姓 名：李小武         教授/博士生导师   系主任

性 别: 男         出生日期：    1969年08 月08 日

办公电话： 024-83678479       Email：xwli@mail.neu.edu.cn

1. 学习简历

1988年09月 ── 1992年07月   南昌大学物理系，理学学士

1992年09月 ── 1995年07月   中国科学院金属研究所材料疲劳与断裂国家重点实验室，工学硕士

1995年09月 ── 1998年06月   中国科学院金属研究所材料疲劳与断裂国家重点实验室，工学博士

2. 工作简历

1998年07月 ── 2000 年08月   中国科学院金属研究所材料疲劳与断裂国家重点实验室，助理研究员

2000年09月 ── 2002 年09月   日本大阪大学工学部材料科学与工程系，JSPS特别研究员

2002年10月 ── 2004 年02月   德国亚琛工业大学物理冶金与金属物理研究所，“洪堡”学者

2004年03月 ── 2005 年10月   日本大阪大学工学部材料科学与工程系，COE特任教员

2005年11月 ── 2015年11月   东北大学理学院，教授/博士生导师

2015年12月 ── 至今   东北大学美高梅mgm1888-官方网站-App Store，教授/博士生导师

3．学术兼职

（1）中国材料研究学会理事

（2）中国材料研究学会疲劳分会理事

（3）国际SCI杂志Journal of Materials Science and Technology (JCR: Q1) 编委

（4）担任40余种国内外知名SCI和EI杂志的审稿专家

（5）美国国家科学基金会(NSF)国际研究计划项目、荷兰材料基础研究基金会（FOM）项目的国际评审专家，以及国家自然科学奖（材料科学组）会评专家等

4．研究方向

（1）金属晶体的循环形变行为及微观变形机制：纯金属和合金单晶体、含沉淀相的双相合金单晶体以及各种多晶材料

（2）金属材料的强韧化及微观机理：重点关注晶界工程优化、层错能、短程有序、第二相、摩擦应力等的影响

（3）先进结构材料的（疲劳）变形与断裂：剧烈塑性变形制备的超细晶材料、高氮奥氏体不锈钢、铁素体不锈钢、轻量化低密度钢、高熵合金等

（4）生物仿生材料的微观结构、力学行为及强韧化机理：天然生物材料（贝壳、珊瑚等）以及人工仿生材料

（5）用于组织工程的生物活性陶瓷复合材料和陶瓷-金属复合材料

5．近年来承担的科研项目

自2005年底回国工作以来，作为项目负责人承担20余项科研项目资助，其中国家级项目8项，省部级项目10项，包括国家自然科学基金面上项目6项等。

代表性项目有：

（1）国家自然科学基金面上项目：“晶界特征分布优化改善含氮奥氏体不锈钢低周疲劳性能研究”，2019.01-2022.12，负责人

（2）国家自然科学基金面上项目：“Cu-Mn和Cu-Ni系列合金的疲劳变形行为及其微观机制：层错能和短程有序的综合影响”，2016.01-2019.12，负责人

（3）国家自然科学基金面上项目：“预低周疲劳变形对金属单晶体静态力学行为影响的机理性研究”，2013.01-2016.12，负责人

（4）国家自然科学基金重点项目：“金属材料复杂服役条件下三维多尺度应力场演化与损伤机制关联性研究”，2013.01-2017.12，子课题负责人

（5）国家自然科学基金面上项目：“面心立方金属晶体疲劳位错结构的热稳定性研究”，2011.01-2013.12，负责人

（6）国家自然科学基金面上项目：“含富Cr沉淀颗粒Fe-Cr不锈钢单晶体的循环形变及损伤行为”，2008.01-2010.12，负责人

（7）国家自然科学基金面上项目：“超细晶金属材料疲劳与断裂行为的温度效应”，2007.01-2009.12，负责人

（8）高等学校博士学科点专项科研基金博导类资助课题：“具有不同层错能的面心立方金属低周疲劳锻炼强韧化机制的研究”，2012.01-2014.12，负责人

（9）教育部新世纪优秀人才支持计划项目：“几种先进结构材料的制备及其疲劳与断裂行为研究”，2008.01-2010.12，负责人

（10）中央高校基本科研业务费项目–创新团队建设项目：“先进结构材料的制备及力学行为研究”，2012.01-2014.12，负责人

6. 获奖及荣誉

（1）中国科学院院长优秀奖学金（1995年），

（2）中国科学院金属研究所所长一等奖学金（1998年）

（3）日本学术振兴会（JSPS）博士后研究奖学金（2000-2002年）

（4）德国“洪堡”（AvH）研究奖学金（2002-2004年）

（5）中国辽宁省自然科学二等奖（2004年）

（6）中国金属学会优秀论文奖，即第二届科协期刊优秀学术论文奖（2004年）

（7）入选中国教育部“新世纪优秀人才支持计划”（2007年）

（8）入选辽宁省“百千万人才工程”百人层次（2007年）

（9）“沈阳市十大杰出青年创新人才”与“沈阳市五四奖章”（2008年）

（10）2006-2008和2014-2016学年度东北大学优秀教师（2008年和2016年）

（11）《金属学报》（中、英文版）优秀审稿专家（2009年）

（12）东北大学本科生毕业论文校优秀指导教师（2013和2017年）

（13）辽宁省和沈阳市自然科学学术成果奖一等奖（2015年和2017年）

（14）方大钢铁奖教金（2016年）

（15）沈阳市高层次领军人才（2017年）

（16）2016-2018年度东北大学“三育人”先进个人（2018年）

（另：指导的研究生曾荣获各类学术奖励60余人次）

7. 学术论文与专利

已在Acta Mater., Scripta Mater., ACS Appl. Mater. Interfaces, PNAS, Nanoscale, J. Phys. Chem. Lett., Sci. Rep., Phil. Mag., Metall. Mater. Trans. A, J. Am. Ceram. Soc., Corros. Sci., J. Alloys Compd., Mater. Sci. Eng. A (or C), JMBBM等国内外有影响的学术期刊和会议上发表论文230余篇（不含会议摘要160余篇），其中SCI收录160余篇，EI收录35篇，第一作者或通讯作者论文170余篇。发表的文章被SCI引用近2000次。有关研究成果曾先后被邀请在国内外重要学术会议上做邀请报告近40次。

代表性论文有：

1.Li, X.W.^ (2013): Monotonic and Cyclic Deformation in Single Crystal. In: The Encyclopedia of Tribology (Chapter No. 248), p. 2313-2323. eds. Q. Jane Wang and Yip-Wah Chung, Springer Science+Business Media, New York 2013. (Invited)

2.Han, D., Zhang, Y.J. and Li, X.W.^(2021): A Crucial Impact of Short-Range Ordering on the Cyclic Deformation and Damage Behavior of Face-centered Cubic Alloys: A Case Study on Cu-Mn Alloys.Acta Mater., 205, 116559.

3.Guan, X.J., Shi, F., Ji, H.M. and Li, X.W.^(2020): A Possibility to Sychronously Improve the High-Temperature Strength and Ductility in Face-Centered Cubic Metals Through Grain Boundary Engineering.Scripta Mater., 187, 216-220.

4.Zhang, Y.J. Han, D., Li, X.W.^(2020): A Unique Two-stage Strength-Ductility Match in Low-Solution-Hardening Ni-Cr Alloys: Decisive Role of Short Range Oridering.Scripta Mater.,178, 269-273.

5.Xu, Q., Jiang, J.L., Xie, H.P., Liu, Y.N., Cao, L., Li, X.W.^, Tian, J.^ and Zhang, X.^(2020): Novel Injectable and Self-setting Composite Materials for Bone Defect Repair.Sci. China Mater.,63, No. 5, 876-887.

6.Liang, S.M., Ji, H.M., Li, X.W.^(2020): Thickness-dependent Mechanical Properties of Nacre in Cristaria plicata Shell: Critical Role of Interfaces.J. Mater. Sci. Technol.,44, 1-8.

7.Ji, H.M., Liang, S.M., Li, X.W.^ and Chen, D.L.^(2020): Kinking and Cracking Behavior in Nacre under Stepwise Compressive Loading.Mater. Sci. Eng. C,108, 110364.

8.Ji, H.M., Yang, W., Chen, D.L. and Li, X.W.^(2020): Natural Arrangement of Fiber-like Aragonites and Its Impact on Mechanical Behavior of Mollusk Shells: A Review.J. Mech. Behav. Biomed. Mater.,110, 103941 (Pages 1-23). (Invited)

9.Yan, Y., Liu, Y.L., Liu, M.Q., Han, D. and Li, X.W.^(2020): Thickness-dependent Mechanical Behavior of <111>-oriented Cu Single Crystals. Metall. Mater. Trans. A, 51, 2044-2052.

10.Guan, X.J., Shi, F., Jia, Z.P., Li, X.W.^(2020): Grain Boundary Engineering of AL6XN Super-austenitic Stainless Steel: Distinctive Effects of Planar-Slip Dislocations and Deformation Twins.Mater. Charact.,170, 110689.

11.Shi, F., Gao, R.H., Guan, X.J., Liu, C.M.andLi, X.W.^,(2020): Application of Grain Boundary Engineering to Improve Intergranular Corrosion Resistance in a Fe-Cr-Mn-Mo-N High-nitrogen and Nickel-free Austenitic Stainless Steel.Acta Metall. Sin. (Engl. Lett.), 33, No. 6, 789-798. (封面文章)

12.Guan, X.J., Shi, F., Ji, H.M., Li, X.W.^(2019): Gain Boundary Character Distribution Optimization of Cu-16at.%Al Alloy by Thermomechanical Process: Critical Role of Deformation Microstructure.Mater. Sci. Eng. A, 765, 138299.

13.Ji, H.M., Li, X.W.^ and Chen, D.L.^(2019): Crack Initiation and Growth in a Special Quasi-sandwich Crossed-lamellar Structure in Cymbiola nobilis Seashell.J. Mech. Behav. Biomed. Mater., 90, 104-112.

14.Han, D., Guan, X.J., Yan, Y., Shi, F. and Li, X.W.^(2019): Anomalous Recovery of Working Hardening Rate in Cu-Mn Alloys with High Stacking Fault Energies under Uniaxial Compression.Mater. Sci. Eng. A, 743, 745-754.

15.Li, R.G., Xie, Q.G., Wang, Y.D.^, Liu, W.J.^, Wang, M.G., Wu, G.L., Li, X.W., Zhang, M.H., Lu, Z.P., Geng, C. and Zhu, T.^(2018): Unraveling Submicron-scale Mechanical Heterogeneity by Three-dimensional X-ray Micro-diffraction.PNAS, 115, 483-488.

16.Wang, X., Ji, H.M. and Li, X.W.^(2018): Microstructure-related in vitro Bioactivity of a Natural Ceramic of Saxidomus purpuratus Shell.Mater. Des., 139, 512-520.

17.Ji, H.M., Li, X.W.^ and Chen, D.L.^(2018): Deformation and Fracture Behavior of a Natural Shell Ceramic: Coupled Effects of Shell Shapes and Microstructures.Mater. Sci. Eng. C, 90, 557-567.

18.Zhang, H.W., Qin, X.Z.^, Wu, Y.S., Zhou, L.Z. andLi, X.W.^ (2018): Effect of Cr Content on the Microstructures and Stress Rupture Properties of a Directionally Solidified Ni-based Superalloy During Long-term Exposure. Mater. Sci. Eng. A, 718, 449-460.

19.Zhang, H.W., Qin, X.Z., Li, X.W.^and Zhou, L.Z.^(2018): Effect of Minor additions on the Microstructures and Stress Rupture Properties of a Directionally Solidified Ni-based Superalloy. Mater. Sci. Eng. A, 711, 303-312.

20.Zhang, H.W., Wu, Y.S., Qin, X.Z.^, Zhou, L.Z. andLi, X.W.^ (2018): Microstructures and Mechanical Properties of a Directionally Solidified Ni-based Superalloy: Influence of Boron Content. J. Alloys Compd., 767, 915-923.

21.Ji, H.M., Li, X.W.^ and Chen, D.L.^(2018): A Self-assembled Smart Architecture against Drilling Predation in a Pinctada maxima Shell: Protective Mechanisms.J. Mater. Sci.,53, 3417-3426.

22.Hou, J.P.^, Chen, Q.Y., Wang, Q., Yu, H.Y., Zhang, Z.J., Li, R., Li, X.W.^ and Zhang, Z.F. (2018): Interface Characterization and Performances of a Novel Pure Al Clad Al Alloy Wire. Adv. Eng. Mater., 20, No. 8, 1800082 (Pages 1-6).

23.Li, X.W.^, Ji, H.M., Yang, W., Zhang, G.P. and Chen, D.L. (2017): Mechanical Properties of Crossed-lamallar Structures in Biological Shells: A Review.J. Mech. Behav. Biomed. Mater., 74, 54-71.(Invited)

24.Han, D., Wang, Z.Y., Yan, Y., Shi, F. and Li, X.W.^(2017): A Good Combination of Strength and Ductility in Cu-Mn Alloys with High Stacking Fault Energies: Determinant Effect of Short Range Ordering.Scripta Mater., 133, 59-64.

25.Wang, Z.Y., Han, D. and Li, X.W.^(2017): Competitive Effect of Stacking Fault Energy and Short-range Clustering on the Plastic Deformation Behavior of Cu-Ni Alloys.Mater. Sci. Eng. A, 679, 484-492.

26.Yan, Y., Qi, C.J., Han, D., Ji, H.M., Zhang, M.Q. and Li, X.W.^(2017): Effect of Low-Cycle Fatigue Pre-deformation on Uniaxial Tensile Behavior of Cu-16at.%Al Alloy with Low Stacking Fault Energy.Metall. Mater, Trans. A, 48, 678-684.

27.Ji, H.M., Li, X.W.^ and Chen, D.L.^(2017): Cymbiola nobilis Shell: Toughening Mechanisms in a Crossed-Lamellar Structure.Scientific Reports, 7, 40043.

28.Qin, X.M., Wu, Y.Q., Liu, Y.^, Chi, B.Q.,Li, X.W.^, Wang, Y. and Zhao, X.L. (2017): Origins ofDirac Cone Formation in AB₃ and A₃B (A, B= C, Si, and Ge) Binary Monolayers. Scientific Reports, 7, 10546.

29.Chi, B.Q., Liu, Y.^, Li, X.W.^, Qin, X.M. and Zhao, X.L. (2017): Exceptional Ring Topology Makes Diamond Allotropes as Light-weight Superhard Materials. Diamond and Related Materials, 80, 140-146.

30.Zhang, L., Li, X.W.^, Zhang, L.L.^, Song, Z.Y., Long, W., Jin, Y. and Wang, L. (2017): Effects of La Doping on Electrical Conductivity, Thermal Expansion and Electrochemical Performance in La_xSr_1-xCo_0.9Sb_0.1O_3-δ Cathodes for IT-SOFCs. Ceram. Inter., 43, No. 8, 6487-6493.

31.Liu, M.Q., Liu, Y.L., Yan, Y., Han, D. and Li, X.W.^(2017): Thickness-Dependent Tensile and Fatigue Behavior of a Single-Slip-Oriented Cu Single Crystal.Cryst. Res. Tech., 52, No. 12, 1700178.

32.Qin, X.M., Liu, Y.^, Chi, B.Q.,Zhao, X.L. and Li, X.W.^(2016): Origin of Dirac Conesand Pairity Dependent Electronic Structures of -graphyne Derivatives and Silagraphynes. Nanoscale, 8, 15223-15232.

33.Li, X.W.^, Wang, X.M., Yan, Y., Guo, W.W. and Qi, C.J. (2016): Effect of Pre-fatigue on the Monotonic Deformation Behavior of a Coplanar Double-Slip-Oriented Cu Single Crystal.Metals, 6, 293.

34.Shi, F., Tian, P.C., He, Z.H., Jia, N., Qi, Y., Liu, C.M.andLi, X.W.^,(2016): Improving Intergranular Corrosion Resistance in a High-Nitrogen Austenitic Stainless Steel Through Grain Boundary Character Distribution Optimization.Corros. Sci., 107, 49-59.

35.Shao, C.W., Shi, F. and Li, X.W.^(2016): Influence of Cyclic Stress Amplitude on Mechanisms of Deformation of a High Nitrogen Austenitic Stainless Steel.Mater. Sci. Eng. A, 667, 208-216.

36.Yan, Y., Deng, W.P., Gao, Z.F., Zhu, J., Wang, Z.J. and Li, X.W.^(2016): Coupled Influence of Temperature and Strain Rate on Tensile Deformation Characteristics of Hot-Extruded AZ31 Magnisum Alloy.Acta Metall. Sin. (Engl. Lett.), 29, No. 2, 163-172.

37.Ji, H.M., Jiang, Y., Yang, W., Zhang, G.P. and Li, X.W.^(2015): Biological Self-Arrangement of Fiber Like Aragonite and Its Effect on Mechanical Behavior of Veined rapa whelk Shell.J. Am. Ceram. Soc., 98, 3319-3325.

38.Wang, B, Duan, Q.Q., Yao, G., Pang, J.C., Zhang, Z.F., Wang, L. and Li, X.W.^ (2015): Fatigue Fracture Behavior of Spot Welded Hot-stamped Steels under Tensile-Shear Load. Fat. Fract. Eng. Mater. Struct., 38, 914-922.

39.Qin, X.M., Liu, Y.^,Li, X.W.^, Xu, J.C., Chi, B.Q.,Zhai, D. and Zhao, X.L. (2015): Origin of Dirac Cones in SiC Siligraphene: A Combined Density Functional and Tight-Binding Study.J. Phys. Chem. Lett., 6, 1333-1339.

40.Shao, C.W., Shi, F., and Li, X.W.^(2015): Cyclic Deformation Behavior of Fe-18Cr-18Mn-0.63N Nickel-Free High Nitrogen Austenitic Stainless Steel. Metall. Mater. Trans. A, 46, 1610-1620.

41.Ji, H.M. and Li, X.W.^(2014): Microstructural Characteristic and Its Relation to Mechanical Properties of Clinocardium californiense Shell.J. Am. Ceram. Soc., 97, 3991-3998.

42.Li, X.W.^, Peng, N., Wu, X.M.. and Wang, Z.G. (2014): Plastic-Strain-Amplitude Dependence of Dislocation Structures in Cyclically Deformed <112>-Oriented Cu-7at.%Al Alloy Single Crystals.Metall. Mater. Trans. A, 45, 3835-3843.

43.Zhang, X., Li, X.W.^, Li, J.G. and Sun, X.D. (2014): Preparation and Properties of a Novel Biodegradable 3D Porous Magnesium Scaffold for Bone Tissue Engineering. Mater. Sci. Eng. C, 42, 362-367.

44.Ji, H.M., Zhang, W.Q. and Li, X.W.^(2014): Fractal Analysis of Microstructures-Related Indentation Toughness of Clinocardium californiense Shell.Ceram. Inter., 40, 7627-7631.

45.Yan, Y., Lu, M., Guo, W.W. and Li, X.W.^ (2014): Effect of Pre-fatigue Deformation on the Thickness-Dependent Tensile Behavior of Coarse-Grained Pure Aluminum Sheets. Mater. Sci. Eng. A, 600, 99-107.

46.Zhang, X., Li, X.W.^, Li, J.G. and Sun, X.D. (2014): Preparation and Characterizations of Bioglass Ceramic Cement/Ca-P Coating on Pure Magnesium for Biomedical Applications. ACS Appl. Mater. Interface, 6, 513-525.

47.Li, X.W.^, Wang, X.M., Guo, W.W., Qi, C.J. and Yan, Y. (2013): Effect of Cyclic Pre-deformation on the Uniaxial Tensile Deformation Behavior of [017] Copper Single Crystals Oriented for Critical Double Slip.Metall. Mater. Trans. A, 44, 1631-1635.

48.Yan, Y.^, Jin. W. and Li, X.W.^(2013): Texture Development in the Ni47Ti44Nb9 Shape Memory Alloy during Successive Thermo-Mechanical Processing and Its Effect on Shape Memory and Mechanical Properties. Metall. Mater. Trans. A, 44, 978-989.

49.Zhang, X., Li, X.W.^, Li, J.G. and Sun, X.D. (2013): Processing, Microstructures and Mechanical Properties of Biomedical Magnesium with a Specific Two-Layer Structure. Prog. Nat. Sci.: Mater. Inter., 23, No. 2, 183-189.

50.Li, X.W.^, and Umakoshi, Y. (2012): Dislocation Structures in a Cyclically Deformed Single-Slip-Oriented Fe-35wt.%Cr Alloy Single Crystal Containing Fine Cr-Rich Precipitates. Metall. Mater. Trans. A, 43, 5038-5047.

51.Jiang, Q.W. and Li, X.W.^(2012): Effect of Pre-annealing Treatment on the Compressive Deformation and Damage Behavior of Ultrafine-grained Copper.Mater. Sci. Eng. A, 546, 59-67.

52.Li, X.W.^, Zhang, X., Zhang, P.L., Yasuda, H.Y. and Umakoshi, Y. (2012): Effect of Sintering Temperature on the Structure and Bioactivity of HAp-5wt.%SO₂ Bioceramic Composites. Mater. Tech., 27, No. 1, 46-48.

53.Yang, W., Zhang, G.P., Liu, H.S. and Li, X.W.^(2011): Microstructural Charaterization and Hardness Behavior of a Biological Saxidomus Purpuratus Shell.J. Mater. Sci. Tech., 27, 139-146.

54.Li, X.W.^, Zhou, Y. Guo, W.W. and Zhang, G.P. (2009): Characterization of Dislocation Structures in [-111] Copper Single Crystals Using Electron Channeling Contrast Technique in SEM.Cryst. Res. Tech., 44, 315-321.

55.Li, X.W.^, Jiang, Q.W., Liu Y. and Wang, Y. (2009): Effect of Strain Rate on the High-Temperature Compressive Deformation Behavior of Ultrafine-Grained Copper. Inter. J. Mod. Phys. B, 23, No. 6-7, 1758-1763.

56.Li, P., Zhang, Z.F., Li, X.W., Li, S.X. and Wang, Z.G. (2009): Effect of Orientations on the Cyclic Deformation Behavior of Silver Single Crystals: Comparison with the Behavior of Copper and Nickel Single Crystals. Acta Mater., 57, 4845-4854.

57.Yu, Z.Y., Jiang, Q.W. and Li, X.W.^(2008): Temperature-Dependent Plastic Deformation and Damage Behavior of Ultrafine-Grained Copper under Uniaxial Compression.Phys. Stat. Sol. (a), 205, 2417-2421.

58.Li, X.W.^, Jiang, Q.W., Wu, Y., Wang, Y. and Umakoshi, Y. (2008): Stress-Amplitude-Dependent Deformation Characteristics and Microstructures of Cyclically Stressed Ultrafine-Grained Copper.Adv. Eng. Mater., 10, 720-726.

59.Li, X.W.^ and Umakoshi, Y. (2008): Fatigue Fracture Behavior of a Single-Slip-Oriented Fe-35wt.%Cr Alloy Single Crystals Containing Fine-Scale Cr-Rich Precipitates. Mater. Sci. Eng. A, 483-484, 426-429.

60.Li, X.W.^and Zhou, Y. (2007): SEM-ECC Observations of Dislocation Structures in a Cyclically Deformed CuSingle Crystal Oriented for [223] Conjugate Double Slip. J. Mater. Sci., 42, 4716-4719.

61.Li, X.W.^, Yasuda, H.Y. and Umakoshi, Y. (2006): Bioceramic Composites Sintered From Hydroxyapatite and Silica at 1200C: Preparation, Microstructures and Bone-Like Layer Growth in Stimulated Body Fluid. J. Mater. Sci.: Mater. Med., 17, 573-581.

62.Li, X.W.^, Wu, S.D., Wu, Y., Yasuda, H.Y. and Umakoshi, Y. (2005): Temperature-Dependent Microstructures in Fatigued Ultrafine-Grained Copper Produced by Equal Channel Angular Pressing. Adv. Eng. Mater., 7, 829-833.

63.Li, X.W.^, Umakoshi, Y., Wu, S.D., Wang, Z.G., Alexandrov, I.V. and Valiev, R.Z. (2004): Temperature Effects on the Fatigue Behavior of Ultrafine-Grained Copper Produced by Equal Channel Angular Pressing.Phys. Stat. Sol. (a), 201, R119-R122.

64.Li, X.W.^ and Umakoshi, Y. (2003): Cyclic Deformation Behavior of A Single-Slip-Oriented Fe-35wt.%Cr Alloy Single Crystals Containing Fine Cr-Rich Precipitates.Scripta Mater., 48, 545-550.

65.Li, X.W.^, Wu, X.M., Wang, Z.G. and Umakoshi, Y. (2003): Orientation Dependence of Dislocation Structures in Cyclically Deformed Cu-16 At. Pct Al Alloy Single Crystals.Metall. Mater. Trans. A,34A, 307-318.

66.Li, X.W.^, Wu, X.M., Wang, Z.G. and Umakoshi, Y. (2002): Dislocation Structure in a Fatigued Cu-16at.%Al Alloy Single Crystals Oriented for Double Slip.Phys. Stat. Sol. (a),192, R1-R3.

67.Li, X.W.^, Umakoshi, Y., Gong, B., Li, S.X. and Wang, Z.G. (2002): Dislocation Structure in Fatigued Critical and Conjugate Double-Slip-Oriented Copper Single Crystals.Mater. Sci. Eng. A,333, 51-59.

68.Li, X.W.^, Wang, Z.G., Zhang, Y.W., Li, S.X. and Umakoshi, Y. (2002): Dislocation Structure in Cyclically Deformed Coplanar Double-Slip-Oriented Copper Single Crystals. Phys. Stat. Sol. (a),191, 97-105.

69.Li, X.W.^, Y. Umakoshi, Wang, Z.G. and Li, S.X. (2001): The Fatigue Limits of Copper Single Crystals Cyclically Deformed at Constant Plastic Strain Amplitudes. Phil. Mag. Lett., 81, 465-472.

70.Li, X.W.^, Wang, Z.G. and Li, S.X. (2000): Deformation Bands in Cyclically Deformed Copper Single Crystals. Phil. Mag. A, 80, 1901-1912.

71.Li, X.W.^, Wang, Z.G. and Li, S.X. (1999): Influence of Crystallographic Orientation on Cyclic Strain-Hardening Behavior of Copper Single Crystals. Phil. Mag. Lett., 79, 869-875.

72.Li, X.W.^, Wang, Z.G. and Li, S.X. (1999): Survey of Plateau Behavior in the Cyclic Stress-Strain Curve of Copper Single Crystals. Phil. Mag. Lett., 79, 715-719.

73.Li, X.W.^, Wang, Z.G. and Li, S.X. (1999): Cyclic Deformation Behavior of Double-Slip-Oriented Copper Single Crystals IV. Change of Hysteresis Loop Shape and Formation of Persistent Slip Band.Mater. Sci. Eng. A, 271, 315-321.

74.Li, X.W.^, Wang, Z.G. and Li, S.X. (1999): Cyclic Deformation Behavior of Double-Slip-Oriented Copper Single Crystals III. Conjugate Double Slip Orientation on 0010-Side in the Stereographic Triangle. Mater. Sci. Eng. A, 269, 166-174.

75.Li, X.W.^, Wang, Z.G. and Li, S.X. (1999): Cyclic Deformation Behavior of Double-Slip-Oriented Copper Single Crystals II. Critical Double Slip Orientation on 001-011 Side in the Stereographic Triangle. Mater. Sci. Eng.A, 265, 18-24.

76.Li, X.W.^, Wang, Z.G. and Li, S.X. (1999): Cyclic Deformation Behavior of Double-Slip-Oriented Copper Single Crystals I. Coplanar Double Slip Orientation on 011-Side in the Stereographic Triangle. Mater. Sci. Eng.A, 260, 132-138.

77.Li, X.W.^, Wang, Z.G., Li, G.Y., Wu, S.D. and Li, S.X. (1998): Cyclic Stress-strain Response and Surface Deformation Features of [011] Multiple-Slip-Oriented Copper Single Crystals. Acta Mater., 46, 4497-4505.

78.Li, X.W.^, Hu, Y.M. and Wang, Z.G. (1998): Investigation of Dislocation Structure in a Cyclically Deformed Copper Single Crystal Using Electron Channeling Contrast Technique in SEM. Mater. Sci. Eng. A, 248, 299-303.

79.Li, X.W.^, Tian, J.F., Han, N.L., Kang, Y. and Wang, Z.G. (1996): Quantitative Study on Correlation between Fracture Surface Roughness and Fatigue Properties of SiC/Al Composite.Mater. Lett.,29, 235-240.

80.Li, X.W.^, Tian, J.F., Kang, Y. and Wang, Z.G. (1995): Quantitative Analysis of Fracture Surface by Roughness and Fractal Method.Scripta Metall. Mater., 33, 803-809.

8. 著作
1. 李小武，颜莹，于宁，石锋 编著，金属材料的界面及其性质，沈阳：东北

大学出版社，2020.12。（ISBN 978-7-5517-2663-4）