ResearcherID || Mendeley || GScholar || ORCID |

Research Interests:

  • Dynamics crushing of cellular materials
  • Rate-sensitive mechanisms of materials
  • Crashworthiness design of structures
  • Finite element simulation
  • Progressive buckling of structures
  • Adhesive contact of elastic objects
  • Teaching Experiences:

  • 2010-: Advanced Applied Mathematics
  • 2014-2018: Thermodynamics & Statistical Physics
  • 2022: Engineering Thermodynamics
  • 2020-2021: Science & Society: Freshman Seminars
  • Contact Me:

  • Homepage: http://staff.ustc.edu.cn/~zjzheng
  • Email: zjzheng(at)ustc.edu.cn
  • | ResearchGate || ScholarMate || BaiduScholar

    研究方向:

  • 多胞材料的动态压溃
  • 材料的率敏感性机理
  • 轻质结构耐撞性设计
  • 细观有限元模拟
  • 结构的渐进屈曲
  • 吸附接触力学
  • 教学经历:

  • 2010- :高等应用数学
  • 2014-2018:热力学与统计物理
  • 2022:工程热力学
  • 2020-2021:“科学与社会”研讨课
  • 工作单位:

  • 中国科学技术大学 工程科学学院 近代力学系
  • 中国科学院材料力学行为和设计重点实验室
  • 材料和结构冲击实验室(力五楼505)
  • Selected Publications:

      2022

    1. [100] Peng KF, Zheng ZJ*, Chang BX, Zhou FH, Yu JL. Impact damping performance and mechanisms of 3D-printed density gradient cylindrical shell chains.
      International Journal of Impact Engineering 2022; XXX: 104319.
      Published online July 2022 | doi: 10.1016/j.ijimpeng.2022.104319 | SCI | EI |
    2. [99] Peng KF, Zheng ZJ*, Pan H, Zhang YL, Zhao K, Yu JL. Quasi-static and dynamic compaction of granular materials: A strain-activated statistical compaction model and its evaluation.
      Mechanics of Materials 2022; 167: 104250.
      Published April 2022 | doi: 10.1016/j.mechmat.2022.104250 | SCI |
    3. [98] Wang GF, Zhang YL*, Zheng ZJ*, Chen HB, Yu JL. Crashworthiness design and impact tests of aluminum foam-filled crash boxes.
      Thin-Walled Structures 2022; XXX: XXX.
      Published XXX 2022 | doi: | SCI | EI |
    4. [97] Wu KJ, Song YH, Zhang X, Zhang SS, Zheng ZJ, Gong XL, He LH, Yao HB*, Ni Y*. A prestressing strategy enabled synergistic energy-dissipation in impact-resistant nacre-like structures.
      Advanced Science 2022: 2104867.
      Published 2022 | doi: 10.1002/advs.202104867 | SCI |
    5. [96] 彭克锋, 郑志军*, 周风华, 虞吉林. 密度梯度柱壳链的弹性波传播特性研究.
      力学学报 2022.
    6. [95] 张元瑞, 朱玉东, 郑志军*, 虞吉林. 泡沫子弹冲击固支单梁的耦合分析模型.
      力学学报 2022.
    7. [94] 张豪, 常白雪, 赵凯, 郑志军*, 虞吉林. 三种蜂窝夹芯板的抗爆性能分析.
      北京理工大学学报 2022.
      Published 2022 | doi:
    8. [93] Zhang YR, Wang GF, Zhang YL*, Zheng ZJ, Ye J, QU Y, Yu JL. Filling design and optimization of automobile seat crossbeam based on aluminum foam composite structure.
      Journal of Mechanical Strength 2022; 44(1): 140-147.
      张元瑞, 汪高飞, 张永亮*, 郑志军, 叶坚, 瞿元, 虞吉林. 基于泡沫铝复合结构的汽车座椅横梁填充设计与优化. 机械强度 2022; 44(1): 140-147.
      Published 2022 | doi: 10.16579/j.issn.1001.9669.2022.01.019
    9. 2021

    10. [92] Zhu YD, Zheng ZJ*, Zhang YL, Wu HA, Yu JL. Adhesion of elastic wavy surfaces: Interface strengthening/weakening and mode transition mechanisms.
      Journal of the Mechanics and Physics of Solids 2021; 151: 104402.
      Published June 2021 | doi: 10.1016/j.jmps.2021.104402 | SCI |
      News: 中国科大在吸附接触力学领域取得新进展 News: Researchers Show the Adhesion Mechanics of Surface Roughness
    11. [91] Peng KF, Zheng ZJ*, Chang BX, Pan H, Yu, JL. Wide-range control of impulse transmission by cylindrical shell chains with varying aspect ratios.
      International Journal of Impact Engineering 2021; 158: 104017.
      Published December 2021 | doi: 10.1016/j.ijimpeng.2021.104017 | SCI |
    12. [90] Peng KF, Pan H, Zheng ZJ*, Yu, JL. Compaction behavior and densification mechanisms of Cu-W composite powders.
      Powder Technology 2021; 382: 478-490
      Published April 2021 | doi: 10.1016/j.powtec.2021.01.013 | SCI | EI
    13. [89] Zhang YR, Wang GF, Zhang YL*, Ye J, Zeng T, Zhao K, Zheng ZJ, Wan R. Crashworthiness design of car threshold based on aluminium foam sandwich structure.
      International Journal of Crashworthiness 2021.
      Published online: 31 May 2021 | doi: 10.1080/13588265.2021.1914978 | SCI |
    14. [88] Gao WT, Peng KF, Zhang YL, Zheng H, Zhao K, Zheng ZJ*. On ballistic performance of a metal target with crescent-shaped cavity structure.
      Baozha Yu Chongji/Explosion and Shock Waves 2021, 41(5): 053303. (in Chinese)
      高伟韬, 彭克锋, 张永亮, 郑航, 赵凯, 郑志军*. 月牙形空腔结构金属靶的抗弹性能分析. 爆炸与冲击 2021, 41(5): 053303.
      Published May 2021 | doi: 10.11883/bzycj-2020-0473 | EI
    15. [87] Peng KF, Cui ST, Pan H, Zheng ZJ*, Yu, JL. Simplified model of elastic wave propagation in cylindrical shell chain under impact load and its analytical solution.
      Baozha Yu Chongji/Explosion and Shock Waves 2021; 41(1), 011403. (in Chinese)
      彭克锋, 崔世堂, 潘昊, 郑志军*, 虞吉林. 冲击载荷作用下柱壳链中的弹性波传播简化模型及其解析解. 爆炸与冲击 2021; 41(1), 011403.
      Published Janary 2021 | doi: 10.11883/bzycj-2020-0246 | EI
    16. [86] Chen M, Zhang YL*, Zheng H, Zhao K, Zheng ZJ*. Ballistic performance analysis and gradient optimization design of ceramic ball and metal composite armor.
      Chinese Journal of High Pressure Physics 2021; 35(5): 054201. (in Chinese)
      陈铭, 张永亮*, 郑航, 赵凯, 郑志军*. 陶瓷球金属复合结构的抗弹性能和梯度设计. 高压物理学报 2021; 35(5): 054201.
      Published October 2021 | doi: 10.11858/gywlxb.20210739 |
    17. [85] Wang GF, Zhang YL*, Zheng ZJ, Ye J, Qin YL, Ke J, Yu JL. Axial compression characteristic of non-equal length double square tube structures filled with aluminum foam.
      Journal of Vibration and Shock 2021; 40(24): 90-98. (in Chinese)
      汪高飞, 张永亮*, 郑志军, 叶坚, 秦玉林, 柯俊, 虞吉林. 泡沫铝填充非等长双方管的轴向压溃特性研究. 振动与冲击 2021; 40(24): 90-98.
      Published December 2021 | http://jvs.sjtu.edu.cn/CN/Y2021/V40/I24/90 |
    18. [84] Wang GF, Zhang YL*, Zheng ZJ, Ye J, Zeng T, Li ZH, Yu JL. Experimental investigations on the quasi-static axial crushing of aluminum foam-filled crash box.
      Journal of Experimental Mechanics 2021; 36(5): 581-591. (in Chinese)
      汪高飞, 张永亮*, 郑志军, 叶坚, 曾婷, 李志虎, 虞吉林. 泡沫铝填充吸能盒的轴向压缩性能实验研究. 实验力学 2021; 36(5): 581-591.
      Published 2021 | 10.7520/1001-4888-21-003 |
    19. 2020

    20. [83] Chang BX, Zheng ZJ*, Zhang YL*, Zhao K, He SY, Yu JL. Crashworthiness design of graded cellular materials: An asymptotic solution considering loading rate sensitivity.
      International Journal of Impact Engineering 2020; 143: 103611.
      Published September 2020 | doi: 10.1016/j.ijimpeng.2020.103611 | SCI | EI
    21. [82] Wang SL, Ding YY, Yu F, Zheng ZJ*, Wang Y. Crushing behavior and deformation mechanism of additively manufactured Voronoi-based random open-cell polymer foams.
      Materials Today Communications 2020; 25: 101406.
      Published December 2020 | doi: 10.1016/j.mtcomm.2020.101406 | SCI | EI
    22. [81] Ding YY*, Zheng YX, Zheng ZJ*, Wang YG, He SY, Zhou FH. Blast Alleviation of Sacrificial Cladding with Graded and Uniform Cellular Materials.
      Materials 2020, 13(24): 5616.
      Published 2020 | doi: 10.3390/ma13245616 | SCI | EI
    23. 2019

    24. [80] Zhu CF, Zheng ZJ*, Wang SL, Zhao K, Yu JL. Modification and verification of the Deshpande–Fleck foam model: A variable ellipticity.
      International Journal of Mechanical Sciences 2019; 151: 331–342.
      Published February 2019 | doi: 10.1016/j.ijmecsci.2018.11.028 | SCI | EI
    25. [79] Wu KJ, Zheng ZJ, Zhang SS, He LH, Yao HB, Gong XL, Ni Y*. Interfacial strength-controlled energy dissipation mechanism and optimization in impact-resistant nacreous structure.
      Materials & Design 2019; 163: 107532.
      Published February 2019 | doi: 10.1016/j.matdes.2018.12.004 | SCI | EI
    26. [78] Wang SL, Zheng ZJ*, Ding YY, Zhu CF, Yu JL. Dynamic crushing of cellular materials: A particle velocity-based analytical method and its application.
      Acta Mechanica Sinica 2019: 35(4), 839-851.
      Published August 2019 | doi: 10.1007/s10409-019-00859-w | SCI | EI
    27. [77] Ding ZY, Zheng ZJ*, Yu JL. A wave propagation model of distributed energy absorption system for trains.
      International Journal of Crashworthiness 2019; 24(5): 508-522.
      Published February 2019 | doi: 10.1080/13588265.2018.1479482 | SCI | EI
    28. [76] Wang P, Zhu CF, Zheng ZJ*, Yu JL. Dynamic stress-strain states of cellular materials and a uniformly approximated relation.
      Baozha Yu Chongji/Explosion and Shock Waves 2019; 39(1): 013102(1-8). (in Chinese)
      王鹏, 朱长锋, 郑志军*, 虞吉林. 多胞材料的动态应力应变状态及其一致近似关系. 爆炸与冲击 2019; 39(1): 013102(1-8).
      Published January 2019 |doi: 10.11883/bzycj-2017-0280 | EI
    29. [75] Ding ZY, Zheng ZJ*, Yu JL. Wave propagation characteristics and parameter analysis of the distributed energy absorption system of trains.
      Baozha Yu Chongji/Explosion and Shock Waves 2019; 39(3): 035101(1-10). (in Chinese)
      丁兆洋, 郑志军*, 虞吉林. 列车分布式吸能系统的波传播特性和参数分析. 爆炸与冲击 2019; 39(3): 035101(1-10).
      [当期封面论文] | Published March 2019 | doi: 10.11883/bzycj-2018-0053 | EI
    30. [74] Chang BX, Zheng ZJ*, Zhao K, He SY, Yu JL. Design of gradient foam metal materials with a constant impact load.
      Baozha Yu Chongji/Explosion and Shock Waves 2019; 39(4): 041101(1-9). (in Chinese)
      常白雪, 郑志军*, 赵凯, 何思渊, 虞吉林. 具有恒定冲击载荷的梯度泡沫金属材料设计. 爆炸与冲击 2019; 39(4): 041101(1-9).
      [特别约稿论文] [《爆炸与冲击》2018~2019年优秀论文] | Published April 2019 | doi: 10.11883/bzycj-2018-0431 | EI
    31. [73] Peng KF, Pan H, Zhao K, Zheng ZJ*, Yu JL. Dynamic compaction behaviors of copper powders using multi-particle finite element method.
      Chinese Journal of High Pressure Physics 2019; 33(4): 044102(1-8). (in Chinese)
      彭克锋, 潘昊, 赵凯, 郑志军*, 虞吉林. 铜粉末动态压缩行为的多颗粒有限元分析. 高压物理学报 2019; 33(4): 044102(1-8).
      Published August 2019 | doi: 10.11858/gywlxb.20180665 |
    32. 2018

    33. [72] Wang SL, Zheng ZJ*, Zhu CF, Ding YY, Yu JL. Crushing and densification of rapid prototyping polylactide foam: Meso-structural effect and a statistical constitutive model.
      Mechanics of Materials 2018; 127: 65-76.
      Published December 2018 | doi: 10.1016/j.mechmat.2018.09.003 | SCI | EI
    34. [71] Ding YY*, Zheng ZJ*, Wang YG, Zhou FH. Impact resistance and design of graded cellular cladding.
      International Journal of Applied Mechanics 2018; 10(10): 1850107.
      Published December 2018 | doi: 10.1142/S1758825118501077 | SCI | EI
    35. [70] Wang P, Zheng ZJ*, Liao SF, Yu JL. Strain-rate effect on initial crush stress of irregular honeycomb under dynamic loading and its deformation mechanism.
      Acta Mechanica Sinica 2018; 34(1): 117-129.
      Published February 2018 | doi: 10.1007/s10409-017-0716-1 | SCI | EI
    36. [69] Chang BX, Zheng ZJ*, Zhao K, Yu JL. A simplified model and its asymptotic solution for the crashworthiness design of graded cellular material.
      SCIENTIA SINICA Physica, Mechanica & Astronomica 2018; 48(9): 094615. (in Chinese)
      常白雪, 郑志军*, 赵凯, 虞吉林. 梯度多胞材料耐撞性设计的简化模型和渐近解. 中国科学: 物理学 力学 天文学 2018; 48(9): 094615.
      [校庆专刊论文] | Publised 31 July 2018 | doi: 10.1360/SSPMA2018-00162
    37. [68] Zheng ZJ*, Zhan SG, Dai LH. Review of the second national symposium on explosion and impact dynamics for young scholars.
      Chinese Journal of Theoretical and Applied Mechanics 2018; 50(1): 177-187. (in Chinese)
      郑志军*, 詹世革, 戴兰宏. 第二届全国爆炸与冲击动力学青年学者学术研讨会报告综述. 力学学报 2018; 50(1): 177-187.
      doi: 10.6052/0459-1879-18-008 | EI
      News: 第二届全国爆炸与冲击动力学青年学者学术研讨会在合肥召开
    38. [67] Ding YY*, Zheng ZJ, Wang SL, Zhou FH, Yu JL. The dependence of energy absorption behaviour of cellular materials on relative density and impact velocity.
      Chinese Journal of Solid Mechanics 2018; 39(6): 578-586. (in Chinese)
      丁圆圆*, 郑志军, 王士龙, 周风华, 虞吉林. 多孔材料吸能行为对相对密度和冲击速度的依赖性. 固体力学学报 2018; 39(6): 578-586.
      doi: 10.19636/j.cnki.cjsm42-1250/o3.2018.030
    39. [66] Huang SN, Ding YY, Wang SL, He SY, Zheng ZJ*, Yu JL. Experimental investigation of dynamic material parameters of closed-cell aluminium foam.
      Journal of Experimental Mechanics 2018; 33(6): 851-861. (in Chinese)
      黄苏南, 丁圆圆, 王士龙, 何思渊, 郑志军*, 虞吉林. 闭孔泡沫铝动态材料参数的实验研究. 实验力学 2018; 33(6): 851-861.
      Published December 2018 | doi: 10.7520/1001-4888-17-211
    40. 2017

    41. [65] Wang SL, Ding YY, Wang CF, Zheng ZJ*, Yu JL. Dynamic material parameters of closed-cell foams under high-velocity impact.
      International Journal of Impact Engineering 2017; 99: 111–121.
      doi: 10.1016/j.ijimpeng.2016.09.013 | SCI | EI
    42. [64] Yang J, Wang SL, Ding YY, Zheng ZJ*, Yu JL. Crashworthiness of graded cellular materials: A design strategy based on a nonlinear plastic shock model.
      Materials Science and Engineering A-Structural Materials Properties Microstructure and Processing 2017; 680: 411–420.
      doi: 10.1016/j.msea.2016.11.010 | SCI | EI
    43. [63] Li ZB*, Zheng ZJ, Yu JL, Lu FY. Deformation and perforation of sandwich panels with aluminum-foam core at elevated temperatures.
      International Journal of Impact Engineering 2017; 109: 366–377.
      doi: | SCI | EI
    44. [62] Wang P, Wang XK, Zheng ZJ*, Yu JL. Stress distribution in graded cellular materials under dynamic compression.
      Latin American Journal of Solids and Structures 2017; 14(7): 1251–1272.
      doi: 10.1590/1679-78253428 | SCI | EI
    45. [61] Cai ZY, Ding YY, Wang SL,Zheng ZJ*, Yu JL. Anti-blast analysis of graded cellular sacrificial cladding.
      Baozha Yu Chongji/Explosion and Shock Waves 2017; 37(3): 396-404. (in Chinese)
      蔡正宇, 丁圆圆, 王士龙, 郑志军*, 虞吉林. 梯度多胞牺牲层的抗爆炸分析. 爆炸与冲击 2017; 37(3): 396–404.
      [《爆炸与冲击》2016~2017年优秀论文] | doi: 10.11883/1001-1455(2017)03-0396-09 | EI
    46. 2016

    47. [60] Ding YY, Wang SL, Zheng ZJ*, Yang LM, Yu JL. Dynamic crushing of cellular materials: A unique dynamic stress–strain state curve.
      Mechanics of Materials 2016; 100: 219–231.
      doi: 10.1016/j.mechmat.2016.07.001 | SCI | EI
    48. [59] Ding YY, Wang SL, Zheng ZJ*, Yang LM, Yu JL. On the stress–strain states of cellular materials under high loading rates.
      Theoretical and Applied Mechanics Letters 2016; 6(3): 122–125.
      doi: 10.1016/j.taml.2016.05.001
    49. [58] Ding YY, Wang SL, Zhao K, Zheng ZJ*, Yang LM, Yu JL. Blast alleviation of cellular sacrificial cladding: A nonlinear plastic shock model.
      International Journal of Applied Mechanics 2016; 8(4):1650057.
      doi: 10.1142/S1758825116500575 | SCI | EI
    50. [57] Li SY, Zheng ZJ*, Yu JL, Qian CQ. Dynamic simulation and safety evaluation of high-speed trains meeting in open air.
      Acta Mechanica Sinica 2016; 32(2): 206–214.
      doi: 10.1007/s10409-015-0471-0 | SCI | EI
    51. [56] Yang J, Wang SL, Zheng ZJ*, Yu JL. Impact resistance of graded cellular metals using cell-based finite element models.
      Key Engineering Materials 2016; 703: 400-405.
      EI
    52. 2015

    53. [55] Ding YY, Wang SL, Zheng ZJ*, Yang LM, Yu JL. Anti-blast design of cellular sacrificial cladding based on a nonlinear plastic shock model.
      20th International Conference on Composite Materials (ICCM2016), Copenhagen, 19-24th July 2015.
    54. [54] Wang SL, Ding YY, Zheng ZJ*, Yu JL. Effect of relative density on shock wave speed of cellular material under dynamic impact. 20th International Conference on Composite Materials (ICCM2016), Copenhagen, 19-24th July 2015.
    55. [53] Wang P, Liao SF, Zheng ZJ*, Yu JL. Shock wave speed of irregular honeycombs under dynamic compression.
      The 2nd International Conference on Advanced Materials, Mechanics and Structural Engineering (AMMSE2015) , Je-ju Island, South Korea, September 18-20, 2015.
    56. [52] Ding YY, Wang SL, Zheng ZJ*, Yang LM and Yu JL. Dynamic behavior of cellular materials under combined shear-compression.
      Applied Mechanics and Materials 2015; 835: 649-653.
      doi: 10.4028/www.scientific.net/AMM.835.649
    57. [51] Li SY, Zheng ZJ*, Yu JL. Energy-absorbing structure design and crashworthiness analysis of high-speed trains.
      Baozha Yu Chongji/Explosion and Shock Waves 2015; 35(2): 164–170. (in Chinese)
      李松晏, 郑志军*, 虞吉林. 高速列车吸能结构设计和耐撞性分析. 爆炸与冲击 2015; 35(2): 164-170.
      doi: 10.11883/1001-1455(2015)02-0164-07 | EI | CSCD
    58. 2014

    59. [50] Zheng ZJ*, Wang CF, Yu JL, Reid SR, Harrigan JJ. Dynamic stress-strain states for metal foams using a 3D cellular model.
      Journal of the Mechanics and Physics of Solids 2014; 72: 93–114.
      doi: 10.1016/j.jmps.2014.07.013 | SCI | EI |
      News: 多胞金属率敏感性机理研究取得新进展
    60. [49] Liao SF, Zheng ZJ*, Yu JL. On the local nature of the strain field calculation method for measuring heterogeneous deformation of cellular materials.
      International Journal of Solids and Structures 2014; 51(2): 478–490.
      doi: 10.1016/j.ijsolstr.2013.10.019 | SCI | EI
    61. [48] Li ZB, Zheng ZJ*, Yu JL, Yang J, Lu FY. Spherical indentation of closed-cell aluminum foams: An empirical force-depth relation.
      Materials Science and Engineering A-Structural Materials Properties Microstructure and Processing 2014; 618: 433–437.
      doi: 10.1016/j.msea.2014.09.013 | SCI | EI
    62. [47] Qian CQ, Zheng ZJ*, Yu JL, Li SY. Dynamic response of elastic beam to a moving pulse: Finite element analysis of critical velocity.
      Journal of Vibroengineering 2014; 16(7): 3197–3208.
      SCI | EI
    63. [46] Li ZB, Zheng ZJ*, Yu JL, Qian CQ, Lu FY. Deformation and failure mechanisms of sandwich beams under three-point bending at elevated temperatures.
      Composite Structures 2014; 111: 285–290.
      doi: 10.1016/j.compstruct.2014.01.005 | SCI | EI
    64. [45] Li ZB, Zheng ZJ*, Yu JL, Yang J. Indentation of composite sandwich panels with aluminum foam core: An experimental parametric study.
      Journal of Reinforced Plastics and Composites, 2014; 33(18): 1671–1681.
      doi: 10.1177/0731684414541994 | SCI |
    65. [44] Zheng ZJ*, Wang XK, Yu JL. Mass impact of density-graded cellular metals in a temperature field.
      Proceedings of ISIE2013. Applied Mechanics and Materials, 2014; 566: 599–604.
      The 8th International Symposium on Impact Engineering(ISIE2013), September 2-6, 2013, Osaka, Japan.
      doi: 10.4028/www.scientific.net/AMM.566.599 | EI
    66. [43] Yu JL*, Liao SF, Zheng ZJ, Wang CF. Dynamic crushing of Voronoi honeycombs: local stress-strain states.
      Proceedings of ISIE2013. Applied Mechanics and Materials, 2014; 566: 563–568.
      The 8th International Symposium on Impact Engineering(ISIE2013), September 2-6, 2013, Osaka, Japan.
      doi: 10.4028/www.scientific.net/AMM.566.563 | EI
    67. [42] Qian CQ, Zheng ZJ*, Yu JL. Dynamic response of elastic beam to a moving pulse: A theoretical study on critical velocity.
      Applied Mechanics and Materials, 2014; 496-500: 609-612.
      doi:10.4028/www.scientific.net/AMM.496-500.609 | EI | CPCI-S
    68. [41] Li YY, Zheng ZJ*, Yu JL, Wang CF. Finite element analysis of deformation modes of closed-cell metallic foam.
      Baozha Yu Chongji/Explosion and Shock Waves 2014; 34: 464–470. (in Chinese)
      李妍妍, 郑志军*, 虞吉林, 王长峰. 闭孔泡沫金属变形模式的有限元分析. 爆炸与冲击 2014; 34: 464–470.
      EI
    69. [40] Ding YY, Wang SL, Zheng ZJ, Yang LM, Yu JL*. Anti-blast analysis of cellular sacrificial cladding.
      Lixue Xuebao/Chinese Journal of Theoretical and Applied Mechanics 2014, 46(6): 825–833. (in Chinese)
      丁圆圆,王士龙,郑志军,杨黎明,虞吉林*. 多胞牺牲层的抗爆炸分析. 力学学报 2014; 46(6): 825–833.
      doi: 10.6052/0459-1879-14-187 | EI
    70. [39] Wang CF, Zheng ZJ, Yu JL*. Micro-inertia effect and dynamic plastic Poisson's ratio of metallic foams under compression.
      Baozha Yu Chongji/Explosion and Shock Waves 2014; 34(5): 601–607. (in Chinese)
      王长峰, 郑志军, 虞吉林*. 泡沫金属的微惯性效应和动态塑性泊松比. 爆炸与冲击 2014; 34(5): 601–607.
      doi: 10.11883/1001-1455(2014)05-0601-07 | EI
    71. 2013

    72. [38] Zheng ZJ*, Yu JL, Wang CF, Liao SF, Liu YD. Dynamic crushing of cellular materials: A unified framework of plastic shock wave models.
      International Journal of Impact Engineering 2013; 53: 29–43.
      The 3rd International Conference on Impact Loading of Lightweight Structures(ICILLS2011), June 28-July 1, 2011, Valenciennes, France.
      doi: 10.1016/j.ijimpeng.2012.06.012 | SCI | EI
    73. [37] Liao SF, Zheng ZJ*, Yu JL. Dynamic crushing of 2D cellular structures: Local strain field and shock wave velocity.
      International Journal of Impact Engineering 2013; 57: 7–16.
      doi: 10.1016/j.ijimpeng.2013.01.008 | SCI | EI
    74. [36] Liao SF, Zheng ZJ*, Yu JL, Li ZB. A design guide of double-layer cellular claddings for blast alleviation.
      International Journal of Aerospace and Lightweight Structures 2013; 3(1): 109–133.
      doi: 10.3850/S201042862013000550
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      Materials & Design 2013; 52: 1058–1064.
      doi: 10.1016/j.matdes.2013.06.067 | SCI | EI
    76. [34] Li ZB, Zheng ZJ*, Yu JL. Low-velocity perforation behavior of composite sandwich panels with aluminum foam core.
      Journal of Sandwich Structures & Materials 2013; 15(1): 92-109.
      doi: 10.1177/1099636212454538 | SCI | EI
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      Theoretical and Applied Mechanics Letters 2013; 3(3): 031001(1–5). [PDF]
      [Theoretical & Applied Mechanics Letters 2013 Best Paper Award]
    78. [32] Xie ZY, Zheng ZJ*, Yu JL. Localized indentation of sandwich panels with metallic foam core: Analytical models for two types of indenters.
      Composites Part B-Engineering 2013; 44(1): 212–217.
      doi: 10.1016/j.compositesb.2012.05.046 | SCI | EI
    79. [31] Yao HB, Ge J, Wang CF, Wang X, Hu W, Zheng ZJ, Ni Y, Yu SH*. A flexible and highly pressure sensitive graphene-polyurethane sponge based on fractured microstructure design.
      Advanced Materials 2013; 25(46): 6692-6698.
      doi: 10.1002/adma.201303041| SCI | EI
    80. [30] Qian CQ, Zheng ZJ*, Yu JL, Li SY. Dynamic response of side windows of high-speed trains subjected to crossing air pressure pulse.
      Jixie Gongcheng Xuebao/Journal of Mechanical Engineering 2013; 49(9): 30–36. (in Chinese)
      钱春强, 郑志军*, 虞吉林, 李松晏. 高速列车侧窗受交会压力波作用的动态响应. 机械工程学报 2013; 49(9): 30–36.
      doi: 10.3901/JME.2013.09.030 | EI
    81. [29] Wang CF, Zheng ZJ*, Yu JL. Dynamic crushing models for a foam rod striking a rigid wall.
      Baozha Yu Chongji/Explosion and Shock Waves 2013; 33(6): 587–593. (in Chinese)
      王长峰, 郑志军*, 虞吉林. 泡沫杆撞击刚性壁的动态压溃模型. 爆炸与冲击2013; 33(6): 587–593.
      EI
    82. 2012

    83. [28] Zheng ZJ, Liu YD, Yu JL*, Reid SR. Dynamic crushing of cellular materials: Continuum-based wave models for the transitional and shock modes.
      International Journal of Impact Engineering 2012; 42: 66–79.
      doi: 10.1016/j.ijimpeng.2011.09.009 | SCI | EI
    84. [27] Zheng ZJ, Yu JL*. Effect of random defects on dynamic response of honeycomb structures.
      Materials Science Forum 2012; 706–709: 805–810.
      The 7th International conference on Processing and Manufacturing of Advanced Materials (THERMEC'2011), August 1-5, 2011, Quebec, Canada.
      doi: 10.4028/www.scientific.net/MSF.706-709.805 | EI
    85. [26] Zheng ZJ, Yu JL*, Liao SF, Wang CF. Wave propagation in cellular materials under impact loading.
      Advances in Plasticity and Impact Dynamics, Sichuan University Press, pp.77–83, 2012.
      Proceeding of the Third International Symposium on Plasticity and Impact (ISPI2011), December 8-12, 2011, Hong Kong and Nansha, China.
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      Journal of Sandwich Structures & Materials 2012; 14(2): 197–210.
      doi: 10.1177/1099636211421993 | EI | SCI |
    87. [24] Li ZB, Zheng ZJ*, Yu JL, Tang LQ. Effect of temperature on the indentation behavior of closed-cell aluminum foam.
      Materials Science and Engineering A-Structural Materials Properties Microstructure and Processing 2012; 550: 222–226.
      doi: 10.1016/j.msea.2012.04.062 | EI | SCI |
    88. [23] Li ZB, Yu JL*, Zheng ZJ, Guo LW. An experimental study on the crashworthiness of thin-walled tubes and their metallic foam-filled structures.
      Journal of Experimental Mechanics 2012; 27(1): 77–86.(in Chinese)
      李志斌, 虞吉林*, 郑志军, 郭刘伟. 薄壁管及其泡沫金属填充结构耐撞性的实验研究. 实验力学 2012; 27(1): 77–86.
      CSCD
    89. [22] Xie ZY*, Yu JL, Zheng ZJ. Bending behavior of thin-walled cylindrical tubes filled with metallic foam under low-velocity impact.
      Baozha Yu Chongji/Explosion and Shock Waves 2012; 32(2): 169–173. (in Chinese)
      谢中友*, 虞吉林, 郑志军. 低速冲击下泡沫金属填充薄壁圆管的弯曲行为. 爆炸与冲击 2012; 32(2): 169–173.
      EI | CSCD
    90. 2011

    91. [21] Wang CF, Zheng ZJ*, Yu JL. Micro-inertia effect and dynamic Poisson's ratio of closed-cell metallic foams under compression.
      in: J.H. Fan, J.Q. Zhang, H.B. Chen and Z.H. Jin (Eds.), Advances in Heterogeneous Material Mechanics, DEStech Publications, Lancaster, 2011, pp. 266–269.
      The 3rd International Conference on Heterogeneous Material Mechanics (ICHMM-2011), May 22-26, 2011, Shanghai, China.
      CPCI-S | EI
    92. [20] Wang XK, Zheng ZJ*, Yu JL, Wang CF. Impact resistance and energy absorption of functionally graded cellular structures.
      Applied Mechanics and Materials 2011; 69: 73–78.
      International Conference on Material Engineering and Mechanical Engineering (MEME 2011), August 20-21, 2011, Wuhan, China.
      doi: 10.4028/www.scientific.net/AMM.69.73 | EI | CPCI-S
    93. [19] Xie ZY, Yu JL, Zheng ZJ*. A plastic indentation model for sandwich beams with metallic foam cores.
      Acta Mechanica Sinica 2011; 27(6): 963–966.
      doi: 10.1007/s10409-011-0534-9 | SCI | EI
    94. [18] Li C, Zheng ZJ, Yu JL*, Lim CW. Static analysis of ultra-thin beams based on a semi-continuum model.
      Acta Mechanica Sinica 2011; 27(5): 713–719.
      doi: 10.1007/s10409-011-0453-9 | SCI | EI
    95. [17] Xie ZY, Yu JL, Zheng ZJ*. Indentation analysis of metallic foam-filled cylindrical pipe under transversely linear loading.
      Engineering Mechanics 2011; 28(8): 248–251, 256.(in Chinese)
      谢中友, 虞吉林, 郑志军*. 泡沫金属填充圆管横向线载荷作用下的压入分析. 工程力学 2011; 28(8): 248–251, 256.
      EI | CSCD
    96. [16] Tan H, Zheng ZJ, Wang HY*, Xia MF, Ke FJ. The advance of multi-scale simulation method for materials at nano/micrometer scale.
      Advances in Mechanics 2011; 41 (2): 155–171. (in Chinese)
      谭浩, 郑志军, 汪海英*, 夏蒙棼, 柯孚久. 微纳米尺度下材料性能多尺度模拟方法进展. 力学进展 2011; 41 (2): 155–171.
      doi: 10.6052/1000-0992-2011-2-lxjzJ2010-042 | CSCD
    97. 2010

    98. [15] Yu JL*, Zheng ZJ. Dynamic crushing of 2D cellular metals: Microstructure effects and rate-sensitivity mechanisms.
      Acta Mechanica Solida Sinica 2010; 23(S): 45–55.
      Second International Conference on Multiscale Modelling and Simulation (ICMMS), December 17-19, 2010, Guangzhou, China.
    99. [14] Zheng ZJ*, Bai YL. Splitting the fast and slow motions in molecular dynamics simulations based on the change of cold potential well bottom.
      AIP Conference Proceedings 2010; 1233(1): 917–922.
      doi: 10.1063/1.3452302 | CPCI-S
    100. 2009

    101. [13] Liu YD, Yu JL*, Zheng ZJ, Li JR. A numerical study on the rate sensitivity of cellular metals.
      International Journal of Solids and Structures 2009; 46(22–23): 3988–3998.
      doi: 10.1016/j.ijsolstr.2009.07.024 | SCI | EI
    102. [12] Tang YZ*, Zheng ZJ, Xia MF, Bai YL. Mechanisms underlying two kinds of surface effects on elastic constants.
      Chinese Physics Letters 2009; 26(12): 126201.
      | SCI | EI
    103. [11] Tang YZ*, Zheng ZJ, Xia MF, Bai YL. A unified guide to two opposite size effects in nano elastic materials.
      Acta Mechanica Solida Sinica 2009; 22(6): 605–622.
      | SCI |
    104. [10] Yu JL*, Liu YD, Zheng ZJ, Li JR, Yu TX. Influences of inertia and material property on the dynamic behavior of cellular metals.
      in: H. Zhao and N.A. Fleck (Eds.), IUTAM Symposium on Mechanical Properties of Cellular Materials, Springer, Dordrecht, 2009; 12: 149–157.
      IUTAM Symposium on Mechanical Properties of Cellular Materials, September 17-21, 2007, LMT-Cachan, Paris, France.
      CPCI-S:BIY28
    105. [9] Lin J*, Zheng ZJ, Yu JL, Bai YL. A thin liquid film and its effects in an atomic force microscopy measurement.
      Chinese Physics Letters 2009; 26(8): 086802(1–4).
      doi: 10.1088/0256-307X/26/8/086802 | SCI | EI
    106. [8] Kou DP, Yu JL*, Zheng ZJ. Effect of randomly removing cell walls on the dynamic crushing behaviour of honeycomb structures.
      Lixue Xuebao/Chinese Journal of Theoretical and Applied Mechanics 2009; 41(6): 859–868. (in Chinese)
      寇东鹏, 虞吉林*, 郑志军. 随机缺陷对蜂窝结构动态行为影响的有限元分析. 力学学报 2009; 41(6): 859–868.
      doi: 10.6052/0459-1879-2009-6-2008-232 | EI | CSCD
    107. 2008

    108. [7] Yu JL*, Wang EH, Li JR, Zheng ZJ. Static and low-velocity impact behavior of sandwich beams with closed-cell aluminum foam core in three-point bending.
      International Journal of Impact Engineering 2008; 35(8): 885–894.
      doi: 10.1016/j.ijimpeng.2008.01.006 | SCI | EI
    109. [6] Liu YD, Yu JL*, Zheng ZJ. Effect of inertia on the dynamic behavior of cellular metal.
      Gaoya Wuli Xuebao/Chinese Journal of High Pressure Physics 2008; 22(2): 118–124. (in Chinese)
      刘耀东, 虞吉林*, 郑志军. 惯性对多孔金属材料动态力学行为的影响. 高压物理学报 2008; 22(2): 118-124.
      doi: 10.11858/gywlxb.2008.02.002 | EI | CSCD
    110. 2007

    111. [5] Zheng ZJ. Study on the Micro/nanoscopic Adhesive Contact Mechanical Models.
      Doctoral Dissertation. University of Science and Technology of China 2007. (in Chinese)
      郑志军. 微纳米吸附接触力学模型的研究. 博士论文 中国科学技术大学 2007.
      doi: CNKI:CDMD:1.2007.098224 | [PDF]
    112. [4] Zheng ZJ, Yu JL*. A generalized maugis model for adhesive contact of arbitrary axisymmetric elastic objects.
      Lixue Xuebao/Chinese Journal of Theoretical and Applied Mechanics 2007; 39(3): 382–388. (in Chinese)
      郑志军, 虞吉林*. 任意轴对称弹性体吸附接触的广义Maugis 模型. 力学学报 2007; 39(3): 382-388.
      doi: 10.6052/0459-1879-2007-3-2006-395 | EI | CSCD
    113. [3] Zheng ZJ, Yu JL*, Li JR, Lin J. Adhesive contact of power-law axisymmetric elastic objects.
      Journal of University of Science and Technology of China 2007; 37(10): 1293–1299. (in Chinese)
      郑志军, 虞吉林*, 李剑荣, 林静. 幂次型表面的轴对称弹性体之间的吸附接触. 中国科学技术大学学报 2007; 37(10): 1293–1299.
      doi: CNKI:SUN:ZKJD.0.2007-10-022 | CSCD
    114. [2] Zheng ZJ, Yu JL*. Using the Dugdale approximation to match a specific interaction in the adhesive contact of elastic objects.
      Journal of Colloid and Interface Science 2007; 310(1): 27–34.
      doi: 10.1016/j.jcis.2007.01.042 | SCI | EI | PubMed
    115. 2005

    116. [1] Zheng ZJ, Yu JL*, Li JR. Dynamic crushing of 2D cellular structures: A finite element study.
      International Journal of Impact Engineering 2005; 32(1–4): 650–664.
      doi: 10.1016/j.ijimpeng.2005.05.007 | SCI | EI
      [100 citations@Web of Science, April 5, 2018] | [200 citations@Google Scholar, June 9, 2019]