕业       硕士学位

1979.9 -- 1983.7
哈尔滨工业大学       工程力学       大学本科毕业       学士学位

2021.7 -- 至今

浙江师范大学      工学院      教授

2004.4 -- 2021.7

哈尔滨工业大学      航天学院      教授