大连理工大学导师：徐天星

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大连理工大学导师：徐天星正文

[导师姓名]
徐天星

[所属院校]
大连理工大学

[基本信息]
导师姓名：徐天星
性别：男
人气指数：705
所属院校：大连理工大学
所属院系：
职称：工程师
导师类型：
招生专业：

[通讯方式]
电子邮件：biandian@dlut.edu.cn,xtx@dlut.edu.cn

[个人简述]
1978年至1993年间续在北京大学学习，获学士学位，硕士学位和博士学位。1993年在大连理工大学做博士后研究工作。在1995年8月出站前夕破格直接晋升为教授，并任工程力学研究所副所长。担任多个高校的客座教授和科学院研究所的客座研究员。
曾任国家211立项专家组成员；国家博士点基金评审专家组成员；教育部高校科技奖评审专家组成员；国家博士点、硕士点及重点学科评审专家；省力学学会流体力学专业委员会主任。曾获得香港CroucherFoundation；中国“国氏”博士后奖励基金（中国优秀博士后，1/10）；“全国优秀博士后人员”称号。承担国家级研究项目十余项，发表学术论文二百余篇，此外专著，专利和软件著作权多项。
以培养多名国际联合培养研究生，并作为大连理工大学和香港城市大学博士研究生联合培养的联络人。
研究领域涉及新的科学理论，数值方法和计算方法，实验方法，工程应用等。主要研究成果包括：
1、现代力学工具和方法研究
完善现代力学先进的工具，即哈密顿体系。利用对偶的观点描述基本问题，将哈密顿体系方法推广到更广泛的领域。并建立系列的数值计算方法。该方法已经在工程中得到了应用。
2、结构稳定性和动力屈曲
建立结构稳定性和动力屈曲问题的控制方程。计算和分析梁板壳等典型工程结构的稳定性，临界载荷，屈曲模态和后屈曲发展路径等。为结构的轻型化及发展和应用提供依据。
3、断裂力学中的辛方法
在弹性断裂问题中，采用辛体系方法，将问题归结为辛本征值和辛本征解问题。这样，表征断裂的标志量应力强度因子（J积分或能量释放率）可直接解析表示出来。从而进一步构造奇异元，克服了有限元计算软件中网格和路径依赖。该方法已经应用于核主泵工程中。
4、辛离散有限元算法
借助于辛体系中的辛本征解，构造出一种辛离散有限元算法。该方法的特点在于，将有限元中的节点位移由辛本征解系数代替，从而在保证精度的前提下减少计算量并可以与有限元软件兼容。
5、纳米表面技术与吸能结构和装置的优化设计与研发
首次提出将纳米表面技术应用于吸能结构和装置。利用纳米表面技术诱导薄壁结构的屈曲模态，提高该结构的吸能效果，降低最大冲击载荷。提出一种新的吸能结构和装置设计原理与研发技术。该技术特别在汽车工业中有重要的应用。
6、纳米表面化结构抗屈曲设计技术
借助于局部纳米表面技术，采用优化设计的方法对整体结构局部表面纳米化，通过局部表面纳米化布局改变材料和结构的力学性能的分布，从而提高结构的抗屈曲能力。该技术可应用于航空飞行器及火箭等方面设计和工艺。
7、纳米表面化结构抗疲劳和断裂优化设计
通过优化设计的方法对整体结构局部表面纳米化布局设计。通过特殊的局部表面纳米化图案布局改变结构的应力和应变分布，以增强结构的抗疲劳和抗断裂特性。此技术在轻型结构的应用中有非常大的空间。
8、深海石油管道失稳问题的可靠性分析
研究了深海石油管道失稳的主要因素和机理。采用蒙特卡洛随机抽样的方法和响应面的方法对样本进行处理，通过数值计算完成可靠性分析。研究方法为类似问题提供一条解决途径。
9、微纳米结构的动力学分析
采用非局部理论和哈密顿体系，建立一种描述微纳米结构动力学控制方程。研究和分析了碳纳米管和石墨烯等结构的动力学特性，发现了一些新的现象。为微纳米结构的应用提供了依据。
10、光纤识别裂纹和结构健康测试技术
采用先进的光纤信息技术，建立识别结构裂纹和缺陷测试方法以及结构健康监测技术。其原理是通过光纤反映的结构应变场信息和结构应变场分析数据，得到结构裂纹和缺陷的准确信息。并编制具有自主版权的分析软件。
11、表面纳米化仿生材料优化设计技术
分析贝壳材料结构功能和机理，并通过局部表面纳米化布局实现仿贝壳材料结构的功能，采用优化设计的方法设计出最优的局部表面纳米化布局图案和仿生材料结构。这种结构具有优良的抗疲劳和抗断裂功能，也为有广泛应用的仿生材料的设计提供一种新的方法和技术。
发表主要学术论文
[1].WangMZ,XuXS,AgeneralizationofAlmansi'stheoremanditsapplication,Appl.Math.Modelling,1990,14(5):275-279
[2].XuXS,WangMZ,1991,GeneralcompletesolutionsoftheequationsofspatialandaxisymmetricStokesflow,Q.JI.Mech.Appl.Math.,1991,44(4):537-548
[3].XuXS,WangMZ,OnthecompletenessofsolutionsofthegeneralizedaxisymmetricStokesflowequations,ActaMathematicaScientia,1993,13(4):222-228
[4].XuXS,SuXY,YuTX,Thepropagationoflongitudinalwaveinrate-dependentplasticsofteningmaterial,SinenceinChina(Ser.A),1994,37(4):450-458
[5].WangW,XuXS,WangMZ,Completenessofgeneralsolutionstoaxisymmetricproblemsoftransverelyisotropicbody,SinenceinChina(Ser.A),1994,37(5):580-596
[6].XuXS,SuXY,WangR,Dynamicbucklingofelastic-plasticcylindricalshellsonaxialstresswaves,SinenceinChina(Ser.A),1995,38(4):472-479
[7].XuXS,ZhongWX,LuYL,StudyofnonlinearlongwaveapproximationinuniformchannelsviaHamiltonianstructure,J.Hydrodynamics,(Ser.B),1995,7(1):66-76
[8]Zhong,WX,XuXS,ZhangHW,HamiltonsystemandtheSaint-Venantprobleminelasticity,Appl.Math.Mech.,1996,17(9):827-836
[9]XuXS,ZhongWX,ZhangHW,TheSaint-Venantproblemandprincipleinelasticity,Int.J.SolidsStructures,1997,34(22):2815-2827
[10]XuXS,XuJY,LiuST,LiuKX,Dynamicaxisymmetricandnon-axisymmetricbucklingoffinitecylindricalshellsinpropagtingangreflectingofaxialstresswaves,J.PhysivFrance,1997,7,C3-617-C3-622
[11]XuXS,YuTX,SuXY,Propagationofwaveinrate-dependentplasticsofteningrodandbeam,J.EngineeringMechanics,1997,123(3):190-195
[12]XuXS,GuoXL,Atheoreticalandexperimentalstudyonthenonlinearshallowwaterwaveincontainers,J.ExperimentalMechanics,2002,16(3):298-304
[13]XuXS,GuoXL,AmethodofHamiltonianformulationforelasticstructuralvibrationinrotatingsystem,J.VibrationEngineering,2003,16(1):36-40
[14]GuQ,XuXS,LeungAYT,TheapplicationofHamiltoniansystemfortwo-dimensionaltransverselyisotropicpiezoelectricmedia.JournalofZhejiangUniversity,Science.2005,6(9):915-921
[15]XuXS,GuQ,LeungAYT,ZhenJJ,Asymplecticeigensolutionmethodintransverselyisotropicpiezoelectriccylindricalmedia.JournalofZhejiangUniversity,Science.2005,6(9):922-927
[16]WangGP,XuXS,Stokesflowinlid-drivencavitiesviaHamiltoniansystem,JournalofJilinUniversity(EngineeringandTechnologyEdition),2006,36:102-106
[17]XuXS,ZhangWX,LiX,Anapplicationofthesymplecticsystemintwo-dimensionalviscoelasticity,InternationalJournalofEngineeringScience,2006,44:897–914
[18]XuXS,MaY,LimCW,ChuHJDynamicbucklingofcylindricalshellssubjecttoanaxialimpactinasymplecticsystem.InternationalJournalofSolidsandStructures,200643:3905–3919
[19]LeungAYT,XuXS.Theboundarylayerphenomenaintwo-dimensionaltransverselyisotropicpiezoelectricmediabyexactsymplecticexpansion,Int.J.Numer.Meth.Engng2007;69:2381–2408
[20]XuXS,DuanZ,MaY,ChuHJ.Asymplecticmethodanddynamicbucklingofelasticcylindricalshellsunderbothaxialimpactandinternalorexternalpressure,Explosionandshockwaves,2007,27(6):509-514
[21]XuXS,WangGP,SunFM.AanalyticalandnumericalmethodofsymplecticsystemforStokesflowinthetwo-dimensionalrectangulardomain.AppliedMathematicsandMechanics,2008,29(6):715-724
[22]XuXS,LeungAYT,GuQ,3Dsymplecticexpansionforpiezoelectricmedia，InternationalJournalforNumericalMethodsinEngineering,2008,74:1848–1871
[23]XuXS,ChuHJ,LimCW.Hamiltoniansystemfordynamicbucklingoftransverselyisotropiccylindricalshellssubjecttoanaxialimpact.InternationalJournalofStructureandDynamics,2008,2(3):487-504
[24]SunFM,XuXS,TheControlMechanismofaNewFish-LikeUnderwaterRobotwithTwoTails,LectureNotesinComputerScience,2008,LNAI5314(1)304–313
[25]ZhangWX,XuXS,Hamiltoniansystemand2Dproblemofthermo-viscoelasticity.JournalofUniversityofScienceandTechnologyofChina,2008,38(2):200-206
[26]LeungAYT,XuXS,ZhouZH,WuYF,Analyticstressintensityfactorsforfiniteelasticdiscusingsymplecticexpansion.EngineeringFractureMechanics.2009;76(12):1866-1882
[27]XuXS,MaJQ,LimCW,ChuHJ.Dynamiclocalandglobalbucklingofcylindricalshellsunderaxialimpact.EngineeringStructures,2009,31(5):1132-1140
[28]XuXS,ChuHJ,LimCW.AsymplecyicHamiltonianappoachforthermalbucklingofcylindricalshells.InternationalJournalofStructuralStabilityandDynamics,2010,10(2):273-286
[29]XuXS,ZhouZH,LeungAYT.Analyticalstressintensityfactorsforedge-crackedcylinder.InternationalJournalofMechanicalSciences,2010,52:892–903
[30]XuXS,MaJQ,LimCW,ZhangG.Dynamictorsionalbucklingofcylindricalshells.ComputersandStructures,2010,88:322–330
[31]LeungAYT,XuXS,ZhouZH.Hamiltonianapproachtoanalyticalthermalstressintensityfactors—Part1:thermalintensityfactor.JournalofThermalStresses,2010,33:262–278
[32]LeungAYT,XuXS,ZhouZH.Hamiltonianapproachtoanalyticalthermalstressintensityfactors—Paret2:thermalstressintensityfactor.JournalofThermalStresses,2010,33:279–301
[33]ZhouZH,XuXS,LeungAYT.ModeIIIedge-crackinmagneto-electro-elasticmediabysymplecticexpansion.EngineeringFractureMechanics,2010,77:3157–3173
[34]ZhangWX,XuXS,YuanF.Thesymplecticsystemmethodinthestressanalysisof2Delasto-viscoelasticfiberreinforcedcomposites.ArchApplMech,2010,80:829-841
[35]ZhouZH,WongKW,XuXS,LeungAYT.NaturalvibrationofcircularandannularthinplatesbyHamiltonianapproach.JournalofSoundandVibration,2010,330:1005–1017
[36]SunFM,BianYN,ArimaH,IkegamiY,XuXS.Strengthcharacteristicsoftheself-sustainedwaveingroovedchannelswithdifferentgroovelength.HeatMassTransfer,2010,46:1229–1237
[37]LimCW,XuXS.SymplecticElasticity:TheoryandApplications.AppliedMechanicsReviews.2010,63/050802-1-050802-10
[38]ZhouZH,XuXSandLeungAYT.AnalyticalModeIIIelectromagneticpermeablecracksinmagnetoelectroelasticmaterials.Computers&Structures,2011,89:631-645
[39]ZhouZH,XuXS,LeungAYT.TransientthermalstressintensityfactorsforModeIedge-cracks.NuclearEngineeringandDesign.2011,241:3613-3623
[40]XuXS,ZhangG,ZengQC,ChuHJ,BambooNode-TypeLocalBucklingofCylindricalShellsUnderAxialImpact.AdvancesinVibrationEngineering,2011,10(1):41-52
[41]ZhouZH,WongKW,XuXS,LeungAYT.NaturalvibrationofcircularandannularthinplatesbyHamiltonianapproach.JournalofSoundandVibration.2011,330(5):1005-1017
[42]SunJB,XuXS,LimCW.DynamicBucklingofCylindricalshellsunderAxialImpactinHamiltonianSystem.Int.J.NonlinearSci.Numer.Simul,2012(13):93-97.
[43]ZhangWX,XuXS,Thesymplecticapproachfortwo-dimensionalthermo-viscoelasticanalysis,InternationalJournalofEngineeringScience2012,50:56-69
[44]WuYF,XuXS,SunJB,JiangC.Analyticalsolutionforthebondstrengthofexternallybondedreinforcement.CompositeStructures.2012,94:3232-3239
[45]DongJZ,XuXS,ZhangY.NonlinearWavesDrivenbyMotionalPlatesinShallowTwo-LayerFluid.AdvncesinVibrationEngineering,2012,11(4):389-402
[46]XuXS,SunJB,LimCW,DynamictorsionalbucklingofcylindricalshellsinHamiltoniansystem,Thin-WalledStructures64(2013)23-30
[47]SunJB,XuXS,LimCW,TanVBC.Anenergyconservativesymplecticmethodologyforbucklingofcylindricalshellsunderaxialcompression,ActaMech,224(2013),1579-1592
[48]SunJB,XuXS,LimCW.Localizationofdynamicbucklingpatternsofcylindricalshellsunderaxialimpact,InternationalJournalofMechanicalSciences66(2013)101-108
[49]ZhouZH,XuXS,LeungAYT,HuangY.StressintensityfactorsandT-stressforanedgeinterfacecrackbysymplecticexpansion.EngineeringFractureMechanics102(2013)334-347
[50]SunJB,XuXS,LimCW.Accuratesymplecticspacesolutionsforthermalbucklingoffunctionallygradedcylindricalshells.Composites:PartB55(2013)208-214
[51]SunJB,XuXS,LimCW.Torsionalbucklingoffunctionallygradedcylindricalshellswithtemperature-dependentproperties.InternationalJournalofStructuralStabilityandDynamics,2014,14(1):1350048-1–23.
[52]ZhouZH,XuXS,LeungAYT.Thefiniteelementdiscretizedsymplecticmethodforinterfacecracks,CompositesPartB,2014,58:335–342.
[53]SunJB,XuXS,LimCW.Bucklingoffunctionallygradedcylindricalshellsundercombinedthermalandcompressiveloads.JournalofThermalStresses,2014,37:340-362
[54]SunJB,XuXS,LimCW.BucklingofcylindricalshellsunderexternalpressureinaHamiltoniansystem.JournalofTheoreticalandAppliedMechanics.2014,52(3):641-653
[55]LeungAYT,ZhouZH,XuXS,Determinationofstressintensityfactorsbythefiniteelementdiscretizedsymplecticmethod,InternationalJournalofSolidsandStructures,2014,51,1115-1122.
[56]ZhouZH,AYTLeung,XuXS,LuoXW,Mixed-modethermalstressintensityfactorsfromthefiniteelementdiscretizedsymplecticmethod,InternationalJournalofSolidsandStructures,2014,51(21):3798-3806.
[57]XuCH,ZhouZH,XuXS,LeungAYT,FractureanalysisofmodeIIIcrackproblemsforthepiezoelectricbimorph,ArchiveofAppliedMechanics,2014,84(7),1057-1079.
[58]JiabinSun,XinshengXu,C.W.Lim,WeiyuQiao.AccuratebucklinganalysisforsheardeformableFGMcylindricalshellsunderaxialcompressionandthermalloads.CompositeStructures,2015,123:246-256
[59]XuXS,ChengXH,ZhouZH,XuCH,Ananalyticalapproachforthemixed-modecrackinlinearviscoelasticmedia,EuropeanJournalofMechanicsA/Solids,2015,52:12-25
[60]XuCH,ZhouZH,XuXS,Electroelasticsingularitiesandintensityfactorsforaninterfacecrackinpiezoelectric-elasticbimaterials,AppliedMathematicalModelling.2015,39:2721-2739
[61]ZhouZH,XuCH,XuXS,LeungAYT,Thefiniteelementdiscretizedsymplecticmethodforthesteady-stateheatconductionwithsingularitiesincompositestructures,NumericalHeatTransfer,PartB:Fundamentals.2015,67:302-319
[62]XuCH,ZhouZH,LeungAYT,XuXS,LuoXW.ThefiniteelementdiscretizedsymplecticmethodforcompositemodeIIIcracks.EngineeringFractureMechanics.2015,140:43-60
[63]XuCH,ZhouZH,XuXS,EvaluationofmodeIIIinterfacecracksinmagnetoelectroelasticbimaterialsbysymplecticexpansion,Journalofintelligentmaterialsystemsandstructures,2015,26(11):1417-1441
[64]SunJB,LimCW,XuXS,MaoH.Accuratebucklingsolutionsofgrid-stiffenedfunctionallygradedcylindricalshellsundercompressiveandthermalloads.CompositesPartB,2016,89:96-107
[65]SunJB,LimCW,ZhouZH,XuXS,SunW.Rigorousbucklinganalysisofsize-dependentfunctionallygradedcylindricalnanoshells,JournalofAppliedPhysics,119,214303(2016)
[66]SunJB,XuXS,LimCW,ZhouZH,XiaoSY,Accuratethermo-electro-mechanicalbucklingofsheardeformablepiezoelectricfiber-reinforcedcompositecylindricalshells,CompositeStruct.,141,221-231,2016.
[67]QiuWB,ZhouZH,XuXS,Thedynamicbehaviorofcircularplatesunderimpactloads,JournalofVibrationEngineeringandTechnologies,2016,4(2):111-116
[68]SunJB,XuXS,LimCW,Combinedloadbucklingforcylindricalshellsbasedonasymplecticelasticityapproach,JournalofTheoreticalandAppliedMechanics,2016,54(3):705-716
[69]XuW,TongZZ,LeungAYT,XuXS,ZhouZH,EvaluationofthestresssingularityofaninterfaceV-notchinabimaterialplateunderbending,EngineeringFractureMechanics,2016,168:11-25
[70]HuJL,XuXS.Fast-startcontrolofbionicfishusinggiantmagnetostrictivematerials.JournalofVibrationEngineering&Technologies,2017,5(2):207-211
[71]XuXS,TongZZ,RongDL,ChengXH,XuCH,ZhouZH.Fractureanalysisofmagnetoelectroelasticbimaterialswithimperfectinterfacesbysymplecticexpansion,AppliedMathematicsandMechanics,2017,38(8):1043-1058.

[科研工作]
研究领域涉及新的科学理论，数值方法和计算方法，实验方法，工程应用等。主要研究成果包括：
1、现代力学工具和方法研究
完善现代力学先进的工具，即哈密顿体系。利用对偶的观点描述基本问题，将哈密顿体系方法推广到更广泛的领域。并建立系列的数值计算方法。该方法已经在工程中得到了应用。
2、结构稳定性和动力屈曲
建立结构稳定性和动力屈曲问题的控制方程。计算和分析梁板壳等典型工程结构的稳定性，临界载荷，屈曲模态和后屈曲发展路径等。为结构的轻型化及发展和应用提供依据。
3、断裂力学中的辛方法
在弹性断裂问题中，采用辛体系方法，将问题归结为辛本征值和辛本征解问题。这样，表征断裂的标志量应力强度因子（J积分或能量释放率）可直接解析表示出来。从而进一步构造奇异元，克服了有限元计算软件中网格和路径依赖。该方法已经应用于核主泵工程中。
4、辛离散有限元算法
借助于辛体系中的辛本征解，构造出一种辛离散有限元算法。该方法的特点在于，将有限元中的节点位移由辛本征解系数代替，从而在保证精度的前提下减少计算量并可以与有限元软件兼容。
5、纳米表面技术与吸能结构和装置的优化设计与研发
首次提出将纳米表面技术应用于吸能结构和装置。利用纳米表面技术诱导薄壁结构的屈曲模态，提高该结构的吸能效果，降低最大冲击载荷。提出一种新的吸能结构和装置设计原理与研发技术。该技术特别在汽车工业中有重要的应用。
6、纳米表面化结构抗屈曲设计技术
借助于局部纳米表面技术，采用优化设计的方法对整体结构局部表面纳米化，通过局部表面纳米化布局改变材料和结构的力学性能的分布，从而提高结构的抗屈曲能力。该技术可应用于航空飞行器及火箭等方面设计和工艺。
7、纳米表面化结构抗疲劳和断裂优化设计
通过优化设计的方法对整体结构局部表面纳米化布局设计。通过特殊的局部表面纳米化图案布局改变结构的应力和应变分布，以增强结构的抗疲劳和抗断裂特性。此技术在轻型结构的应用中有非常大的空间。
8、深海石油管道失稳问题的可靠性分析
研究了深海石油管道失稳的主要因素和机理。采用蒙特卡洛随机抽样的方法和响应面的方法对样本进行处理，通过数值计算完成可靠性分析。研究方法为类似问题提供一条解决途径。
9、微纳米结构的动力学分析
采用非局部理论和哈密顿体系，建立一种描述微纳米结构动力学控制方程。研究和分析了碳纳米管和石墨烯等结构的动力学特性，发现了一些新的现象。为微纳米结构的应用提供了依据。
10、光纤识别裂纹和结构健康测试技术
采用先进的光纤信息技术，建立识别结构裂纹和缺陷测试方法以及结构健康监测技术。其原理是通过光纤反映的结构应变场信息和结构应变场分析数据，得到结构裂纹和缺陷的准确信息。并编制具有自主版权的分析软件。
11、表面纳米化仿生材料优化设计技术
分析贝壳材料结构功能和机理，并通过局部表面纳米化布局实现仿贝壳材料结构的功能，采用优化设计的方法设计出最优的局部表面纳米化布局图案和仿生材料结构。这种结构具有优良的抗疲劳和抗断裂功能，也为有广泛应用的仿生材料的设计提供一种新的方法和技术。
发表主要学术论文
[1].WangMZ,XuXS,AgeneralizationofAlmansi'stheoremanditsapplication,Appl.Math.Modelling,1990,14(5):275-279
[2].XuXS,WangMZ,1991,GeneralcompletesolutionsoftheequationsofspatialandaxisymmetricStokesflow,Q.JI.Mech.Appl.Math.,1991,44(4):537-548
[3].XuXS,WangMZ,OnthecompletenessofsolutionsofthegeneralizedaxisymmetricStokesflowequations,ActaMathematicaScientia,1993,13(4):222-228
[4].XuXS,SuXY,YuTX,Thepropagationoflongitudinalwaveinrate-dependentplasticsofteningmaterial,SinenceinChina(Ser.A),1994,37(4):450-458
[5].WangW,XuXS,WangMZ,Completenessofgeneralsolutionstoaxisymmetricproblemsoftransverelyisotropicbody,SinenceinChina(Ser.A),1994,37(5):580-596
[6].XuXS,SuXY,WangR,Dynamicbucklingofelastic-plasticcylindricalshellsonaxialstresswaves,SinenceinChina(Ser.A),1995,38(4):472-479
[7].XuXS,ZhongWX,LuYL,StudyofnonlinearlongwaveapproximationinuniformchannelsviaHamiltonianstructure,J.Hydrodynamics,(Ser.B),1995,7(1):66-76
[8]Zhong,WX,XuXS,ZhangHW,HamiltonsystemandtheSaint-Venantprobleminelasticity,Appl.Math.Mech.,1996,17(9):827-836
[9]XuXS,ZhongWX,ZhangHW,TheSaint-Venantproblemandprincipleinelasticity,Int.J.SolidsStructures,1997,34(22):2815-2827
[10]XuXS,XuJY,LiuST,LiuKX,Dynamicaxisymmetricandnon-axisymmetricbucklingoffinitecylindricalshellsinpropagtingangreflectingofaxialstresswaves,J.PhysivFrance,1997,7,C3-617-C3-622
[11]XuXS,YuTX,SuXY,Propagationofwaveinrate-dependentplasticsofteningrodandbeam,J.EngineeringMechanics,1997,123(3):190-195
[12]XuXS,GuoXL,Atheoreticalandexperimentalstudyonthenonlinearshallowwaterwaveincontainers,J.ExperimentalMechanics,2002,16(3):298-304
[13]XuXS,GuoXL,AmethodofHamiltonianformulationforelasticstructuralvibrationinrotatingsystem,J.VibrationEngineering,2003,16(1):36-40
[14]GuQ,XuXS,LeungAYT,TheapplicationofHamiltoniansystemfortwo-dimensionaltransverselyisotropicpiezoelectricmedia.JournalofZhejiangUniversity,Science.2005,6(9):915-921
[15]XuXS,GuQ,LeungAYT,ZhenJJ,Asymplecticeigensolutionmethodintransverselyisotropicpiezoelectriccylindricalmedia.JournalofZhejiangUniversity,Science.2005,6(9):922-927
[16]WangGP,XuXS,Stokesflowinlid-drivencavitiesviaHamiltoniansystem,JournalofJilinUniversity(EngineeringandTechnologyEdition),2006,36:102-106
[17]XuXS,ZhangWX,LiX,Anapplicationofthesymplecticsystemintwo-dimensionalviscoelasticity,InternationalJournalofEngineeringScience,2006,44:897–914
[18]XuXS,MaY,LimCW,ChuHJDynamicbucklingofcylindricalshellssubjecttoanaxialimpactinasymplecticsystem.InternationalJournalofSolidsandStructures,200643:3905–3919
[19]LeungAYT,XuXS.Theboundarylayerphenomenaintwo-dimensionaltransverselyisotropicpiezoelectricmediabyexactsymplecticexpansion,Int.J.Numer.Meth.Engng200769:2381–2408
[20]XuXS,DuanZ,MaY,ChuHJ.Asymplecticmethodanddynamicbucklingofelasticcylindricalshellsunderbothaxialimpactandinternalorexternalpressure,Explosionandshockwaves,2007,27(6):509-514
[21]XuXS,WangGP,SunFM.AanalyticalandnumericalmethodofsymplecticsystemforStokesflowinthetwo-dimensionalrectangulardomain.AppliedMathematicsandMechanics,2008,29(6):715-724
[22]XuXS,LeungAYT,GuQ,3Dsymplecticexpansionforpiezoelectricmedia，InternationalJournalforNumericalMethodsinEngineering,2008,74:1848–1871
[23]XuXS,ChuHJ,LimCW.Hamiltoniansystemfordynamicbucklingoftransverselyisotropiccylindricalshellssubjecttoanaxialimpact.InternationalJournalofStructureandDynamics,2008,2(3):487-504
[24]SunFM,XuXS,TheControlMechanismofaNewFish-LikeUnderwaterRobotwithTwoTails,LectureNotesinComputerScience,2008,LNAI5314(1)304–313
[25]ZhangWX,XuXS,Hamiltoniansystemand2Dproblemofthermo-viscoelasticity.JournalofUniversityofScienceandTechnologyofChina,2008,38(2):200-206
[26]LeungAYT,XuXS,ZhouZH,WuYF,Analyticstressintensityfactorsforfiniteelasticdiscusingsymplecticexpansion.EngineeringFractureMechanics.200976(12):1866-1882
[27]XuXS,MaJQ,LimCW,ChuHJ.Dynamiclocalandglobalbucklingofcylindricalshellsunderaxialimpact.EngineeringStructures,2009,31(5):1132-1140
[28]XuXS,ChuHJ,LimCW.AsymplecyicHamiltonianappoachforthermalbucklingofcylindricalshells.InternationalJournalofStructuralStabilityandDynamics,2010,10(2):273-286
[29]XuXS,ZhouZH,LeungAYT.Analyticalstressintensityfactorsforedge-crackedcylinder.InternationalJournalofMechanicalSciences,2010,52:892–903
[30]XuXS,MaJQ,LimCW,ZhangG.Dynamictorsionalbucklingofcylindricalshells.ComputersandStructures,2010,88:322–330
[31]LeungAYT,XuXS,ZhouZH.Hamiltonianapproachtoanalyticalthermalstressintensityfactors—Part1:thermalintensityfactor.JournalofThermalStresses,2010,33:262–278
[32]LeungAYT,XuXS,ZhouZH.Hamiltonianapproachtoanalyticalthermalstressintensityfactors—Paret2:thermalstressintensityfactor.JournalofThermalStresses,2010,33:279–301
[33]ZhouZH,XuXS,LeungAYT.ModeIIIedge-crackinmagneto-electro-elasticmediabysymplecticexpansion.EngineeringFractureMechanics,2010,77:3157–3173
[34]ZhangWX,XuXS,YuanF.Thesymplecticsystemmethodinthestressanalysisof2Delasto-viscoelasticfiberreinforcedcomposites.ArchApplMech,2010,80:829-841
[35]ZhouZH,WongKW,XuXS,LeungAYT.NaturalvibrationofcircularandannularthinplatesbyHamiltonianapproach.JournalofSoundandVibration,2010,330:1005–1017
[36]SunFM,BianYN,ArimaH,IkegamiY,XuXS.Strengthcharacteristicsoftheself-sustainedwaveingroovedchannelswithdifferentgroovelength.HeatMassTransfer,2010,46:1229–1237
[37]LimCW,XuXS.SymplecticElasticity:TheoryandApplications.AppliedMechanicsReviews.2010,63/050802-1-050802-10
[38]ZhouZH,XuXSandLeungAYT.AnalyticalModeIIIelectromagneticpermeablecracksinmagnetoelectroelasticmaterials.Computers&Structures,2011,89:631-645
[39]ZhouZH,XuXS,LeungAYT.TransientthermalstressintensityfactorsforModeIedge-cracks.NuclearEngineeringandDesign.2011,241:3613-3623
[40]XuXS,ZhangG,ZengQC,ChuHJ,BambooNode-TypeLocalBucklingofCylindricalShellsUnderAxialImpact.AdvancesinVibrationEngineering,2011,10(1):41-52
[41]ZhouZH,WongKW,XuXS,LeungAYT.NaturalvibrationofcircularandannularthinplatesbyHamiltonianapproach.JournalofSoundandVibration.2011,330(5):1005-1017
[42]SunJB,XuXS,LimCW.DynamicBucklingofCylindricalshellsunderAxialImpactinHamiltonianSystem.Int.J.NonlinearSci.Numer.Simul,2012(13):93-97.
[43]ZhangWX,XuXS,Thesymplecticapproachfortwo-dimensionalthermo-viscoelasticanalysis,InternationalJournalofEngineeringScience2012,50:56-69
[44]WuYF,XuXS,SunJB,JiangC.Analyticalsolutionforthebondstrengthofexternallybondedreinforcement.CompositeStructures.2012,94:3232-3239
[45]DongJZ,XuXS,ZhangY.NonlinearWavesDrivenbyMotionalPlatesinShallowTwo-LayerFluid.AdvncesinVibrationEngineering,2012,11(4):389-402
[46]XuXS,SunJB,LimCW,DynamictorsionalbucklingofcylindricalshellsinHamiltoniansystem,Thin-WalledStructures64(2013)23-30
[47]SunJB,XuXS,LimCW,TanVBC.Anenergyconservativesymplecticmethodologyforbucklingofcylindricalshellsunderaxialcompression,ActaMech,224(2013),1579-1592
[48]SunJB,XuXS,LimCW.Localizationofdynamicbucklingpatternsofcylindricalshellsunderaxialimpact,InternationalJournalofMechanicalSciences66(2013)101-108
[49]ZhouZH,XuXS,LeungAYT,HuangY.StressintensityfactorsandT-stressforanedgeinterfacecrackbysymplecticexpansion.EngineeringFractureMechanics102(2013)334-347
[50]SunJB,XuXS,LimCW.Accuratesymplecticspacesolutionsforthermalbucklingoffunctionallygradedcylindricalshells.Composites:PartB55(2013)208-214
[51]SunJB,XuXS,LimCW.Torsionalbucklingoffunctionallygradedcylindricalshellswithtemperature-dependentproperties.InternationalJournalofStructuralStabilityandDynamics,2014,14(1):1350048-1–23.
[52]ZhouZH,XuXS,LeungAYT.Thefiniteelementdiscretizedsymplecticmethodforinterfacecracks,CompositesPartB,2014,58:335–342.
[53]SunJB,XuXS,LimCW.Bucklingoffunctionallygradedcylindricalshellsundercombinedthermalandcompressiveloads.JournalofThermalStresses,2014,37:340-362
[54]SunJB,XuXS,LimCW.BucklingofcylindricalshellsunderexternalpressureinaHamiltoniansystem.JournalofTheoreticalandAppliedMechanics.2014,52(3):641-653
[55]LeungAYT,ZhouZH,XuXS,Determinationofstressintensityfactorsbythefiniteelementdiscretizedsymplecticmethod,InternationalJournalofSolidsandStructures,2014,51,1115-1122.
[56]ZhouZH,AYTLeung,XuXS,LuoXW,Mixed-modethermalstressintensityfactorsfromthefiniteelementdiscretizedsymplecticmethod,InternationalJournalofSolidsandStructures,2014,51(21):3798-3806.
[57]XuCH,ZhouZH,XuXS,LeungAYT,FractureanalysisofmodeIIIcrackproblemsforthepiezoelectricbimorph,ArchiveofAppliedMechanics,2014,84(7),1057-1079.
[58]JiabinSun,XinshengXu,C.W.Lim,WeiyuQiao.AccuratebucklinganalysisforsheardeformableFGMcylindricalshellsunderaxialcompressionandthermalloads.CompositeStructures,2015,123:246-256
[59]XuXS,ChengXH,ZhouZH,XuCH,Ananalyticalapproachforthemixed-modecrackinlinearviscoelasticmedia,EuropeanJournalofMechanicsA/Solids,2015,52:12-25
[60]XuCH,ZhouZH,XuXS,Electroelasticsingularitiesandintensityfactorsforaninterfacecrackinpiezoelectric-elasticbimaterials,AppliedMathematicalModelling.2015,39:2721-2739
[61]ZhouZH,XuCH,XuXS,LeungAYT,Thefiniteelementdiscretizedsymplecticmethodforthesteady-stateheatconductionwithsingularitiesincompositestructures,NumericalHeatTransfer,PartB:Fundamentals.2015,67:302-319
[62]XuCH,ZhouZH,LeungAYT,XuXS,LuoXW.ThefiniteelementdiscretizedsymplecticmethodforcompositemodeIIIcracks.EngineeringFractureMechanics.2015,140:43-60
[63]XuCH,ZhouZH,XuXS,EvaluationofmodeIIIinterfacecracksinmagnetoelectroelasticbimaterialsbysymplecticexpansion,Journalofintelligentmaterialsystemsandstructures,2015,26(11):1417-1441
[64]SunJB,LimCW,XuXS,MaoH.Accuratebucklingsolutionsofgrid-stiffenedfunctionallygradedcylindricalshellsundercompressiveandthermalloads.CompositesPartB,2016,89:96-107
[65]SunJB,LimCW,ZhouZH,XuXS,SunW.Rigorousbucklinganalysisofsize-dependentfunctionallygradedcylindricalnanoshells,JournalofAppliedPhysics,119,214303(2016)
[66]SunJB,XuXS,LimCW,ZhouZH,XiaoSY,Accuratethermo-electro-mechanicalbucklingofsheardeformablepiezoelectricfiber-reinforcedcompositecylindricalshells,CompositeStruct.,141,221-231,2016.
[67]QiuWB,ZhouZH,XuXS,Thedynamicbehaviorofcircularplatesunderimpactloads,JournalofVibrationEngineeringandTechnologies,2016,4(2):111-116
[68]SunJB,XuXS,LimCW,Combinedloadbucklingforcylindricalshellsbasedonasymplecticelasticityapproach,JournalofTheoreticalandAppliedMechanics,2016,54(3):705-716
[69]XuW,TongZZ,LeungAYT,XuXS,ZhouZH,EvaluationofthestresssingularityofaninterfaceV-notchinabimaterialplateunderbending,EngineeringFractureMechanics,2016,168:11-25
[70]HuJL,XuXS.Fast-startcontrolofbionicfishusinggiantmagnetostrictivematerials.JournalofVibrationEngineering&Technologies,2017,5(2):207-211
[71]XuXS,TongZZ,RongDL,ChengXH,XuCH,ZhouZH.Fractureanalysisofmagnetoelectroelasticbimaterialswithimperfectinterfacesbysymplecticexpansion,AppliedMathematicsandMechanics,2017,38(8):1043-1058.

[教育背景]
1992.11995.12大连广播电视大学（自考）工业电气自动化
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