张振军
工学博士
中国科学院金属研究所,副研究员
1986年生于宁夏盐池
联系方式
办公室电话:83978226
Email:zjzhang@imr.ac.cn
教育和工作经历
2003/09 - 2007/07,山东大学,材料科学与工程系,学士
2007/09 - 2013/06,中国科学院金属研究所,博士
2013/07 - 2017/09,中国科学院金属研究所,助理研究员
2017/10 - 至今,中国科学院金属研究所,副研究员
研究方向
材料单向及循环载荷下的形变损伤微观机制
主要成果
建立了共格孪晶界面疲劳损伤开裂判据;提出了通过调整位错滑移方式来改善疲劳损伤机理,优化疲劳性能的方法;建立了双相材料混合杨氏模量、剪切模量以及泊松比的统一计算方程。已发表Nature Communications、Acta Materialia(10)等论文近40余篇,H因子12。
在研项目
国家自然科学青年基金项目(项目批准号:51401207)。
获奖情况
2013年 朱李月华优秀博士生奖学金
发表论文
1. Zhang ZJ, Zhang P, Zhang ZF. Cyclic softening behaviors of ultra-fine grained Cu-Zn alloys; Acta Materialia; 121:331;2016
2. Zhang ZJ, Zhang P, Li LL, Zhang ZF. Fatigue cracking at twin boundaries: Effects of crystallographic orientation and stacking fault energy; Acta Materialia; 60:3113;2012
3. Zhang ZJ, Li LL, Zhang P, Zhang ZF. Fatigue cracking at twin boundary: Effect of dislocation reactions; Applied Physics Letters; 101;2012
4. Zhang ZJ, An XH, Zhang P, Yang MX, Yang G, Wu SD, Zhang ZF. Effects of dislocation slip mode on high-cycle fatigue behaviors of ultrafine-grained Cu-Zn alloy processed by equal-channel angular pressing; Scripta Materialia; 68:389;2013
5. Zhang P*, Zhang ZJ*, Li LL, Zhang ZF. Twin boundary: Stronger or weaker interface to resist fatigue cracking?; Scripta Materialia; 66:854;2012
6. Zhang ZJ, Pang JC, Zhang ZF. Optimizing the fatigue strength of ultrafine-grained Cu-Zn alloys; Materials Science and Engineering A; 666:305;2016
7. Zhang ZJ, Duan QQ, An XH, Wu SD, Yang G, Zhang ZF. Microstructure and mechanical properties of Cu and Cu-Zn alloys produced by equal channel angular pressing; Materials Science and Engineering A; 528:4259;2011
8. Yang CL, Zhang ZJ#, Cai T, Zhang P, Zhang ZF. Recovery of strain-hardening rate in Ni-Si alloys; Scientific Reports; 5:15532 2015
9. Li LL, Zhang ZJ, Zhang P, Wang ZG, Zhang ZF. Controllable fatigue cracking mechanisms of copper bicrystals with a coherent twin boundary; Nature Communications; 5;2014
10. Liu R, Zhang ZJ, Zhang P, Zhang ZF. Extremely-low-cycle fatigue behaviors of Cu and Cu-Al alloys: Damage mechanisms and life prediction; Acta Materialia; 83:341;2015
11. Li RH, Zhang ZJ, Zhang P, Zhang ZF. Improved fatigue properties of ultrafine-grained copper under cyclic torsion loading; Acta Materialia; 61:5857;2013
12. Li LL, Zhang ZJ, Zhang P, Yang JB, Zhang ZF. Distinct fatigue cracking modes of grain boundaries with coplanar slip systems; Acta Materialia; 120:120;2016
13. Li LL, Zhang P, Zhang ZJ, Zhou HF, Qu SX, Yang JB, Zhang ZF. Strain localization and fatigue cracking behaviors of Cu bicrystal with an inclined twin boundary; Acta Materialia; 73:167;2014
14. Li LL, Zhang P, Zhang ZJ, Zhang ZF. Effect of crystallographic orientation and grain boundary character on fatigue cracking behaviors of coaxial copper bicrystals; Acta Materialia; 61:425;2013
15. Shao CW, Zhang P, Liu R, Zhang ZJ, Pang JC, Zhang ZF. Low-cycle and extremely-low-cycle fatigue behaviors of high-Mn austenitic TRIP/TWIP alloys: Property evaluation, damage mechanisms and life prediction; Acta Materialia; 103:781;2016
16. Shao CW, Zhang P, Liu R, Zhang ZJ, Pang JC, Duan QQ, Zhang ZF. A remarkable improvement of low-cycle fatigue resistance of high-Mn austenitic TWIP alloys with similar tensile properties: Importance of slip mode; Acta Materialia; 118:196;2016
17. Tian YZ, Zhao LJ, Park N, Liu R, Zhang P, Zhang ZJ, Shibata A, Zhang ZF, Tsuji N. Revealing the deformation mechanisms of Cu-Al alloys with high strength and good ductility; Acta Materialia; 110:61;2016