中国科学院金属研究所刘增乾

fangyangzhong

刘增乾，男，1987年9月生，中国科学院金属研究所“引进优秀学者”、研究员，中国科学院青年创新促进会会员。本科到博士阶段学习在北京航空航天大学材料科学与工程学院完成，2009年获工学学士学位，2013年获工学博士学位。2013年获金属所“葛庭燧奖研金”资助加入材料疲劳与断裂实验室从事博士后研究，合作导师为张哲峰研究员，2015年获金属所“引进优秀学者”项目资助留所工作，2015-2017年应材料力学领域国际知名学者Robert O. Ritchie教授邀请赴加州大学伯克利分校、劳伦斯-伯克利国家实验室从事博士后研究。主要从事生物力学与仿生材料研究，旨在利用生物力学原理从仿生角度提高人造材料抵抗疲劳与断裂的能力，在Prog. Mater. Sci.、Adv. Mater.、Biomaterials、Acta Biomater.、Acta Mater.等SCI刊物上发表论文56篇，被引用1000余次，并受邀担任Acta Biomater.等期刊审稿人，申请仿生材料发明专利10余项，部分研究成果受到Materials Today、Advances in Engineering、科技日报、光明网等报道，培养的研究生获得辽宁省优秀毕业生和师昌绪奖学金等荣誉。

发表论文
[1] Z. Q. Liu, W. H. Wang, M. Q. Jiang, Z. F. Zhang. Intrinsic factor controlling the deformation and ductile-to-brittle transition of metallic glasses. Philos Mag Lett. 94: 658 (2014).
[2] Z. Q. Liu, Z. F. Zhang. Strengthening and toughening metallic glasses: The elastic perspectives and opportunities. J Appl Phys 115: 163505 (2014).
[3] Z. Q. Liu, G. Liu, R. T. Qu, Z. F. Zhang, S. J. Wu, T. Zhang. Microstructural percolation assisted breakthrough of trade-off between strength and ductility in CuZr-based metallic glass composites. Sci Rep 4: 4167 (2014).
[4] Z. Q. Liu, R. F. Wang, R. T. Qu, Z. F. Zhang. Precisely predicting and designing the elasticity of metallic glasses. J Appl Phys 115: 203513 (2014).
[5] Z. Q. Liu, H. Wang, T. Zhang. Bulk metallic glass composites ductilized by core-shell structured dual crystalline phases through controlled inoculation. Intermetallics 45: 24 (2014).
[6] Z. Q. Liu, M. J. Shi, T. Zhang. Composition dependences and optimization of the magnetic properties of Fe-based metallic glasses. Mater Res Exp in press (2014).
[7] Z. Q. Liu, Z. F. Zhang. Universal softening and intrinsic local fluctuations in metallic glasses. Appl Phys Lett 103: 181909 (2013).
[8] Z. Q. Liu, Z. F. Zhang. Mechanical properties of structural amorphous steels: Intrinsic correlations, conflicts, and optimizing strategies. J Appl Phys 114: 243519 (2013).
[9] Z. Q. Liu, L. Huang, W. Wu, X. K. Luo, M. J. Shi, P. K. Liaw, W. He, T. Zhang. Novel low Cu content and Ni-free Zr-based bulk metallic glasses for biomedical applications. J Non-Cryst Solids 363: 1 (2013).
[10] Z. Q. Liu, R. Li, G. Liu, W. Su, H. Wang, Y. Li, M. Shi, X. Luo, G. Wu, T. Zhang. Microstructural tailoring and improvement of mechanical properties in CuZr-based bulk metallic glass composites. Acta Mater 60: 3128 (2012).
[11] Z. Q. Liu, R. Li, G. Liu, K. Song, S. Pauly, T. Zhang, J. Eckert. Pronounced ductility in CuZrAl ternary bulk metallic glass composites with optimized microstructure through melt adjustment. AIP Adv 2: 0321761 (2012).
[12] Z. Q. Liu, Y. Yang, R. Li, L. Huang, T. Zhang. Formation and mechanical properties of Zr-based bulk metallic glass composites with high oxygen levels. Chin Sci Bull 57: 3931 (2012).
[13] Z. Q. Liu, R. Li, G. Wang, S. Wu, X. Lu, T. Zhang. Quasi phase transition model of shear bands in metallic glasses. Acta Mater 59: 7416 (2011).
[14] Z. Q. Liu, R. Li, H. Wang, T. Zhang. Nitrogen-doping effect on glass formation and primary phase selection in Cu-Zr-Al alloys. J Alloys Compd 539: 5033 (2011)-5037
[15] Z. Q. Liu, R. Li, L. Huang, X. Lu, T. Zhang. Coring micron- and milli-scale holes in metallic glasses. J Non-Cryst Solids 357: 3190 (2011).