学术活动

 

英文期刊论文(请见ResearcherID)

 

http://www.researcherid.com/rid/F-4455-2010 

专著:

S. N. Atluri and S. Shen, The Meshless Local Petrov-Galerkin (MLPG) Method. Tech Science Press, Los Angeles, 2002, 440 pages.
 

 期刊论文

  

1.        Pengfei Yu, Shuling Hu, and *S. Shen, Electrochemomechanics with flexoelectricity and modelling of electrochemical strain microscopy in mixed ionic-electronic conductors. Journal of Applied Physics, 120065102 (12 pages), 2016
2.        *Wenshan Yu, *S. Shen, Energetics of point defect interacting with grain boundaries undergone plastic deformations. Int. J. Plasticity, 2016 (In press)
        H. L. Wang, *S. Shen, A chemomechanical model for stress evolution and distribution in the viscoplastic oxide scale during oxidation.ASME J. Appl. Mech., ?: ? (? pages), 2016 (In press)
4.        R. Z. Zhang, X. Liang, *S. Shen, A Timoshenko dielectric beam model with flexoelectric effect. Meccanica, 2015 (In press)
5.        Wenyuan Liu, Wei Xia, *S. Shen, Fully coupling chemomechanical yield theory based on evolution equations. International Journal of Applied Mechanics, 8: 1650058 (12 pages), 2016
6.        *W.S. Yu, *S. Shen, Q. F. Liu, Point defect interacting with bi-crystal copper grain boundaries. Comput. Mater. Sci., 118: 47-55, 2016
        Jianfeng Lu, Jiangyan Lv, *Xu Liang, Minglong Xu, and *S. Shen, Improved approach to measure the direct flexoelectric coefficient of bulk PVDF. Journal of Applied Physics, 119094104 (6 pages), 2016
8.        X. Liang, W.J. Yang, S. L. Hu, *S. Shen, Buckling and vibration of flexoelectric nanofilms subjected to mechanical loads. Journal of Physics D: Applied Physics, 49: 115307(10pp), 2016
9.        Shuwen Zhang, *Minglong Xu, Kaiyuan Liu, S. Shen, A flexoelectricity effect-based sensor for direct torque measurement. Journal of Physics D: Applied Physics, 48: 485502, 2015
10.    Shuwen Zhang, Xu Liang, *Minglong Xu, Bo Feng, S. Shen, Shear flexoelectric response along 3121 direction in polyvinylidene fluoride. Appl. Phys. Lett., 107: 142902, 2015
    Y. H. Suo, *S. Shen, Coupling diffusion-reaction-mechanics model for oxidation. Acta Mech, 226: 3375-3386, 2015
12.    X. Liang, S. L. Hu, *S. Shen, Size-dependent buckling and vibration behaviors of piezoelectric nanostructures due to flexoelectricity. Smart Mater. Struct., 24: 105012(13 pages), 2015
    *Q. F. Liu, L. Wang, S. Shen, Effects of Geometry and Shape on the Mechanical Behaviors of Silicon Nanowires. CMC: Computers Materials & Continua, 46(2): 105-123, 2015
    Y. H. Suo, X. X. Yang, S. Shen, Residual stress analysis due to chemomechanical coupled effect, intrinsic strain and creep deformation during oxidation. Oxidation of Metals, 84: 413-427, 2015
    L. Wang, *Q. F. Liu, S. Shen, Effects of void-crack interaction and void distribution on crack propagation in single crystal silicon. Engineering Fracture Mechanics, 146: 56-66, 2015
    Shuwen Zhang, *Minglong Xu, Xu Liang, and S. Shen, Shear Flexoelectric coefficient μ1211 in Polyvinylidene Fluoride. Journal of Applied Physics, 117 205102 (5 pages), 2015
    W.J. Yang, X. Liang, *S. Shen, Electromechanical responses of piezoelectric nanoplates with flexoelectricity. Acta Mech, 226: 3097-3110, 2015
18.    Q. F. Liu, L. Wang, S. Shen, Effect of surface roughness on elastic limit of silicon nanowires. Comput. Mater. Sci.,101: 267-274, 2015
    H. L. Wang, Y. H. Suo, *S. Shen, Reaction-diffusion-stress coupling effect in inelastic oxide scale during oxidation. Oxidation of Metals, 83: 507-519, 2015
    X. Liang, S. L. Hu, *S. Shen, Surface effects on the post-buckling of piezoelectric nanowires. Physica E, 69: 61-64, 2015
    P. F. Yu, *S. Shen, A fully coupled theory and variational principle for thermal-electrical-chemical-mechanical processes. ASME J. Appl. Mech., 81: 111005 (12 pages), 2014
    S. S. Yang, *S. Shen, Anti-plane circular nano-inclusion problem with electric field gradient and strain gradient effects. CMC: Computers Materials & Continua, 40(3): 219-239, 2014
23.    X. Liang, S. L. Hu, *S. Shen, Effects of surface and flexoelectricity on the piezoelectric nanobeam. Smart Mater. Struct., 23: 035020 (8 pages), 2014
24.    X. Liang, S. L. Hu, *S. Shen, A new Bernoulli-Euler beam model based on a simplified strain gradient elasticity theory and its applications. Composite Structures, 111: 317-323, 2014
    C. C. Liu, S. L. Hu, *S. Shen, Effect of Flexoelectricity on Band Structures of One-Dimensional Phononic Crystals. ASME J. Appl. Mech., 81: 051007 (6 pages), 2014
26.    X. Wang, *S. Shen, Effects of temperature and strain on thermal properties of Ni/Al laminated structure. Comput. Mater. Sci., 84: 13-17, 2014.
    Y. H. Suo, *S. Shen, Analytical solution for 2D non-Fick transient mass transfer with arbitrary initial and periodic boundary conditions. ASME Journal of Heat Transfer, 135: 082001 (9 pages), 2013
    Y. H. Suo, *S. Shen, General approach on chemistry and stress coupling effects during oxidation. Journal of Applied Physics, 114: 164905 (6 pages), 2013
    S. L. Hu, *S. Shen, Non-equilibrium thermodynamics and variational principles for fully coupled thermal mechanical chemical processes, Acta Mech, 224: 2895-2910, 2013
30.    X. Liang, S. L. Hu, *S. Shen, Bernoulli-Euler dielectric beam model based on strain-gradient effect. ASME J. Appl. Mech., 80: 044502, 2013
    Ying Xu 91: 397-408, 2013

 

X. Liang, *S. Shen, Size-dependent piezoelectricity and elasticity due to the electric field-strain gradient coupling and strain gradient elasticity. International Journal of Applied Mechanics, 5: 1350015 (16 pages), 2013
   
33.    X. Liang, *S. Shen, Dynamic analysis of Bernoulli-Euler piezoelectric nanobeam with electrostatic force. SCIENCE CHINA Physics, Mechanics & Astronomy, 56: 1930-1937, 2013
    Y. H. Suo, *S. Shen, Analytical solution for one-dimensional coupled non-Fick diffusion and mechanics. Archive of Applied Mechanics, 83: 397-411, 2013
35.    Q. F. Liu, *S. Shen, Interaction of Voids and Nano-ductility in Single Crystal Silicon. Comput. Mater. Sci., 67: 123-132, 2013.
    S. S. Yang, S. L. Hu, *S. Shen, Local electroelastic field and effective electroelastic moduli of piezoelectric nanocomposites with interface effect. CMC: Computers Materials & Continua, 29(3): 279-298, 2012
37.    Q. F. Liu, *S. Shen, On the large-strain plasticity of silicon nanowires: Effects of axial orientation and surface. Int. J. Plasticity, 38: 146-158, 2012
38.    C. C. Liu, S. L. Hu, *S. Shen, Effect of flexoelectricity on electrostatic potential in a bent piezoelectric nanowire. Smart Mater. Struct., 21: 115024 (9pp), 2012
39.    X. Liang, *S. Shen, Effect of electrostatic force on a piezoelectric nanobeam. Smart Mater. Struct., 21: 015001 (6pp), 2012
    Y. H. Suo, *S. Shen, Dynamical theoretical model and variational principles for coupled temperature–diffusion–mechanics. Acta Mech, 223: 29-41, 2012
    Y. Xu, *S. Shen, Surface electric Gibbs free energy and its effect on the electromechanical behavior of nano-dielectrics. CMC: Computers Materials & Continua, 28: 81-95, 2012
    X. H. Wu, Z.J. Chang, Y.L. Lu, W.Q. Tao, S. Shen, An analysis of the convection-diffusion problems using meshless and meshbased methods.Engineering Analysis with Boundary Elements, 36: 1040-1048, 2012
43.    X. H. Wu, Z.J. Chang, W.Q. Tao, Z.Y. Li, S. Shen, MLPG method for convection-dominated flow problems. Progress in computational fluid dynamics, 12: 27-26, 2012
44.    H. B. Li, *S. Shen, The mechanical properties of bamboo and vascular bundles. J. Mater. Res., 26: 2749-2756, 2011 (封面文章)
45.    Y. Zhang, *S. Shen, Influences of surface on the interaction between holes or edge. Archive of Applied Mechanics, 81: 385–395, 2011.
46.    H. B. Li, *S. Shen, Experimental Investigation on Mechanical Behavior of Moso Bamboo Vascular Bundles. Key Engineering Materials, 462-463: 744-749, 2011.
47.    *S. Shen, S. Hu, A theory of flexoelectricity with surface effect for elastic dielectrics. Journal of the Mechanics and Physics of Solids, 58: 665-677, 2010
48.    W. S. Yu, *S. Shen, Multiscale study on the tensile fracture of Al-terminated Cu(111)/ a-Al2O3(0001) interface. Comput. Mater. Sci., 48: 228-240, 2010.
    W. S. Yu, *S. Shen, Initial dislocation topologies of nanoindentation into copper (0 0 1) film with a nanocavity. Engineering Fracture Mechanics, 77: 3329-3340, 2010
    Q. F. Liu, *S. Shen, Effects of Surface Orientation and Temperature on Tensile Deformation of Gold Nanowires. CMC: Computers Materials & Continua, 17: 59-75, 2010
    T. T. Hu, *S. Shen, Effects of TGO Roughness on Indentation Response of Thermal Barrier Coatings. CMC: Computers Materials & Continua, 17: 41-57, 2010
    S. Hu, *S. Shen, Variational principles and governing equations in nano-dielectrics with the flexoelectric effect. SCIENCE CHINA Physics, Mechanics & Astronomy, 53: 1497-1504, 2010.
53.    X. H. Wu, W. Q. Tao, S. Shen, X. W. Zhu, A stabilized MLPG method for steady state incompressible fluid flow simulation. J. Comput. Phys., 229: 8564-8577, 2010
54.    W. S. Yu, *S. Shen, Effects of small indenter size and its position on incipient yield loading during nanoindentation. Mater. Sci. Eng. A, 526: 211-218, 2009
    S. Hu, *S. Shen, Electric field gradient theory with surface effect for nano-dielectrics. CMC: Computers, Materials, & Continua, 13: 63-87, 2009.
56.    W. S. Yu, *S. Shen, Multiscale analysis of the effects of nanocavity on nanoindentation. Comput. Mater. Sci., 46: 425-430, 2009
57.    Y. Zhang, *S. Shen, A modified multiscale model for microcantilever sensor. CMC: Computers, Materials, & Continua. 8(1): 17-22, 2008
58.    S. Hu, *S. Shen, Analysis of the interaction between two nanovoids using bipolar coordinates. CMES: Comput. Model. Engng. Sci., 30(2): 57-64, 2008
59.    S. Hu, *S. Shen, T. Nishioka, Numerical analysis for a crack in piezoelectric material under impact. Int. J. Solids Structures, 44: 8457-8492, 2007
60.    X.H. Wu, S. Shen, *W. Tao, Meshless local Petrov-Galerkin collocation method for two-dimensional heat conduction problems. CMES: Comput. Model. Engng. Sci., 22: 65-76, 2007
61.    *S. Shen, and S. N. Atluri, An analytical model for shot-peening induced residual stresses. CMC: Computers, Materials, & Continuua62.    S. N. Atluri, and*S. Shen, Simulation of a 4th order ODE: Illustration of various MLPG methods. 7(3): 241-268, 2005
63.    *S. Shen and S. N. Atluri, A tangent stiffness MLPG method for atom/continuum multiscale simulation. 7(1): 49-67, 2005
64.    *S. N. Atluri and S. Shen, The basis of meshless domain discretization: the meshless local Petrov Galerkin (MLPG) method. Advances in Computational Mathematics, 23(1-2): 73-93, 2005
65.    *S. Shen, and S. N. Atluri, Multiscale simulation based on the meshless local Petrov-Galerkin (MLPG) method. CMES: Computer Modeling in Engineering & Sciences, 5(3): 235-255, 2004  
66.    *S. Shen, and S. N. Atluri, Atomic-level stress calculation and continuum-molecular system equivalence. 6(1): 91-104, 2004, 4
67.    *S. Shen, and S. N. Atluri, Computational nano-mechanics and multiscale simulation. CMC: Computers, Materials, & Continuua68.    *S. Shen and T. Nishioka, (69.    Q. Li, *S. Shen, Z. D. Han, and S. N. Atluri, Application of Meshless Local Petrov-Galerkin (MLPG) to Problems with Singularities, and Material Discontinuities, in 3-D Elasticity. CMES: Computer Modeling in Engineering & Sciences, 4(5): 567-581, 2003
70.    *T. Nishioka, S. Shen and J. H. Yu, Dynamic J integral for dynamic interfacial cracks in piezoelectric bimaterials: formulation, material separation and component separation method. International Journal of Fracture, 122(3-4): 101-130, 2003
71.    *CMES: Computer Modeling in Engineering & Sciences(72.    , Analysis of materials with strain gradient effects: a meshless local Petrov-Galerkin approach, with nodal displacements only. (2003):74.    T. Nishioka and *S. Shen, Higher order asymptotic solution for an interfacial crack in piezoelectric bimaterial under impact. Materials of Science Research International, 7(3): 157-165, 200
      .*S. Shen and T. Nishioka, Fracture of piezoelectric materials: energy density criterion. Theoretical and Applied Fracture Mechanics, ): 78.    *S. Shen, Z. B. Kuang and T. Nishioka, Dynamics mode-III interfacial crack in nonlinear 11(4): 211-222, 2000
75.      *S. Shen and T. Nishioka, A unified method for subsonic and intersonic crack growth along an anisotropic bimaterial interface. Journal of the Mechanics and Physics of Solids, ): 76.    *S. Shen, T. Nishioka, Z. B. Kuang and Z. X. Liu, Nonlinear electromechanical interfacial fracture for piezoelectric ceramics. Mechanics of Materials, 32(77.
79.    *S. Shen and T. Nishioka, Crack propagation piezoelectric bimaterial. Theoretical and Applied Fracture Mechanics): 80.    *S. Shen, Z. B. Kuang and T. Nishioka, Wave scattering from an interface crack in a laminated piezoelectric plate. Eur.  J. Mechanics A/Solids, ): 81.    *S. Shen, Z. B. Kuang and T. Nishioka, A phenomenological model for ferroelectric fatigue. Int. J. Appl. Electromagnetics and Mechanics, ):
82.    *S. Shen, T. Nishioka and Z. B. Kuang, Impact interfacial fracture for piezoelectric ceramic. Mechanics Research Communications, 26(3): 347-352, 1999
83.    *S. Shen and Z. B. Kuang, An alternative expression of piezoelectric representation and its application in inclusion problem. Int. J. Appl. Electromagnetics and Mechanics, 10(4): 279-292, 1999
84.    *S. Shen, Z. B. Kuang and S. Hu, On interface crack in laminated anisotropic medium. Int. J. Solids Structures, 36(28): 4251-4268, 1999
85.    *S. Shen, Z. B. Kuang and S. Hu, Interface crack problems of a piezoelectric laminated plate. Eur. J. Mechanics A/Solids, 18: 219-238, 1999
86.    *S. Shen and Z. B. Kuang, An active control model of laminated piezothermoelastic plate. Int. J. Solids Structures, 36(13): 1925-1947, 1999
87.    *S. Shen and Z. B. Kuang, Wave scattering from an interface crack in laminated anisotropic media. Mechanics Research Communications, 25(5): 509-517, 1998
88.    *S. Shen, Z. B. Kuang and S. Hu, Wave propagation in multilayered anisotropic media. Mechanics Research Communications, 25(5): 503-507, 1998
89.    *S. Shenand Z. B. Kuang, Interface crack in bi-piezothermoelastic media and the interaction with a point heat source. Int. J. Solids Structures, 35(30): 3899-3915, 1998  
90.    X. X. Yang, S. Shen and *Z. B. Kuang, A general solution for piezothermoelastic materials. Eur. J. Mechanics A/Solids, 16(5): 779-793, 1997
91.    S. Shen and *Z. B. Kuang, Interface crack in bi-piezothermoelastic media. Acta Mechanica Solida Sinica, 9(1): 13-26, 1996
 
中文期刊论文
92.    申胜平,傅祥炯, “三维疲劳裂纹闭合模型”, 固体力学学报, Vol.16, 特刊, 1995
93.    申胜平, 王旭,匡震邦,“热释电材料断裂力学”,固体力学学报, Vol.16, No.4, pp.283-293, 1995
94.    杨晓翔, 申胜平,匡震邦,“热释电材料的通解”, 复合材料学报, Vol.13, No.4, pp.95-101, 1996
95.    胡淑玲, 申胜平*,具有挠曲电效应的纳米电介质变分原理及控制方程,中国科学G3912):1762-17692009
96.    吴学红,李增耀,申胜平,陶文铨,不规则区域热传导问题无网格PetrovGalerkin方法的数值模拟,工程热物理学报308):1350-13522009
97.    吴学红,朱兴旺,申胜平,陶文铨,对流项占优问题的MLPG/SUPG方法数值模拟,计算力学学报, 28(4): 574-5782011
98.    王鑫, 鲁丹,申胜平*Ni/Al层合结构热传导性能的非平衡分子动力学研究,中国科学: 物理学力学天文学44(3): 1-8, 2014
 

发明专利

 

1.        李斯,梁旭,张舒文,申胜平*,徐明龙,一种基于测量电荷的挠曲电系数直接测量装置及方法,专利号:ZL 2014 1 0114668.9, 2015415
2.        李斯,梁旭,申胜平*,徐明龙,一种高精度基于金属弹性元件的挠曲电式压力传感器,专利号:ZL 201310656546.8, 2015826
3.        李斯,梁旭,申胜平*,徐明龙,一种基于微机电系统的挠曲电式微压力传感器,专利号:ZL 201310655468.X, 2015826
4.        卢建锋,梁旭,胡淑玲,申胜平*,徐明龙,一种高灵敏度叠层式挠曲电压力传感器,专利号:ZL 201410290568.1, 201585
科研项目
项目编号 项目名称 项目来源 起讫时间 承担角色 项目类别
11632014 高温富氧环境下金属陶瓷复合涂层力热化学耦合效应及破坏机理 国家自然科学基金项目2017-1~负责人纵向项目
11025209 固体力学 国家自然科学基金项目2011-1~负责人纵向项目
11021202 轻质非均匀介质的力学行为 国家自然科学基金项目2011-1~骨干成员纵向项目
10672130 热障涂层失效机理的跨尺度研究 国家自然科学基金项目2007-1~2009-12负责人纵向项目
10972173 具有挠曲电效应的纳米电介质的力电行为及缺陷分析 国家自然科学基金项目2010-1~负责人纵向项目
11321062 轻质非均匀介质的力学行为 国家自然科学基金项目2014-1~骨干成员纵向项目
11072184 纳米压电半导体材料和器件的力电耦合行为研究 国家自然科学基金项目2011-1~骨干成员纵向项目
NCET-05-0827 无网格法及其在纳米力学中的应用 国家教育部项目2006-1~2008-12负责人纵向项目
留学回国人员科研启动基金 多尺度方法研究 国家教育部项目2007-1~2009-1负责人纵向项目
西安交大腾飞人才项目 无网格法及多尺度方法 国家教育部项目2005-8~2008-7负责人纵向项目
教育部科技重大项目 膜基系统冲击破坏机理研究 国家教育部项目2009-1~2011-12骨干成员纵向项目
2013 863项目 “863”高科技项目2014-7~负责人纵向项目
2014 863项目 “863”高科技项目2015-7~负责人纵向项目
2015 863项目 “863”高科技项目2016-7~负责人纵向项目
2010 863项目 “863”高科技项目2010-4~负责人纵向项目
2008 863项目 “863”高科技项目2008-4~2009-3负责人纵向项目
2009 863项目 “863”高科技项目2009-4~2010-3负责人纵向项目
2012 863项目 “863”高科技项目2013-7~负责人纵向项目
2011 863项目 “863”高科技项目2011-11~负责人纵向项目
2007CB707700 大型动力装备制造基础研究 973项目2007-5~2011-8骨干成员纵向项目
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研究队伍

申胜平:教授,博士生导师.

团队成员:邓谦(副教授),郁汶山(副教授),夏巍(讲师),梁旭(副教授)
 

在读研究生

 博士生:

卢建锋,挠曲电性能的实验研究

王亮,高温材料的分子动力学分析

王海龙,高温陶瓷力-化学反应耦合问题

吁鹏飞,电化学显微镜力-电-化学反应耦合理论

胡涛涛,动态挠曲电效应及器件设计

李大涛,高超声速飞行器隔热瓦高温力学性能分析

吴连平,材料失效机理分子动力学分析

杨文君,考虑挠曲电效应的波传播及传感器设计

陈建勇,力-化学反应耦合问题的数值方法及大变形问题

邓锋,挠曲电数值分析

刘文源,力电化学耦合非线性理论及功能设计

 

 硕士生:

赵东伟,高超速飞机环境载荷分析

赵兴红,高超速飞机环境载荷分析软件

张功喜,功能结构设计

文馨,俘能器设计


已毕业研究生

 

博士:

郁汶山,刘群峰,李红波,锁要红,梁旭,杨莎莎,王海龙,吁鹏飞,李大涛,卢建锋,胡涛涛

 

硕士:

刘广东,张   岩,胡涛涛,陈   蓉,秦思韡,徐   莹,王   鑫,李   麟,刘晨晨,车   睿,李斯,袁振沪,吕江彦、张润芝、隋文姝,赵东伟