徐松林
研究员
中国科学技术大学近代力学系(安徽合肥)
邮编: 230026
电话: 13865944698
传真: 0551-63606459
Education
Ph.D., Wuhan Institute of Rock and Soil Mechanics, CAS (2000);
M.S., Wuhan Institute of Rock and Soil Mechanics, CAS (1996);
B.S., Zhengzhou University of Technology (1993).
Research Area/Interests:
Dynamic behavior of materials, especially the brittle materials;
Dimensionless analysis method;
Micromechanics: Using micromechanical method to analyze the dynamic behavior of complicated materials, e.g., the composites, rock and concrete, etc.;
Compression and shear combined impacting technique and corresponding numerical analyses.
Citations/Papers:
[1] Liangzhu Yuan, Songlin Xu, Haifeng Yang, et al.Dynamic responses of 2-D fractional medium subjected to impact. International Journal of Mechanical Sciences, 2025, 300: 110448
[2] Liangzhu Yuan, Songlin Xu, Meiduo Chen, et al.Stress wave in the mesoscopic discontinuous medium by fractional approach. International Journal of Mechanical Sciences, 2024, 272: 109197.
[3] Pengfei Wang, Deya Wang, Yangfan Wu, et al. Uncovering the interface slipping and microplastic accumulation mechanism of carbon nanotube fibers under different temperatures. Carbon, 2025, 233: 119898.
[4] Pengfei Wang, Wenshuai Wang, Jie Tian, et al. Surface state induced velocity transition for layered carbon nanotube films under transverse penetration loading. Composite Structures, 2025, 369: 119339.
[5] Yushan Xie, Songlin Xu, Liangzhu Yuan, et al. Dynamic responses of laminated and graded ZrC-Mo composites. International Journal of Mechanical Sciences, 2024, 271: 109134.
[6] Yangfan Wu, Pengfei Wang, Deya Wang, et al. Unveiling the microstructural evolution and interaction mechanisms for twisted structures. International Journal of Mechanical Sciences, 2024, 279: 109514.
[7] Yangfan Wu, Pengfei Wang, Deya Wang, et al.Synergistic ductility deformation and helical design of carbon nanotube fiber composites. Carbon, 2024, 229: 119441.
[8] Haifeng Yang, Songlin Xu, Liangzhu Yuan, et al. Dynamic failures at the metal-glass interface under impact loading. International Journal of Impact Engineering, 2025, 195: 105136.
[9] Meiduo Chen, Xianglin Zhang, Songlin Xu, et al. Dynamic failure of aramid paper honeycomb under intermediate strain rate loading. Thin-Walled Structures, 2025, 215: 113362.
[10] Yuan Liangzhu, Miao Chunhe, Songlin Xu, et al. Stress-wave propagation in multilayered and density-graded viscoelastic medium. International Journal of Impact Engineering, 2023, 173: 104415.
[11] Deya Wang, Pengfei Wang, Yangfan Wu, et al. Temperature and rate-dependent plastic deformation mechanism of carbon nanotube fiber: Experiments and modeling. Journal of the Mechanics and Physics of Solids, 2023, 173: 105241.
[12]Meiduo Chen, Songlin Xu, Liangzhu Yuan, et al. Influence of stress state on dynamic behaviorsof concrete under true triaxial confinements. International Journal of Mechanical Sciences, 2023, 253: 108399.
[13] Chunhe Miao, Songlin Xu, Liangzhu Yuan, et al. Experimental investigation of failure diffusion in brittle materials subjected to low-speed impact. International Journal of Mechanical Sciences, 2023, 259: 108632.
[14] Jianhua Lu, Songlin Xu, Ying Li, Chunhe Miao, et al. Investigations on the compression-shear coupled stress waves propagating in heterogeneous rock. Mechanics of Materials, 2023, 186: 104786.
[15] Chunhe Miao, Songlin Xu, Jianhua Lu, et al. Dynamic breakage of double glass spheres chain subjected to impacting loading. International Journal of Mechanical Sciences, 2022, 232: 107610.
[16] Yushan Xie, Songlin Xu, Junyu Huang, et al. Dynamic compaction induced heterogeneity in boron carbide powder. Ceramics International, 2022, 48(23): 34999-35010.
[17] Xiao Xue, Pengfei Wang, Ming Gong, et al. Time-dependent microstructural evolution mechanisms of twisted carbon nanotube fibers under tension and relaxation. International Journal of Plasticity, 2021, 136: 102866.
[18] Songlin Xu, Junfang Shan, Lei Zhang, et al. Dynamic compression behaviors of concrete under true triaxial confinement: An experimental technique. Mechanics of Materials, 2020, 140: 103220.
[19] Junfang Shan, Songlin Xu, Lijiang Zhou, et al. Dynamic fracture of aramid paper honeycomb subjected to impact loading. Composite Structures, 2019, 223: 119062
[20] Hebin Jiang, Songlin Xu, Junfang Shan, et al. Dynamic breakage of porous hexagonal boron nitride ceramics subjected to impact loading. Powder Technology, 2019, 353: 359-371.
[21] Zhou LJ, Xu Songlin, Shan Junfang, et al. Heterogeneity in deformation of granite under dynamic combined compression/shear loading. Mechanics of Materials, 2018, 123: 1-18.
[22] Shan JF, Xu SL, Liu YG, et al. Dynamic breakage of glass sphere subjected to impact loading. Powder Technology, 2018, 330: 317-329
[23] Wang P, Yang J, Sun G, et al. Twist induced plasticity and failure mechanism of helical carbon nanotube fibers under different strain rates. International Journal of Plasticity, 2018, 110: 74-94.
[24] Huang J, Hu S, Xu S, Luo S. Fractal crushing of granular materials under confined compression at different strain rates. International Journal of Impact Engineering, 2017, 106: 259- 265.
[25] Pengfei Wang, Jinglei Yang, Xin Li, et al. Modification of the contact surfaces for improving the puncture resistance of laminar structures. Scientific Report, 2017, 7(1):6615
[26] Huang JY, E JC, et al. Dynamic deformation and fracture of single crystal silicon: Fracture modes, damage laws, and anisotropy. Acta Materialia, 2016, 114: 136-145.
[27] Huang J, Xu S, Hu S. The role of contact friction in the dynamic breakage behavior of granular materials. Granular Matter, 2015, 17: 111-120.
[28] Huang JY, Xu SL, Hu SS, Influence of particle breakage on the dynamic compression responses of brittle granular materials, Mechanics of Materials, 2014,68:15~28.
[29] Songlin Xu, Junyu Huang, Pengfei Wang, et al, Investigation of rock material under combined compression and shear loading: an experimental technique. International Journal of Impact Engineering, 2015, 86: 206-222.
[30] Pengfei Wang, Songlin Xu, et al, Experimental investigation on the strain-rate effect and inertia effect of close-cell aluminum foam subjected to dynamic loading. Materials Science & Engineering A. 2014, 620:253-261