Lan-Hong Dai (戴兰宏)

Stake Key Laboratory of Nonlinear Mechanics (LNM)
Institute of Mechanics
Chinese Academy of Sciences
No 15 Beisihuanxi Road, Beijing 100190
P.R. China
中国科学院力学研究所非线性力学国家重点实验室，北京 100190，中国

Email: lhdai@lnm.imech.ac.cn
 
学习与工作经历

    1992.9-1996.8:   中国科学院力学研究所， 固体力学博士学位
    1996.9-1998.9:   北京大学力学系， 博士后
    1998.12:      中科院力学研究所 非线性力学国家重点实验室 副研究员
    1999.2-1999.12:  香港科技大学，访问工作
    2001.12：     中科院力学研究所 非线性力学国家重点实验室 研究员
    2003.6：      中科院力学研究所 非线性力学国家重点实验室 研究员、博士生导师
    2005.10-2006.10:  哈佛大学，访问工作
    2006.10-至今：   中科院力学研究所 非线性力学国家重点实验室 研究员、博士生导师

社会任职

    现任中国科学院力学研究所学位委员会主任，中国科学院大学工程科学学院教授，中国力学学会副理事长，中国力学学会爆炸力学专业委员会主任委员，中国力学学会固体力学专业委员会委员，《力学学报》编委、《力学进展》编委、《固体力学学报》编委，《爆炸与冲击》编委、《科技导报》编委，中国物理学会非晶态物理专业委员会委员，中国复合材料学会常务理事、《复合材料学报》编委，国际材料动态行为学会（DYMAT）会员。

获奖与荣誉

    1、国家杰出青年科学基金获得者

    2、“新世纪百千万人才工程”国家级人选入选者

    3、享受国务院政府特殊津贴

    4、中国科学院“朱李月华”优秀教师奖

    5、中国科学院优秀研究生指导教师奖

主要研究领域

    1. 冲击动力学
       冲击载荷下材料变形与破坏、绝热剪切带、动态本构、断裂

    2. 新型材料力学性能
       非晶合金（金属玻璃）及其复合材料、高熵合金、先进金属材料等材料体系的制备与结构表征、剪切带形成与演化动力学、本构、宏细微观断裂机理

    3. 无序物质非线性力学
       无序合金（非晶与高熵合金）、颗粒物质复杂流体的变形与流动不稳定、断裂、非平衡结构的涌现与时空关联、斑图（花样）动力学；介尺度力学与多尺度力学的理论与模拟
研究项目

    国家自然科学基金重大项目“无序合金塑性流动与强韧化机理”  （负责人）

    科技部国家重点研发计划项目“多场耦合条件下金属结构材料损伤演化行为的跨尺度关联评价”（负责人）

    中国科学院战略性先导专项B项目“复杂介质系统前沿与交叉力学”（负责人）

    中国科学院前沿领域重点部署项目“先进高强金属材料剪切带的涌现与调控”（负责人）

    国家自然科学基金项目“非晶合金剪切带涌现的内禀动力学机制”（负责人）

 
论文专著

    (#Equal contribution; *Corresponding Author)

    Shear banding in bulk metallic glasses (Chapter 8, Author: Lan Hong Dai)
    in Adiabatic Shear Localization: Frontiers and Advances (2nd ed, by B. Dodd and Y.L. Bai), Elsevier, 2012

    Superior strength-ductility CoCrNi medium-entropy alloy wire
    J.P.Liu, J.X.Chen, T.W.Liu, C.Li, Y.Chen*, L.H.Dai*
    Scr. Mater., 2020, 181, 19-24.

    Statistical complexity of potential energy landscape as a dynamic signature of the glass transition
    D.Han,D.Wei,P.H.Cao,Y.J.Wang*,L.H.Dai*
    Phys. Rev. B, 2020, 101, 064205.

    Atomistic structural mechanism for the glass Transition: Entropic contribution
    D.Han, D.Wei, J.Yang, H.L.Li, M.Q.Jiang, Y.J.Wang*, L.H.Dai*, A. Zaccone*
    Phys. Rev. B, 2020, 101, 014113.

    "Self-sharpening" tungsten high-entropy alloy
    X.F.Liu, Z.L.Tian, X.F.Zhang, H.H.Chen, T.W.Liu, Y.Chen, Y.J.Wang, L.H.Dai*
    Acta Mater., 2020, 186, 257-266.

    Dislocation nucleation and evolution at the ferrite-cementite interface under cyclic loadings
    L.W.Liang, Y.J.Wang*, Y.Chen, H.Y.Wang, L.H.Dai*
    Acta Mater., 2020, 186,267-277.

    Hierarchical-microstructure based modeling for plastic deformation of partial recrystallized copper
    Y. Liu, S.L.Cai*, M.Y.Su, Y.J.Wang, L.H.Dai*
    Mech. Mater., 2019, 139, 103207.

    Probing the role of Johari-Goldstein relaxation in the plasticity of metallic glasses
    M.Zhang*, Y.Chen*, R.G.He, S.F.Guo, J.Ma, L.H.Dai*
    Mater. Res. Lett., 2019,7(9), 383-391.

    Ratchetting in cold-drawn pearlitic steel wires
    L.W.Liang, L.Xiang, Y.J.Wang, Y.Chen, H.Y.Wang, L.H.Dai*
    Metal. Mater. Trans. A, 2019,50(10), 4561-4568.

    One-step annealing optimizes strength-ductility tradeoff in pearlitic steel wires
    L.Xiang, L.W.Liang, Y.J.Wang, Y.Chen, H.Y.Wang, L.H.Dai*
    Mater. Sci. Eng. A, 2019, 757, 1-13.

    Influence of surface energy and thermal effects on cavitation instabilities in metallic glasses
    X.Huang, Z. Ling, L.H.Dai*
    Mech. Mater., 2019,131,113-120.

    Revisiting the structure-property relationship of metallic glasses: Common spatial correlation revealed as a hidden rule
    D. Wei, J. Yang, M.Q.Jiang, B.C.Wei, Y.J.Wang*, L.H.Dai*
    Phys. Rev. B, 2019, 99, 014115.

    Enhancing strength without compromising ductility in copper by combining extrusion machining and heat treatment
    Y.Liu, S.L.Cai*, F.G.Xu, Y.J.Wang, L.H.Dai*
    J. Mater. Process. Tech., 2019, 267, 52-60.

    Susceptibility of shear banding to chemical short-range order in metallic glasses
    Z.Y.Yang, Y.J.Wang*, L.H.Dai*
    Scr. Mater., 2019, 162, 141-145.

    A comparative study of the rate effect on deformation mode in ductile and brittle bulk metallic glasses
    D.Zhou, B. Hou, B.J. Li, S. Y. Zhang, L.H.Dai, Y.L.Li*
    Intermetallics, 2018,96, 94-103.

    Strong resistance to hydrogen embrittlement of high-entropy alloy
    Z.Pu, Y.Chen*, L.H.Dai*
    Mater. Sci. Eng. A, 2018, 736, 156-166.

    A free energy landscape perspective on the nature of collective diffusion in amorphous solids
    Y.J.Wang*, J.P.Du, S.Shinzato, L.H.Dai*, S. Ogata*
    Acta Mater. 2018, 157, 165-173.

    Dilatancy induced dutile-brittle transition of shear band in metallic glasses
    F.Zheng, M.Q.Jiang, L.H.Dai*
    Proc. R. Soc. A 2018，474, 20170836.

    Extraordinary creep relaxation time in a La-based metallic glass
    M.Zhang*, Y.Chen, D.Wei, L.H.Dai*
    J. Mater. Sci. 2018, 53, 2956-2964.

     Failure Assessment for the High-Strength Pipelines with Constant-Depth Circumferential Surface Cracks
    X.Liu, Z.X.Lu, Y.Chen, Y.L.Sui, L.H.Dai*
    Advances in Materials Science and Engineering, 2018,208914,1-11.

    Improved J Estimation by GE/EPRI method for the thin-walled pipes with small constant-depth circumferential surface cracks
    X.Liu, Z.X.Lu, Y.Chen, Y.L.Sui, L.H.Dai*
    J. Pressure Vessel Technol., 2018, 140, 011201.

    On the instability of chip flow in high-speed machining.
    G.G.Ye, M.Q.Jiang, S.F.Xue, W. Ma, L.H.Dai*
    Mechanics of Materials, 2018, 116, 104-119.

    Universal structural softening in metallic glasses indicated by boson heat capacity peak
    M.Q.Jiang*, M.Peterlechner, Y.J.Wang, W.H.Wang, F.Jiang, L.H.Dai and G.Wilde
    Appl. Phys. Lett. 2017, 111,261901.

    Suppression of Hopf bifurcation in metal cutting by extrusion machining
    Y.Liu, S.L.Cai*, X.C. Shang, L.H.Dai*
    Nonlinear Dyn 2017, 88, 433-453.

    Strain gradient drives shear banding in metallic glasses
    Z.L.Tian, Y.J.Wang, Y.Chen, L.H.Dai*
    Phys. Rev. B 2017, 96, 094103.

    Atomic theory of viscoelastic response and memory effects in metallic glasses
    B.Y.Cui, J.Yang, J.C.Qiao, M.Q.Jiang, L.H.Dai, Y.J.Wang*, A. Zaccone*
    Phys. Rev. B 2017, 96, 094203.

    Elastic-plastic modeling of metallic strands and wire ropes under axial tension and torsion loads
    L.Xiang, H.Y.Wang, Y.Chen, Y.J.Guan, L.H.Dai*
    Int. J. Solids Struct., 2017, 129,103-118.

    Cavitation bubble dynamics during pulsed laser ablation of a metallic glass in water
    M.Q.Jiang*, X.Q.Wu, Y.P.Wei, G. Wilde, L.H.Dai*
    Extreme Mechanics Letters, 2017, 11, 24-29.

    Shear band dilatation in amorphous alloys
    M.Q.Jiang*, G. Wilde, L.H.Dai*
    Scr. Mater., 2017, 127, 54-57.

    Tuning plasticity of in-situ dendrite metallic glass composites via the dendrite-volume-fraction-dependent shear banding
    X.F.Liu, Y.Chen, M.Q.Jiang, P.K.Liaw, L.H.Dai*
    Mater. Sci. Eng. A, 2017, 680, 121-129.

    Onset and evolution of discontinuously segmented chip flow in ultra-high-speed cutting Ti-6AL-4V
    G.G.Ye, S.F.Xue, W. Ma, L.H.Dai*
    Int. J. Adv. Manuf. Technol., 2017, 88(1), 1161-1174.

    Enhancing surface integrity by high-speed extrusion machining
    Y.Liu,S.L.Cai*,S.H.Shang,L.H.Dai*
    Int. J. Adv. Manuf. Technol., 2017,89(5),2141-2150.

    Transition from stress-driven to thermally activated stress relaxation in metallic glasses.
    J.C.Qiao, Y.J. Wang*, L.Z.Zhao, L.H.Dai, D. Crespo, J.M. Pelletier, L.M.Keer, and Y.Yao*
    Phys. Rev. B, 2016, 94, 104203.

    Correlation between strain rate sensitivity and a relaxation of metallic glasses
    M.Zhang, Y.J.Wang, L.H.Dai*
    AIP Adavances, 2016(6), 075022.

    Intrinsic structural defects on medium range in metallic glasses
    X.Huang, Z.Ling, Y.J.Wang, L.H.Dai*
    Intermetallics, 2016, 75, 36-41.

    Shock compression response of high entropy alloys
    Z.J.Jiang, J.Y.He, H.Y.Wang, H.S.Zhang, Z.P.Lu and L.H.Dai*
    Mater. Res. Lett., 2016, 4(4), 226-232.

    Understanding the serrated flow and Johari-Goldstein relaxation of metallic glasses
    M.Zhang, Y.J.Wang, L.H.Dai*
    J. Non-Cryst. Solids, 2016,444,23-30.

    Time-,stress-,and temperature-dependent deformation in nanostructured copper: creep tests and simulations
    X.S.Yang#, Y.J.Wang#, H.R.Zhai, G.Y. Wang, Y.J. Su, L.H.Dai, S. Ogata*, T. Y. Zhang*
    J. Mech. Phys. Solids, 2016,94,191-206.

    Determination of dynamic shear strength of 2024 aluminum alloy under shock compression.
    H.S.Zhang,M.Yan,H.Y.Wang,L.T.Shen, and L.H.Dai*.
    AIP Advances, 2016,6,045309.

    A metallic glass syntactic foam with enhanced energy absorption performance.
    H.Lin,H.Y.Wang,C.Lu,L.H.Dai*
    Scr. Mater.,2016,119,47-50.

    Time, Stress, and temperature-dependent deformation in nanostructured copper: Stress relaxation tests and simulations.
    X.S.Yang#, Y.J.Wang#, G.Y.Wang, H. R. Zhai, L.H.Dai, T.Y.Zhang*
    Acta Mater.,2016,108,252-263.

    An index of shear banding susceptibility of metallic glasses.
    M.Zhang, Y.Chen, L.H.Dai*
    Intermetallics, 2016,71,12-17.

    A new method for grain refinement in magnesium alloy: High speed extrusion machining.
    Y.Liu*, S.L.Cai, L.H.Dai
    Mater. Sci. Eng. A, 2016, 651,878-885.

    Nature of crack-tip plastic zone in metallic glasses.
    Y.Chen, L.H.Dai*
    Inter. J. Plasticity, 2016, 77, 54-74.

    Size-dependent plastic deformation and failure mechanisms of nanotwinned Ni3Al: insights form atomistic cracking model.
    Y.J.Wang*, K. Tsuchiya, L.H.Dai*
    Mater. Sci. Eng. A, 2016, 649,449-460.

    Direct atomic-scale evidence for shear–dilatation correlation in metallic glasses.
    Y.J.Wang*, M.Q.Jiang, Z.L.Tian, L.H.Dai*
    Scr. Mater. 2016, 112,37-41.

    Thermal expansion accompanying the glass-liquid transition and crystallization.
    M.Q.Jiang*, M.Naderi, Y.J. Wang, M. Peterlechner, X.F.Liu, F. Zeng, F. Jiang, L.H. Dai* and G. Wilde
    AIP Advances,2015,5,127133.

    Universal enthalpy-entropy compensation rule for the deformation of metallic glasses.
    Y.J.Wang*, M.Zhang, L. Liu, O. Shigenobu, L. H. Dai*
    Phys. Rev. B, 2015, 92, 174118.

    Understanding ductile-to-brittle transition of metallic glasses from shear transformation zone dilatation.
    M.Q.Jiang*, G. Wilde, F. Jiang, L. H. Dai*
    Theor. Appl. Mech. Lett., 2015,5,200-204.

    On the compressive failure of tungsten fiber reinforced Zr-based bulk metallic glass composite.
    J. H. Chen, Y. Chen, M. Q. Jiang, X. W. Chen, H. F. Zhang, L. H. Dai*
    Int. J. Solids. Struct. 2015, 69-70,428-441.

    Modelling the tuned criticality in stick-slip friction during metal cutting.
    Q. Wang, C. Lu, G.G.Ye, L. H. Dai*
    Modelling Simul. Mater. Sci. Eng. 2015, 12, 055013.

    Heterogeneous dynamics of metallic glasses.
    M. Zhang*, L. H. Dai, Y. Liu, L. Liu
    Scr. Mater. 2015, 107,111-114.

    Modeling of multi-strand wire ropes subjected to axial tension and torsion loads.
    L. Xiang, H. Y. Wang, Y. Chen, Y. J. Guan, Y. L. Wang, L. H. Dai*
    Int. J. Solids Struct. 2015, 58,233-246.

    Explosive boiling of a metallic glass superheated by nanosecond pulse laser ablation.
    M. Q. Jiang*, Y. P. Wei, G. Wilde, and L. H. Dai*
    Appl. Phys. Lett. 2015, 106, 021904.

    Dynamic shear punch behavior of tungsten fiber reinforced Zr-based bulk metallic glass matrix composites.
    J. H. Chen, Y. Chen, M. Q. Jiang, X. W. Chen, H. M. Fu, H. F. Zhang, L. H. Dai*
    International Journal of Impact Engineering 2015, 79,22-31.

    Bridging shear transformation zone to the atomic structure of amorphous solids.
    M. Zhang, Y. J. Wang and L. H. Dai*
    J. Non-Crystalline Solids 2015, 410, 100-105.

    Origin of stress overshoot in amorphous solids.
    M. Q. Jiang*, G. Wilde and L. H. Dai*
    Mech. Mater. 2015, 81, 72-83.

    Joining of bulk metallic glass to brass by thick-walled cylinder explosion.
    M. Q. Jiang*, B. M. Huang, Z. J. Jiang, C. Lu and L. H. Dai*
    Scr. Mater. 2015, 97,17-20.

    Dynamic fragmentation induced by network-like shear bands in a Zr-based bulk metallic glass.
    F. Zeng, Y. Chen, M. Q. Jiang, C. Lu, L. H. Dai*
    Intermetallics 2015, 56, 96-100.

    Characterization of the deformation field in large-strain extrusion machining.
    S. L. Cai, Y. Chen, G. G. Ye, M. Q. Jiang, H. Y. Wang, L. H. Dai*
    J. Mater. Proc. Techno. 2015, 216,48-58.

    Ductile-to-brittle transition in spallation of metallic glasses.
    X. Huang, Z. Ling and L. H. Dai*
    J. Appl. Phys. 2014, 116, 143503.

    Suppression of repeated adiabatic shear banding by dynamic large strain extrusion machining.
    S.L. Cai, L. H. Dai*
    J. Mech. Phys. Solids 2014, 73, 84-102.

    Wavelike fracture pattern in a metallic glass: a Kelvin-Helmholtz flow instability.
    M. Q. Jiang, G. Wilde, C. B. Qu, F. Jiang, H. M. Xiao, J. H. Chen, S. Y. Fu, L. H. Dai*
    Phil. Mag. Lett. 2014, 94(10),669-677.

    Direct observation on the evolution of shear banding and buckling in Tungsten fiber reinforced Zr-based bulk metallic glasses composite.
    J. H. Chen, Y. Chen, M. Q. Jiang, X. W. Chen, H. M. Fu, H. F. Zhang, L. H. Dai*
    Metallurgical and Materials Transactions A 2014, 45A, 5397-5408.

    Mechanical  annealing in the flow of supercooled metallic liquid.
    M. Zhang, L. H. Dai, L. Liu*
    J. Appl. Phys. 2014, 116, 053522.

    Cryogenic-temperature-induced transition from shear to dilatational failure in metallic glasses.
    M. Q. Jiang*, G. Wilde, J. H. Chen, C. B. Qu, S. Y. Fu, F. Jiang, L. H. Dai*
    Acta Mater. 2014, 77,248-257.

    Critical cutting speed for onset of serrated chip flow in high speed machining.
    G. G. Ye, Y. Chen, S. F. Xue, L. H. Dai*
    International Journal of Machine Tools & Manufacture 2014, 86,18-33.

    Onset and direction of shear banding instability in metallic glasses.
    Y. Chen, L. H. Dai*
    J. Mater. Sci. Technol. 2014, 30(6), 616-621.

    工程科学前沿的拓荒者——郑哲敏.
    戴兰宏*
    力学进展 2013,43(3): 265-294.

    A universal power law for metallic glasses.
    M. Q. Jiang, G. Wilde, J. B. Gao and L. H. Dai
    Scr. Mater. 2013, 69(10)：760-763.

    Collective evolution dynamics of multiple shear bands in bulk metallic glasses.
    Y. Chen, M.Q. Jiang, L.H. Dai
    International Journal of Plasticity 2013, 50:18-36.

    Strain rate dependent shear banding behavior of a Zr-based bulk metallic glass composite.
    J.H. Chen, M.Q. Jiang, Y. Chen, L.H. Dai
    Materials Science & Engineering A 2013, 576:134-139.

    Cavitation instability in bulk metallic glasses.
    X. Huang, Z. Ling, L.H. Dai
    International Journal of Solids and Structures 2013, 50: 1364-1372.

    Modeling periodic adiabatic shear band evolution during high speed machining Ti-6Al-4V alloy.
    G.G. Ye, S.F. Xue, M.Q. Jiang, X.H. Tong, L.H. Dai
    International Journal of Plasticity 2013, 40:39-55.

    Relation between ideal and real strengths of metallic glasses.
    M. Q. Jiang, F, Jiang, V. Keryvin, J. X. Meng, J. Sun, and L. H. Dai
    J. Non-Cryst. Solids 2012, 358: 3119-3123.

    Saffman-Taylor fingering in nanosecond pulse laser ablating bulk metallic glass in water.
    Y. Liu, M.Q. Jiang, G.W. Yang, J.H. Chen, Y.J. Guan, L.H. Dai
    Intermetallics 2012, 31: 325-329.

    Energy absorption mechanism of open-cell Zr-based bulk metallic glass foam.
    X. Wei, J. H. Chen, L. H. Dai
    Scripta Mater. 2012, 66:721-724.

    非晶合金泡沫材料的研究进展.
    魏秀，蒋敏强，陈军红，戴兰宏
    材料科学与工程学报 2012,03(2)：291-305.

    Cutting AISI 1045 steel at very high speeds.
    G.G. Ye, S.F. Xue, W. Ma, M.Q. Jiang, Z. Ling, X.H. Tong, L.H. Dai
    International Journal of Machine Tools & Manufacture 2012, 56: 1-9.

    Instability criterion of materials in combined stress states and its application to orthogonal cutting process.
    W. Ma, X.W. Li, L.H. Dai, Z. Ling
    International Journal of Plasticity 2012, 30-31: 18-40.

    Amorphous alloy reinforced Whipple shield structure.
    X. Huang, Z. Ling, Z.D. Liu, H.S. Zhang, L.H. Dai
    International Journal of Impact Engineering 2012, 42: 1-10.

    非晶合金塑脆断裂转变的控制参数.
    陈艳，戴兰宏
    中国科学：物理学 力学 天文学 2012,42: 551-559.

    Temperature-dependent yield asymmetry between tension and compression in metallic glasses.
    Y. Chen, M.Q. Jiang, L.H. Dai
    Acta Phys. Sin. 2012, 61: 036201.

    How does spallation microdamage nucleate in bulk amorphous alloys under shock loading?
    X. Huang, Z. Ling, H. S. Zhang, J. Ma, L.H. Dai
    Journal of Applied Physics 2011, 110: 103519.

    Surface rippling on bulk metallic glass under nanosecond pulse laser ablation.
    Y. Liu, M.Q. Jiang, G.W. Yang, Y.J. Guan, L.H. Dai
    Applied Physics Letters 99 (2011) 191902.

    Influence of cutting conditions on the cutting performance of TiAl6V4.
    G.G. Ye, S.F. Xue, X.H. Tong, L.H. Dai
    Adv. Mater. Res. 2011, 337: 387-391.

    Slip-line field modeling of orthogonal machining pressure sensitive materials.
    G.G. Ye, S.F. Xue, X.H. Tong, L.H. Dai
    Int. J. Adv. Manuf. Technol. 2012, 58: 907-914.

    Failure criterion for metallic glasses.
    Y. Chen, M.Q. Jiang, Y.J. Wei, and L.H. Dai
    Philos. Mag. 2011,91: 4536-4554

    Crack branching instability and directional stability in dynamic fracture of a tough bulk metallic glass
    M.Q. Jiang, J.X. Meng, V. Keryvin, and L.H. Dai
    Intermetallics 2011, 19, 1775-1779.

    How does the initial free volume distribution affect shear band formation in metallic glass?
    Y. Chen, M.Q. Jiang, and L.H. Dai
    Sci. China Series G: Physics, Mechanics & Astronomy . 2011, 54: 1488-1494.

    Shear-band toughness of bulk metallic glasses.
    M.Q. Jiang, and L.H. Dai
    Acta Mater. 2011, 59: 4525-4537.

    Metallic glass nanofilms.
    M.Q. Jiang, G.H. Duan, and L.H. Dai
    J. Non-Cryst. Solids 2011, 357: 1621-1627.

    Frequency-dependent focal adhesion instability and cell reorientation under cyclic substrate stretching.
    Y. Zhong, D. Kong, L. H. Dai, and B. H. Ji
    Cellular and Molecular Bioengineering 2011, 4(3):442-456.

    Fractal in fracture of bulk metallic glass.
    M.Q. Jiang, J.X. Meng, J. B. Gao, X.-L. Wang, T. Rouxel, V. Keryvin, Z. Ling, and L.H. Dai
    Intermetallics 2010, 18: 2468-2471.

    Intrinsic correlation between dilatation and pressure sensitivity of plastic flow in metallic glasses.
    L. Sun, M.Q. Jiang, and L.H. Dai
    Scripta Mater. 2010, 63: 943-946.

    Stabilizing to disruptive transition of focal adhesion response to mechanical forces.
    D. Kong, B.H. Ji, L.H. Dai
    J. Biomech. 2010, 43: 2524-2529.

    Short-range-order effects on intrinsic plasticity of metallic glasses.
    M.Q. Jiang, and L.H. Dai
    Phil. Mag. Lett. 2010, 90: 269-277.

    Nanoscale periodic corrugation to dimple transition due to "beat" in a bulk metallic glass.
    M.Q. Jiang, Z. Ling, J.X. Meng, J.B. Gao, and L.H. Dai
    Scripta Mater. 2010, 62: 572-575.

    Smaller Deborah number inducing more serrated plastic flow of metallic glass.
    M.Q. Jiang, S.Y. Jiang, Z. Ling, and L.H. Dai
    Comput. Mater. Sci. 2009, 46: 767-771.

    On the origin of shear banding instability in metallic glasses.
    M.Q. Jiang, and L.H. Dai
    J. Mech. Phys. Solids 2009, 57: 1267-1292.

    Formation mechanism of lamellar chips during machining of bulk metallic glass.
    M.Q. Jiang, and L.H. Dai
    Acta Mater. 2009, 57: 2730-2738.

    Prediction of shear-band thickness in metallic glasses.
    M.Q. Jiang, W.H. Wang, and L.H. Dai
    Scripta Mater. 2009, 60: 1004-1007.

    Inherent shear-dilatation coexistence in metallic glass.
    M.Q. Jiang, S.Y. Jiang, and L.H. Dai
    Chin. Phys. Lett. 2009, 26: 016103.

    Atomistic origin of rate-dependent serrated plastic flow in metallic glasses.
    S.Y. Jiang, M.Q. Jiang, L.H. Dai, and Y.G. Yao
    Nanoscale Res.Lett. 2008, 3: 524-529.

    Stability of Adhesion Clusters and Cell Reorientation under Lateral Cyclic Tension.
    Dong Kong, Baohua Ji and Lanhong Dai
    Biophys Journal 2008, 95:4034-4044.

    Basic mechanical behaviors and mechanics of shear banding in BMGs.
    L.H. Dai and Y.L. Bai
    Int. J. Impact Eng. 2008,35:704-716.

    Dynamic fracture instability of tough bulk metallic glass.
    J.X. Meng, Z. Ling, M.Q. Jiang, H.S. Zhang, L.H. Dai
    Appl. Phys. Lett. 2008,92:171909.

    Concentrated-mass cantilever enhances multiple harmonics in tapping-mode atomic force microscopy.
    Huiling Li, Yan Chen, Lanhong Dai
    Appl. Phys. Lett. 2008,92:151903.

    Energy dissipation in fracture of bulk metallic glasses via inherent competition between local softening and quasi-cleavage.
    M.Q. Jiang, Z. Ling, J.X. Meng, L.H. Dai
    Philos. Mag. 2008, 88:407-426.

    Numerical study of pile-up in bulk metallic glass during spherical indentation.
    Ai Ke, Dai Lanhong
    Sci. China Series G: Physics, Mechanics & Astronomy 2008, 51: 379-386.

    A modified free volume model for characterizing of rate effect in bulk metallic glasses.
    LIU Long-Fei, DAI Lan-Hong, BAI Yi-Long
    Chin. Phys. Lett. 2008, 25: 1052-1055.

    On mechanical properties of metallic glass and its liquid vitrification characteristics.
    M.Q. Jiang and L.H. Dai
    Adv. Mater.Res. 2008, 41-42: 247-252.

    Nonlinear mechanical modeling of cell adhension.
    Dong Kong, Baohua Ji and Lanhong Dai
    Journal Theoretical Biology 2008, 250:75-84.

    Intrinic correlation between fragility and bulk modulus in metallic glasses.
    M.Q. Jiang, and L.H. Dai
    Phys. Rev.B 2007, 76:054204.

    液体的fragility及其与玻璃固体力学性能的关联.
    戴兰宏，蒋敏强
    力学进展 2007, 37: 346-360.

    A new modified expanding cavity model for characterizing the spherical indentation behavior of bulk metallic glass with pile-up.
    K. Ai and L.H.Dai.
    Scripta Mater. 2007, 56:761-764.

    Charaterization of rate-dependent shear behavior of Zr-based bulk metallic glass using shear-punch testing.
    L.F. Liu, L.H. Dai,Y.L. Bai, B.C. Wei, J. Eckert.
    J. Mater. Res. 2006, 1(1):153-160.

    Adiabatic shear banding instability in bulk metallic glasses.
    L.H.Dai, M.Yan, L.F.Liu, Y.L. Bai.
    Appl. Phys. Lett. 2005,87:141916.

    Initiation and propagation of shear bands in Zr-based bulk metallic glass under quasi-static and dynamic loadings.
    L.F.Liu,L.H.Dai,Y.L.Bai,B.C.Wei.
    J. Non-Cryst. Solids 2005,351:3259-3270.

    Release Behaviour of shock loaded LY12 aluminum alloy.
    M.Yan,L.H.Dai,L.T.Shen.
    Chin. Phys. Lett. 2005, 22:2903-2905.

    Behavior of multiple shear bands in Zr-based bulk metallic glass.
    L.F.Liu,L.H.Dai,Y.L.Bai,B.C.Wei,J.Eckert.
    Mater. Chem. Phys. 2005,93:174-177.

    Strain rate-dependent compressive deformation behavior of Nd-based bulk metallic glass.
    L.F.Liu,L.H.Dai,Y.L.Bai,B.C.Wei,G.S.Yu.
    Intermetallics 2005,13:827-832.

    Formation of adiabatic shear band in metal matrix composites.
    L.H.Dai, L.F.Liu, Y.L.Bai.
    Int. J.  Solids & Struct. 2004,41:5979-5993.

    Serrated plastic flow in Zr-based bulk metallic glass during nanoindentation.
    L.H.Dai, L.F.Liu, M.Yan, B.C. Wei, J.Eckert.
    Chin. Phys. Lett. 2004, 21(8)：1593－1595.

    Characterization of rate-dependent loading/unloading dynamic constitutive behavior of aluminum alloy by Lagrange experiment.
    M.Yan, L.H.Dai,L.T.Shen, J.L.Shang.
    J. Mater. Sci. 2004, 39: 3179-3181.

    Effect of particle size on the formation of adiabatic shear band in particle reinforced metal matrix composites.
    L.H.Dai, L.F.Liu, Y.L.Bai.
    Mater.Lett. 2004, 58: 1773-1776.

    Shear strength measurements in LY-12 aluminum alloy during shock loading.
    L.H.Dai, M.Yan, L.T.Shen.
    Chin. Phys. Lett. 2004,21: 707-708.

    Strain gradient effects on deformation strengthening behavior of particle reinforced metal matrix composites.
    L.F.Liu, L.H. Dai, G.W. Yang.
    Mater. Sci. Eng. 2003,A345: 190-196.

    Onset of adiabatic shear instability in strain gradient dependent metal matrix composites.
    L.H. Dai, L.F. Liu, Y.L. Bai.
    International Journal of Nonlinear Science & Numerical Simulation. 2002, 3: 685-688.

    Size-dependent inelastic behavior of particle reinforced metal matrix composites.
    L.H. Dai, Z. Ling and Y. L. Bai.
    Composites Science and Technology 2001, 61: 1057-1063.

    An incremental micromechanical scheme for nonlinear composites.
    L.H. Dai and G.J. Huang .
    International Journal of Mechanical Science 2001, 43: 1179-1193.

    Effect of reinforcing particle size on the formation of microbands in SiCp/6151 Al matrix composites.
    L.F.Liu, L.H.Dai, G.W.Yang.
    Journal of Materials Science Letters 2001, 20: 2097-2098.

    Strain gradient effect on the initiation of adiabatic shear localization in metal matrix composites.
    L.H. Dai , Z. Ling and Y.L., Bai.
    Key Engineering Materials 2000, 177-180: 401-406.

    A strain gradient strengthening law for particle reinforced metal matrix composites
    L.H. Dai, Z. Ling and Y.L., Bai.
    Scripta Materialia 1999, 41(3): 245-251.

    Explicit expressions of bounds for effective moduli for multiphase composites by the generalized self-consistent method.
    L.H. Dai, Z.P. Huang and R. Wang.
    Composites Science and Technology 1999 , 59(11): 1691-1699.

    An explicit expression of the effective moduli for composite materials filled with coated inclusions.
    L. H. Dai, Z. P. Huang, and R. Wang.
    Acta Mechanica Sinca (English Series) 1998,14(1):37-52.

    A generalized self-consistent Mori-Tanaka scheme for predicyion of the eefctive moduli of hybrid multiphase particulate composites.
    L.H. Dai, Z.P. Huang and R. Wang.
    Polymer Composites 1998, 19: 506-513.

    Experimental investigation on shear strength of unidirectional C/Al composite under dynamic torsional loading.
    L.H. Dai, Y.L. Bai and R. S.W. Lee.
    Composites Science and Technology 1998, 58: 1667-1673.

    Transverse shear strength of unidirectional carbon fiber reinforced aluminum matrix composite under static and dynamic loadings.
    L.H. Dai and Y.L. Bai.
    Journal of Composite Materials 1998, 32(3): 246-257.

 
讲授课程

    中国科学院大学: 《弹塑性力学》

 
课题组成员#team

    课题组名称：  冲击动力学与新型材料力学性能

    课题组群：27655592

    Current members:

Name
   

Status
   

Research interests
   

Email
Hai-ying Wang
(汪海英）     研究员、博士生导师     冲击动力学与材料力学性能     why@lnm.imech.ac.cn
Min-qiang Jiang
(蒋敏强)     研究员、博士生导师     非晶态材料的变形断裂     mqjiang@lnm.imech.ac.cn 
Yan Chen
(陈艳)     副研究员     新型材料力学性能     chenyan@lnm.imech.ac.cn
Yun-jiang Wang
(王云江)     研究员      非晶及纳米晶原子尺度模拟     yjwang@imech.ac.cn
Tian-Wei Liu
（刘天威）     助理研究员     金属材料结构与表征     liutianwei@lnm.imech.ac.cn
Zhong Ling
(凌中)     副研究员     材料动力学性能与微结构表征     lingz@lnm.imech.ac.cn
Xingfa Liu
（刘兴发）     博士生     非晶态合金材料制备及力学性能     lxf827@mail.ustc.edu.cn
Hao Lin
（林浩）     博士生     新型材料力学性能     linhao@imech.ac.cn
Zhuo Pu
（蒲卓）     博士生     新型材料力学性能     415637404@qq.com
Chen Li
（李琛）     博士生     新型材料力学性能     lichen114@mails.ucas.ac.cn
Xin Sun
（孙星）     博士生     新型材料力学性能     sunxing@imech.ac.cn
Dan Wei
（魏丹）     博士生     新型材料力学性能     weidan@lnm.imech.ac.cn
Mingyao Su
(苏明耀）     博士生     金属高速切削力学行为     sumingyao@imech.ac.cn
Jie Yang
(杨杰）     硕士生     新型材料力学性能     yangjie@imech.ac.cn
Chencheng Gong
（龚臣成）     博士生     新型聚合物材料力学性能     gongchencheng@imech.ac.cn
Zhoucan Xie
（谢周璨）     博士生     材料冲击动力学行为     zhoucanxie@163.com
Ruyue Song
（宋如月）     硕士生     新型材料力学性能     songruyue@imech.ac.cn
Xuan Song
（宋璇）     硕士生     新型材料力学性能     songxuan@imech.ac.cn
Dong Han
（韩懂）     硕士生     新型材料力学性能     handong@imech.ac.cn
Feng Chen
（陈峰）     硕士生     新型材料力学性能     chenfeng@imech.ac.cn
Lunwei Liang
（梁伦伟）     硕士生     新型材料力学性能     lianglunwei@imech.ac.cn
Gan Ding
（丁淦）     硕士生     新型材料力学性能     1750233490@qq.com
Jin Meng
（孟锦）     硕士生     新型材料力学性能     mengjin@lnm.imech.ac.cn
Yong Lei
（雷勇）     硕士生     新型材料力学性能     leiyong@lnm.imech.ac.cn
Jun Duan
（段军）     硕士生     新型材料力学性能     1965890981@qq.com

 

    Former members:

       Name
   

Status
   

Research interests
   

毕业去向
  Min Yan
(阎敏)     2005.06硕士毕业      冲击荷载下硬铝合金的加卸载响应     步步高（深圳）

 Ke Ai
(艾科)
    2007.06硕士毕业    

纳米压入下大块金属玻璃的Pile-up研究
     索尼爱立信（北京）

Si-yue Jiang
(江思跃)
    2007.12硕士毕业    

金属玻璃塑性变形的分子模拟
    安世亚太（北京）

Ji-xing Meng
(孟积兴)
    2008.06硕士毕业    

高速冲击下金属玻璃断裂特征
    the University of Rennes（法国）：攻读博士

Min-qiang Jiang
(蒋敏强)
    2009.06博士毕业    

非晶态合金的变形与断裂
    中科院力学所 非线性力学国家重点实验室（北京） 

Dong Kong
(孔冬)
    2009.06博士毕业     

软物质力学性能
    海信科龙（广东）

Liang Sun
(孙亮)
    2010.06硕士毕业    

非晶态合金流动的微观机理
    三一重工（长沙）
Yang Liu
(刘阳)     2011.06博士毕业    

块体非晶态合金激光冲击烧蚀行为
    山东烟台
Yan Chen
(陈艳)     2011.06博士毕业     

块体非晶态合金的断裂机理
    中科院力学所 非线性力学国家重点实验室（北京）
Bao-ming Huang
（黄宝明)     2011.06硕士毕业    

块体非晶态合金的多重剪切带行为
    史密斯钻头（北京）
Jie Yu
(余杰)     2011.06硕士毕业    

轮轨接触中的力学问题
    史密斯钻头（北京）
Xin Huang
（黄鑫）     2012.06博士毕业     非晶合金冲击动力学行为     中国工程物理研究院（四川绵阳）
Xiu Wei
（魏秀）     2013.09博士后出站     非晶合金泡沫材料的制备及力学性能     中国科学院院士工作局（北京）
Wen Qin
（覃文）     2014.09硕士毕业     金属高速切削力学行为     肯尼亚
Wei-Wei Yang
(杨薇薇)     2013硕士毕业（联合培养）     金属高速切削力学行为      
Juan Zheng
(郑娟)     2014硕士毕业（联合培养）     新型材料力学性能    
Jun-hong Chen
(陈军红)     2014.12博士毕业      非晶合金复合材料的制备与力学性能     中国工程物理研究院（四川绵阳）
Gui-gen Ye
(叶贵根)     2015.01 博士后出站      金属高速切削力学行为     中国石油大学
Yue Lan
(兰岳)    

2015.04 博士毕业
    水下爆炸载荷下结构的动力响应     四川理工学院机械工程学院
Fan Zeng
(曾繁)     2015.05 博士毕业     非晶合金的动态破坏     中物院高性能数值模拟软件中心
Songlin Cai
(蔡松林)     2015.05 博士毕业    

金属高速切削力学行为
      中国电力科学研究院
Xia Liu
(刘霞)     2015.06 博士毕业     动态断裂不稳定行为     北京航空航天大学  
Meng Zhang
(张猛）     2016博士后出站     非晶态材料力学性能     暨南大学
Qi Wang
(王祺)     2016博士毕业     金属高速切削力学行为     中国舰船研究设计中心
Zhijie Jiang
(姜智捷）      2017博士毕业     新型材料力学性能       
Liang Xiang
(向亮)     2017博士毕业     材料冲击动力学行为     中国工程物理研究院（四川绵阳）
Zhi-li Tian
(田智立)     2017博士毕业     非晶态合金微观力学行为     中国航天科工集团三院306所